xref: /freebsd/contrib/llvm-project/clang/lib/StaticAnalyzer/Checkers/StdLibraryFunctionsChecker.cpp (revision 02e9120893770924227138ba49df1edb3896112a)
1 //=== StdLibraryFunctionsChecker.cpp - Model standard functions -*- 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 checker improves modeling of a few simple library functions.
10 //
11 // This checker provides a specification format - `Summary' - and
12 // contains descriptions of some library functions in this format. Each
13 // specification contains a list of branches for splitting the program state
14 // upon call, and range constraints on argument and return-value symbols that
15 // are satisfied on each branch. This spec can be expanded to include more
16 // items, like external effects of the function.
17 //
18 // The main difference between this approach and the body farms technique is
19 // in more explicit control over how many branches are produced. For example,
20 // consider standard C function `ispunct(int x)', which returns a non-zero value
21 // iff `x' is a punctuation character, that is, when `x' is in range
22 //   ['!', '/']   [':', '@']  U  ['[', '\`']  U  ['{', '~'].
23 // `Summary' provides only two branches for this function. However,
24 // any attempt to describe this range with if-statements in the body farm
25 // would result in many more branches. Because each branch needs to be analyzed
26 // independently, this significantly reduces performance. Additionally,
27 // once we consider a branch on which `x' is in range, say, ['!', '/'],
28 // we assume that such branch is an important separate path through the program,
29 // which may lead to false positives because considering this particular path
30 // was not consciously intended, and therefore it might have been unreachable.
31 //
32 // This checker uses eval::Call for modeling pure functions (functions without
33 // side effets), for which their `Summary' is a precise model. This avoids
34 // unnecessary invalidation passes. Conflicts with other checkers are unlikely
35 // because if the function has no other effects, other checkers would probably
36 // never want to improve upon the modeling done by this checker.
37 //
38 // Non-pure functions, for which only partial improvement over the default
39 // behavior is expected, are modeled via check::PostCall, non-intrusively.
40 //
41 //===----------------------------------------------------------------------===//
42 
43 #include "ErrnoModeling.h"
44 #include "clang/StaticAnalyzer/Checkers/BuiltinCheckerRegistration.h"
45 #include "clang/StaticAnalyzer/Core/BugReporter/BugType.h"
46 #include "clang/StaticAnalyzer/Core/Checker.h"
47 #include "clang/StaticAnalyzer/Core/CheckerManager.h"
48 #include "clang/StaticAnalyzer/Core/PathSensitive/CallEvent.h"
49 #include "clang/StaticAnalyzer/Core/PathSensitive/CheckerContext.h"
50 #include "clang/StaticAnalyzer/Core/PathSensitive/CheckerHelpers.h"
51 #include "clang/StaticAnalyzer/Core/PathSensitive/DynamicExtent.h"
52 #include "llvm/ADT/STLExtras.h"
53 #include "llvm/ADT/SmallString.h"
54 #include "llvm/ADT/StringExtras.h"
55 #include "llvm/Support/FormatVariadic.h"
56 
57 #include <optional>
58 #include <string>
59 
60 using namespace clang;
61 using namespace clang::ento;
62 
63 namespace {
64 class StdLibraryFunctionsChecker
65     : public Checker<check::PreCall, check::PostCall, eval::Call> {
66 
67   class Summary;
68 
69   /// Specify how much the analyzer engine should entrust modeling this function
70   /// to us.
71   enum InvalidationKind {
72     /// No \c eval::Call for the function, it can be modeled elsewhere.
73     /// This checker checks only pre and post conditions.
74     NoEvalCall,
75     /// The function is modeled completely in this checker.
76     EvalCallAsPure
77   };
78 
79   /// Given a range, should the argument stay inside or outside this range?
80   enum RangeKind { OutOfRange, WithinRange };
81 
82   static RangeKind negateKind(RangeKind K) {
83     switch (K) {
84     case OutOfRange:
85       return WithinRange;
86     case WithinRange:
87       return OutOfRange;
88     }
89     llvm_unreachable("Unknown range kind");
90   }
91 
92   /// The universal integral type to use in value range descriptions.
93   /// Unsigned to make sure overflows are well-defined.
94   typedef uint64_t RangeInt;
95 
96   /// Describes a single range constraint. Eg. {{0, 1}, {3, 4}} is
97   /// a non-negative integer, which less than 5 and not equal to 2.
98   typedef std::vector<std::pair<RangeInt, RangeInt>> IntRangeVector;
99 
100   /// A reference to an argument or return value by its number.
101   /// ArgNo in CallExpr and CallEvent is defined as Unsigned, but
102   /// obviously uint32_t should be enough for all practical purposes.
103   typedef uint32_t ArgNo;
104   /// Special argument number for specifying the return value.
105   static const ArgNo Ret;
106 
107   /// Get a string representation of an argument index.
108   /// E.g.: (1) -> '1st arg', (2) - > '2nd arg'
109   static void printArgDesc(ArgNo, llvm::raw_ostream &Out);
110   /// Print value X of the argument in form " (which is X)",
111   /// if the value is a fixed known value, otherwise print nothing.
112   /// This is used as simple explanation of values if possible.
113   static void printArgValueInfo(ArgNo ArgN, ProgramStateRef State,
114                                 const CallEvent &Call, llvm::raw_ostream &Out);
115   /// Append textual description of a numeric range [RMin,RMax] to
116   /// \p Out.
117   static void appendInsideRangeDesc(llvm::APSInt RMin, llvm::APSInt RMax,
118                                     QualType ArgT, BasicValueFactory &BVF,
119                                     llvm::raw_ostream &Out);
120   /// Append textual description of a numeric range out of [RMin,RMax] to
121   /// \p Out.
122   static void appendOutOfRangeDesc(llvm::APSInt RMin, llvm::APSInt RMax,
123                                    QualType ArgT, BasicValueFactory &BVF,
124                                    llvm::raw_ostream &Out);
125 
126   class ValueConstraint;
127 
128   /// Pointer to the ValueConstraint. We need a copyable, polymorphic and
129   /// default initializable type (vector needs that). A raw pointer was good,
130   /// however, we cannot default initialize that. unique_ptr makes the Summary
131   /// class non-copyable, therefore not an option. Releasing the copyability
132   /// requirement would render the initialization of the Summary map infeasible.
133   /// Mind that a pointer to a new value constraint is created when the negate
134   /// function is used.
135   using ValueConstraintPtr = std::shared_ptr<ValueConstraint>;
136 
137   /// Polymorphic base class that represents a constraint on a given argument
138   /// (or return value) of a function. Derived classes implement different kind
139   /// of constraints, e.g range constraints or correlation between two
140   /// arguments.
141   /// These are used as argument constraints (preconditions) of functions, in
142   /// which case a bug report may be emitted if the constraint is not satisfied.
143   /// Another use is as conditions for summary cases, to create different
144   /// classes of behavior for a function. In this case no description of the
145   /// constraint is needed because the summary cases have an own (not generated)
146   /// description string.
147   class ValueConstraint {
148   public:
149     ValueConstraint(ArgNo ArgN) : ArgN(ArgN) {}
150     virtual ~ValueConstraint() {}
151 
152     /// Apply the effects of the constraint on the given program state. If null
153     /// is returned then the constraint is not feasible.
154     virtual ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
155                                   const Summary &Summary,
156                                   CheckerContext &C) const = 0;
157 
158     /// Represents that in which context do we require a description of the
159     /// constraint.
160     enum DescriptionKind {
161       /// Describe a constraint that was violated.
162       /// Description should start with something like "should be".
163       Violation,
164       /// Describe a constraint that was assumed to be true.
165       /// This can be used when a precondition is satisfied, or when a summary
166       /// case is applied.
167       /// Description should start with something like "is".
168       Assumption
169     };
170 
171     /// Give a description that explains the constraint to the user. Used when
172     /// a bug is reported or when the constraint is applied and displayed as a
173     /// note. The description should not mention the argument (getArgNo).
174     /// See StdLibraryFunctionsChecker::reportBug about how this function is
175     /// used (this function is used not only there).
176     virtual void describe(DescriptionKind DK, const CallEvent &Call,
177                           ProgramStateRef State, const Summary &Summary,
178                           llvm::raw_ostream &Out) const {
179       // There are some descendant classes that are not used as argument
180       // constraints, e.g. ComparisonConstraint. In that case we can safely
181       // ignore the implementation of this function.
182       llvm_unreachable(
183           "Description not implemented for summary case constraints");
184     }
185 
186     /// Give a description that explains the actual argument value (where the
187     /// current ValueConstraint applies to) to the user. This function should be
188     /// called only when the current constraint is satisfied by the argument.
189     /// It should produce a more precise description than the constraint itself.
190     /// The actual value of the argument and the program state can be used to
191     /// make the description more precise. In the most simple case, if the
192     /// argument has a fixed known value this value can be printed into \p Out,
193     /// this is done by default.
194     /// The function should return true if a description was printed to \p Out,
195     /// otherwise false.
196     /// See StdLibraryFunctionsChecker::reportBug about how this function is
197     /// used.
198     virtual bool describeArgumentValue(const CallEvent &Call,
199                                        ProgramStateRef State,
200                                        const Summary &Summary,
201                                        llvm::raw_ostream &Out) const {
202       if (auto N = getArgSVal(Call, getArgNo()).getAs<NonLoc>()) {
203         if (const llvm::APSInt *Int = N->getAsInteger()) {
204           Out << *Int;
205           return true;
206         }
207       }
208       return false;
209     }
210 
211     /// Return those arguments that should be tracked when we report a bug about
212     /// argument constraint violation. By default it is the argument that is
213     /// constrained, however, in some special cases we need to track other
214     /// arguments as well. E.g. a buffer size might be encoded in another
215     /// argument.
216     /// The "return value" argument number can not occur as returned value.
217     virtual std::vector<ArgNo> getArgsToTrack() const { return {ArgN}; }
218 
219     /// Get a constraint that represents exactly the opposite of the current.
220     virtual ValueConstraintPtr negate() const {
221       llvm_unreachable("Not implemented");
222     };
223 
224     /// Check whether the constraint is malformed or not. It is malformed if the
225     /// specified argument has a mismatch with the given FunctionDecl (e.g. the
226     /// arg number is out-of-range of the function's argument list).
227     /// This condition can indicate if a probably wrong or unexpected function
228     /// was found where the constraint is to be applied.
229     bool checkValidity(const FunctionDecl *FD) const {
230       const bool ValidArg = ArgN == Ret || ArgN < FD->getNumParams();
231       assert(ValidArg && "Arg out of range!");
232       if (!ValidArg)
233         return false;
234       // Subclasses may further refine the validation.
235       return checkSpecificValidity(FD);
236     }
237 
238     /// Return the argument number (may be placeholder for "return value").
239     ArgNo getArgNo() const { return ArgN; }
240 
241   protected:
242     /// Argument to which to apply the constraint. It can be a real argument of
243     /// the function to check, or a special value to indicate the return value
244     /// of the function.
245     /// Every constraint is assigned to one main argument, even if other
246     /// arguments are involved.
247     ArgNo ArgN;
248 
249     /// Do constraint-specific validation check.
250     virtual bool checkSpecificValidity(const FunctionDecl *FD) const {
251       return true;
252     }
253   };
254 
255   /// Check if a single argument falls into a specific "range".
256   /// A range is formed as a set of intervals.
257   /// E.g. \code {['A', 'Z'], ['a', 'z'], ['_', '_']} \endcode
258   /// The intervals are closed intervals that contain one or more values.
259   ///
260   /// The default constructed RangeConstraint has an empty range, applying
261   /// such constraint does not involve any assumptions, thus the State remains
262   /// unchanged. This is meaningful, if the range is dependent on a looked up
263   /// type (e.g. [0, Socklen_tMax]). If the type is not found, then the range
264   /// is default initialized to be empty.
265   class RangeConstraint : public ValueConstraint {
266     /// The constraint can be specified by allowing or disallowing the range.
267     /// WithinRange indicates allowing the range, OutOfRange indicates
268     /// disallowing it (allowing the complementary range).
269     RangeKind Kind;
270 
271     /// A set of intervals.
272     IntRangeVector Ranges;
273 
274     /// A textual description of this constraint for the specific case where the
275     /// constraint is used. If empty a generated description will be used that
276     /// is built from the range of the constraint.
277     StringRef Description;
278 
279   public:
280     RangeConstraint(ArgNo ArgN, RangeKind Kind, const IntRangeVector &Ranges,
281                     StringRef Desc = "")
282         : ValueConstraint(ArgN), Kind(Kind), Ranges(Ranges), Description(Desc) {
283     }
284 
285     const IntRangeVector &getRanges() const { return Ranges; }
286 
287     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
288                           const Summary &Summary,
289                           CheckerContext &C) const override;
290 
291     void describe(DescriptionKind DK, const CallEvent &Call,
292                   ProgramStateRef State, const Summary &Summary,
293                   llvm::raw_ostream &Out) const override;
294 
295     bool describeArgumentValue(const CallEvent &Call, ProgramStateRef State,
296                                const Summary &Summary,
297                                llvm::raw_ostream &Out) const override;
298 
299     ValueConstraintPtr negate() const override {
300       RangeConstraint Tmp(*this);
301       Tmp.Kind = negateKind(Kind);
302       return std::make_shared<RangeConstraint>(Tmp);
303     }
304 
305   protected:
306     bool checkSpecificValidity(const FunctionDecl *FD) const override {
307       const bool ValidArg =
308           getArgType(FD, ArgN)->isIntegralType(FD->getASTContext());
309       assert(ValidArg &&
310              "This constraint should be applied on an integral type");
311       return ValidArg;
312     }
313 
314   private:
315     /// A callback function that is used when iterating over the range
316     /// intervals. It gets the begin and end (inclusive) of one interval.
317     /// This is used to make any kind of task possible that needs an iteration
318     /// over the intervals.
319     using RangeApplyFunction =
320         std::function<bool(const llvm::APSInt &Min, const llvm::APSInt &Max)>;
321 
322     /// Call a function on the intervals of the range.
323     /// The function is called with all intervals in the range.
324     void applyOnWithinRange(BasicValueFactory &BVF, QualType ArgT,
325                             const RangeApplyFunction &F) const;
326     /// Call a function on all intervals in the complementary range.
327     /// The function is called with all intervals that fall out of the range.
328     /// E.g. consider an interval list [A, B] and [C, D]
329     /// \code
330     /// -------+--------+------------------+------------+----------->
331     ///        A        B                  C            D
332     /// \endcode
333     /// We get the ranges [-inf, A - 1], [D + 1, +inf], [B + 1, C - 1].
334     /// The \p ArgT is used to determine the min and max of the type that is
335     /// used as "-inf" and "+inf".
336     void applyOnOutOfRange(BasicValueFactory &BVF, QualType ArgT,
337                            const RangeApplyFunction &F) const;
338     /// Call a function on the intervals of the range or the complementary
339     /// range.
340     void applyOnRange(RangeKind Kind, BasicValueFactory &BVF, QualType ArgT,
341                       const RangeApplyFunction &F) const {
342       switch (Kind) {
343       case OutOfRange:
344         applyOnOutOfRange(BVF, ArgT, F);
345         break;
346       case WithinRange:
347         applyOnWithinRange(BVF, ArgT, F);
348         break;
349       };
350     }
351   };
352 
353   /// Check relation of an argument to another.
354   class ComparisonConstraint : public ValueConstraint {
355     BinaryOperator::Opcode Opcode;
356     ArgNo OtherArgN;
357 
358   public:
359     ComparisonConstraint(ArgNo ArgN, BinaryOperator::Opcode Opcode,
360                          ArgNo OtherArgN)
361         : ValueConstraint(ArgN), Opcode(Opcode), OtherArgN(OtherArgN) {}
362     ArgNo getOtherArgNo() const { return OtherArgN; }
363     BinaryOperator::Opcode getOpcode() const { return Opcode; }
364     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
365                           const Summary &Summary,
366                           CheckerContext &C) const override;
367   };
368 
369   /// Check null or non-null-ness of an argument that is of pointer type.
370   class NotNullConstraint : public ValueConstraint {
371     using ValueConstraint::ValueConstraint;
372     // This variable has a role when we negate the constraint.
373     bool CannotBeNull = true;
374 
375   public:
376     NotNullConstraint(ArgNo ArgN, bool CannotBeNull = true)
377         : ValueConstraint(ArgN), CannotBeNull(CannotBeNull) {}
378 
379     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
380                           const Summary &Summary,
381                           CheckerContext &C) const override;
382 
383     void describe(DescriptionKind DK, const CallEvent &Call,
384                   ProgramStateRef State, const Summary &Summary,
385                   llvm::raw_ostream &Out) const override;
386 
387     bool describeArgumentValue(const CallEvent &Call, ProgramStateRef State,
388                                const Summary &Summary,
389                                llvm::raw_ostream &Out) const override;
390 
391     ValueConstraintPtr negate() const override {
392       NotNullConstraint Tmp(*this);
393       Tmp.CannotBeNull = !this->CannotBeNull;
394       return std::make_shared<NotNullConstraint>(Tmp);
395     }
396 
397   protected:
398     bool checkSpecificValidity(const FunctionDecl *FD) const override {
399       const bool ValidArg = getArgType(FD, ArgN)->isPointerType();
400       assert(ValidArg &&
401              "This constraint should be applied only on a pointer type");
402       return ValidArg;
403     }
404   };
405 
406   /// Check null or non-null-ness of an argument that is of pointer type.
407   /// The argument is meant to be a buffer that has a size constraint, and it
408   /// is allowed to have a NULL value if the size is 0. The size can depend on
409   /// 1 or 2 additional arguments, if one of these is 0 the buffer is allowed to
410   /// be NULL. This is useful for functions like `fread` which have this special
411   /// property.
412   class NotNullBufferConstraint : public ValueConstraint {
413     using ValueConstraint::ValueConstraint;
414     ArgNo SizeArg1N;
415     std::optional<ArgNo> SizeArg2N;
416     // This variable has a role when we negate the constraint.
417     bool CannotBeNull = true;
418 
419   public:
420     NotNullBufferConstraint(ArgNo ArgN, ArgNo SizeArg1N,
421                             std::optional<ArgNo> SizeArg2N,
422                             bool CannotBeNull = true)
423         : ValueConstraint(ArgN), SizeArg1N(SizeArg1N), SizeArg2N(SizeArg2N),
424           CannotBeNull(CannotBeNull) {}
425 
426     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
427                           const Summary &Summary,
428                           CheckerContext &C) const override;
429 
430     void describe(DescriptionKind DK, const CallEvent &Call,
431                   ProgramStateRef State, const Summary &Summary,
432                   llvm::raw_ostream &Out) const override;
433 
434     bool describeArgumentValue(const CallEvent &Call, ProgramStateRef State,
435                                const Summary &Summary,
436                                llvm::raw_ostream &Out) const override;
437 
438     ValueConstraintPtr negate() const override {
439       NotNullBufferConstraint Tmp(*this);
440       Tmp.CannotBeNull = !this->CannotBeNull;
441       return std::make_shared<NotNullBufferConstraint>(Tmp);
442     }
443 
444   protected:
445     bool checkSpecificValidity(const FunctionDecl *FD) const override {
446       const bool ValidArg = getArgType(FD, ArgN)->isPointerType();
447       assert(ValidArg &&
448              "This constraint should be applied only on a pointer type");
449       return ValidArg;
450     }
451   };
452 
453   // Represents a buffer argument with an additional size constraint. The
454   // constraint may be a concrete value, or a symbolic value in an argument.
455   // Example 1. Concrete value as the minimum buffer size.
456   //   char *asctime_r(const struct tm *restrict tm, char *restrict buf);
457   //   // `buf` size must be at least 26 bytes according the POSIX standard.
458   // Example 2. Argument as a buffer size.
459   //   ctime_s(char *buffer, rsize_t bufsz, const time_t *time);
460   // Example 3. The size is computed as a multiplication of other args.
461   //   size_t fread(void *ptr, size_t size, size_t nmemb, FILE *stream);
462   //   // Here, ptr is the buffer, and its minimum size is `size * nmemb`.
463   class BufferSizeConstraint : public ValueConstraint {
464     // The concrete value which is the minimum size for the buffer.
465     std::optional<llvm::APSInt> ConcreteSize;
466     // The argument which holds the size of the buffer.
467     std::optional<ArgNo> SizeArgN;
468     // The argument which is a multiplier to size. This is set in case of
469     // `fread` like functions where the size is computed as a multiplication of
470     // two arguments.
471     std::optional<ArgNo> SizeMultiplierArgN;
472     // The operator we use in apply. This is negated in negate().
473     BinaryOperator::Opcode Op = BO_LE;
474 
475   public:
476     BufferSizeConstraint(ArgNo Buffer, llvm::APSInt BufMinSize)
477         : ValueConstraint(Buffer), ConcreteSize(BufMinSize) {}
478     BufferSizeConstraint(ArgNo Buffer, ArgNo BufSize)
479         : ValueConstraint(Buffer), SizeArgN(BufSize) {}
480     BufferSizeConstraint(ArgNo Buffer, ArgNo BufSize, ArgNo BufSizeMultiplier)
481         : ValueConstraint(Buffer), SizeArgN(BufSize),
482           SizeMultiplierArgN(BufSizeMultiplier) {}
483 
484     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
485                           const Summary &Summary,
486                           CheckerContext &C) const override;
487 
488     void describe(DescriptionKind DK, const CallEvent &Call,
489                   ProgramStateRef State, const Summary &Summary,
490                   llvm::raw_ostream &Out) const override;
491 
492     bool describeArgumentValue(const CallEvent &Call, ProgramStateRef State,
493                                const Summary &Summary,
494                                llvm::raw_ostream &Out) const override;
495 
496     std::vector<ArgNo> getArgsToTrack() const override {
497       std::vector<ArgNo> Result{ArgN};
498       if (SizeArgN)
499         Result.push_back(*SizeArgN);
500       if (SizeMultiplierArgN)
501         Result.push_back(*SizeMultiplierArgN);
502       return Result;
503     }
504 
505     ValueConstraintPtr negate() const override {
506       BufferSizeConstraint Tmp(*this);
507       Tmp.Op = BinaryOperator::negateComparisonOp(Op);
508       return std::make_shared<BufferSizeConstraint>(Tmp);
509     }
510 
511   protected:
512     bool checkSpecificValidity(const FunctionDecl *FD) const override {
513       const bool ValidArg = getArgType(FD, ArgN)->isPointerType();
514       assert(ValidArg &&
515              "This constraint should be applied only on a pointer type");
516       return ValidArg;
517     }
518   };
519 
520   /// The complete list of constraints that defines a single branch.
