test/Analysis/dynamic-cast.cpp - platform/external/clang - Git at Google

 // RUN: %clang_cc1 -triple i386-apple-darwin10 -analyze -analyzer-checker=core -verify %s

 class A {
 public:
     virtual void f(){};

 };
 class B : public A{
 public:
   int m;
 };
 class C : public A{};

 class BB: public B{};

 // A lot of the tests below have the if statement in them, which forces the
 // analyzer to explore both path - when the result is 0 and not. This makes
 // sure that we definitely know that the result is non-0 (as the result of
 // the cast).
 int testDynCastFromRadar() {
     B aa;
     A *a = &aa;
     const int* res = 0;
     B *b = dynamic_cast<B*>(a);
     static const int i = 5;
     if(b) {
         res = &i;
     } else {
         res = 0;
     }
     return *res; // no warning
 }

 int testBaseToBase1() {
   B b;
   B *pb = &b;
   B *pbb = dynamic_cast<B*>(pb);
   const int* res = 0;
   static const int i = 5;
   if (pbb) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // no warning
 }

 int testMultipleLevelsOfSubclassing1() {
   BB bb;
   B *pb = &bb;
   A *pa = pb;
   B *b = dynamic_cast<B*>(pa);
   const int* res = 0;
   static const int i = 5;
   if (b) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // no warning
 }

 int testMultipleLevelsOfSubclassing2() {
   BB bb;
   A *pbb = &bb;
   B *b = dynamic_cast<B*>(pbb);
   BB *s = dynamic_cast<BB*>(b);
   const int* res = 0;
   static const int i = 5;
   if (s) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // no warning
 }

 int testMultipleLevelsOfSubclassing3() {
   BB bb;
   A *pbb = &bb;
   B *b = dynamic_cast<B*>(pbb);
   return b->m; // no warning
 }

 int testLHS() {
     B aa;
     A *a = &aa;
     return (dynamic_cast<B*>(a))->m;
 }

 int testLHS2() {
     B aa;
     A *a = &aa;
     return (*dynamic_cast<B*>(a)).m;
 }

 int testDynCastUnknown2(class A *a) {
   B *b = dynamic_cast<B*>(a);
   return b->m; // no warning
 }

 int testDynCastUnknown(class A *a) {
   B *b = dynamic_cast<B*>(a);
   const int* res = 0;
   static const int i = 5;
   if (b) {
     res = &i;
   } else {
     res = 0;
   }
   return *res; // expected-warning {{Dereference of null pointer}}
 }

 int testDynCastFail2() {
   C c;
   A *pa = &c;
   B *b = dynamic_cast<B*>(pa);
   return b->m; // expected-warning {{dereference of a null pointer}}
 }

 int testLHSFail() {
     C c;
     A *a = &c;
     return (*dynamic_cast<B*>(a)).m; // expected-warning {{Dereference of null pointer}}
 }

 int testBaseToDerivedFail() {
   A a;
   B *b = dynamic_cast<B*>(&a);
   return b->m; // expected-warning {{dereference of a null pointer}}
 }

 int testConstZeroFail() {
   B *b = dynamic_cast<B*>((A *)0);
   return b->m; // expected-warning {{dereference of a null pointer}}
 }

 int testConstZeroFail2() {
   A *a = 0;
   B *b = dynamic_cast<B*>(a);
   return b->m; // expected-warning {{dereference of a null pointer}}
 }

 int testUpcast() {
   B b;
   A *a = dynamic_cast<A*>(&b);
   const int* res = 0;
   static const int i = 5;
   if (a) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // no warning
 }

 int testCastToVoidStar() {
   A a;
   void *b = dynamic_cast<void*>(&a);
   const int* res = 0;
   static const int i = 5;
   if (b) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // no warning
 }

 int testReferenceSuccesfulCast() {
   B rb;
   B &b = dynamic_cast<B&>(rb);
   int *x = 0;
   return *x; // expected-warning {{Dereference of null pointer}}
 }

 int testReferenceFailedCast() {
   A a;
   B &b = dynamic_cast<B&>(a);
   int *x = 0;
   return *x; // no warning (An exception is thrown by the cast.)
 }

 // Here we allow any outcome of the cast and this is good because there is a
 // situation where this will fail. So if the user has written the code in this
 // way, we assume they expect the cast to succeed.
 // Note, this might need special handling if we track types of symbolic casts
 // and use them for dynamic_cast handling.
 int testDynCastMostLikelyWillFail(C *c) {
   B *b = 0;
   b = dynamic_cast<B*>(c);
   const int* res = 0;
   static const int i = 5;
   if (b) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // expected-warning{{Dereference of null pointer}}
 }

 class M : public B, public C {};
 void callTestDynCastMostLikelyWillFail() {
   M m;
   testDynCastMostLikelyWillFail(&m);
 }

 // False positives/negatives.