521   using ConstraintSet = std::vector<ValueConstraintPtr>;
522 
523   /// Define how a function affects the system variable 'errno'.
524   /// This works together with the \c ErrnoModeling and \c ErrnoChecker classes.
525   /// Currently 3 use cases exist: success, failure, irrelevant.
526   /// In the future the failure case can be customized to set \c errno to a
527   /// more specific constraint (for example > 0), or new case can be added
528   /// for functions which require check of \c errno in both success and failure
529   /// case.
530   class ErrnoConstraintBase {
531   public:
532     /// Apply specific state changes related to the errno variable.
533     virtual ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
534                                   const Summary &Summary,
535                                   CheckerContext &C) const = 0;
536     /// Get a NoteTag about the changes made to 'errno' and the possible bug.
537     /// It may return \c nullptr (if no bug report from \c ErrnoChecker is
538     /// expected).
539     virtual const NoteTag *describe(CheckerContext &C,
540                                     StringRef FunctionName) const {
541       return nullptr;
542     }
543 
544     virtual ~ErrnoConstraintBase() {}
545 
546   protected:
547     ErrnoConstraintBase() = default;
548 
549     /// This is used for conjure symbol for errno to differentiate from the
550     /// original call expression (same expression is used for the errno symbol).
551     static int Tag;
552   };
553 
554   /// Reset errno constraints to irrelevant.
555   /// This is applicable to functions that may change 'errno' and are not
556   /// modeled elsewhere.
557   class ResetErrnoConstraint : public ErrnoConstraintBase {
558   public:
559     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
560                           const Summary &Summary,
561                           CheckerContext &C) const override {
562       return errno_modeling::setErrnoState(State, errno_modeling::Irrelevant);
563     }
564   };
565 
566   /// Do not change errno constraints.
567   /// This is applicable to functions that are modeled in another checker
568   /// and the already set errno constraints should not be changed in the
569   /// post-call event.
570   class NoErrnoConstraint : public ErrnoConstraintBase {
571   public:
572     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
573                           const Summary &Summary,
574                           CheckerContext &C) const override {
575       return State;
576     }
577   };
578 
579   /// Set errno constraint at failure cases of standard functions.
580   /// Failure case: 'errno' becomes not equal to 0 and may or may not be checked
581   /// by the program. \c ErrnoChecker does not emit a bug report after such a
582   /// function call.
583   class FailureErrnoConstraint : public ErrnoConstraintBase {
584   public:
585     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
586                           const Summary &Summary,
587                           CheckerContext &C) const override {
588       SValBuilder &SVB = C.getSValBuilder();
589       NonLoc ErrnoSVal =
590           SVB.conjureSymbolVal(&Tag, Call.getOriginExpr(),
591                                C.getLocationContext(), C.getASTContext().IntTy,
592                                C.blockCount())
593               .castAs<NonLoc>();
594       return errno_modeling::setErrnoForStdFailure(State, C, ErrnoSVal);
595     }
596   };
597 
598   /// Set errno constraint at success cases of standard functions.
599   /// Success case: 'errno' is not allowed to be used.
600   /// \c ErrnoChecker can emit bug report after such a function call if errno
601   /// is used.
602   class SuccessErrnoConstraint : public ErrnoConstraintBase {
603   public:
604     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
605                           const Summary &Summary,
606                           CheckerContext &C) const override {
607       return errno_modeling::setErrnoForStdSuccess(State, C);
608     }
609 
610     const NoteTag *describe(CheckerContext &C,
611                             StringRef FunctionName) const override {
612       return errno_modeling::getNoteTagForStdSuccess(C, FunctionName);
613     }
614   };
615 
616   class ErrnoMustBeCheckedConstraint : public ErrnoConstraintBase {
617   public:
618     ProgramStateRef apply(ProgramStateRef State, const CallEvent &Call,
619                           const Summary &Summary,
620                           CheckerContext &C) const override {
621       return errno_modeling::setErrnoStdMustBeChecked(State, C,
622                                                       Call.getOriginExpr());
623     }
624 
625     const NoteTag *describe(CheckerContext &C,
626                             StringRef FunctionName) const override {
627       return errno_modeling::getNoteTagForStdMustBeChecked(C, FunctionName);
628     }
629   };
630 
631   /// A single branch of a function summary.
632   ///
633   /// A branch is defined by a series of constraints - "assumptions" -
634   /// that together form a single possible outcome of invoking the function.
635   /// When static analyzer considers a branch, it tries to introduce
636   /// a child node in the Exploded Graph. The child node has to include
637   /// constraints that define the branch. If the constraints contradict
638   /// existing constraints in the state, the node is not created and the branch
639   /// is dropped; otherwise it's queued for future exploration.
640   /// The branch is accompanied by a note text that may be displayed
641   /// to the user when a bug is found on a path that takes this branch.
642   ///
643   /// For example, consider the branches in `isalpha(x)`:
644   ///   Branch 1)
645   ///     x is in range ['A', 'Z'] or in ['a', 'z']
646   ///     then the return value is not 0. (I.e. out-of-range [0, 0])
647   ///     and the note may say "Assuming the character is alphabetical"
648   ///   Branch 2)
649   ///     x is out-of-range ['A', 'Z'] and out-of-range ['a', 'z']
650   ///     then the return value is 0
651   ///     and the note may say "Assuming the character is non-alphabetical".
652   class SummaryCase {
653     ConstraintSet Constraints;
654     const ErrnoConstraintBase &ErrnoConstraint;
655     StringRef Note;
656 
657   public:
658     SummaryCase(ConstraintSet &&Constraints, const ErrnoConstraintBase &ErrnoC,
659                 StringRef Note)
660         : Constraints(std::move(Constraints)), ErrnoConstraint(ErrnoC),
661           Note(Note) {}
662 
663     SummaryCase(const ConstraintSet &Constraints,
664                 const ErrnoConstraintBase &ErrnoC, StringRef Note)
665         : Constraints(Constraints), ErrnoConstraint(ErrnoC), Note(Note) {}
666 
667     const ConstraintSet &getConstraints() const { return Constraints; }
668     const ErrnoConstraintBase &getErrnoConstraint() const {
669       return ErrnoConstraint;
670     }
671     StringRef getNote() const { return Note; }
672   };
673 
674   using ArgTypes = std::vector<std::optional<QualType>>;
675   using RetType = std::optional<QualType>;
676 
677   // A placeholder type, we use it whenever we do not care about the concrete
678   // type in a Signature.
679   const QualType Irrelevant{};
680   bool static isIrrelevant(QualType T) { return T.isNull(); }
681 
682   // The signature of a function we want to describe with a summary. This is a
683   // concessive signature, meaning there may be irrelevant types in the
684   // signature which we do not check against a function with concrete types.
685   // All types in the spec need to be canonical.
686   class Signature {
687     using ArgQualTypes = std::vector<QualType>;
688     ArgQualTypes ArgTys;
689     QualType RetTy;
690     // True if any component type is not found by lookup.
691     bool Invalid = false;
692 
693   public:
694     // Construct a signature from optional types. If any of the optional types
695     // are not set then the signature will be invalid.
696     Signature(ArgTypes ArgTys, RetType RetTy) {
697       for (std::optional<QualType> Arg : ArgTys) {
698         if (!Arg) {
699           Invalid = true;
700           return;
701         } else {
702           assertArgTypeSuitableForSignature(*Arg);
703           this->ArgTys.push_back(*Arg);
704         }
705       }
706       if (!RetTy) {
707         Invalid = true;
708         return;
709       } else {
710         assertRetTypeSuitableForSignature(*RetTy);
711         this->RetTy = *RetTy;
712       }
713     }
714 
715     bool isInvalid() const { return Invalid; }
716     bool matches(const FunctionDecl *FD) const;
717 
718   private:
719     static void assertArgTypeSuitableForSignature(QualType T) {
720       assert((T.isNull() || !T->isVoidType()) &&
721              "We should have no void types in the spec");
722       assert((T.isNull() || T.isCanonical()) &&
723              "We should only have canonical types in the spec");
724     }
725     static void assertRetTypeSuitableForSignature(QualType T) {
726       assert((T.isNull() || T.isCanonical()) &&
727              "We should only have canonical types in the spec");
728     }
729   };
730 
731   static QualType getArgType(const FunctionDecl *FD, ArgNo ArgN) {
732     assert(FD && "Function must be set");
733     QualType T = (ArgN == Ret)
734                      ? FD->getReturnType().getCanonicalType()
735                      : FD->getParamDecl(ArgN)->getType().getCanonicalType();
736     return T;
737   }
738 
739   using SummaryCases = std::vector<SummaryCase>;
740 
741   /// A summary includes information about
742   ///   * function prototype (signature)
743   ///   * approach to invalidation,
744   ///   * a list of branches - so, a list of list of ranges,
745   ///   * a list of argument constraints, that must be true on every branch.
746   ///     If these constraints are not satisfied that means a fatal error
747   ///     usually resulting in undefined behaviour.
748   ///
749   /// Application of a summary:
750   ///   The signature and argument constraints together contain information
751   ///   about which functions are handled by the summary. The signature can use
752   ///   "wildcards", i.e. Irrelevant types. Irrelevant type of a parameter in
753   ///   a signature means that type is not compared to the type of the parameter
754   ///   in the found FunctionDecl. Argument constraints may specify additional
755   ///   rules for the given parameter's type, those rules are checked once the
756   ///   signature is matched.
757   class Summary {
758     const InvalidationKind InvalidationKd;
759     SummaryCases Cases;
760     ConstraintSet ArgConstraints;
761 
762     // The function to which the summary applies. This is set after lookup and
763     // match to the signature.
764     const FunctionDecl *FD = nullptr;
765 
766   public:
767     Summary(InvalidationKind InvalidationKd) : InvalidationKd(InvalidationKd) {}
768 
769     Summary &Case(ConstraintSet &&CS, const ErrnoConstraintBase &ErrnoC,
770                   StringRef Note = "") {
771       Cases.push_back(SummaryCase(std::move(CS), ErrnoC, Note));
772       return *this;
773     }
774     Summary &Case(const ConstraintSet &CS, const ErrnoConstraintBase &ErrnoC,
775                   StringRef Note = "") {
776       Cases.push_back(SummaryCase(CS, ErrnoC, Note));
777       return *this;
778     }
779     Summary &ArgConstraint(ValueConstraintPtr VC) {
780       assert(VC->getArgNo() != Ret &&
781              "Arg constraint should not refer to the return value");
782       ArgConstraints.push_back(VC);
783       return *this;
784     }
785 
786     InvalidationKind getInvalidationKd() const { return InvalidationKd; }
787     const SummaryCases &getCases() const { return Cases; }
788     const ConstraintSet &getArgConstraints() const { return ArgConstraints; }
789 
790     QualType getArgType(ArgNo ArgN) const {
791       return StdLibraryFunctionsChecker::getArgType(FD, ArgN);
792     }
793 
794     // Returns true if the summary should be applied to the given function.
795     // And if yes then store the function declaration.
796     bool matchesAndSet(const Signature &Sign, const FunctionDecl *FD) {
797       bool Result = Sign.matches(FD) && validateByConstraints(FD);
798       if (Result) {
799         assert(!this->FD && "FD must not be set more than once");
800         this->FD = FD;
801       }
802       return Result;
803     }
804 
805   private:
806     // Once we know the exact type of the function then do validation check on
807     // all the given constraints.
808     bool validateByConstraints(const FunctionDecl *FD) const {
809       for (const SummaryCase &Case : Cases)
810         for (const ValueConstraintPtr &Constraint : Case.getConstraints())
811           if (!Constraint->checkValidity(FD))
812             return false;
813       for (const ValueConstraintPtr &Constraint : ArgConstraints)
814         if (!Constraint->checkValidity(FD))
815           return false;
816       return true;
817     }
818   };
819 
820   // The map of all functions supported by the checker. It is initialized
821   // lazily, and it doesn't change after initialization.
822   using FunctionSummaryMapType = llvm::DenseMap<const FunctionDecl *, Summary>;
823   mutable FunctionSummaryMapType FunctionSummaryMap;
824 
825   mutable std::unique_ptr<BugType> BT_InvalidArg;
826   mutable bool SummariesInitialized = false;
827 
828   static SVal getArgSVal(const CallEvent &Call, ArgNo ArgN) {
829     return ArgN == Ret ? Call.getReturnValue() : Call.getArgSVal(ArgN);
830   }
831   static std::string getFunctionName(const CallEvent &Call) {
832     assert(Call.getDecl() &&
833            "Call was found by a summary, should have declaration");
834     return cast<NamedDecl>(Call.getDecl())->getNameAsString();
835   }
836 
837 public:
838   void checkPreCall(const CallEvent &Call, CheckerContext &C) const;
839   void checkPostCall(const CallEvent &Call, CheckerContext &C) const;
840   bool evalCall(const CallEvent &Call, CheckerContext &C) const;
841 
842   CheckerNameRef CheckName;
843   bool AddTestFunctions = false;
844 
845   bool DisplayLoadedSummaries = false;
846   bool ModelPOSIX = false;
847   bool ShouldAssumeControlledEnvironment = false;
848 
849 private:
850   std::optional<Summary> findFunctionSummary(const FunctionDecl *FD,
851                                              CheckerContext &C) const;
852   std::optional<Summary> findFunctionSummary(const CallEvent &Call,
853                                              CheckerContext &C) const;
854 
855   void initFunctionSummaries(CheckerContext &C) const;
856 
857   void reportBug(const CallEvent &Call, ExplodedNode *N,
858                  const ValueConstraint *VC, const ValueConstraint *NegatedVC,
859                  const Summary &Summary, CheckerContext &C) const {
860     assert(Call.getDecl() &&
861            "Function found in summary must have a declaration available");
862     SmallString<256> Msg;
863     llvm::raw_svector_ostream MsgOs(Msg);
864 
865     MsgOs << "The ";
866     printArgDesc(VC->getArgNo(), MsgOs);
867     MsgOs << " to '" << getFunctionName(Call) << "' ";
868     bool ValuesPrinted =
869         NegatedVC->describeArgumentValue(Call, N->getState(), Summary, MsgOs);
870     if (ValuesPrinted)
871       MsgOs << " but ";
872     else
873       MsgOs << "is out of the accepted range; It ";
874     VC->describe(ValueConstraint::Violation, Call, C.getState(), Summary,
875                  MsgOs);
876     Msg[0] = toupper(Msg[0]);
877     if (!BT_InvalidArg)
878       BT_InvalidArg = std::make_unique<BugType>(
879           CheckName, "Function call with invalid argument",
880           categories::LogicError);
881     auto R = std::make_unique<PathSensitiveBugReport>(*BT_InvalidArg, Msg, N);
882 
883     for (ArgNo ArgN : VC->getArgsToTrack()) {
884       bugreporter::trackExpressionValue(N, Call.getArgExpr(ArgN), *R);
885       R->markInteresting(Call.getArgSVal(ArgN));
886       // All tracked arguments are important, highlight them.
887       R->addRange(Call.getArgSourceRange(ArgN));
888     }
889 
890     C.emitReport(std::move(R));
891   }
892 
893   /// These are the errno constraints that can be passed to summary cases.
894   /// One of these should fit for a single summary case.
895   /// Usually if a failure return value exists for function, that function
896   /// needs different cases for success and failure with different errno
897   /// constraints (and different return value constraints).
898   const NoErrnoConstraint ErrnoUnchanged{};
899   const ResetErrnoConstraint ErrnoIrrelevant{};
900   const ErrnoMustBeCheckedConstraint ErrnoMustBeChecked{};
901   const SuccessErrnoConstraint ErrnoMustNotBeChecked{};
902   const FailureErrnoConstraint ErrnoNEZeroIrrelevant{};
903 };
904 
905 int StdLibraryFunctionsChecker::ErrnoConstraintBase::Tag = 0;
906 
907 const StdLibraryFunctionsChecker::ArgNo StdLibraryFunctionsChecker::Ret =
908     std::numeric_limits<ArgNo>::max();
909 
910 static BasicValueFactory &getBVF(ProgramStateRef State) {
911   ProgramStateManager &Mgr = State->getStateManager();
912   SValBuilder &SVB = Mgr.getSValBuilder();
913   return SVB.getBasicValueFactory();
914 }
915 
916 } // end of anonymous namespace
917 
918 void StdLibraryFunctionsChecker::printArgDesc(
919     StdLibraryFunctionsChecker::ArgNo ArgN, llvm::raw_ostream &Out) {
920   Out << std::to_string(ArgN + 1);
921   Out << llvm::getOrdinalSuffix(ArgN + 1);
922   Out << " argument";
923 }
924 
925 void StdLibraryFunctionsChecker::printArgValueInfo(ArgNo ArgN,
926                                                    ProgramStateRef State,
927                                                    const CallEvent &Call,
928                                                    llvm::raw_ostream &Out) {
929   if (const llvm::APSInt *Val =
930           State->getStateManager().getSValBuilder().getKnownValue(
931               State, getArgSVal(Call, ArgN)))
932     Out << " (which is " << *Val << ")";
933 }
934 
935 void StdLibraryFunctionsChecker::appendInsideRangeDesc(llvm::APSInt RMin,
936                                                        llvm::APSInt RMax,
937                                                        QualType ArgT,
938                                                        BasicValueFactory &BVF,
939                                                        llvm::raw_ostream &Out) {
940   if (RMin.isZero() && RMax.isZero())
941     Out << "zero";
942   else if (RMin == RMax)
943     Out << RMin;
944   else if (RMin == BVF.getMinValue(ArgT)) {
945     if (RMax == -1)
946       Out << "< 0";
947     else
948       Out << "<= " << RMax;
949   } else if (RMax == BVF.getMaxValue(ArgT)) {
950     if (RMin.isOne())
951       Out << "> 0";
952     else
953       Out << ">= " << RMin;
954   } else if (RMin.isNegative() == RMax.isNegative() &&
955              RMin.getLimitedValue() == RMax.getLimitedValue() - 1) {
956     Out << RMin << " or " << RMax;
957   } else {
958     Out << "between " << RMin << " and " << RMax;
959   }
960 }
961 
962 void StdLibraryFunctionsChecker::appendOutOfRangeDesc(llvm::APSInt RMin,
963                                                       llvm::APSInt RMax,
964                                                       QualType ArgT,
965                                                       BasicValueFactory &BVF,
966                                                       llvm::raw_ostream &Out) {
967   if (RMin.isZero() && RMax.isZero())
968     Out << "nonzero";
969   else if (RMin == RMax) {
970     Out << "not equal to " << RMin;
971   } else if (RMin == BVF.getMinValue(ArgT)) {
972     if (RMax == -1)
973       Out << ">= 0";
974     else
975       Out << "> " << RMax;
976   } else if (RMax == BVF.getMaxValue(ArgT)) {
977     if (RMin.isOne())
978       Out << "<= 0";
979     else
980       Out << "< " << RMin;
981   } else if (RMin.isNegative() == RMax.isNegative() &&
982              RMin.getLimitedValue() == RMax.getLimitedValue() - 1) {
983     Out << "not " << RMin << " and not " << RMax;
984   } else {
985     Out << "not between " << RMin << " and " << RMax;
986   }
987 }
988 
989 void StdLibraryFunctionsChecker::RangeConstraint::applyOnWithinRange(
990     BasicValueFactory &BVF, QualType ArgT, const RangeApplyFunction &F) const {
991   if (Ranges.empty())
992     return;
993 
994   for (auto [Start, End] : getRanges()) {
995     const llvm::APSInt &Min = BVF.getValue(Start, ArgT);
996     const llvm::APSInt &Max = BVF.getValue(End, ArgT);
997     assert(Min <= Max);
998     if (!F(Min, Max))
999       return;
1000   }
1001 }
1002 
1003 void StdLibraryFunctionsChecker::RangeConstraint::applyOnOutOfRange(
1004     BasicValueFactory &BVF, QualType ArgT, const RangeApplyFunction &F) const {
1005   if (Ranges.empty())
1006     return;
1007 
1008   const IntRangeVector &R = getRanges();
1009   size_t E = R.size();
1010 
1011   const llvm::APSInt &MinusInf = BVF.getMinValue(ArgT);
1012   const llvm::APSInt &PlusInf = BVF.getMaxValue(ArgT);
1013 
1014   const llvm::APSInt &RangeLeft = BVF.getValue(R[0].first - 1ULL, ArgT);
1015   const llvm::APSInt &RangeRight = BVF.getValue(R[E - 1].second + 1ULL, ArgT);
1016 
1017   // Iterate over the "holes" between intervals.
1018   for (size_t I = 1; I != E; ++I) {
1019     const llvm::APSInt &Min = BVF.getValue(R[I - 1].second + 1ULL, ArgT);
1020     const llvm::APSInt &Max = BVF.getValue(R[I].first - 1ULL, ArgT);
1021     if (Min <= Max) {
1022       if (!F(Min, Max))
1023         return;
1024     }
1025   }
1026   // Check the interval [T_MIN, min(R) - 1].
1027   if (RangeLeft != PlusInf) {
1028     assert(MinusInf <= RangeLeft);
1029     if (!F(MinusInf, RangeLeft))
1030       return;
1031   }
1032   // Check the interval [max(R) + 1, T_MAX],
1033   if (RangeRight != MinusInf) {
1034     assert(RangeRight <= PlusInf);
1035     if (!F(RangeRight, PlusInf))
1036       return;
1037   }
1038 }
1039 
1040 ProgramStateRef StdLibraryFunctionsChecker::RangeConstraint::apply(
1041     ProgramStateRef State, const CallEvent &Call, const Summary &Summary,
1042     CheckerContext &C) const {
1043   ConstraintManager &CM = C.getConstraintManager();
1044   SVal V = getArgSVal(Call, getArgNo());
1045   QualType T = Summary.getArgType(getArgNo());
1046 
1047   if (auto N = V.getAs<NonLoc>()) {
1048     auto ExcludeRangeFromArg = [&](const llvm::APSInt &Min,
1049                                    const llvm::APSInt &Max) {
1050       State = CM.assumeInclusiveRange(State, *N, Min, Max, false);
1051       return static_cast<bool>(State);
1052     };
1053     // "OutOfRange R" is handled by excluding all ranges in R.
1054     // "WithinRange R" is treated as "OutOfRange [T_MIN, T_MAX] \ R".
1055     applyOnRange(negateKind(Kind), C.getSValBuilder().getBasicValueFactory(), T,
1056                  ExcludeRangeFromArg);
1057   }
1058 
1059   return State;
1060 }
1061 
1062 void StdLibraryFunctionsChecker::RangeConstraint::describe(
1063     DescriptionKind DK, const CallEvent &Call, ProgramStateRef State,
1064     const Summary &Summary, llvm::raw_ostream &Out) const {
1065 
1066   BasicValueFactory &BVF = getBVF(State);
1067   QualType T = Summary.getArgType(getArgNo());
1068 
1069   Out << ((DK == Violation) ? "should be " : "is ");
1070   if (!Description.empty()) {
1071     Out << Description;
1072   } else {
1073     unsigned I = Ranges.size();
1074     if (Kind == WithinRange) {
1075       for (const std::pair<RangeInt, RangeInt> &R : Ranges) {
1076         appendInsideRangeDesc(BVF.getValue(R.first, T),
1077                               BVF.getValue(R.second, T), T, BVF, Out);
1078         if (--I > 0)
1079           Out << " or ";
1080       }
1081     } else {
1082       for (const std::pair<RangeInt, RangeInt> &R : Ranges) {
1083         appendOutOfRangeDesc(BVF.getValue(R.first, T),
1084                              BVF.getValue(R.second, T), T, BVF, Out);
1085         if (--I > 0)
1086           Out << " and ";
1087       }
1088     }
1089   }
1090 }
1091 
1092 bool StdLibraryFunctionsChecker::RangeConstraint::describeArgumentValue(
1093     const CallEvent &Call, ProgramStateRef State, const Summary &Summary,
1094     llvm::raw_ostream &Out) const {
1095   unsigned int NRanges = 0;
1096   bool HaveAllRanges = true;
1097 
1098   ProgramStateManager &Mgr = State->getStateManager();
1099   BasicValueFactory &BVF = Mgr.getSValBuilder().getBasicValueFactory();
1100   ConstraintManager &CM = Mgr.getConstraintManager();
1101   SVal V = getArgSVal(Call, getArgNo());
1102 
1103   if (auto N = V.getAs<NonLoc>()) {
1104     if (const llvm::APSInt *Int = N->getAsInteger()) {
1105       Out << "is ";
1106       Out << *Int;
1107       return true;
1108     }
1109     QualType T = Summary.getArgType(getArgNo());
1110     SmallString<128> MoreInfo;
1111     llvm::raw_svector_ostream MoreInfoOs(MoreInfo);
1112     auto ApplyF = [&](const llvm::APSInt &Min, const llvm::APSInt &Max) {
1113       if (CM.assumeInclusiveRange(State, *N, Min, Max, true)) {
1114         if (NRanges > 0)
1115           MoreInfoOs << " or ";
1116         appendInsideRangeDesc(Min, Max, T, BVF, MoreInfoOs);
1117         ++NRanges;
1118       } else {
1119         HaveAllRanges = false;
1120       }
1121       return true;
1122     };
1123 
1124     applyOnRange(Kind, BVF, T, ApplyF);
1125     assert(NRanges > 0);
1126     if (!HaveAllRanges || NRanges == 1) {
1127       Out << "is ";
1128       Out << MoreInfo;
1129       return true;
1130     }
1131   }
1132   return false;
1133 }
1134 
1135 ProgramStateRef StdLibraryFunctionsChecker::ComparisonConstraint::apply(
1136     ProgramStateRef State, const CallEvent &Call, const Summary &Summary,
1137     CheckerContext &C) const {
1138 
1139   ProgramStateManager &Mgr = State->getStateManager();
1140   SValBuilder &SVB = Mgr.getSValBuilder();
1141   QualType CondT = SVB.getConditionType();
1142   QualType T = Summary.getArgType(getArgNo());
1143   SVal V = getArgSVal(Call, getArgNo());
1144 
1145   BinaryOperator::Opcode Op = getOpcode();
1146   ArgNo OtherArg = getOtherArgNo();
1147   SVal OtherV = getArgSVal(Call, OtherArg);
1148   QualType OtherT = Summary.getArgType(OtherArg);
1149   // Note: we avoid integral promotion for comparison.
1150   OtherV = SVB.evalCast(OtherV, T, OtherT);
1151   if (auto CompV = SVB.evalBinOp(State, Op, V, OtherV, CondT)
1152                        .getAs<DefinedOrUnknownSVal>())
1153     State = State->assume(*CompV, true);
1154   return State;
1155 }
1156 
1157 ProgramStateRef StdLibraryFunctionsChecker::NotNullConstraint::apply(
1158     ProgramStateRef State, const CallEvent &Call, const Summary &Summary,
1159     CheckerContext &C) const {
1160   SVal V = getArgSVal(Call, getArgNo());
1161   if (V.isUndef())
1162     return State;
1163 
1164   DefinedOrUnknownSVal L = V.castAs<DefinedOrUnknownSVal>();
1165   if (!isa<Loc>(L))
1166     return State;
1167 
1168   return State->assume(L, CannotBeNull);
1169 }
1170 
1171 void StdLibraryFunctionsChecker::NotNullConstraint::describe(
1172     DescriptionKind DK, const CallEvent &Call, ProgramStateRef State,
1173     const Summary &Summary, llvm::raw_ostream &Out) const {
1174   assert(CannotBeNull &&
1175          "Describe should not be used when the value must be NULL");
1176   if (DK == Violation)
1177     Out << "should not be NULL";
1178   else
1179     Out << "is not NULL";
1180 }
1181 
1182 bool StdLibraryFunctionsChecker::NotNullConstraint::describeArgumentValue(
1183     const CallEvent &Call, ProgramStateRef State, const Summary &Summary,
1184     llvm::raw_ostream &Out) const {
1185   assert(!CannotBeNull && "This function is used when the value is NULL");
1186   Out << "is NULL";
1187   return true;
1188 }
1189 
1190 ProgramStateRef StdLibraryFunctionsChecker::NotNullBufferConstraint::apply(
1191     ProgramStateRef State, const CallEvent &Call, const Summary &Summary,
1192     CheckerContext &C) const {
1193   SVal V = getArgSVal(Call, getArgNo());
1194   if (V.isUndef())
1195     return State;
1196   DefinedOrUnknownSVal L = V.castAs<DefinedOrUnknownSVal>();
1197   if (!isa<Loc>(L))
1198     return State;
1199 
1200   std::optional<DefinedOrUnknownSVal> SizeArg1 =
1201       getArgSVal(Call, SizeArg1N).getAs<DefinedOrUnknownSVal>();
1202   std::optional<DefinedOrUnknownSVal> SizeArg2;
1203   if (SizeArg2N)
1204     SizeArg2 = getArgSVal(Call, *SizeArg2N).getAs<DefinedOrUnknownSVal>();
1205 
1206   auto IsArgZero = [State](std::optional<DefinedOrUnknownSVal> Val) {
1207     if (!Val)
1208       return false;
1209     auto [IsNonNull, IsNull] = State->assume(*Val);
1210     return IsNull && !IsNonNull;
1211   };
1212 
1213   if (IsArgZero(SizeArg1) || IsArgZero(SizeArg2))
1214     return State;
1215 
1216   return State->assume(L, CannotBeNull);
1217 }
1218 
1219 void StdLibraryFunctionsChecker::NotNullBufferConstraint::describe(
1220     DescriptionKind DK, const CallEvent &Call, ProgramStateRef State,
1221     const Summary &Summary, llvm::raw_ostream &Out) const {
1222   assert(CannotBeNull &&
1223          "Describe should not be used when the value must be NULL");
1224   if (DK == Violation)
1225     Out << "should not be NULL";
1226   else
1227     Out << "is not NULL";
1228 }
1229 
1230 bool StdLibraryFunctionsChecker::NotNullBufferConstraint::describeArgumentValue(
1231     const CallEvent &Call, ProgramStateRef State, const Summary &Summary,
1232     llvm::raw_ostream &Out) const {
1233   assert(!CannotBeNull && "This function is used when the value is NULL");
1234   Out << "is NULL";
1235   return true;
1236 }
1237 
1238 ProgramStateRef StdLibraryFunctionsChecker::BufferSizeConstraint::apply(
1239     ProgramStateRef State, const CallEvent &Call, const Summary &Summary,
1240     CheckerContext &C) const {
1241   SValBuilder &SvalBuilder = C.getSValBuilder();
1242   // The buffer argument.
1243   SVal BufV = getArgSVal(Call, getArgNo());
1244 
1245   // Get the size constraint.
1246   const SVal SizeV = [this, &State, &Call, &Summary, &SvalBuilder]() {
1247     if (ConcreteSize) {
1248       return SVal(SvalBuilder.makeIntVal(*ConcreteSize));
1249     }
1250     assert(SizeArgN && "The constraint must be either a concrete value or "
1251                        "encoded in an argument.");
1252     // The size argument.
1253     SVal SizeV = getArgSVal(Call, *SizeArgN);
1254     // Multiply with another argument if given.
1255     if (SizeMultiplierArgN) {
1256       SVal SizeMulV = getArgSVal(Call, *SizeMultiplierArgN);
1257       SizeV = SvalBuilder.evalBinOp(State, BO_Mul, SizeV, SizeMulV,
1258                                     Summary.getArgType(*SizeArgN));
1259     }
1260     return SizeV;
1261   }();
1262 
1263   // The dynamic size of the buffer argument, got from the analyzer engine.
1264   SVal BufDynSize = getDynamicExtentWithOffset(State, BufV);
1265 
1266   SVal Feasible = SvalBuilder.evalBinOp(State, Op, SizeV, BufDynSize,
1267                                         SvalBuilder.getContext().BoolTy);
1268   if (auto F = Feasible.getAs<DefinedOrUnknownSVal>())
1269     return State->assume(*F, true);
1270 
1271   // We can get here only if the size argument or the dynamic size is
1272   // undefined. But the dynamic size should never be undefined, only
1273   // unknown. So, here, the size of the argument is undefined, i.e. we
1274   // cannot apply the constraint. Actually, other checkers like
1275   // CallAndMessage should catch this situation earlier, because we call a
1276   // function with an uninitialized argument.
1277   llvm_unreachable("Size argument or the dynamic size is Undefined");
1278 }
1279 
1280 void StdLibraryFunctionsChecker::BufferSizeConstraint::describe(
1281     DescriptionKind DK, const CallEvent &Call, ProgramStateRef State,
1282     const Summary &Summary, llvm::raw_ostream &Out) const {
1283   Out << ((DK == Violation) ? "should be " : "is ");
1284   Out << "a buffer with size equal to or greater than ";
1285   if (ConcreteSize) {
1286     Out << *ConcreteSize;
1287   } else if (SizeArgN) {
1288     Out << "the value of the ";
1289     printArgDesc(*SizeArgN, Out);
1290     printArgValueInfo(*SizeArgN, State, Call, Out);
1291     if (SizeMultiplierArgN) {
1292       Out << " times the ";
1293       printArgDesc(*SizeMultiplierArgN, Out);
1294       printArgValueInfo(*SizeMultiplierArgN, State, Call, Out);
1295     }
1296   }
1297 }
1298 
1299 bool StdLibraryFunctionsChecker::BufferSizeConstraint::describeArgumentValue(
1300     const CallEvent &Call, ProgramStateRef State, const Summary &Summary,
1301     llvm::raw_ostream &Out) const {
1302   SVal BufV = getArgSVal(Call, getArgNo());
1303   SVal BufDynSize = getDynamicExtentWithOffset(State, BufV);
1304   if (const llvm::APSInt *Val =
1305           State->getStateManager().getSValBuilder().getKnownValue(State,
1306                                                                   BufDynSize)) {
1307     Out << "is a buffer with size " << *Val;
1308     return true;
1309   }
1310   return false;
1311 }
1312 
1313 void StdLibraryFunctionsChecker::checkPreCall(const CallEvent &Call,
1314                                               CheckerContext &C) const {
1315   std::optional<Summary> FoundSummary = findFunctionSummary(Call, C);
1316   if (!FoundSummary)
1317     return;
1318 
1319   const Summary &Summary = *FoundSummary;
1320   ProgramStateRef State = C.getState();
1321 
1322   ProgramStateRef NewState = State;
1323   ExplodedNode *NewNode = C.getPredecessor();
1324   for (const ValueConstraintPtr &Constraint : Summary.getArgConstraints()) {
1325     ValueConstraintPtr NegatedConstraint = Constraint->negate();
1326     ProgramStateRef SuccessSt = Constraint->apply(NewState, Call, Summary, C);
1327     ProgramStateRef FailureSt =
1328         NegatedConstraint->apply(NewState, Call, Summary, C);
1329     // The argument constraint is not satisfied.
1330     if (FailureSt && !SuccessSt) {
1331       if (ExplodedNode *N = C.generateErrorNode(State, NewNode))
1332         reportBug(Call, N, Constraint.get(), NegatedConstraint.get(), Summary,
1333                   C);
1334       break;
1335     }
1336     // We will apply the constraint even if we cannot reason about the
1337     // argument. This means both SuccessSt and FailureSt can be true. If we
1338     // weren't applying the constraint that would mean that symbolic
1339     // execution continues on a code whose behaviour is undefined.
1340     assert(SuccessSt);
1341     NewState = SuccessSt;
1342     if (NewState != State) {
1343       SmallString<128> Msg;
1344       llvm::raw_svector_ostream Os(Msg);
1345       Os << "Assuming that the ";
1346       printArgDesc(Constraint->getArgNo(), Os);
1347       Os << " to '";
1348       Os << getFunctionName(Call);
1349       Os << "' ";
1350       Constraint->describe(ValueConstraint::Assumption, Call, NewState, Summary,
1351                            Os);
1352       const auto ArgSVal = Call.getArgSVal(Constraint->getArgNo());
1353       NewNode = C.addTransition(
1354           NewState, NewNode,
1355           C.getNoteTag([Msg = std::move(Msg), ArgSVal](
1356                            PathSensitiveBugReport &BR, llvm::raw_ostream &OS) {
1357             if (BR.isInteresting(ArgSVal))
1358               OS << Msg;
1359           }));
1360     }
1361   }
1362 }
1363 
1364 void StdLibraryFunctionsChecker::checkPostCall(const CallEvent &Call,
1365                                                CheckerContext &C) const {
1366   std::optional<Summary> FoundSummary = findFunctionSummary(Call, C);
1367   if (!FoundSummary)
1368     return;
1369 
1370   // Now apply the constraints.
1371   const Summary &Summary = *FoundSummary;
1372   ProgramStateRef State = C.getState();
1373   ExplodedNode *Node = C.getPredecessor();
1374 
1375   // Apply case/branch specifications.
1376   for (const SummaryCase &Case : Summary.getCases()) {
1377     ProgramStateRef NewState = State;
1378     for (const ValueConstraintPtr &Constraint : Case.getConstraints()) {
1379       NewState = Constraint->apply(NewState, Call, Summary, C);
1380       if (!NewState)
1381         break;
1382     }
1383 
1384     if (NewState)
1385       NewState = Case.getErrnoConstraint().apply(NewState, Call, Summary, C);
1386 
1387     if (!NewState)
1388       continue;
1389 
1390     // It is possible that NewState == State is true.
1391     // It can occur if another checker has applied the state before us.
1392     // Still add these note tags, the other checker should add only its
1393     // specialized note tags. These general note tags are handled always by
1394     // StdLibraryFunctionsChecker.
1395     ExplodedNode *Pred = Node;
1396     if (!Case.getNote().empty()) {
1397       const SVal RV = Call.getReturnValue();
1398       // If there is a description for this execution branch (summary case),
1399       // use it as a note tag.
1400       std::string Note =
1401           llvm::formatv(Case.getNote().str().c_str(),
1402                         cast<NamedDecl>(Call.getDecl())->getDeclName());
1403       if (Summary.getInvalidationKd() == EvalCallAsPure) {
1404         const NoteTag *Tag = C.getNoteTag(
1405             [Node, Note, RV](PathSensitiveBugReport &BR) -> std::string {
1406               // Try to omit the note if we know in advance which branch is
1407               // taken (this means, only one branch exists).
1408               // This check is performed inside the lambda, after other
1409               // (or this) checkers had a chance to add other successors.
1410               // Dereferencing the saved node object is valid because it's part
1411               // of a bug report call sequence.
1412               // FIXME: This check is not exact. We may be here after a state
1413               // split that was performed by another checker (and can not find
1414               // the successors). This is why this check is only used in the
1415               // EvalCallAsPure case.
1416               if (BR.isInteresting(RV) && Node->succ_size() > 1)
1417                 return Note;
1418               return "";
1419             });
1420         Pred = C.addTransition(NewState, Pred, Tag);
1421       } else {
1422         const NoteTag *Tag =
1423             C.getNoteTag([Note, RV](PathSensitiveBugReport &BR) -> std::string {
1424               if (BR.isInteresting(RV))
1425                 return Note;
1426               return "";
1427             });
1428         Pred = C.addTransition(NewState, Pred, Tag);
1429       }
1430       if (!Pred)
1431         continue;
1432     }
1433 
1434     // If we can get a note tag for the errno change, add this additionally to
1435     // the previous. This note is only about value of 'errno' and is displayed
1436     // if 'errno' is interesting.
1437     if (const auto *D = dyn_cast<FunctionDecl>(Call.getDecl()))
1438       if (const NoteTag *NT =
1439               Case.getErrnoConstraint().describe(C, D->getNameAsString()))
1440         Pred = C.addTransition(NewState, Pred, NT);
1441 
1442     // Add the transition if no note tag could be added.
1443     if (Pred == Node && NewState != State)
1444       C.addTransition(NewState);
1445   }
1446 }
1447 
1448 bool StdLibraryFunctionsChecker::evalCall(const CallEvent &Call,
1449                                           CheckerContext &C) const {
1450   std::optional<Summary> FoundSummary = findFunctionSummary(Call, C);
1451   if (!FoundSummary)
1452     return false;
1453 
1454   const Summary &Summary = *FoundSummary;
1455   switch (Summary.getInvalidationKd()) {
1456   case EvalCallAsPure: {
1457     ProgramStateRef State = C.getState();
1458     const LocationContext *LC = C.getLocationContext();
1459     const auto *CE = cast<CallExpr>(Call.getOriginExpr());
1460     SVal V = C.getSValBuilder().conjureSymbolVal(
1461         CE, LC, CE->getType().getCanonicalType(), C.blockCount());
1462     State = State->BindExpr(CE, LC, V);
1463 
1464     C.addTransition(State);
1465 
1466     return true;
1467   }
1468   case NoEvalCall:
1469     // Summary tells us to avoid performing eval::Call. The function is possibly
1470     // evaluated by another checker, or evaluated conservatively.
1471     return false;
1472   }
1473   llvm_unreachable("Unknown invalidation kind!");
1474 }
1475 
1476 bool StdLibraryFunctionsChecker::Signature::matches(
1477     const FunctionDecl *FD) const {
1478   assert(!isInvalid());
1479   // Check the number of arguments.
1480   if (FD->param_size() != ArgTys.size())
1481     return false;
1482 
1483   // The "restrict" keyword is illegal in C++, however, many libc
1484   // implementations use the "__restrict" compiler intrinsic in functions
1485   // prototypes. The "__restrict" keyword qualifies a type as a restricted type
1486   // even in C++.
1487   // In case of any non-C99 languages, we don't want to match based on the
1488   // restrict qualifier because we cannot know if the given libc implementation
1489   // qualifies the paramter type or not.
1490   auto RemoveRestrict = [&FD](QualType T) {
1491     if (!FD->getASTContext().getLangOpts().C99)
1492       T.removeLocalRestrict();
1493     return T;
1494   };
1495 
1496   // Check the return type.
1497   if (!isIrrelevant(RetTy)) {
1498     QualType FDRetTy = RemoveRestrict(FD->getReturnType().getCanonicalType());
1499     if (RetTy != FDRetTy)
1500       return false;
1501   }
1502 
1503   // Check the argument types.
1504   for (auto [Idx, ArgTy] : llvm::enumerate(ArgTys)) {
1505     if (isIrrelevant(ArgTy))
1506       continue;
1507     QualType FDArgTy =
1508         RemoveRestrict(FD->getParamDecl(Idx)->getType().getCanonicalType());
1509     if (ArgTy != FDArgTy)
1510       return false;
1511   }
1512 
1513   return true;
1514 }
1515 
1516 std::optional<StdLibraryFunctionsChecker::Summary>
1517 StdLibraryFunctionsChecker::findFunctionSummary(const FunctionDecl *FD,
1518                                                 CheckerContext &C) const {
1519   if (!FD)
1520     return std::nullopt;
1521 
1522   initFunctionSummaries(C);
1523 
1524   auto FSMI = FunctionSummaryMap.find(FD->getCanonicalDecl());
1525   if (FSMI == FunctionSummaryMap.end())
1526     return std::nullopt;
1527   return FSMI->second;
1528 }
1529 
1530 std::optional<StdLibraryFunctionsChecker::Summary>
1531 StdLibraryFunctionsChecker::findFunctionSummary(const CallEvent &Call,
1532                                                 CheckerContext &C) const {
1533   const FunctionDecl *FD = dyn_cast_or_null<FunctionDecl>(Call.getDecl());
1534   if (!FD)
1535     return std::nullopt;
1536   return findFunctionSummary(FD, C);
1537 }
1538 
1539 void StdLibraryFunctionsChecker::initFunctionSummaries(
1540     CheckerContext &C) const {
1541   if (SummariesInitialized)
1542     return;
1543   SummariesInitialized = true;
1544 
1545   SValBuilder &SVB = C.getSValBuilder();
1546   BasicValueFactory &BVF = SVB.getBasicValueFactory();
1547   const ASTContext &ACtx = BVF.getContext();
1548   Preprocessor &PP = C.getPreprocessor();
1549 
1550   // Helper class to lookup a type by its name.