 // Due to symbolic regions not being typed.
 int testDynCastFalsePositive(BB *c) {
   B *b = 0;
   b = dynamic_cast<B*>(c);
   const int* res = 0;
   static const int i = 5;
   if (b) {
       res = &i;
   } else {
       res = 0;
   }
   return *res; // expected-warning{{Dereference of null pointer}}
 }

 // Does not work when we new an object.
 int testDynCastFail3() {
   A *a = new A();
   B *b = dynamic_cast<B*>(a);
   return b->m;
 }
	// RUN: %clang_cc1 -triple i386-apple-darwin10 -analyze -analyzer-checker=core -verify %s

	class A {
	public:
	virtual void f(){};

	};
	class B : public A{
	public:
	int m;
	};
	class C : public A{};

	class BB: public B{};

	// A lot of the tests below have the if statement in them, which forces the
	// analyzer to explore both path - when the result is 0 and not. This makes
	// sure that we definitely know that the result is non-0 (as the result of
	// the cast).
	int testDynCastFromRadar() {
	B aa;
	A *a = &aa;
	const int* res = 0;
	B b = dynamic_cast<B>(a);
	static const int i = 5;
	if(b) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // no warning
	}

	int testBaseToBase1() {
	B b;
	B *pb = &b;
	B pbb = dynamic_cast<B>(pb);
	const int* res = 0;
	static const int i = 5;
	if (pbb) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // no warning
	}

	int testMultipleLevelsOfSubclassing1() {
	BB bb;
	B *pb = &bb;
	A *pa = pb;
	B b = dynamic_cast<B>(pa);
	const int* res = 0;
	static const int i = 5;
	if (b) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // no warning
	}

	int testMultipleLevelsOfSubclassing2() {
	BB bb;
	A *pbb = &bb;
	B b = dynamic_cast<B>(pbb);
	BB s = dynamic_cast<BB>(b);
	const int* res = 0;
	static const int i = 5;
	if (s) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // no warning
	}

	int testMultipleLevelsOfSubclassing3() {
	BB bb;
	A *pbb = &bb;
	B b = dynamic_cast<B>(pbb);
	return b->m; // no warning
	}

	int testLHS() {
	B aa;
	A *a = &aa;
	return (dynamic_cast<B*>(a))->m;
	}

	int testLHS2() {
	B aa;
	A *a = &aa;
	return (dynamic_cast<B>(a)).m;
	}

	int testDynCastUnknown2(class A *a) {
	B b = dynamic_cast<B>(a);
	return b->m; // no warning
	}

	int testDynCastUnknown(class A *a) {
	B b = dynamic_cast<B>(a);
	const int* res = 0;
	static const int i = 5;
	if (b) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // expected-warning {{Dereference of null pointer}}
	}

	int testDynCastFail2() {
	C c;
	A *pa = &c;
	B b = dynamic_cast<B>(pa);
	return b->m; // expected-warning {{dereference of a null pointer}}
	}

	int testLHSFail() {
	C c;
	A *a = &c;
	return (dynamic_cast<B>(a)).m; // expected-warning {{Dereference of null pointer}}
	}

	int testBaseToDerivedFail() {
	A a;
	B b = dynamic_cast<B>(&a);
	return b->m; // expected-warning {{dereference of a null pointer}}
	}

	int testConstZeroFail() {
	B b = dynamic_cast<B>((A *)0);
	return b->m; // expected-warning {{dereference of a null pointer}}
	}

	int testConstZeroFail2() {
	A *a = 0;
	B b = dynamic_cast<B>(a);
	return b->m; // expected-warning {{dereference of a null pointer}}
	}

	int testUpcast() {
	B b;
	A a = dynamic_cast<A>(&b);
	const int* res = 0;
	static const int i = 5;
	if (a) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // no warning
	}

	int testCastToVoidStar() {
	A a;
	void b = dynamic_cast<void>(&a);
	const int* res = 0;
	static const int i = 5;
	if (b) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // no warning
	}

	int testReferenceSuccesfulCast() {
	B rb;
	B &b = dynamic_cast<B&>(rb);
	int *x = 0;
	return *x; // expected-warning {{Dereference of null pointer}}
	}

	int testReferenceFailedCast() {
	A a;
	B &b = dynamic_cast<B&>(a);
	int *x = 0;
	return *x; // no warning (An exception is thrown by the cast.)
	}

	// Here we allow any outcome of the cast and this is good because there is a
	// situation where this will fail. So if the user has written the code in this
	// way, we assume they expect the cast to succeed.
	// Note, this might need special handling if we track types of symbolic casts
	// and use them for dynamic_cast handling.
	int testDynCastMostLikelyWillFail(C *c) {
	B *b = 0;
	b = dynamic_cast<B*>(c);
	const int* res = 0;
	static const int i = 5;
	if (b) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // expected-warning{{Dereference of null pointer}}
	}

	class M : public B, public C {};
	void callTestDynCastMostLikelyWillFail() {
	M m;
	testDynCastMostLikelyWillFail(&m);
	}

	// False positives/negatives.

	// Due to symbolic regions not being typed.
	int testDynCastFalsePositive(BB *c) {
	B *b = 0;
	b = dynamic_cast<B*>(c);
	const int* res = 0;
	static const int i = 5;
	if (b) {
	res = &i;
	} else {
	res = 0;
	}
	return *res; // expected-warning{{Dereference of null pointer}}
	}

	// Does not work when we new an object.
	int testDynCastFail3() {
	A *a = new A();
	B b = dynamic_cast<B>(a);
	return b->m;
	}