1551   class LookupType {
1552     const ASTContext &ACtx;
1553 
1554   public:
1555     LookupType(const ASTContext &ACtx) : ACtx(ACtx) {}
1556 
1557     // Find the type. If not found then the optional is not set.
1558     std::optional<QualType> operator()(StringRef Name) {
1559       IdentifierInfo &II = ACtx.Idents.get(Name);
1560       auto LookupRes = ACtx.getTranslationUnitDecl()->lookup(&II);
1561       if (LookupRes.empty())
1562         return std::nullopt;
1563 
1564       // Prioritze typedef declarations.
1565       // This is needed in case of C struct typedefs. E.g.:
1566       //   typedef struct FILE FILE;
1567       // In this case, we have a RecordDecl 'struct FILE' with the name 'FILE'
1568       // and we have a TypedefDecl with the name 'FILE'.
1569       for (Decl *D : LookupRes)
1570         if (auto *TD = dyn_cast<TypedefNameDecl>(D))
1571           return ACtx.getTypeDeclType(TD).getCanonicalType();
1572 
1573       // Find the first TypeDecl.
1574       // There maybe cases when a function has the same name as a struct.
1575       // E.g. in POSIX: `struct stat` and the function `stat()`:
1576       //   int stat(const char *restrict path, struct stat *restrict buf);
1577       for (Decl *D : LookupRes)
1578         if (auto *TD = dyn_cast<TypeDecl>(D))
1579           return ACtx.getTypeDeclType(TD).getCanonicalType();
1580       return std::nullopt;
1581     }
1582   } lookupTy(ACtx);
1583 
1584   // Below are auxiliary classes to handle optional types that we get as a
1585   // result of the lookup.
1586   class GetRestrictTy {
1587     const ASTContext &ACtx;
1588 
1589   public:
1590     GetRestrictTy(const ASTContext &ACtx) : ACtx(ACtx) {}
1591     QualType operator()(QualType Ty) {
1592       return ACtx.getLangOpts().C99 ? ACtx.getRestrictType(Ty) : Ty;
1593     }
1594     std::optional<QualType> operator()(std::optional<QualType> Ty) {
1595       if (Ty)
1596         return operator()(*Ty);
1597       return std::nullopt;
1598     }
1599   } getRestrictTy(ACtx);
1600   class GetPointerTy {
1601     const ASTContext &ACtx;
1602 
1603   public:
1604     GetPointerTy(const ASTContext &ACtx) : ACtx(ACtx) {}
1605     QualType operator()(QualType Ty) { return ACtx.getPointerType(Ty); }
1606     std::optional<QualType> operator()(std::optional<QualType> Ty) {
1607       if (Ty)
1608         return operator()(*Ty);
1609       return std::nullopt;
1610     }
1611   } getPointerTy(ACtx);
1612   class {
1613   public:
1614     std::optional<QualType> operator()(std::optional<QualType> Ty) {
1615       return Ty ? std::optional<QualType>(Ty->withConst()) : std::nullopt;
1616     }
1617     QualType operator()(QualType Ty) { return Ty.withConst(); }
1618   } getConstTy;
1619   class GetMaxValue {
1620     BasicValueFactory &BVF;
1621 
1622   public:
1623     GetMaxValue(BasicValueFactory &BVF) : BVF(BVF) {}
1624     std::optional<RangeInt> operator()(QualType Ty) {
1625       return BVF.getMaxValue(Ty).getLimitedValue();
1626     }
1627     std::optional<RangeInt> operator()(std::optional<QualType> Ty) {
1628       if (Ty) {
1629         return operator()(*Ty);
1630       }
1631       return std::nullopt;
1632     }
1633   } getMaxValue(BVF);
1634 
1635   // These types are useful for writing specifications quickly,
1636   // New specifications should probably introduce more types.
1637   // Some types are hard to obtain from the AST, eg. "ssize_t".
1638   // In such cases it should be possible to provide multiple variants
1639   // of function summary for common cases (eg. ssize_t could be int or long
1640   // or long long, so three summary variants would be enough).
1641   // Of course, function variants are also useful for C++ overloads.
1642   const QualType VoidTy = ACtx.VoidTy;
1643   const QualType CharTy = ACtx.CharTy;
1644   const QualType WCharTy = ACtx.WCharTy;
1645   const QualType IntTy = ACtx.IntTy;
1646   const QualType UnsignedIntTy = ACtx.UnsignedIntTy;
1647   const QualType LongTy = ACtx.LongTy;
1648   const QualType SizeTy = ACtx.getSizeType();
1649 
1650   const QualType VoidPtrTy = getPointerTy(VoidTy); // void *
1651   const QualType IntPtrTy = getPointerTy(IntTy);   // int *
1652   const QualType UnsignedIntPtrTy =
1653       getPointerTy(UnsignedIntTy); // unsigned int *
1654   const QualType VoidPtrRestrictTy = getRestrictTy(VoidPtrTy);
1655   const QualType ConstVoidPtrTy =
1656       getPointerTy(getConstTy(VoidTy));            // const void *
1657   const QualType CharPtrTy = getPointerTy(CharTy); // char *
1658   const QualType CharPtrRestrictTy = getRestrictTy(CharPtrTy);
1659   const QualType ConstCharPtrTy =
1660       getPointerTy(getConstTy(CharTy)); // const char *
1661   const QualType ConstCharPtrRestrictTy = getRestrictTy(ConstCharPtrTy);
1662   const QualType Wchar_tPtrTy = getPointerTy(WCharTy); // wchar_t *
1663   const QualType ConstWchar_tPtrTy =
1664       getPointerTy(getConstTy(WCharTy)); // const wchar_t *
1665   const QualType ConstVoidPtrRestrictTy = getRestrictTy(ConstVoidPtrTy);
1666   const QualType SizePtrTy = getPointerTy(SizeTy);
1667   const QualType SizePtrRestrictTy = getRestrictTy(SizePtrTy);
1668 
1669   const RangeInt IntMax = BVF.getMaxValue(IntTy).getLimitedValue();
1670   const RangeInt UnsignedIntMax =
1671       BVF.getMaxValue(UnsignedIntTy).getLimitedValue();
1672   const RangeInt LongMax = BVF.getMaxValue(LongTy).getLimitedValue();
1673   const RangeInt SizeMax = BVF.getMaxValue(SizeTy).getLimitedValue();
1674 
1675   // Set UCharRangeMax to min of int or uchar maximum value.
1676   // The C standard states that the arguments of functions like isalpha must
1677   // be representable as an unsigned char. Their type is 'int', so the max
1678   // value of the argument should be min(UCharMax, IntMax). This just happen
1679   // to be true for commonly used and well tested instruction set
1680   // architectures, but not for others.
1681   const RangeInt UCharRangeMax =
1682       std::min(BVF.getMaxValue(ACtx.UnsignedCharTy).getLimitedValue(), IntMax);
1683 
1684   // Get platform dependent values of some macros.
1685   // Try our best to parse this from the Preprocessor, otherwise fallback to a
1686   // default value (what is found in a library header).
1687   const auto EOFv = tryExpandAsInteger("EOF", PP).value_or(-1);
1688   const auto AT_FDCWDv = tryExpandAsInteger("AT_FDCWD", PP).value_or(-100);
1689 
1690   // Auxiliary class to aid adding summaries to the summary map.
1691   struct AddToFunctionSummaryMap {
1692     const ASTContext &ACtx;
1693     FunctionSummaryMapType &Map;
1694     bool DisplayLoadedSummaries;
1695     AddToFunctionSummaryMap(const ASTContext &ACtx, FunctionSummaryMapType &FSM,
1696                             bool DisplayLoadedSummaries)
1697         : ACtx(ACtx), Map(FSM), DisplayLoadedSummaries(DisplayLoadedSummaries) {
1698     }
1699 
1700     // Add a summary to a FunctionDecl found by lookup. The lookup is performed
1701     // by the given Name, and in the global scope. The summary will be attached
1702     // to the found FunctionDecl only if the signatures match.
1703     //
1704     // Returns true if the summary has been added, false otherwise.
1705     bool operator()(StringRef Name, Signature Sign, Summary Sum) {
1706       if (Sign.isInvalid())
1707         return false;
1708       IdentifierInfo &II = ACtx.Idents.get(Name);
1709       auto LookupRes = ACtx.getTranslationUnitDecl()->lookup(&II);
1710       if (LookupRes.empty())
1711         return false;
1712       for (Decl *D : LookupRes) {
1713         if (auto *FD = dyn_cast<FunctionDecl>(D)) {
1714           if (Sum.matchesAndSet(Sign, FD)) {
1715             auto Res = Map.insert({FD->getCanonicalDecl(), Sum});
1716             assert(Res.second && "Function already has a summary set!");
1717             (void)Res;
1718             if (DisplayLoadedSummaries) {
1719               llvm::errs() << "Loaded summary for: ";
1720               FD->print(llvm::errs());
1721               llvm::errs() << "\n";
1722             }
1723             return true;
1724           }
1725         }
1726       }
1727       return false;
1728     }
1729     // Add the same summary for different names with the Signature explicitly
1730     // given.
1731     void operator()(std::vector<StringRef> Names, Signature Sign, Summary Sum) {
1732       for (StringRef Name : Names)
1733         operator()(Name, Sign, Sum);
1734     }
1735   } addToFunctionSummaryMap(ACtx, FunctionSummaryMap, DisplayLoadedSummaries);
1736 
1737   // Below are helpers functions to create the summaries.
1738   auto ArgumentCondition = [](ArgNo ArgN, RangeKind Kind, IntRangeVector Ranges,
1739                               StringRef Desc = "") {
1740     return std::make_shared<RangeConstraint>(ArgN, Kind, Ranges, Desc);
1741   };
1742   auto BufferSize = [](auto... Args) {
1743     return std::make_shared<BufferSizeConstraint>(Args...);
1744   };
1745   struct {
1746     auto operator()(RangeKind Kind, IntRangeVector Ranges) {
1747       return std::make_shared<RangeConstraint>(Ret, Kind, Ranges);
1748     }
1749     auto operator()(BinaryOperator::Opcode Op, ArgNo OtherArgN) {
1750       return std::make_shared<ComparisonConstraint>(Ret, Op, OtherArgN);
1751     }
1752   } ReturnValueCondition;
1753   struct {
1754     auto operator()(RangeInt b, RangeInt e) {
1755       return IntRangeVector{std::pair<RangeInt, RangeInt>{b, e}};
1756     }
1757     auto operator()(RangeInt b, std::optional<RangeInt> e) {
1758       if (e)
1759         return IntRangeVector{std::pair<RangeInt, RangeInt>{b, *e}};
1760       return IntRangeVector{};
1761     }
1762     auto operator()(std::pair<RangeInt, RangeInt> i0,
1763                     std::pair<RangeInt, std::optional<RangeInt>> i1) {
1764       if (i1.second)
1765         return IntRangeVector{i0, {i1.first, *(i1.second)}};
1766       return IntRangeVector{i0};
1767     }
1768   } Range;
1769   auto SingleValue = [](RangeInt v) {
1770     return IntRangeVector{std::pair<RangeInt, RangeInt>{v, v}};
1771   };
1772   auto LessThanOrEq = BO_LE;
1773   auto NotNull = [&](ArgNo ArgN) {
1774     return std::make_shared<NotNullConstraint>(ArgN);
1775   };
1776   auto IsNull = [&](ArgNo ArgN) {
1777     return std::make_shared<NotNullConstraint>(ArgN, false);
1778   };
1779   auto NotNullBuffer = [&](ArgNo ArgN, ArgNo SizeArg1N, ArgNo SizeArg2N) {
1780     return std::make_shared<NotNullBufferConstraint>(ArgN, SizeArg1N,
1781                                                      SizeArg2N);
1782   };
1783 
1784   std::optional<QualType> FileTy = lookupTy("FILE");
1785   std::optional<QualType> FilePtrTy = getPointerTy(FileTy);
1786   std::optional<QualType> FilePtrRestrictTy = getRestrictTy(FilePtrTy);
1787 
1788   std::optional<QualType> FPosTTy = lookupTy("fpos_t");
1789   std::optional<QualType> FPosTPtrTy = getPointerTy(FPosTTy);
1790   std::optional<QualType> ConstFPosTPtrTy = getPointerTy(getConstTy(FPosTTy));
1791   std::optional<QualType> FPosTPtrRestrictTy = getRestrictTy(FPosTPtrTy);
1792 
1793   constexpr llvm::StringLiteral GenericSuccessMsg(
1794       "Assuming that '{0}' is successful");
1795   constexpr llvm::StringLiteral GenericFailureMsg("Assuming that '{0}' fails");
1796 
1797   // We are finally ready to define specifications for all supported functions.
1798   //
1799   // Argument ranges should always cover all variants. If return value
1800   // is completely unknown, omit it from the respective range set.
1801   //
1802   // Every item in the list of range sets represents a particular
1803   // execution path the analyzer would need to explore once
1804   // the call is modeled - a new program state is constructed
1805   // for every range set, and each range line in the range set
1806   // corresponds to a specific constraint within this state.
1807 
1808   // The isascii() family of functions.
1809   // The behavior is undefined if the value of the argument is not
1810   // representable as unsigned char or is not equal to EOF. See e.g. C99
1811   // 7.4.1.2 The isalpha function (p: 181-182).
1812   addToFunctionSummaryMap(
1813       "isalnum", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1814       Summary(EvalCallAsPure)
1815           // Boils down to isupper() or islower() or isdigit().
1816           .Case({ArgumentCondition(0U, WithinRange,
1817                                    {{'0', '9'}, {'A', 'Z'}, {'a', 'z'}}),
1818                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1819                 ErrnoIrrelevant, "Assuming the character is alphanumeric")
1820           // The locale-specific range.
1821           // No post-condition. We are completely unaware of
1822           // locale-specific return values.
1823           .Case({ArgumentCondition(0U, WithinRange, {{128, UCharRangeMax}})},
1824                 ErrnoIrrelevant)
1825           .Case(
1826               {ArgumentCondition(
1827                    0U, OutOfRange,
1828                    {{'0', '9'}, {'A', 'Z'}, {'a', 'z'}, {128, UCharRangeMax}}),
1829                ReturnValueCondition(WithinRange, SingleValue(0))},
1830               ErrnoIrrelevant, "Assuming the character is non-alphanumeric")
1831           .ArgConstraint(ArgumentCondition(0U, WithinRange,
1832                                            {{EOFv, EOFv}, {0, UCharRangeMax}},
1833                                            "an unsigned char value or EOF")));
1834   addToFunctionSummaryMap(
1835       "isalpha", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1836       Summary(EvalCallAsPure)
1837           .Case({ArgumentCondition(0U, WithinRange, {{'A', 'Z'}, {'a', 'z'}}),
1838                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1839                 ErrnoIrrelevant, "Assuming the character is alphabetical")
1840           // The locale-specific range.
1841           .Case({ArgumentCondition(0U, WithinRange, {{128, UCharRangeMax}})},
1842                 ErrnoIrrelevant)
1843           .Case({ArgumentCondition(
1844                      0U, OutOfRange,
1845                      {{'A', 'Z'}, {'a', 'z'}, {128, UCharRangeMax}}),
1846                  ReturnValueCondition(WithinRange, SingleValue(0))},
1847                 ErrnoIrrelevant, "Assuming the character is non-alphabetical"));
1848   addToFunctionSummaryMap(
1849       "isascii", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1850       Summary(EvalCallAsPure)
1851           .Case({ArgumentCondition(0U, WithinRange, Range(0, 127)),
1852                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1853                 ErrnoIrrelevant, "Assuming the character is an ASCII character")
1854           .Case({ArgumentCondition(0U, OutOfRange, Range(0, 127)),
1855                  ReturnValueCondition(WithinRange, SingleValue(0))},
1856                 ErrnoIrrelevant,
1857                 "Assuming the character is not an ASCII character"));
1858   addToFunctionSummaryMap(
1859       "isblank", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1860       Summary(EvalCallAsPure)
1861           .Case({ArgumentCondition(0U, WithinRange, {{'\t', '\t'}, {' ', ' '}}),
1862                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1863                 ErrnoIrrelevant, "Assuming the character is a blank character")
1864           .Case({ArgumentCondition(0U, OutOfRange, {{'\t', '\t'}, {' ', ' '}}),
1865                  ReturnValueCondition(WithinRange, SingleValue(0))},
1866                 ErrnoIrrelevant,
1867                 "Assuming the character is not a blank character"));
1868   addToFunctionSummaryMap(
1869       "iscntrl", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1870       Summary(EvalCallAsPure)
1871           .Case({ArgumentCondition(0U, WithinRange, {{0, 32}, {127, 127}}),
1872                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1873                 ErrnoIrrelevant,
1874                 "Assuming the character is a control character")
1875           .Case({ArgumentCondition(0U, OutOfRange, {{0, 32}, {127, 127}}),
1876                  ReturnValueCondition(WithinRange, SingleValue(0))},
1877                 ErrnoIrrelevant,
1878                 "Assuming the character is not a control character"));
1879   addToFunctionSummaryMap(
1880       "isdigit", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1881       Summary(EvalCallAsPure)
1882           .Case({ArgumentCondition(0U, WithinRange, Range('0', '9')),
1883                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1884                 ErrnoIrrelevant, "Assuming the character is a digit")
1885           .Case({ArgumentCondition(0U, OutOfRange, Range('0', '9')),
1886                  ReturnValueCondition(WithinRange, SingleValue(0))},
1887                 ErrnoIrrelevant, "Assuming the character is not a digit"));
1888   addToFunctionSummaryMap(
1889       "isgraph", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1890       Summary(EvalCallAsPure)
1891           .Case({ArgumentCondition(0U, WithinRange, Range(33, 126)),
1892                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1893                 ErrnoIrrelevant,
1894                 "Assuming the character has graphical representation")
1895           .Case(
1896               {ArgumentCondition(0U, OutOfRange, Range(33, 126)),
1897                ReturnValueCondition(WithinRange, SingleValue(0))},
1898               ErrnoIrrelevant,
1899               "Assuming the character does not have graphical representation"));
1900   addToFunctionSummaryMap(
1901       "islower", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1902       Summary(EvalCallAsPure)
1903           // Is certainly lowercase.
1904           .Case({ArgumentCondition(0U, WithinRange, Range('a', 'z')),
1905                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1906                 ErrnoIrrelevant, "Assuming the character is a lowercase letter")
1907           // Is ascii but not lowercase.
1908           .Case({ArgumentCondition(0U, WithinRange, Range(0, 127)),
1909                  ArgumentCondition(0U, OutOfRange, Range('a', 'z')),
1910                  ReturnValueCondition(WithinRange, SingleValue(0))},
1911                 ErrnoIrrelevant,
1912                 "Assuming the character is not a lowercase letter")
1913           // The locale-specific range.
1914           .Case({ArgumentCondition(0U, WithinRange, {{128, UCharRangeMax}})},
1915                 ErrnoIrrelevant)
1916           // Is not an unsigned char.
1917           .Case({ArgumentCondition(0U, OutOfRange, Range(0, UCharRangeMax)),
1918                  ReturnValueCondition(WithinRange, SingleValue(0))},
1919                 ErrnoIrrelevant));
1920   addToFunctionSummaryMap(
1921       "isprint", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1922       Summary(EvalCallAsPure)
1923           .Case({ArgumentCondition(0U, WithinRange, Range(32, 126)),
1924                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1925                 ErrnoIrrelevant, "Assuming the character is printable")
1926           .Case({ArgumentCondition(0U, OutOfRange, Range(32, 126)),
1927                  ReturnValueCondition(WithinRange, SingleValue(0))},
1928                 ErrnoIrrelevant, "Assuming the character is non-printable"));
1929   addToFunctionSummaryMap(
1930       "ispunct", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1931       Summary(EvalCallAsPure)
1932           .Case({ArgumentCondition(
1933                      0U, WithinRange,
1934                      {{'!', '/'}, {':', '@'}, {'[', '`'}, {'{', '~'}}),
1935                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1936                 ErrnoIrrelevant, "Assuming the character is a punctuation mark")
1937           .Case({ArgumentCondition(
1938                      0U, OutOfRange,
1939                      {{'!', '/'}, {':', '@'}, {'[', '`'}, {'{', '~'}}),
1940                  ReturnValueCondition(WithinRange, SingleValue(0))},
1941                 ErrnoIrrelevant,
1942                 "Assuming the character is not a punctuation mark"));
1943   addToFunctionSummaryMap(
1944       "isspace", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1945       Summary(EvalCallAsPure)
1946           // Space, '\f', '\n', '\r', '\t', '\v'.
1947           .Case({ArgumentCondition(0U, WithinRange, {{9, 13}, {' ', ' '}}),
1948                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1949                 ErrnoIrrelevant,
1950                 "Assuming the character is a whitespace character")
1951           // The locale-specific range.
1952           .Case({ArgumentCondition(0U, WithinRange, {{128, UCharRangeMax}})},
1953                 ErrnoIrrelevant)
1954           .Case({ArgumentCondition(0U, OutOfRange,
1955                                    {{9, 13}, {' ', ' '}, {128, UCharRangeMax}}),
1956                  ReturnValueCondition(WithinRange, SingleValue(0))},
1957                 ErrnoIrrelevant,
1958                 "Assuming the character is not a whitespace character"));
1959   addToFunctionSummaryMap(
1960       "isupper", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1961       Summary(EvalCallAsPure)
1962           // Is certainly uppercase.
1963           .Case({ArgumentCondition(0U, WithinRange, Range('A', 'Z')),
1964                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1965                 ErrnoIrrelevant,
1966                 "Assuming the character is an uppercase letter")
1967           // The locale-specific range.
1968           .Case({ArgumentCondition(0U, WithinRange, {{128, UCharRangeMax}})},
1969                 ErrnoIrrelevant)
1970           // Other.
1971           .Case({ArgumentCondition(0U, OutOfRange,
1972                                    {{'A', 'Z'}, {128, UCharRangeMax}}),
1973                  ReturnValueCondition(WithinRange, SingleValue(0))},
1974                 ErrnoIrrelevant,
1975                 "Assuming the character is not an uppercase letter"));
1976   addToFunctionSummaryMap(
1977       "isxdigit", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1978       Summary(EvalCallAsPure)
1979           .Case({ArgumentCondition(0U, WithinRange,
1980                                    {{'0', '9'}, {'A', 'F'}, {'a', 'f'}}),
1981                  ReturnValueCondition(OutOfRange, SingleValue(0))},
1982                 ErrnoIrrelevant,
1983                 "Assuming the character is a hexadecimal digit")
1984           .Case({ArgumentCondition(0U, OutOfRange,
1985                                    {{'0', '9'}, {'A', 'F'}, {'a', 'f'}}),
1986                  ReturnValueCondition(WithinRange, SingleValue(0))},
1987                 ErrnoIrrelevant,
1988                 "Assuming the character is not a hexadecimal digit"));
1989   addToFunctionSummaryMap(
1990       "toupper", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1991       Summary(EvalCallAsPure)
1992           .ArgConstraint(ArgumentCondition(0U, WithinRange,
1993                                            {{EOFv, EOFv}, {0, UCharRangeMax}},
1994                                            "an unsigned char value or EOF")));
1995   addToFunctionSummaryMap(
1996       "tolower", Signature(ArgTypes{IntTy}, RetType{IntTy}),
1997       Summary(EvalCallAsPure)
1998           .ArgConstraint(ArgumentCondition(0U, WithinRange,
1999                                            {{EOFv, EOFv}, {0, UCharRangeMax}},
2000                                            "an unsigned char value or EOF")));
2001   addToFunctionSummaryMap(
2002       "toascii", Signature(ArgTypes{IntTy}, RetType{IntTy}),
2003       Summary(EvalCallAsPure)
2004           .ArgConstraint(ArgumentCondition(0U, WithinRange,
2005                                            {{EOFv, EOFv}, {0, UCharRangeMax}},
2006                                            "an unsigned char value or EOF")));
2007 
2008   // The getc() family of functions that returns either a char or an EOF.
2009   addToFunctionSummaryMap(
2010       {"getc", "fgetc"}, Signature(ArgTypes{FilePtrTy}, RetType{IntTy}),
2011       Summary(NoEvalCall)
2012           .Case({ReturnValueCondition(WithinRange,
2013                                       {{EOFv, EOFv}, {0, UCharRangeMax}})},
2014                 ErrnoIrrelevant));
2015   addToFunctionSummaryMap(
2016       "getchar", Signature(ArgTypes{}, RetType{IntTy}),
2017       Summary(NoEvalCall)
2018           .Case({ReturnValueCondition(WithinRange,
2019                                       {{EOFv, EOFv}, {0, UCharRangeMax}})},
2020                 ErrnoIrrelevant));
2021 
2022   // read()-like functions that never return more than buffer size.
2023   auto FreadSummary =
2024       Summary(NoEvalCall)
2025           .Case({ArgumentCondition(1U, WithinRange, Range(1, SizeMax)),
2026                  ArgumentCondition(2U, WithinRange, Range(1, SizeMax)),
2027                  ReturnValueCondition(BO_LT, ArgNo(2)),
2028                  ReturnValueCondition(WithinRange, Range(0, SizeMax))},
2029                 ErrnoNEZeroIrrelevant, GenericFailureMsg)
2030           .Case({ArgumentCondition(1U, WithinRange, Range(1, SizeMax)),
2031                  ReturnValueCondition(BO_EQ, ArgNo(2)),
2032                  ReturnValueCondition(WithinRange, Range(0, SizeMax))},
2033                 ErrnoMustNotBeChecked, GenericSuccessMsg)
2034           .Case({ArgumentCondition(1U, WithinRange, SingleValue(0)),
2035                  ReturnValueCondition(WithinRange, SingleValue(0))},
2036                 ErrnoMustNotBeChecked, GenericSuccessMsg)
2037           .ArgConstraint(NotNullBuffer(ArgNo(0), ArgNo(1), ArgNo(2)))
2038           .ArgConstraint(NotNull(ArgNo(3)))
2039           .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(0), /*BufSize=*/ArgNo(1),
2040                                     /*BufSizeMultiplier=*/ArgNo(2)));
2041 
2042   // size_t fread(void *restrict ptr, size_t size, size_t nitems,
2043   //              FILE *restrict stream);
2044   addToFunctionSummaryMap(
2045       "fread",
2046       Signature(ArgTypes{VoidPtrRestrictTy, SizeTy, SizeTy, FilePtrRestrictTy},
2047                 RetType{SizeTy}),
2048       FreadSummary);
2049   // size_t fwrite(const void *restrict ptr, size_t size, size_t nitems,
2050   //               FILE *restrict stream);
2051   addToFunctionSummaryMap("fwrite",
2052                           Signature(ArgTypes{ConstVoidPtrRestrictTy, SizeTy,
2053                                              SizeTy, FilePtrRestrictTy},
2054                                     RetType{SizeTy}),
2055                           FreadSummary);
2056 
2057   std::optional<QualType> Ssize_tTy = lookupTy("ssize_t");
2058   std::optional<RangeInt> Ssize_tMax = getMaxValue(Ssize_tTy);
2059 
2060   auto ReadSummary =
2061       Summary(NoEvalCall)
2062           .Case({ReturnValueCondition(LessThanOrEq, ArgNo(2)),
2063                  ReturnValueCondition(WithinRange, Range(-1, Ssize_tMax))},
2064                 ErrnoIrrelevant);
2065 
2066   // FIXME these are actually defined by POSIX and not by the C standard, we
2067   // should handle them together with the rest of the POSIX functions.
2068   // ssize_t read(int fildes, void *buf, size_t nbyte);
2069   addToFunctionSummaryMap(
2070       "read", Signature(ArgTypes{IntTy, VoidPtrTy, SizeTy}, RetType{Ssize_tTy}),
2071       ReadSummary);
2072   // ssize_t write(int fildes, const void *buf, size_t nbyte);
2073   addToFunctionSummaryMap(
2074       "write",
2075       Signature(ArgTypes{IntTy, ConstVoidPtrTy, SizeTy}, RetType{Ssize_tTy}),
2076       ReadSummary);
2077 
2078   auto GetLineSummary =
2079       Summary(NoEvalCall)
2080           .Case({ReturnValueCondition(WithinRange,
2081                                       Range({-1, -1}, {1, Ssize_tMax}))},
2082                 ErrnoIrrelevant);
2083 
2084   QualType CharPtrPtrRestrictTy = getRestrictTy(getPointerTy(CharPtrTy));
2085 
2086   // getline()-like functions either fail or read at least the delimiter.
2087   // FIXME these are actually defined by POSIX and not by the C standard, we
2088   // should handle them together with the rest of the POSIX functions.
2089   // ssize_t getline(char **restrict lineptr, size_t *restrict n,
2090   //                 FILE *restrict stream);
2091   addToFunctionSummaryMap(
2092       "getline",
2093       Signature(
2094           ArgTypes{CharPtrPtrRestrictTy, SizePtrRestrictTy, FilePtrRestrictTy},
2095           RetType{Ssize_tTy}),
2096       GetLineSummary);
2097   // ssize_t getdelim(char **restrict lineptr, size_t *restrict n,
2098   //                  int delimiter, FILE *restrict stream);
2099   addToFunctionSummaryMap(
2100       "getdelim",
2101       Signature(ArgTypes{CharPtrPtrRestrictTy, SizePtrRestrictTy, IntTy,
2102                          FilePtrRestrictTy},
2103                 RetType{Ssize_tTy}),
2104       GetLineSummary);
2105 
2106   {
2107     Summary GetenvSummary =
2108         Summary(NoEvalCall)
2109             .ArgConstraint(NotNull(ArgNo(0)))
2110             .Case({NotNull(Ret)}, ErrnoIrrelevant,
2111                   "Assuming the environment variable exists");
2112     // In untrusted environments the envvar might not exist.
2113     if (!ShouldAssumeControlledEnvironment)
2114       GetenvSummary.Case({NotNull(Ret)->negate()}, ErrnoIrrelevant,
2115                          "Assuming the environment variable does not exist");
2116 
2117     // char *getenv(const char *name);
2118     addToFunctionSummaryMap(
2119         "getenv", Signature(ArgTypes{ConstCharPtrTy}, RetType{CharPtrTy}),
2120         std::move(GetenvSummary));
2121   }
2122 
2123   if (ModelPOSIX) {
2124     const auto ReturnsZeroOrMinusOne =
2125         ConstraintSet{ReturnValueCondition(WithinRange, Range(-1, 0))};
2126     const auto ReturnsZero =
2127         ConstraintSet{ReturnValueCondition(WithinRange, SingleValue(0))};
2128     const auto ReturnsMinusOne =
2129         ConstraintSet{ReturnValueCondition(WithinRange, SingleValue(-1))};
2130     const auto ReturnsNonnegative =
2131         ConstraintSet{ReturnValueCondition(WithinRange, Range(0, IntMax))};
2132     const auto ReturnsNonZero =
2133         ConstraintSet{ReturnValueCondition(OutOfRange, SingleValue(0))};
2134     const auto ReturnsFileDescriptor =
2135         ConstraintSet{ReturnValueCondition(WithinRange, Range(-1, IntMax))};
2136     const auto &ReturnsValidFileDescriptor = ReturnsNonnegative;
2137 
2138     auto ValidFileDescriptorOrAtFdcwd = [&](ArgNo ArgN) {
2139       return std::make_shared<RangeConstraint>(
2140           ArgN, WithinRange, Range({AT_FDCWDv, AT_FDCWDv}, {0, IntMax}),
2141           "a valid file descriptor or AT_FDCWD");
2142     };
2143 
2144     // FILE *fopen(const char *restrict pathname, const char *restrict mode);
2145     addToFunctionSummaryMap(
2146         "fopen",
2147         Signature(ArgTypes{ConstCharPtrRestrictTy, ConstCharPtrRestrictTy},
2148                   RetType{FilePtrTy}),
2149         Summary(NoEvalCall)
2150             .Case({NotNull(Ret)}, ErrnoMustNotBeChecked, GenericSuccessMsg)
2151             .Case({IsNull(Ret)}, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2152             .ArgConstraint(NotNull(ArgNo(0)))
2153             .ArgConstraint(NotNull(ArgNo(1))));
2154 
2155     // FILE *tmpfile(void);
2156     addToFunctionSummaryMap(
2157         "tmpfile", Signature(ArgTypes{}, RetType{FilePtrTy}),
2158         Summary(NoEvalCall)
2159             .Case({NotNull(Ret)}, ErrnoMustNotBeChecked, GenericSuccessMsg)
2160             .Case({IsNull(Ret)}, ErrnoNEZeroIrrelevant, GenericFailureMsg));
2161 
2162     // FILE *freopen(const char *restrict pathname, const char *restrict mode,
2163     //               FILE *restrict stream);
2164     addToFunctionSummaryMap(
2165         "freopen",
2166         Signature(ArgTypes{ConstCharPtrRestrictTy, ConstCharPtrRestrictTy,
2167                            FilePtrRestrictTy},
2168                   RetType{FilePtrTy}),
2169         Summary(NoEvalCall)
2170             .Case({ReturnValueCondition(BO_EQ, ArgNo(2))},
2171                   ErrnoMustNotBeChecked, GenericSuccessMsg)
2172             .Case({IsNull(Ret)}, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2173             .ArgConstraint(NotNull(ArgNo(1)))
2174             .ArgConstraint(NotNull(ArgNo(2))));
2175 
2176     // int fclose(FILE *stream);
2177     addToFunctionSummaryMap(
2178         "fclose", Signature(ArgTypes{FilePtrTy}, RetType{IntTy}),
2179         Summary(NoEvalCall)
2180             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2181             .Case({ReturnValueCondition(WithinRange, SingleValue(EOFv))},
2182                   ErrnoNEZeroIrrelevant, GenericFailureMsg)
2183             .ArgConstraint(NotNull(ArgNo(0))));
2184 
2185     // int fseek(FILE *stream, long offset, int whence);
2186     // FIXME: It can be possible to get the 'SEEK_' values (like EOFv) and use
2187     // these for condition of arg 2.
2188     // Now the range [0,2] is used (the `SEEK_*` constants are usually 0,1,2).
2189     addToFunctionSummaryMap(
2190         "fseek", Signature(ArgTypes{FilePtrTy, LongTy, IntTy}, RetType{IntTy}),
2191         Summary(NoEvalCall)
2192             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2193             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2194             .ArgConstraint(NotNull(ArgNo(0)))
2195             .ArgConstraint(ArgumentCondition(2, WithinRange, {{0, 2}})));
2196 
2197     // int fgetpos(FILE *restrict stream, fpos_t *restrict pos);
2198     // From 'The Open Group Base Specifications Issue 7, 2018 edition':
2199     // "The fgetpos() function shall not change the setting of errno if
2200     // successful."
2201     addToFunctionSummaryMap(
2202         "fgetpos",
2203         Signature(ArgTypes{FilePtrRestrictTy, FPosTPtrRestrictTy},
2204                   RetType{IntTy}),
2205         Summary(NoEvalCall)
2206             .Case(ReturnsZero, ErrnoUnchanged, GenericSuccessMsg)
2207             .Case(ReturnsNonZero, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2208             .ArgConstraint(NotNull(ArgNo(0)))
2209             .ArgConstraint(NotNull(ArgNo(1))));
2210 
2211     // int fsetpos(FILE *stream, const fpos_t *pos);
2212     // From 'The Open Group Base Specifications Issue 7, 2018 edition':
2213     // "The fsetpos() function shall not change the setting of errno if
2214     // successful."
2215     addToFunctionSummaryMap(
2216         "fsetpos",
2217         Signature(ArgTypes{FilePtrTy, ConstFPosTPtrTy}, RetType{IntTy}),
2218         Summary(NoEvalCall)
2219             .Case(ReturnsZero, ErrnoUnchanged, GenericSuccessMsg)
2220             .Case(ReturnsNonZero, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2221             .ArgConstraint(NotNull(ArgNo(0)))
2222             .ArgConstraint(NotNull(ArgNo(1))));
2223 
2224     // long ftell(FILE *stream);
2225     // From 'The Open Group Base Specifications Issue 7, 2018 edition':
2226     // "The ftell() function shall not change the setting of errno if
2227     // successful."
2228     addToFunctionSummaryMap(
2229         "ftell", Signature(ArgTypes{FilePtrTy}, RetType{LongTy}),
2230         Summary(NoEvalCall)
2231             .Case({ReturnValueCondition(WithinRange, Range(1, LongMax))},
2232                   ErrnoUnchanged, GenericSuccessMsg)
2233             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2234             .ArgConstraint(NotNull(ArgNo(0))));
2235 
2236     // int fileno(FILE *stream);
2237     addToFunctionSummaryMap(
2238         "fileno", Signature(ArgTypes{FilePtrTy}, RetType{IntTy}),
2239         Summary(NoEvalCall)
2240             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2241                   GenericSuccessMsg)
2242             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2243             .ArgConstraint(NotNull(ArgNo(0))));
2244 
2245     // void rewind(FILE *stream);
2246     // This function indicates error only by setting of 'errno'.
2247     addToFunctionSummaryMap("rewind",
2248                             Signature(ArgTypes{FilePtrTy}, RetType{VoidTy}),
2249                             Summary(NoEvalCall)
2250                                 .Case({}, ErrnoMustBeChecked)
2251                                 .ArgConstraint(NotNull(ArgNo(0))));
2252 
2253     // void clearerr(FILE *stream);
2254     addToFunctionSummaryMap(
2255         "clearerr", Signature(ArgTypes{FilePtrTy}, RetType{VoidTy}),
2256         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2257 
2258     // int feof(FILE *stream);
2259     addToFunctionSummaryMap(
2260         "feof", Signature(ArgTypes{FilePtrTy}, RetType{IntTy}),
2261         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2262 
2263     // int ferror(FILE *stream);
2264     addToFunctionSummaryMap(
2265         "ferror", Signature(ArgTypes{FilePtrTy}, RetType{IntTy}),
2266         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2267 
2268     // long a64l(const char *str64);
2269     addToFunctionSummaryMap(
2270         "a64l", Signature(ArgTypes{ConstCharPtrTy}, RetType{LongTy}),
2271         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2272 
2273     // char *l64a(long value);
2274     addToFunctionSummaryMap("l64a",
2275                             Signature(ArgTypes{LongTy}, RetType{CharPtrTy}),
2276                             Summary(NoEvalCall)
2277                                 .ArgConstraint(ArgumentCondition(
2278                                     0, WithinRange, Range(0, LongMax))));
2279 
2280     // int open(const char *path, int oflag, ...);
2281     addToFunctionSummaryMap(
2282         "open", Signature(ArgTypes{ConstCharPtrTy, IntTy}, RetType{IntTy}),
2283         Summary(NoEvalCall)
2284             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2285                   GenericSuccessMsg)
2286             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2287             .ArgConstraint(NotNull(ArgNo(0))));
2288 
2289     // int openat(int fd, const char *path, int oflag, ...);
2290     addToFunctionSummaryMap(
2291         "openat",
2292         Signature(ArgTypes{IntTy, ConstCharPtrTy, IntTy}, RetType{IntTy}),
2293         Summary(NoEvalCall)
2294             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2295                   GenericSuccessMsg)
2296             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2297             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2298             .ArgConstraint(NotNull(ArgNo(1))));
2299 
2300     // int access(const char *pathname, int amode);
2301     addToFunctionSummaryMap(
2302         "access", Signature(ArgTypes{ConstCharPtrTy, IntTy}, RetType{IntTy}),
2303         Summary(NoEvalCall)
2304             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2305             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2306             .ArgConstraint(NotNull(ArgNo(0))));
2307 
2308     // int faccessat(int dirfd, const char *pathname, int mode, int flags);
2309     addToFunctionSummaryMap(
2310         "faccessat",
2311         Signature(ArgTypes{IntTy, ConstCharPtrTy, IntTy, IntTy},
2312                   RetType{IntTy}),
2313         Summary(NoEvalCall)
2314             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2315             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2316             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2317             .ArgConstraint(NotNull(ArgNo(1))));
2318 
2319     // int dup(int fildes);
2320     addToFunctionSummaryMap(
2321         "dup", Signature(ArgTypes{IntTy}, RetType{IntTy}),
2322         Summary(NoEvalCall)
2323             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2324                   GenericSuccessMsg)
2325             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2326             .ArgConstraint(
2327                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2328 
2329     // int dup2(int fildes1, int filedes2);
2330     addToFunctionSummaryMap(
2331         "dup2", Signature(ArgTypes{IntTy, IntTy}, RetType{IntTy}),
2332         Summary(NoEvalCall)
2333             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2334                   GenericSuccessMsg)
2335             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2336             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
2337             .ArgConstraint(
2338                 ArgumentCondition(1, WithinRange, Range(0, IntMax))));
2339 
2340     // int fdatasync(int fildes);
2341     addToFunctionSummaryMap(
2342         "fdatasync", Signature(ArgTypes{IntTy}, RetType{IntTy}),
2343         Summary(NoEvalCall)
2344             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2345             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2346             .ArgConstraint(
2347                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2348 
2349     // int fnmatch(const char *pattern, const char *string, int flags);
2350     addToFunctionSummaryMap(
2351         "fnmatch",
2352         Signature(ArgTypes{ConstCharPtrTy, ConstCharPtrTy, IntTy},
2353                   RetType{IntTy}),
2354         Summary(NoEvalCall)
2355             .ArgConstraint(NotNull(ArgNo(0)))
2356             .ArgConstraint(NotNull(ArgNo(1))));
2357 
2358     // int fsync(int fildes);
2359     addToFunctionSummaryMap(
2360         "fsync", Signature(ArgTypes{IntTy}, RetType{IntTy}),
2361         Summary(NoEvalCall)
2362             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2363             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2364             .ArgConstraint(
2365                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2366 
2367     std::optional<QualType> Off_tTy = lookupTy("off_t");
2368 
2369     // int truncate(const char *path, off_t length);
2370     addToFunctionSummaryMap(
2371         "truncate",
2372         Signature(ArgTypes{ConstCharPtrTy, Off_tTy}, RetType{IntTy}),
2373         Summary(NoEvalCall)
2374             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2375             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2376             .ArgConstraint(NotNull(ArgNo(0))));
2377 
2378     // int symlink(const char *oldpath, const char *newpath);
2379     addToFunctionSummaryMap(
2380         "symlink",
2381         Signature(ArgTypes{ConstCharPtrTy, ConstCharPtrTy}, RetType{IntTy}),
2382         Summary(NoEvalCall)
2383             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2384             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2385             .ArgConstraint(NotNull(ArgNo(0)))
2386             .ArgConstraint(NotNull(ArgNo(1))));
2387 
2388     // int symlinkat(const char *oldpath, int newdirfd, const char *newpath);
2389     addToFunctionSummaryMap(
2390         "symlinkat",
2391         Signature(ArgTypes{ConstCharPtrTy, IntTy, ConstCharPtrTy},
2392                   RetType{IntTy}),
2393         Summary(NoEvalCall)
2394             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2395             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2396             .ArgConstraint(NotNull(ArgNo(0)))
2397             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(1)))
2398             .ArgConstraint(NotNull(ArgNo(2))));
2399 
2400     // int lockf(int fd, int cmd, off_t len);
2401     addToFunctionSummaryMap(
2402         "lockf", Signature(ArgTypes{IntTy, IntTy, Off_tTy}, RetType{IntTy}),
2403         Summary(NoEvalCall)
2404             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2405             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2406             .ArgConstraint(
2407                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2408 
2409     std::optional<QualType> Mode_tTy = lookupTy("mode_t");
2410 
2411     // int creat(const char *pathname, mode_t mode);
2412     addToFunctionSummaryMap(
2413         "creat", Signature(ArgTypes{ConstCharPtrTy, Mode_tTy}, RetType{IntTy}),
2414         Summary(NoEvalCall)
2415             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2416                   GenericSuccessMsg)
2417             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2418             .ArgConstraint(NotNull(ArgNo(0))));
2419 
2420     // unsigned int sleep(unsigned int seconds);
2421     addToFunctionSummaryMap(
2422         "sleep", Signature(ArgTypes{UnsignedIntTy}, RetType{UnsignedIntTy}),
2423         Summary(NoEvalCall)
2424             .ArgConstraint(
2425                 ArgumentCondition(0, WithinRange, Range(0, UnsignedIntMax))));
2426 
2427     std::optional<QualType> DirTy = lookupTy("DIR");
2428     std::optional<QualType> DirPtrTy = getPointerTy(DirTy);
2429 
2430     // int dirfd(DIR *dirp);
2431     addToFunctionSummaryMap(
2432         "dirfd", Signature(ArgTypes{DirPtrTy}, RetType{IntTy}),
2433         Summary(NoEvalCall)
2434             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2435                   GenericSuccessMsg)
2436             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2437             .ArgConstraint(NotNull(ArgNo(0))));
2438 
2439     // unsigned int alarm(unsigned int seconds);
2440     addToFunctionSummaryMap(
2441         "alarm", Signature(ArgTypes{UnsignedIntTy}, RetType{UnsignedIntTy}),
2442         Summary(NoEvalCall)
2443             .ArgConstraint(
2444                 ArgumentCondition(0, WithinRange, Range(0, UnsignedIntMax))));
2445 
2446     // int closedir(DIR *dir);
2447     addToFunctionSummaryMap(
2448         "closedir", Signature(ArgTypes{DirPtrTy}, RetType{IntTy}),
2449         Summary(NoEvalCall)
2450             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2451             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2452             .ArgConstraint(NotNull(ArgNo(0))));
2453 
2454     // char *strdup(const char *s);
2455     addToFunctionSummaryMap(
2456         "strdup", Signature(ArgTypes{ConstCharPtrTy}, RetType{CharPtrTy}),
2457         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2458 
2459     // char *strndup(const char *s, size_t n);
2460     addToFunctionSummaryMap(
2461         "strndup",
2462         Signature(ArgTypes{ConstCharPtrTy, SizeTy}, RetType{CharPtrTy}),
2463         Summary(NoEvalCall)
2464             .ArgConstraint(NotNull(ArgNo(0)))
2465             .ArgConstraint(
2466                 ArgumentCondition(1, WithinRange, Range(0, SizeMax))));
2467 
2468     // wchar_t *wcsdup(const wchar_t *s);
2469     addToFunctionSummaryMap(
2470         "wcsdup", Signature(ArgTypes{ConstWchar_tPtrTy}, RetType{Wchar_tPtrTy}),
2471         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2472 
2473     // int mkstemp(char *template);
2474     addToFunctionSummaryMap(
2475         "mkstemp", Signature(ArgTypes{CharPtrTy}, RetType{IntTy}),
2476         Summary(NoEvalCall)
2477             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2478                   GenericSuccessMsg)
2479             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2480             .ArgConstraint(NotNull(ArgNo(0))));
2481 
2482     // char *mkdtemp(char *template);
2483     // FIXME: Improve for errno modeling.
2484     addToFunctionSummaryMap(
2485         "mkdtemp", Signature(ArgTypes{CharPtrTy}, RetType{CharPtrTy}),
2486         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2487 
2488     // char *getcwd(char *buf, size_t size);
2489     // FIXME: Improve for errno modeling.
2490     addToFunctionSummaryMap(
2491         "getcwd", Signature(ArgTypes{CharPtrTy, SizeTy}, RetType{CharPtrTy}),
2492         Summary(NoEvalCall)
2493             .ArgConstraint(
2494                 ArgumentCondition(1, WithinRange, Range(0, SizeMax))));
2495 
2496     // int mkdir(const char *pathname, mode_t mode);
2497     addToFunctionSummaryMap(
2498         "mkdir", Signature(ArgTypes{ConstCharPtrTy, Mode_tTy}, RetType{IntTy}),
2499         Summary(NoEvalCall)
2500             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2501             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2502             .ArgConstraint(NotNull(ArgNo(0))));
2503 
2504     // int mkdirat(int dirfd, const char *pathname, mode_t mode);
2505     addToFunctionSummaryMap(
2506         "mkdirat",
2507         Signature(ArgTypes{IntTy, ConstCharPtrTy, Mode_tTy}, RetType{IntTy}),
2508         Summary(NoEvalCall)
2509             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2510             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2511             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2512             .ArgConstraint(NotNull(ArgNo(1))));
2513 
2514     std::optional<QualType> Dev_tTy = lookupTy("dev_t");
2515 
2516     // int mknod(const char *pathname, mode_t mode, dev_t dev);
2517     addToFunctionSummaryMap(
2518         "mknod",
2519         Signature(ArgTypes{ConstCharPtrTy, Mode_tTy, Dev_tTy}, RetType{IntTy}),
2520         Summary(NoEvalCall)
2521             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2522             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2523             .ArgConstraint(NotNull(ArgNo(0))));
2524 
2525     // int mknodat(int dirfd, const char *pathname, mode_t mode, dev_t dev);
2526     addToFunctionSummaryMap(
2527         "mknodat",
2528         Signature(ArgTypes{IntTy, ConstCharPtrTy, Mode_tTy, Dev_tTy},
2529                   RetType{IntTy}),
2530         Summary(NoEvalCall)
2531             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2532             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2533             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2534             .ArgConstraint(NotNull(ArgNo(1))));
2535 
2536     // int chmod(const char *path, mode_t mode);
2537     addToFunctionSummaryMap(
2538         "chmod", Signature(ArgTypes{ConstCharPtrTy, Mode_tTy}, RetType{IntTy}),
2539         Summary(NoEvalCall)
2540             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2541             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2542             .ArgConstraint(NotNull(ArgNo(0))));
2543 
2544     // int fchmodat(int dirfd, const char *pathname, mode_t mode, int flags);
2545     addToFunctionSummaryMap(
2546         "fchmodat",
2547         Signature(ArgTypes{IntTy, ConstCharPtrTy, Mode_tTy, IntTy},
2548                   RetType{IntTy}),
2549         Summary(NoEvalCall)
2550             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2551             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2552             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2553             .ArgConstraint(NotNull(ArgNo(1))));
2554 
2555     // int fchmod(int fildes, mode_t mode);
2556     addToFunctionSummaryMap(
2557         "fchmod", Signature(ArgTypes{IntTy, Mode_tTy}, RetType{IntTy}),
2558         Summary(NoEvalCall)
2559             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2560             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2561             .ArgConstraint(
2562                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2563 
2564     std::optional<QualType> Uid_tTy = lookupTy("uid_t");
2565     std::optional<QualType> Gid_tTy = lookupTy("gid_t");
2566 
2567     // int fchownat(int dirfd, const char *pathname, uid_t owner, gid_t group,
2568     //              int flags);
2569     addToFunctionSummaryMap(
2570         "fchownat",
2571         Signature(ArgTypes{IntTy, ConstCharPtrTy, Uid_tTy, Gid_tTy, IntTy},
2572                   RetType{IntTy}),
2573         Summary(NoEvalCall)
2574             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2575             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2576             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2577             .ArgConstraint(NotNull(ArgNo(1))));
2578 
2579     // int chown(const char *path, uid_t owner, gid_t group);
2580     addToFunctionSummaryMap(
2581         "chown",
2582         Signature(ArgTypes{ConstCharPtrTy, Uid_tTy, Gid_tTy}, RetType{IntTy}),
2583         Summary(NoEvalCall)
2584             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2585             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2586             .ArgConstraint(NotNull(ArgNo(0))));
2587 
2588     // int lchown(const char *path, uid_t owner, gid_t group);
2589     addToFunctionSummaryMap(
2590         "lchown",
2591         Signature(ArgTypes{ConstCharPtrTy, Uid_tTy, Gid_tTy}, RetType{IntTy}),
2592         Summary(NoEvalCall)
2593             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2594             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2595             .ArgConstraint(NotNull(ArgNo(0))));
2596 
2597     // int fchown(int fildes, uid_t owner, gid_t group);
2598     addToFunctionSummaryMap(
2599         "fchown", Signature(ArgTypes{IntTy, Uid_tTy, Gid_tTy}, RetType{IntTy}),
2600         Summary(NoEvalCall)
2601             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2602             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2603             .ArgConstraint(
2604                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2605 
2606     // int rmdir(const char *pathname);
2607     addToFunctionSummaryMap(
2608         "rmdir", Signature(ArgTypes{ConstCharPtrTy}, RetType{IntTy}),
2609         Summary(NoEvalCall)
2610             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2611             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2612             .ArgConstraint(NotNull(ArgNo(0))));
2613 
2614     // int chdir(const char *path);
2615     addToFunctionSummaryMap(
2616         "chdir", Signature(ArgTypes{ConstCharPtrTy}, RetType{IntTy}),
2617         Summary(NoEvalCall)
2618             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2619             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2620             .ArgConstraint(NotNull(ArgNo(0))));
2621 
2622     // int link(const char *oldpath, const char *newpath);
2623     addToFunctionSummaryMap(
2624         "link",
2625         Signature(ArgTypes{ConstCharPtrTy, ConstCharPtrTy}, RetType{IntTy}),
2626         Summary(NoEvalCall)
2627             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2628             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2629             .ArgConstraint(NotNull(ArgNo(0)))
2630             .ArgConstraint(NotNull(ArgNo(1))));
2631 
2632     // int linkat(int fd1, const char *path1, int fd2, const char *path2,
2633     //            int flag);
2634     addToFunctionSummaryMap(
2635         "linkat",
2636         Signature(ArgTypes{IntTy, ConstCharPtrTy, IntTy, ConstCharPtrTy, IntTy},
2637                   RetType{IntTy}),
2638         Summary(NoEvalCall)
2639             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2640             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2641             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2642             .ArgConstraint(NotNull(ArgNo(1)))
2643             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(2)))
2644             .ArgConstraint(NotNull(ArgNo(3))));
2645 
2646     // int unlink(const char *pathname);
2647     addToFunctionSummaryMap(
2648         "unlink", Signature(ArgTypes{ConstCharPtrTy}, RetType{IntTy}),
2649         Summary(NoEvalCall)
2650             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2651             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2652             .ArgConstraint(NotNull(ArgNo(0))));
2653 
2654     // int unlinkat(int fd, const char *path, int flag);
2655     addToFunctionSummaryMap(
2656         "unlinkat",
2657         Signature(ArgTypes{IntTy, ConstCharPtrTy, IntTy}, RetType{IntTy}),
2658         Summary(NoEvalCall)
2659             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2660             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2661             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2662             .ArgConstraint(NotNull(ArgNo(1))));
2663 
2664     std::optional<QualType> StructStatTy = lookupTy("stat");
2665     std::optional<QualType> StructStatPtrTy = getPointerTy(StructStatTy);
2666     std::optional<QualType> StructStatPtrRestrictTy =
2667         getRestrictTy(StructStatPtrTy);
2668 
2669     // int fstat(int fd, struct stat *statbuf);
2670     addToFunctionSummaryMap(
2671         "fstat", Signature(ArgTypes{IntTy, StructStatPtrTy}, RetType{IntTy}),
2672         Summary(NoEvalCall)
2673             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2674             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2675             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
2676             .ArgConstraint(NotNull(ArgNo(1))));
2677 
2678     // int stat(const char *restrict path, struct stat *restrict buf);
2679     addToFunctionSummaryMap(
2680         "stat",
2681         Signature(ArgTypes{ConstCharPtrRestrictTy, StructStatPtrRestrictTy},
2682                   RetType{IntTy}),
2683         Summary(NoEvalCall)
2684             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2685             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2686             .ArgConstraint(NotNull(ArgNo(0)))
2687             .ArgConstraint(NotNull(ArgNo(1))));
2688 
2689     // int lstat(const char *restrict path, struct stat *restrict buf);
2690     addToFunctionSummaryMap(
2691         "lstat",
2692         Signature(ArgTypes{ConstCharPtrRestrictTy, StructStatPtrRestrictTy},
2693                   RetType{IntTy}),
2694         Summary(NoEvalCall)
2695             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2696             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2697             .ArgConstraint(NotNull(ArgNo(0)))
2698             .ArgConstraint(NotNull(ArgNo(1))));
2699 
2700     // int fstatat(int fd, const char *restrict path,
2701     //             struct stat *restrict buf, int flag);
2702     addToFunctionSummaryMap(
2703         "fstatat",
2704         Signature(ArgTypes{IntTy, ConstCharPtrRestrictTy,
2705                            StructStatPtrRestrictTy, IntTy},
2706                   RetType{IntTy}),
2707         Summary(NoEvalCall)
2708             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2709             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2710             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2711             .ArgConstraint(NotNull(ArgNo(1)))
2712             .ArgConstraint(NotNull(ArgNo(2))));
2713 
2714     // DIR *opendir(const char *name);
2715     // FIXME: Improve for errno modeling.
2716     addToFunctionSummaryMap(
2717         "opendir", Signature(ArgTypes{ConstCharPtrTy}, RetType{DirPtrTy}),
2718         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2719 
2720     // DIR *fdopendir(int fd);
2721     // FIXME: Improve for errno modeling.
2722     addToFunctionSummaryMap("fdopendir",
2723                             Signature(ArgTypes{IntTy}, RetType{DirPtrTy}),
2724                             Summary(NoEvalCall)
2725                                 .ArgConstraint(ArgumentCondition(
2726                                     0, WithinRange, Range(0, IntMax))));
2727 
2728     // int isatty(int fildes);
2729     addToFunctionSummaryMap(
2730         "isatty", Signature(ArgTypes{IntTy}, RetType{IntTy}),
2731         Summary(NoEvalCall)
2732             .Case({ReturnValueCondition(WithinRange, Range(0, 1))},
2733                   ErrnoIrrelevant)
2734             .ArgConstraint(
2735                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2736 
2737     // FILE *popen(const char *command, const char *type);
2738     // FIXME: Improve for errno modeling.
2739     addToFunctionSummaryMap(
2740         "popen",
2741         Signature(ArgTypes{ConstCharPtrTy, ConstCharPtrTy}, RetType{FilePtrTy}),
2742         Summary(NoEvalCall)
2743             .ArgConstraint(NotNull(ArgNo(0)))
2744             .ArgConstraint(NotNull(ArgNo(1))));
2745 
2746     // int pclose(FILE *stream);
2747     // FIXME: Improve for errno modeling.
2748     addToFunctionSummaryMap(
2749         "pclose", Signature(ArgTypes{FilePtrTy}, RetType{IntTy}),
2750         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2751 
2752     // int close(int fildes);
2753     addToFunctionSummaryMap(
2754         "close", Signature(ArgTypes{IntTy}, RetType{IntTy}),
2755         Summary(NoEvalCall)
2756             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2757             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2758             .ArgConstraint(
2759                 ArgumentCondition(0, WithinRange, Range(-1, IntMax))));
2760 
2761     // long fpathconf(int fildes, int name);
2762     addToFunctionSummaryMap("fpathconf",
2763                             Signature(ArgTypes{IntTy, IntTy}, RetType{LongTy}),
2764                             Summary(NoEvalCall)
2765                                 .ArgConstraint(ArgumentCondition(
2766                                     0, WithinRange, Range(0, IntMax))));
2767 
2768     // long pathconf(const char *path, int name);
2769     addToFunctionSummaryMap(
2770         "pathconf", Signature(ArgTypes{ConstCharPtrTy, IntTy}, RetType{LongTy}),
2771         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2772 
2773     // FILE *fdopen(int fd, const char *mode);
2774     // FIXME: Improve for errno modeling.
2775     addToFunctionSummaryMap(
2776         "fdopen",
2777         Signature(ArgTypes{IntTy, ConstCharPtrTy}, RetType{FilePtrTy}),
2778         Summary(NoEvalCall)
2779             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
2780             .ArgConstraint(NotNull(ArgNo(1))));
2781 
2782     // void rewinddir(DIR *dir);
2783     addToFunctionSummaryMap(
2784         "rewinddir", Signature(ArgTypes{DirPtrTy}, RetType{VoidTy}),
2785         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2786 
2787     // void seekdir(DIR *dirp, long loc);
2788     addToFunctionSummaryMap(
2789         "seekdir", Signature(ArgTypes{DirPtrTy, LongTy}, RetType{VoidTy}),
2790         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2791 
2792     // int rand_r(unsigned int *seedp);
2793     addToFunctionSummaryMap(
2794         "rand_r", Signature(ArgTypes{UnsignedIntPtrTy}, RetType{IntTy}),
2795         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2796 
2797     // int fseeko(FILE *stream, off_t offset, int whence);
2798     addToFunctionSummaryMap(
2799         "fseeko",
2800         Signature(ArgTypes{FilePtrTy, Off_tTy, IntTy}, RetType{IntTy}),
2801         Summary(NoEvalCall)
2802             .Case(ReturnsZeroOrMinusOne, ErrnoIrrelevant)
2803             .ArgConstraint(NotNull(ArgNo(0))));
2804 
2805     // off_t ftello(FILE *stream);
2806     addToFunctionSummaryMap(
2807         "ftello", Signature(ArgTypes{FilePtrTy}, RetType{Off_tTy}),
2808         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2809 
2810     // void *mmap(void *addr, size_t length, int prot, int flags, int fd,
2811     // off_t offset);
2812     // FIXME: Improve for errno modeling.
2813     addToFunctionSummaryMap(
2814         "mmap",
2815         Signature(ArgTypes{VoidPtrTy, SizeTy, IntTy, IntTy, IntTy, Off_tTy},
2816                   RetType{VoidPtrTy}),
2817         Summary(NoEvalCall)
2818             .ArgConstraint(ArgumentCondition(1, WithinRange, Range(1, SizeMax)))
2819             .ArgConstraint(
2820                 ArgumentCondition(4, WithinRange, Range(-1, IntMax))));
2821 
2822     std::optional<QualType> Off64_tTy = lookupTy("off64_t");
2823     // void *mmap64(void *addr, size_t length, int prot, int flags, int fd,
2824     // off64_t offset);
2825     // FIXME: Improve for errno modeling.
2826     addToFunctionSummaryMap(
2827         "mmap64",
2828         Signature(ArgTypes{VoidPtrTy, SizeTy, IntTy, IntTy, IntTy, Off64_tTy},
2829                   RetType{VoidPtrTy}),
2830         Summary(NoEvalCall)
2831             .ArgConstraint(ArgumentCondition(1, WithinRange, Range(1, SizeMax)))
2832             .ArgConstraint(
2833                 ArgumentCondition(4, WithinRange, Range(-1, IntMax))));
2834 
2835     // int pipe(int fildes[2]);
2836     addToFunctionSummaryMap(
2837         "pipe", Signature(ArgTypes{IntPtrTy}, RetType{IntTy}),
2838         Summary(NoEvalCall)
2839             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2840             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2841             .ArgConstraint(NotNull(ArgNo(0))));
2842 
2843     // off_t lseek(int fildes, off_t offset, int whence);
2844     // In the first case we can not tell for sure if it failed or not.
2845     // A return value different from of the expected offset (that is unknown
2846     // here) may indicate failure. For this reason we do not enforce the errno
2847     // check (can cause false positive).
2848     addToFunctionSummaryMap(
2849         "lseek", Signature(ArgTypes{IntTy, Off_tTy, IntTy}, RetType{Off_tTy}),
2850         Summary(NoEvalCall)
2851             .Case(ReturnsNonnegative, ErrnoIrrelevant)
2852             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2853             .ArgConstraint(
2854                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
2855 
2856     // ssize_t readlink(const char *restrict path, char *restrict buf,
2857     //                  size_t bufsize);
2858     addToFunctionSummaryMap(
2859         "readlink",
2860         Signature(ArgTypes{ConstCharPtrRestrictTy, CharPtrRestrictTy, SizeTy},
2861                   RetType{Ssize_tTy}),
2862         Summary(NoEvalCall)
2863             .Case({ReturnValueCondition(LessThanOrEq, ArgNo(2)),
2864                    ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
2865                   ErrnoMustNotBeChecked, GenericSuccessMsg)
2866             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2867             .ArgConstraint(NotNull(ArgNo(0)))
2868             .ArgConstraint(NotNull(ArgNo(1)))
2869             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(1),
2870                                       /*BufSize=*/ArgNo(2)))
2871             .ArgConstraint(
2872                 ArgumentCondition(2, WithinRange, Range(0, SizeMax))));
2873 
2874     // ssize_t readlinkat(int fd, const char *restrict path,
2875     //                    char *restrict buf, size_t bufsize);
2876     addToFunctionSummaryMap(
2877         "readlinkat",
2878         Signature(
2879             ArgTypes{IntTy, ConstCharPtrRestrictTy, CharPtrRestrictTy, SizeTy},
2880             RetType{Ssize_tTy}),
2881         Summary(NoEvalCall)
2882             .Case({ReturnValueCondition(LessThanOrEq, ArgNo(3)),
2883                    ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
2884                   ErrnoMustNotBeChecked, GenericSuccessMsg)
2885             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2886             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2887             .ArgConstraint(NotNull(ArgNo(1)))
2888             .ArgConstraint(NotNull(ArgNo(2)))
2889             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(2),
2890                                       /*BufSize=*/ArgNo(3)))
2891             .ArgConstraint(
2892                 ArgumentCondition(3, WithinRange, Range(0, SizeMax))));
2893 
2894     // int renameat(int olddirfd, const char *oldpath, int newdirfd, const char
2895     // *newpath);
2896     addToFunctionSummaryMap(
2897         "renameat",
2898         Signature(ArgTypes{IntTy, ConstCharPtrTy, IntTy, ConstCharPtrTy},
2899                   RetType{IntTy}),
2900         Summary(NoEvalCall)
2901             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
2902             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2903             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(0)))
2904             .ArgConstraint(NotNull(ArgNo(1)))
2905             .ArgConstraint(ValidFileDescriptorOrAtFdcwd(ArgNo(2)))
2906             .ArgConstraint(NotNull(ArgNo(3))));
2907 
2908     // char *realpath(const char *restrict file_name,
2909     //                char *restrict resolved_name);
2910     // FIXME: Improve for errno modeling.
2911     addToFunctionSummaryMap(
2912         "realpath",
2913         Signature(ArgTypes{ConstCharPtrRestrictTy, CharPtrRestrictTy},
2914                   RetType{CharPtrTy}),
2915         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
2916 
2917     QualType CharPtrConstPtr = getPointerTy(getConstTy(CharPtrTy));
2918 
2919     // int execv(const char *path, char *const argv[]);
2920     addToFunctionSummaryMap(
2921         "execv",
2922         Signature(ArgTypes{ConstCharPtrTy, CharPtrConstPtr}, RetType{IntTy}),
2923         Summary(NoEvalCall)
2924             .Case({ReturnValueCondition(WithinRange, SingleValue(-1))},
2925                   ErrnoIrrelevant)
2926             .ArgConstraint(NotNull(ArgNo(0))));
2927 
2928     // int execvp(const char *file, char *const argv[]);
2929     addToFunctionSummaryMap(
2930         "execvp",
2931         Signature(ArgTypes{ConstCharPtrTy, CharPtrConstPtr}, RetType{IntTy}),
2932         Summary(NoEvalCall)
2933             .Case({ReturnValueCondition(WithinRange, SingleValue(-1))},
2934                   ErrnoIrrelevant)
2935             .ArgConstraint(NotNull(ArgNo(0))));
2936 
2937     // int getopt(int argc, char * const argv[], const char *optstring);
2938     addToFunctionSummaryMap(
2939         "getopt",
2940         Signature(ArgTypes{IntTy, CharPtrConstPtr, ConstCharPtrTy},
2941                   RetType{IntTy}),
2942         Summary(NoEvalCall)
2943             .Case({ReturnValueCondition(WithinRange, Range(-1, UCharRangeMax))},
2944                   ErrnoIrrelevant)
2945             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
2946             .ArgConstraint(NotNull(ArgNo(1)))
2947             .ArgConstraint(NotNull(ArgNo(2))));
2948 
2949     std::optional<QualType> StructSockaddrTy = lookupTy("sockaddr");
2950     std::optional<QualType> StructSockaddrPtrTy =
2951         getPointerTy(StructSockaddrTy);
2952     std::optional<QualType> ConstStructSockaddrPtrTy =
2953         getPointerTy(getConstTy(StructSockaddrTy));
2954     std::optional<QualType> StructSockaddrPtrRestrictTy =
2955         getRestrictTy(StructSockaddrPtrTy);
2956     std::optional<QualType> ConstStructSockaddrPtrRestrictTy =
2957         getRestrictTy(ConstStructSockaddrPtrTy);
2958     std::optional<QualType> Socklen_tTy = lookupTy("socklen_t");
2959     std::optional<QualType> Socklen_tPtrTy = getPointerTy(Socklen_tTy);
2960     std::optional<QualType> Socklen_tPtrRestrictTy =
2961         getRestrictTy(Socklen_tPtrTy);
2962     std::optional<RangeInt> Socklen_tMax = getMaxValue(Socklen_tTy);
2963 
2964     // In 'socket.h' of some libc implementations with C99, sockaddr parameter
2965     // is a transparent union of the underlying sockaddr_ family of pointers
2966     // instead of being a pointer to struct sockaddr. In these cases, the
2967     // standardized signature will not match, thus we try to match with another
2968     // signature that has the joker Irrelevant type. We also remove those
2969     // constraints which require pointer types for the sockaddr param.
2970 
2971     // int socket(int domain, int type, int protocol);
2972     addToFunctionSummaryMap(
2973         "socket", Signature(ArgTypes{IntTy, IntTy, IntTy}, RetType{IntTy}),
2974         Summary(NoEvalCall)
2975             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2976                   GenericSuccessMsg)
2977             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg));
2978 
2979     auto Accept =
2980         Summary(NoEvalCall)
2981             .Case(ReturnsValidFileDescriptor, ErrnoMustNotBeChecked,
2982                   GenericSuccessMsg)
2983             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
2984             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)));
2985     if (!addToFunctionSummaryMap(
2986             "accept",
2987             // int accept(int socket, struct sockaddr *restrict address,
2988             //            socklen_t *restrict address_len);
2989             Signature(ArgTypes{IntTy, StructSockaddrPtrRestrictTy,
2990                                Socklen_tPtrRestrictTy},
2991                       RetType{IntTy}),
2992             Accept))
2993       addToFunctionSummaryMap(
2994           "accept",
2995           Signature(ArgTypes{IntTy, Irrelevant, Socklen_tPtrRestrictTy},
2996                     RetType{IntTy}),
2997           Accept);
2998 
2999     // int bind(int socket, const struct sockaddr *address, socklen_t
3000     //          address_len);
3001     if (!addToFunctionSummaryMap(
3002             "bind",
3003             Signature(ArgTypes{IntTy, ConstStructSockaddrPtrTy, Socklen_tTy},
3004                       RetType{IntTy}),
3005             Summary(NoEvalCall)
3006                 .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3007                 .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3008                 .ArgConstraint(
3009                     ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3010                 .ArgConstraint(NotNull(ArgNo(1)))
3011                 .ArgConstraint(
3012                     BufferSize(/*Buffer=*/ArgNo(1), /*BufSize=*/ArgNo(2)))
3013                 .ArgConstraint(
3014                     ArgumentCondition(2, WithinRange, Range(0, Socklen_tMax)))))
3015       // Do not add constraints on sockaddr.
3016       addToFunctionSummaryMap(
3017           "bind",
3018           Signature(ArgTypes{IntTy, Irrelevant, Socklen_tTy}, RetType{IntTy}),
3019           Summary(NoEvalCall)
3020               .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3021               .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3022               .ArgConstraint(
3023                   ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3024               .ArgConstraint(
3025                   ArgumentCondition(2, WithinRange, Range(0, Socklen_tMax))));
3026 
3027     // int getpeername(int socket, struct sockaddr *restrict address,
3028     //                 socklen_t *restrict address_len);
3029     if (!addToFunctionSummaryMap(
3030             "getpeername",
3031             Signature(ArgTypes{IntTy, StructSockaddrPtrRestrictTy,
3032                                Socklen_tPtrRestrictTy},
3033                       RetType{IntTy}),
3034             Summary(NoEvalCall)
3035                 .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3036                 .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3037                 .ArgConstraint(
3038                     ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3039                 .ArgConstraint(NotNull(ArgNo(1)))
3040                 .ArgConstraint(NotNull(ArgNo(2)))))
3041       addToFunctionSummaryMap(
3042           "getpeername",
3043           Signature(ArgTypes{IntTy, Irrelevant, Socklen_tPtrRestrictTy},
3044                     RetType{IntTy}),
3045           Summary(NoEvalCall)
3046               .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3047               .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3048               .ArgConstraint(
3049                   ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3050 
3051     // int getsockname(int socket, struct sockaddr *restrict address,
3052     //                 socklen_t *restrict address_len);
3053     if (!addToFunctionSummaryMap(
3054             "getsockname",
3055             Signature(ArgTypes{IntTy, StructSockaddrPtrRestrictTy,
3056                                Socklen_tPtrRestrictTy},
3057                       RetType{IntTy}),
3058             Summary(NoEvalCall)
3059                 .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3060                 .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3061                 .ArgConstraint(
3062                     ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3063                 .ArgConstraint(NotNull(ArgNo(1)))
3064                 .ArgConstraint(NotNull(ArgNo(2)))))
3065       addToFunctionSummaryMap(
3066           "getsockname",
3067           Signature(ArgTypes{IntTy, Irrelevant, Socklen_tPtrRestrictTy},
3068                     RetType{IntTy}),
3069           Summary(NoEvalCall)
3070               .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3071               .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3072               .ArgConstraint(
3073                   ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3074 
3075     // int connect(int socket, const struct sockaddr *address, socklen_t
3076     //             address_len);
3077     if (!addToFunctionSummaryMap(
3078             "connect",
3079             Signature(ArgTypes{IntTy, ConstStructSockaddrPtrTy, Socklen_tTy},
3080                       RetType{IntTy}),
3081             Summary(NoEvalCall)
3082                 .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3083                 .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3084                 .ArgConstraint(
3085                     ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3086                 .ArgConstraint(NotNull(ArgNo(1)))))
3087       addToFunctionSummaryMap(
3088           "connect",
3089           Signature(ArgTypes{IntTy, Irrelevant, Socklen_tTy}, RetType{IntTy}),
3090           Summary(NoEvalCall)
3091               .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3092               .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3093               .ArgConstraint(
3094                   ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3095 
3096     auto Recvfrom =
3097         Summary(NoEvalCall)
3098             .Case({ReturnValueCondition(LessThanOrEq, ArgNo(2)),
3099                    ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
3100                   ErrnoMustNotBeChecked, GenericSuccessMsg)
3101             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3102             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3103             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(1),
3104                                       /*BufSize=*/ArgNo(2)));
3105     if (!addToFunctionSummaryMap(
3106             "recvfrom",
3107             // ssize_t recvfrom(int socket, void *restrict buffer,
3108             //                  size_t length,
3109             //                  int flags, struct sockaddr *restrict address,
3110             //                  socklen_t *restrict address_len);
3111             Signature(ArgTypes{IntTy, VoidPtrRestrictTy, SizeTy, IntTy,
3112                                StructSockaddrPtrRestrictTy,
3113                                Socklen_tPtrRestrictTy},
3114                       RetType{Ssize_tTy}),
3115             Recvfrom))
3116       addToFunctionSummaryMap(
3117           "recvfrom",
3118           Signature(ArgTypes{IntTy, VoidPtrRestrictTy, SizeTy, IntTy,
3119                              Irrelevant, Socklen_tPtrRestrictTy},
3120                     RetType{Ssize_tTy}),
3121           Recvfrom);
3122 
3123     auto Sendto =
3124         Summary(NoEvalCall)
3125             .Case({ReturnValueCondition(LessThanOrEq, ArgNo(2)),
3126                    ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
3127                   ErrnoMustNotBeChecked, GenericSuccessMsg)
3128             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3129             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3130             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(1),
3131                                       /*BufSize=*/ArgNo(2)));
3132     if (!addToFunctionSummaryMap(
3133             "sendto",
3134             // ssize_t sendto(int socket, const void *message, size_t length,
3135             //                int flags, const struct sockaddr *dest_addr,
3136             //                socklen_t dest_len);
3137             Signature(ArgTypes{IntTy, ConstVoidPtrTy, SizeTy, IntTy,
3138                                ConstStructSockaddrPtrTy, Socklen_tTy},
3139                       RetType{Ssize_tTy}),
3140             Sendto))
3141       addToFunctionSummaryMap(
3142           "sendto",
3143           Signature(ArgTypes{IntTy, ConstVoidPtrTy, SizeTy, IntTy, Irrelevant,
3144                              Socklen_tTy},
3145                     RetType{Ssize_tTy}),
3146           Sendto);
3147 
3148     // int listen(int sockfd, int backlog);
3149     addToFunctionSummaryMap(
3150         "listen", Signature(ArgTypes{IntTy, IntTy}, RetType{IntTy}),
3151         Summary(NoEvalCall)
3152             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3153             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3154             .ArgConstraint(
3155                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3156 
3157     // ssize_t recv(int sockfd, void *buf, size_t len, int flags);
3158     addToFunctionSummaryMap(
3159         "recv",
3160         Signature(ArgTypes{IntTy, VoidPtrTy, SizeTy, IntTy},
3161                   RetType{Ssize_tTy}),
3162         Summary(NoEvalCall)
3163             .Case({ReturnValueCondition(LessThanOrEq, ArgNo(2)),
3164                    ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
3165                   ErrnoMustNotBeChecked, GenericSuccessMsg)
3166             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3167             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3168             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(1),
3169                                       /*BufSize=*/ArgNo(2))));
3170 
3171     std::optional<QualType> StructMsghdrTy = lookupTy("msghdr");
3172     std::optional<QualType> StructMsghdrPtrTy = getPointerTy(StructMsghdrTy);
3173     std::optional<QualType> ConstStructMsghdrPtrTy =
3174         getPointerTy(getConstTy(StructMsghdrTy));
3175 
3176     // ssize_t recvmsg(int sockfd, struct msghdr *msg, int flags);
3177     addToFunctionSummaryMap(
3178         "recvmsg",
3179         Signature(ArgTypes{IntTy, StructMsghdrPtrTy, IntTy},
3180                   RetType{Ssize_tTy}),
3181         Summary(NoEvalCall)
3182             .Case({ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
3183                   ErrnoMustNotBeChecked, GenericSuccessMsg)
3184             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3185             .ArgConstraint(
3186                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3187 
3188     // ssize_t sendmsg(int sockfd, const struct msghdr *msg, int flags);
3189     addToFunctionSummaryMap(
3190         "sendmsg",
3191         Signature(ArgTypes{IntTy, ConstStructMsghdrPtrTy, IntTy},
3192                   RetType{Ssize_tTy}),
3193         Summary(NoEvalCall)
3194             .Case({ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
3195                   ErrnoMustNotBeChecked, GenericSuccessMsg)
3196             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3197             .ArgConstraint(
3198                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3199 
3200     // int setsockopt(int socket, int level, int option_name,
3201     //                const void *option_value, socklen_t option_len);
3202     addToFunctionSummaryMap(
3203         "setsockopt",
3204         Signature(ArgTypes{IntTy, IntTy, IntTy, ConstVoidPtrTy, Socklen_tTy},
3205                   RetType{IntTy}),
3206         Summary(NoEvalCall)
3207             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3208             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3209             .ArgConstraint(NotNull(ArgNo(3)))
3210             .ArgConstraint(
3211                 BufferSize(/*Buffer=*/ArgNo(3), /*BufSize=*/ArgNo(4)))
3212             .ArgConstraint(
3213                 ArgumentCondition(4, WithinRange, Range(0, Socklen_tMax))));
3214 
3215     // int getsockopt(int socket, int level, int option_name,
3216     //                void *restrict option_value,
3217     //                socklen_t *restrict option_len);
3218     addToFunctionSummaryMap(
3219         "getsockopt",
3220         Signature(ArgTypes{IntTy, IntTy, IntTy, VoidPtrRestrictTy,
3221                            Socklen_tPtrRestrictTy},
3222                   RetType{IntTy}),
3223         Summary(NoEvalCall)
3224             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3225             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3226             .ArgConstraint(NotNull(ArgNo(3)))
3227             .ArgConstraint(NotNull(ArgNo(4))));
3228 
3229     // ssize_t send(int sockfd, const void *buf, size_t len, int flags);
3230     addToFunctionSummaryMap(
3231         "send",
3232         Signature(ArgTypes{IntTy, ConstVoidPtrTy, SizeTy, IntTy},
3233                   RetType{Ssize_tTy}),
3234         Summary(NoEvalCall)
3235             .Case({ReturnValueCondition(LessThanOrEq, ArgNo(2)),
3236                    ReturnValueCondition(WithinRange, Range(0, Ssize_tMax))},
3237                   ErrnoMustNotBeChecked, GenericSuccessMsg)
3238             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3239             .ArgConstraint(ArgumentCondition(0, WithinRange, Range(0, IntMax)))
3240             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(1),
3241                                       /*BufSize=*/ArgNo(2))));
3242 
3243     // int socketpair(int domain, int type, int protocol, int sv[2]);
3244     addToFunctionSummaryMap(
3245         "socketpair",
3246         Signature(ArgTypes{IntTy, IntTy, IntTy, IntPtrTy}, RetType{IntTy}),
3247         Summary(NoEvalCall)
3248             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3249             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3250             .ArgConstraint(NotNull(ArgNo(3))));
3251 
3252     // int shutdown(int socket, int how);
3253     addToFunctionSummaryMap(
3254         "shutdown", Signature(ArgTypes{IntTy, IntTy}, RetType{IntTy}),
3255         Summary(NoEvalCall)
3256             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3257             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3258             .ArgConstraint(
3259                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3260 
3261     // int getnameinfo(const struct sockaddr *restrict sa, socklen_t salen,
3262     //                 char *restrict node, socklen_t nodelen,
3263     //                 char *restrict service,
3264     //                 socklen_t servicelen, int flags);
3265     //
3266     // This is defined in netdb.h. And contrary to 'socket.h', the sockaddr
3267     // parameter is never handled as a transparent union in netdb.h
3268     addToFunctionSummaryMap(
3269         "getnameinfo",
3270         Signature(ArgTypes{ConstStructSockaddrPtrRestrictTy, Socklen_tTy,
3271                            CharPtrRestrictTy, Socklen_tTy, CharPtrRestrictTy,
3272                            Socklen_tTy, IntTy},
3273                   RetType{IntTy}),
3274         Summary(NoEvalCall)
3275             .ArgConstraint(
3276                 BufferSize(/*Buffer=*/ArgNo(0), /*BufSize=*/ArgNo(1)))
3277             .ArgConstraint(
3278                 ArgumentCondition(1, WithinRange, Range(0, Socklen_tMax)))
3279             .ArgConstraint(
3280                 BufferSize(/*Buffer=*/ArgNo(2), /*BufSize=*/ArgNo(3)))
3281             .ArgConstraint(
3282                 ArgumentCondition(3, WithinRange, Range(0, Socklen_tMax)))
3283             .ArgConstraint(
3284                 BufferSize(/*Buffer=*/ArgNo(4), /*BufSize=*/ArgNo(5)))
3285             .ArgConstraint(
3286                 ArgumentCondition(5, WithinRange, Range(0, Socklen_tMax))));
3287 
3288     std::optional<QualType> StructUtimbufTy = lookupTy("utimbuf");
3289     std::optional<QualType> StructUtimbufPtrTy = getPointerTy(StructUtimbufTy);
3290 
3291     // int utime(const char *filename, struct utimbuf *buf);
3292     addToFunctionSummaryMap(
3293         "utime",
3294         Signature(ArgTypes{ConstCharPtrTy, StructUtimbufPtrTy}, RetType{IntTy}),
3295         Summary(NoEvalCall)
3296             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3297             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3298             .ArgConstraint(NotNull(ArgNo(0))));
3299 
3300     std::optional<QualType> StructTimespecTy = lookupTy("timespec");
3301     std::optional<QualType> StructTimespecPtrTy =
3302         getPointerTy(StructTimespecTy);
3303     std::optional<QualType> ConstStructTimespecPtrTy =
3304         getPointerTy(getConstTy(StructTimespecTy));
3305 
3306     // int futimens(int fd, const struct timespec times[2]);
3307     addToFunctionSummaryMap(
3308         "futimens",
3309         Signature(ArgTypes{IntTy, ConstStructTimespecPtrTy}, RetType{IntTy}),
3310         Summary(NoEvalCall)
3311             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3312             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3313             .ArgConstraint(
3314                 ArgumentCondition(0, WithinRange, Range(0, IntMax))));
3315 
3316     // int utimensat(int dirfd, const char *pathname,
3317     //               const struct timespec times[2], int flags);
3318     addToFunctionSummaryMap(
3319         "utimensat",
3320         Signature(
3321             ArgTypes{IntTy, ConstCharPtrTy, ConstStructTimespecPtrTy, IntTy},
3322             RetType{IntTy}),
3323         Summary(NoEvalCall)
3324             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3325             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3326             .ArgConstraint(NotNull(ArgNo(1))));
3327 
3328     std::optional<QualType> StructTimevalTy = lookupTy("timeval");
3329     std::optional<QualType> ConstStructTimevalPtrTy =
3330         getPointerTy(getConstTy(StructTimevalTy));
3331 
3332     // int utimes(const char *filename, const struct timeval times[2]);
3333     addToFunctionSummaryMap(
3334         "utimes",
3335         Signature(ArgTypes{ConstCharPtrTy, ConstStructTimevalPtrTy},
3336                   RetType{IntTy}),
3337         Summary(NoEvalCall)
3338             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3339             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3340             .ArgConstraint(NotNull(ArgNo(0))));
3341 
3342     // int nanosleep(const struct timespec *rqtp, struct timespec *rmtp);
3343     addToFunctionSummaryMap(
3344         "nanosleep",
3345         Signature(ArgTypes{ConstStructTimespecPtrTy, StructTimespecPtrTy},
3346                   RetType{IntTy}),
3347         Summary(NoEvalCall)
3348             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3349             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3350             .ArgConstraint(NotNull(ArgNo(0))));
3351 
3352     std::optional<QualType> Time_tTy = lookupTy("time_t");
3353     std::optional<QualType> ConstTime_tPtrTy =
3354         getPointerTy(getConstTy(Time_tTy));
3355     std::optional<QualType> ConstTime_tPtrRestrictTy =
3356         getRestrictTy(ConstTime_tPtrTy);
3357 
3358     std::optional<QualType> StructTmTy = lookupTy("tm");
3359     std::optional<QualType> StructTmPtrTy = getPointerTy(StructTmTy);
3360     std::optional<QualType> StructTmPtrRestrictTy =
3361         getRestrictTy(StructTmPtrTy);
3362     std::optional<QualType> ConstStructTmPtrTy =
3363         getPointerTy(getConstTy(StructTmTy));
3364     std::optional<QualType> ConstStructTmPtrRestrictTy =
3365         getRestrictTy(ConstStructTmPtrTy);
3366 
3367     // struct tm * localtime(const time_t *tp);
3368     addToFunctionSummaryMap(
3369         "localtime",
3370         Signature(ArgTypes{ConstTime_tPtrTy}, RetType{StructTmPtrTy}),
3371         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
3372 
3373     // struct tm *localtime_r(const time_t *restrict timer,
3374     //                        struct tm *restrict result);
3375     addToFunctionSummaryMap(
3376         "localtime_r",
3377         Signature(ArgTypes{ConstTime_tPtrRestrictTy, StructTmPtrRestrictTy},
3378                   RetType{StructTmPtrTy}),
3379         Summary(NoEvalCall)
3380             .ArgConstraint(NotNull(ArgNo(0)))
3381             .ArgConstraint(NotNull(ArgNo(1))));
3382 
3383     // char *asctime_r(const struct tm *restrict tm, char *restrict buf);
3384     addToFunctionSummaryMap(
3385         "asctime_r",
3386         Signature(ArgTypes{ConstStructTmPtrRestrictTy, CharPtrRestrictTy},
3387                   RetType{CharPtrTy}),
3388         Summary(NoEvalCall)
3389             .ArgConstraint(NotNull(ArgNo(0)))
3390             .ArgConstraint(NotNull(ArgNo(1)))
3391             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(1),
3392                                       /*MinBufSize=*/BVF.getValue(26, IntTy))));
3393 
3394     // char *ctime_r(const time_t *timep, char *buf);
3395     addToFunctionSummaryMap(
3396         "ctime_r",
3397         Signature(ArgTypes{ConstTime_tPtrTy, CharPtrTy}, RetType{CharPtrTy}),
3398         Summary(NoEvalCall)
3399             .ArgConstraint(NotNull(ArgNo(0)))
3400             .ArgConstraint(NotNull(ArgNo(1)))
3401             .ArgConstraint(BufferSize(
3402                 /*Buffer=*/ArgNo(1),
3403                 /*MinBufSize=*/BVF.getValue(26, IntTy))));
3404 
3405     // struct tm *gmtime_r(const time_t *restrict timer,
3406     //                     struct tm *restrict result);
3407     addToFunctionSummaryMap(
3408         "gmtime_r",
3409         Signature(ArgTypes{ConstTime_tPtrRestrictTy, StructTmPtrRestrictTy},
3410                   RetType{StructTmPtrTy}),
3411         Summary(NoEvalCall)
3412             .ArgConstraint(NotNull(ArgNo(0)))
3413             .ArgConstraint(NotNull(ArgNo(1))));
3414 
3415     // struct tm * gmtime(const time_t *tp);
3416     addToFunctionSummaryMap(
3417         "gmtime", Signature(ArgTypes{ConstTime_tPtrTy}, RetType{StructTmPtrTy}),
3418         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
3419 
3420     std::optional<QualType> Clockid_tTy = lookupTy("clockid_t");
3421 
3422     // int clock_gettime(clockid_t clock_id, struct timespec *tp);
3423     addToFunctionSummaryMap(
3424         "clock_gettime",
3425         Signature(ArgTypes{Clockid_tTy, StructTimespecPtrTy}, RetType{IntTy}),
3426         Summary(NoEvalCall)
3427             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3428             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3429             .ArgConstraint(NotNull(ArgNo(1))));
3430 
3431     std::optional<QualType> StructItimervalTy = lookupTy("itimerval");
3432     std::optional<QualType> StructItimervalPtrTy =
3433         getPointerTy(StructItimervalTy);
3434 
3435     // int getitimer(int which, struct itimerval *curr_value);
3436     addToFunctionSummaryMap(
3437         "getitimer",
3438         Signature(ArgTypes{IntTy, StructItimervalPtrTy}, RetType{IntTy}),
3439         Summary(NoEvalCall)
3440             .Case(ReturnsZero, ErrnoMustNotBeChecked, GenericSuccessMsg)
3441             .Case(ReturnsMinusOne, ErrnoNEZeroIrrelevant, GenericFailureMsg)
3442             .ArgConstraint(NotNull(ArgNo(1))));
3443 
3444     std::optional<QualType> Pthread_cond_tTy = lookupTy("pthread_cond_t");
3445     std::optional<QualType> Pthread_cond_tPtrTy =
3446         getPointerTy(Pthread_cond_tTy);
3447     std::optional<QualType> Pthread_tTy = lookupTy("pthread_t");
3448     std::optional<QualType> Pthread_tPtrTy = getPointerTy(Pthread_tTy);
3449     std::optional<QualType> Pthread_tPtrRestrictTy =
3450         getRestrictTy(Pthread_tPtrTy);
3451     std::optional<QualType> Pthread_mutex_tTy = lookupTy("pthread_mutex_t");
3452     std::optional<QualType> Pthread_mutex_tPtrTy =
3453         getPointerTy(Pthread_mutex_tTy);
3454     std::optional<QualType> Pthread_mutex_tPtrRestrictTy =
3455         getRestrictTy(Pthread_mutex_tPtrTy);
3456     std::optional<QualType> Pthread_attr_tTy = lookupTy("pthread_attr_t");
3457     std::optional<QualType> Pthread_attr_tPtrTy =
3458         getPointerTy(Pthread_attr_tTy);
3459     std::optional<QualType> ConstPthread_attr_tPtrTy =
3460         getPointerTy(getConstTy(Pthread_attr_tTy));
3461     std::optional<QualType> ConstPthread_attr_tPtrRestrictTy =
3462         getRestrictTy(ConstPthread_attr_tPtrTy);
3463     std::optional<QualType> Pthread_mutexattr_tTy =
3464         lookupTy("pthread_mutexattr_t");
3465     std::optional<QualType> ConstPthread_mutexattr_tPtrTy =
3466         getPointerTy(getConstTy(Pthread_mutexattr_tTy));
3467     std::optional<QualType> ConstPthread_mutexattr_tPtrRestrictTy =
3468         getRestrictTy(ConstPthread_mutexattr_tPtrTy);
3469 
3470     QualType PthreadStartRoutineTy = getPointerTy(
3471         ACtx.getFunctionType(/*ResultTy=*/VoidPtrTy, /*Args=*/VoidPtrTy,
3472                              FunctionProtoType::ExtProtoInfo()));
3473 
3474     // int pthread_cond_signal(pthread_cond_t *cond);
3475     // int pthread_cond_broadcast(pthread_cond_t *cond);
3476     addToFunctionSummaryMap(
3477         {"pthread_cond_signal", "pthread_cond_broadcast"},
3478         Signature(ArgTypes{Pthread_cond_tPtrTy}, RetType{IntTy}),
3479         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
3480 
3481     // int pthread_create(pthread_t *restrict thread,
3482     //                    const pthread_attr_t *restrict attr,
3483     //                    void *(*start_routine)(void*), void *restrict arg);
3484     addToFunctionSummaryMap(
3485         "pthread_create",
3486         Signature(ArgTypes{Pthread_tPtrRestrictTy,
3487                            ConstPthread_attr_tPtrRestrictTy,
3488                            PthreadStartRoutineTy, VoidPtrRestrictTy},
3489                   RetType{IntTy}),
3490         Summary(NoEvalCall)
3491             .ArgConstraint(NotNull(ArgNo(0)))
3492             .ArgConstraint(NotNull(ArgNo(2))));
3493 
3494     // int pthread_attr_destroy(pthread_attr_t *attr);
3495     // int pthread_attr_init(pthread_attr_t *attr);
3496     addToFunctionSummaryMap(
3497         {"pthread_attr_destroy", "pthread_attr_init"},
3498         Signature(ArgTypes{Pthread_attr_tPtrTy}, RetType{IntTy}),
3499         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
3500 
3501     // int pthread_attr_getstacksize(const pthread_attr_t *restrict attr,
3502     //                               size_t *restrict stacksize);
3503     // int pthread_attr_getguardsize(const pthread_attr_t *restrict attr,
3504     //                               size_t *restrict guardsize);
3505     addToFunctionSummaryMap(
3506         {"pthread_attr_getstacksize", "pthread_attr_getguardsize"},
3507         Signature(ArgTypes{ConstPthread_attr_tPtrRestrictTy, SizePtrRestrictTy},
3508                   RetType{IntTy}),
3509         Summary(NoEvalCall)
3510             .ArgConstraint(NotNull(ArgNo(0)))
3511             .ArgConstraint(NotNull(ArgNo(1))));
3512 
3513     // int pthread_attr_setstacksize(pthread_attr_t *attr, size_t stacksize);
3514     // int pthread_attr_setguardsize(pthread_attr_t *attr, size_t guardsize);
3515     addToFunctionSummaryMap(
3516         {"pthread_attr_setstacksize", "pthread_attr_setguardsize"},
3517         Signature(ArgTypes{Pthread_attr_tPtrTy, SizeTy}, RetType{IntTy}),
3518         Summary(NoEvalCall)
3519             .ArgConstraint(NotNull(ArgNo(0)))
3520             .ArgConstraint(
3521                 ArgumentCondition(1, WithinRange, Range(0, SizeMax))));
3522 
3523     // int pthread_mutex_init(pthread_mutex_t *restrict mutex, const
3524     //                        pthread_mutexattr_t *restrict attr);
3525     addToFunctionSummaryMap(
3526         "pthread_mutex_init",
3527         Signature(ArgTypes{Pthread_mutex_tPtrRestrictTy,
3528                            ConstPthread_mutexattr_tPtrRestrictTy},
3529                   RetType{IntTy}),
3530         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
3531 
3532     // int pthread_mutex_destroy(pthread_mutex_t *mutex);
3533     // int pthread_mutex_lock(pthread_mutex_t *mutex);
3534     // int pthread_mutex_trylock(pthread_mutex_t *mutex);
3535     // int pthread_mutex_unlock(pthread_mutex_t *mutex);
3536     addToFunctionSummaryMap(
3537         {"pthread_mutex_destroy", "pthread_mutex_lock", "pthread_mutex_trylock",
3538          "pthread_mutex_unlock"},
3539         Signature(ArgTypes{Pthread_mutex_tPtrTy}, RetType{IntTy}),
3540         Summary(NoEvalCall).ArgConstraint(NotNull(ArgNo(0))));
3541   }
3542 
3543   // Functions for testing.
3544   if (AddTestFunctions) {
3545     const RangeInt IntMin = BVF.getMinValue(IntTy).getLimitedValue();
3546 
3547     addToFunctionSummaryMap(
3548         "__not_null", Signature(ArgTypes{IntPtrTy}, RetType{IntTy}),
3549         Summary(EvalCallAsPure).ArgConstraint(NotNull(ArgNo(0))));
3550 
3551     addToFunctionSummaryMap(
3552         "__not_null_buffer",
3553         Signature(ArgTypes{VoidPtrTy, IntTy, IntTy}, RetType{IntTy}),
3554         Summary(EvalCallAsPure)
3555             .ArgConstraint(NotNullBuffer(ArgNo(0), ArgNo(1), ArgNo(2))));
3556 
3557     // Test inside range constraints.
3558     addToFunctionSummaryMap(
3559         "__single_val_0", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3560         Summary(EvalCallAsPure)
3561             .ArgConstraint(ArgumentCondition(0U, WithinRange, SingleValue(0))));
3562     addToFunctionSummaryMap(
3563         "__single_val_1", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3564         Summary(EvalCallAsPure)
3565             .ArgConstraint(ArgumentCondition(0U, WithinRange, SingleValue(1))));
3566     addToFunctionSummaryMap(
3567         "__range_1_2", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3568         Summary(EvalCallAsPure)
3569             .ArgConstraint(ArgumentCondition(0U, WithinRange, Range(1, 2))));
3570     addToFunctionSummaryMap(
3571         "__range_m1_1", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3572         Summary(EvalCallAsPure)
3573             .ArgConstraint(ArgumentCondition(0U, WithinRange, Range(-1, 1))));
3574     addToFunctionSummaryMap(
3575         "__range_m2_m1", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3576         Summary(EvalCallAsPure)
3577             .ArgConstraint(ArgumentCondition(0U, WithinRange, Range(-2, -1))));
3578     addToFunctionSummaryMap(
3579         "__range_m10_10", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3580         Summary(EvalCallAsPure)
3581             .ArgConstraint(ArgumentCondition(0U, WithinRange, Range(-10, 10))));
3582     addToFunctionSummaryMap("__range_m1_inf",
3583                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3584                             Summary(EvalCallAsPure)
3585                                 .ArgConstraint(ArgumentCondition(
3586                                     0U, WithinRange, Range(-1, IntMax))));
3587     addToFunctionSummaryMap("__range_0_inf",
3588                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3589                             Summary(EvalCallAsPure)
3590                                 .ArgConstraint(ArgumentCondition(
3591                                     0U, WithinRange, Range(0, IntMax))));
3592     addToFunctionSummaryMap("__range_1_inf",
3593                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3594                             Summary(EvalCallAsPure)
3595                                 .ArgConstraint(ArgumentCondition(
3596                                     0U, WithinRange, Range(1, IntMax))));
3597     addToFunctionSummaryMap("__range_minf_m1",
3598                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3599                             Summary(EvalCallAsPure)
3600                                 .ArgConstraint(ArgumentCondition(
3601                                     0U, WithinRange, Range(IntMin, -1))));
3602     addToFunctionSummaryMap("__range_minf_0",
3603                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3604                             Summary(EvalCallAsPure)
3605                                 .ArgConstraint(ArgumentCondition(
3606                                     0U, WithinRange, Range(IntMin, 0))));
3607     addToFunctionSummaryMap("__range_minf_1",
3608                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3609                             Summary(EvalCallAsPure)
3610                                 .ArgConstraint(ArgumentCondition(
3611                                     0U, WithinRange, Range(IntMin, 1))));
3612     addToFunctionSummaryMap("__range_1_2__4_6",
3613                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3614                             Summary(EvalCallAsPure)
3615                                 .ArgConstraint(ArgumentCondition(
3616                                     0U, WithinRange, Range({1, 2}, {4, 6}))));
3617     addToFunctionSummaryMap(
3618         "__range_1_2__4_inf", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3619         Summary(EvalCallAsPure)
3620             .ArgConstraint(ArgumentCondition(0U, WithinRange,
3621                                              Range({1, 2}, {4, IntMax}))));
3622 
3623     // Test out of range constraints.
3624     addToFunctionSummaryMap(
3625         "__single_val_out_0", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3626         Summary(EvalCallAsPure)
3627             .ArgConstraint(ArgumentCondition(0U, OutOfRange, SingleValue(0))));
3628     addToFunctionSummaryMap(
3629         "__single_val_out_1", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3630         Summary(EvalCallAsPure)
3631             .ArgConstraint(ArgumentCondition(0U, OutOfRange, SingleValue(1))));
3632     addToFunctionSummaryMap(
3633         "__range_out_1_2", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3634         Summary(EvalCallAsPure)
3635             .ArgConstraint(ArgumentCondition(0U, OutOfRange, Range(1, 2))));
3636     addToFunctionSummaryMap(
3637         "__range_out_m1_1", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3638         Summary(EvalCallAsPure)
3639             .ArgConstraint(ArgumentCondition(0U, OutOfRange, Range(-1, 1))));
3640     addToFunctionSummaryMap(
3641         "__range_out_m2_m1", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3642         Summary(EvalCallAsPure)
3643             .ArgConstraint(ArgumentCondition(0U, OutOfRange, Range(-2, -1))));
3644     addToFunctionSummaryMap(
3645         "__range_out_m10_10", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3646         Summary(EvalCallAsPure)
3647             .ArgConstraint(ArgumentCondition(0U, OutOfRange, Range(-10, 10))));
3648     addToFunctionSummaryMap("__range_out_m1_inf",
3649                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3650                             Summary(EvalCallAsPure)
3651                                 .ArgConstraint(ArgumentCondition(
3652                                     0U, OutOfRange, Range(-1, IntMax))));
3653     addToFunctionSummaryMap("__range_out_0_inf",
3654                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3655                             Summary(EvalCallAsPure)
3656                                 .ArgConstraint(ArgumentCondition(
3657                                     0U, OutOfRange, Range(0, IntMax))));
3658     addToFunctionSummaryMap("__range_out_1_inf",
3659                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3660                             Summary(EvalCallAsPure)
3661                                 .ArgConstraint(ArgumentCondition(
3662                                     0U, OutOfRange, Range(1, IntMax))));
3663     addToFunctionSummaryMap("__range_out_minf_m1",
3664                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3665                             Summary(EvalCallAsPure)
3666                                 .ArgConstraint(ArgumentCondition(
3667                                     0U, OutOfRange, Range(IntMin, -1))));
3668     addToFunctionSummaryMap("__range_out_minf_0",
3669                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3670                             Summary(EvalCallAsPure)
3671                                 .ArgConstraint(ArgumentCondition(
3672                                     0U, OutOfRange, Range(IntMin, 0))));
3673     addToFunctionSummaryMap("__range_out_minf_1",
3674                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3675                             Summary(EvalCallAsPure)
3676                                 .ArgConstraint(ArgumentCondition(
3677                                     0U, OutOfRange, Range(IntMin, 1))));
3678     addToFunctionSummaryMap("__range_out_1_2__4_6",
3679                             Signature(ArgTypes{IntTy}, RetType{IntTy}),
3680                             Summary(EvalCallAsPure)
3681                                 .ArgConstraint(ArgumentCondition(
3682                                     0U, OutOfRange, Range({1, 2}, {4, 6}))));
3683     addToFunctionSummaryMap(
3684         "__range_out_1_2__4_inf", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3685         Summary(EvalCallAsPure)
3686             .ArgConstraint(
3687                 ArgumentCondition(0U, OutOfRange, Range({1, 2}, {4, IntMax}))));
3688 
3689     // Test range kind.
3690     addToFunctionSummaryMap(
3691         "__within", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3692         Summary(EvalCallAsPure)
3693             .ArgConstraint(ArgumentCondition(0U, WithinRange, SingleValue(1))));
3694     addToFunctionSummaryMap(
3695         "__out_of", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3696         Summary(EvalCallAsPure)
3697             .ArgConstraint(ArgumentCondition(0U, OutOfRange, SingleValue(1))));
3698 
3699     addToFunctionSummaryMap(
3700         "__two_constrained_args",
3701         Signature(ArgTypes{IntTy, IntTy}, RetType{IntTy}),
3702         Summary(EvalCallAsPure)
3703             .ArgConstraint(ArgumentCondition(0U, WithinRange, SingleValue(1)))
3704             .ArgConstraint(ArgumentCondition(1U, WithinRange, SingleValue(1))));
3705     addToFunctionSummaryMap(
3706         "__arg_constrained_twice", Signature(ArgTypes{IntTy}, RetType{IntTy}),
3707         Summary(EvalCallAsPure)
3708             .ArgConstraint(ArgumentCondition(0U, OutOfRange, SingleValue(1)))
3709             .ArgConstraint(ArgumentCondition(0U, OutOfRange, SingleValue(2))));
3710     addToFunctionSummaryMap(
3711         "__defaultparam",
3712         Signature(ArgTypes{Irrelevant, IntTy}, RetType{IntTy}),
3713         Summary(EvalCallAsPure).ArgConstraint(NotNull(ArgNo(0))));
3714     addToFunctionSummaryMap(
3715         "__variadic",
3716         Signature(ArgTypes{VoidPtrTy, ConstCharPtrTy}, RetType{IntTy}),
3717         Summary(EvalCallAsPure)
3718             .ArgConstraint(NotNull(ArgNo(0)))
3719             .ArgConstraint(NotNull(ArgNo(1))));
3720     addToFunctionSummaryMap(
3721         "__buf_size_arg_constraint",
3722         Signature(ArgTypes{ConstVoidPtrTy, SizeTy}, RetType{IntTy}),
3723         Summary(EvalCallAsPure)
3724             .ArgConstraint(
3725                 BufferSize(/*Buffer=*/ArgNo(0), /*BufSize=*/ArgNo(1))));
3726     addToFunctionSummaryMap(
3727         "__buf_size_arg_constraint_mul",
3728         Signature(ArgTypes{ConstVoidPtrTy, SizeTy, SizeTy}, RetType{IntTy}),
3729         Summary(EvalCallAsPure)
3730             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(0), /*BufSize=*/ArgNo(1),
3731                                       /*BufSizeMultiplier=*/ArgNo(2))));
3732     addToFunctionSummaryMap(
3733         "__buf_size_arg_constraint_concrete",
3734         Signature(ArgTypes{ConstVoidPtrTy}, RetType{IntTy}),
3735         Summary(EvalCallAsPure)
3736             .ArgConstraint(BufferSize(/*Buffer=*/ArgNo(0),
3737                                       /*BufSize=*/BVF.getValue(10, IntTy))));
3738     addToFunctionSummaryMap(
3739         {"__test_restrict_param_0", "__test_restrict_param_1",
3740          "__test_restrict_param_2"},
3741         Signature(ArgTypes{VoidPtrRestrictTy}, RetType{VoidTy}),
3742         Summary(EvalCallAsPure));
3743 
3744     // Test the application of cases.
3745     addToFunctionSummaryMap(
3746         "__test_case_note", Signature(ArgTypes{}, RetType{IntTy}),
3747         Summary(EvalCallAsPure)
3748             .Case({ReturnValueCondition(WithinRange, SingleValue(0))},
3749                   ErrnoIrrelevant, "Function returns 0")
3750             .Case({ReturnValueCondition(WithinRange, SingleValue(1))},
3751                   ErrnoIrrelevant, "Function returns 1"));
3752     addToFunctionSummaryMap(
3753         "__test_case_range_1_2__4_6",
3754         Signature(ArgTypes{IntTy}, RetType{IntTy}),
3755         Summary(EvalCallAsPure)
3756             .Case({ArgumentCondition(0U, WithinRange,
3757                                      IntRangeVector{{IntMin, 0}, {3, 3}}),
3758                    ReturnValueCondition(WithinRange, SingleValue(1))},
3759                   ErrnoIrrelevant)
3760             .Case({ArgumentCondition(0U, WithinRange,
3761                                      IntRangeVector{{3, 3}, {7, IntMax}}),
3762                    ReturnValueCondition(WithinRange, SingleValue(2))},
3763                   ErrnoIrrelevant)
3764             .Case({ArgumentCondition(0U, WithinRange,
3765                                      IntRangeVector{{IntMin, 0}, {7, IntMax}}),
3766                    ReturnValueCondition(WithinRange, SingleValue(3))},
3767                   ErrnoIrrelevant)
3768             .Case({ArgumentCondition(
3769                        0U, WithinRange,
3770                        IntRangeVector{{IntMin, 0}, {3, 3}, {7, IntMax}}),
3771                    ReturnValueCondition(WithinRange, SingleValue(4))},
3772                   ErrnoIrrelevant));
3773   }
3774 }
3775 
3776 void ento::registerStdCLibraryFunctionsChecker(CheckerManager &mgr) {
3777   auto *Checker = mgr.registerChecker<StdLibraryFunctionsChecker>();
3778   Checker->CheckName = mgr.getCurrentCheckerName();
3779   const AnalyzerOptions &Opts = mgr.getAnalyzerOptions();
3780   Checker->DisplayLoadedSummaries =
3781       Opts.getCheckerBooleanOption(Checker, "DisplayLoadedSummaries");
3782   Checker->ModelPOSIX = Opts.getCheckerBooleanOption(Checker, "ModelPOSIX");
3783   Checker->ShouldAssumeControlledEnvironment =
3784       Opts.ShouldAssumeControlledEnvironment;
3785 }
3786 
3787 bool ento::shouldRegisterStdCLibraryFunctionsChecker(
3788     const CheckerManager &mgr) {
3789   return true;
3790 }
3791 
3792 void ento::registerStdCLibraryFunctionsTesterChecker(CheckerManager &mgr) {
3793   auto *Checker = mgr.getChecker<StdLibraryFunctionsChecker>();
3794   Checker->AddTestFunctions = true;
3795 }
3796 
3797 bool ento::shouldRegisterStdCLibraryFunctionsTesterChecker(
3798     const CheckerManager &mgr) {
3799   return true;
3800 }
3801