test/Analysis/new.cpp - third_party/swift-clang - Git at Google

 // RUN: %clang_cc1 -analyze -analyzer-checker=core,unix.Malloc,debug.ExprInspection -analyzer-store region -std=c++11 -verify %s
 #include "Inputs/system-header-simulator-cxx.h"

 void clang_analyzer_eval(bool);

 typedef __typeof__(sizeof(int)) size_t;
 extern "C" void *malloc(size_t);
 extern "C" void free(void *);

 int someGlobal;

 class SomeClass {
 public:
   void f(int *p);
 };

 void testImplicitlyDeclaredGlobalNew() {
   if (someGlobal != 0)
     return;

   // This used to crash because the global operator new is being implicitly
   // declared and it does not have a valid source location. (PR13090)
   void *x = ::operator new(0);
   ::operator delete(x);

   // Check that the new/delete did not invalidate someGlobal;
   clang_analyzer_eval(someGlobal == 0); // expected-warning{{TRUE}}
 }

 void *testPlacementNew() {
   int *x = (int *)malloc(sizeof(int));
   *x = 1;
   clang_analyzer_eval(*x == 1); // expected-warning{{TRUE}};

   void *y = new (x) int;
   clang_analyzer_eval(x == y); // expected-warning{{TRUE}};
   clang_analyzer_eval(*x == 1); // expected-warning{{UNKNOWN}};

   return y;
 }

 void *operator new(size_t, size_t, int *);
 void *testCustomNew() {
   int x[1] = {1};
   clang_analyzer_eval(*x == 1); // expected-warning{{TRUE}};

   void *y = new (0, x) int;
   clang_analyzer_eval(*x == 1); // expected-warning{{UNKNOWN}};

   return y; // no-warning
 }

 void *operator new(size_t, void *, void *);
 void *testCustomNewMalloc() {
   int *x = (int *)malloc(sizeof(int));

   // Should be no-warning (the custom allocator could have freed x).
   void *y = new (0, x) int; // no-warning

   return y;
 }

 void testScalarInitialization() {
   int *n = new int(3);
   clang_analyzer_eval(*n == 3); // expected-warning{{TRUE}}

   new (n) int();
   clang_analyzer_eval(*n == 0); // expected-warning{{TRUE}}

   new (n) int{3};
   clang_analyzer_eval(*n == 3); // expected-warning{{TRUE}}

   new (n) int{};
   clang_analyzer_eval(*n == 0); // expected-warning{{TRUE}}
 }

 struct PtrWrapper {
   int *x;

   PtrWrapper(int *input) : x(input) {}
 };

 PtrWrapper *testNewInvalidation() {
   // Ensure that we don't consider this a leak.
   return new PtrWrapper(static_cast<int *>(malloc(4))); // no-warning
 }

 void testNewInvalidationPlacement(PtrWrapper *w) {
   // Ensure that we don't consider this a leak.
   new (w) PtrWrapper(static_cast<int *>(malloc(4))); // no-warning
 }

 int **testNewInvalidationScalar() {
   // Ensure that we don't consider this a leak.
   return new (int *)(static_cast<int *>(malloc(4))); // no-warning
 }

 void testNewInvalidationScalarPlacement(int **p) {
   // Ensure that we don't consider this a leak.
   new (p) (int *)(static_cast<int *>(malloc(4))); // no-warning
 }

 void testCacheOut(PtrWrapper w) {
   extern bool coin();
   if (coin())
     w.x = 0;
   new (&w.x) (int*)(0); // we cache out here; don't crash
 }

 void testUseAfter(int *p) {
   SomeClass *c = new SomeClass;
   free(p);
   c->f(p); // expected-warning{{Use of memory after it is freed}}
   delete c;
 }

 //--------------------------------------------------------------------
 // Check for intersection with other checkers from MallocChecker.cpp
 // bounded with unix.Malloc
 //--------------------------------------------------------------------

 // new/delete oparators are subjects of cplusplus.NewDelete.
 void testNewDeleteNoWarn() {
   int i;
   delete &i; // no-warning

   int *p1 = new int;
   delete ++p1; // no-warning

   int *p2 = new int;
   delete p2;
   delete p2; // no-warning

   int *p3 = new int; // no-warning
 }

 // unix.Malloc does not know about operators new/delete.
 void testDeleteMallocked() {
   int *x = (int *)malloc(sizeof(int));
   delete x; // FIXME: Shoud detect pointer escape and keep silent after 'delete' is modeled properly.
 } // expected-warning{{Potential leak of memory pointed to by 'x'}}

 void testDeleteOpAfterFree() {
   int *p = (int *)malloc(sizeof(int));
   free(p);
   operator delete(p); // expected-warning{{Use of memory after it is freed}}
 }

 void testDeleteAfterFree() {
   int *p = (int *)malloc(sizeof(int));
   free(p);
   delete p; // expected-warning{{Use of memory after it is freed}}
 }

 void testStandardPlacementNewAfterFree() {
   int *p = (int *)malloc(sizeof(int));
   free(p);
   p = new(p) int; // expected-warning{{Use of memory after it is freed}}
 }

 void testCustomPlacementNewAfterFree() {
   int *p = (int *)malloc(sizeof(int));
   free(p);
   p = new(0, p) int; // expected-warning{{Use of memory after it is freed}}
 }

 void testUsingThisAfterDelete() {
   SomeClass *c = new SomeClass;
   delete c;
   c->f(0); // no-warning
 }

 void testAggregateNew() {
   struct Point { int x, y; };
   new Point{1, 2}; // no crash

   Point p;
   new (&p) Point{1, 2}; // no crash
   clang_analyzer_eval(p.x == 1); // expected-warning{{TRUE}}
   clang_analyzer_eval(p.y == 2); // expected-warning{{TRUE}}
 }

 //--------------------------------
 // Incorrectly-modelled behavior
 //--------------------------------

 int testNoInitialization() {
   int *n = new int;

   // Should warn that *n is uninitialized.
   if (*n) { // no-warning
     delete n;
     return 0;
   }
   delete n;
   return 1;
 }

 int testNoInitializationPlacement() {
   int n;
   new (&n) int;

   // Should warn that n is uninitialized.
   if (n) { // no-warning
     return 0;
   }
   return 1;
 }

 // Test modelling destructor call on call to delete
 class IntPair{
 public:
   int x;
   int y;
   IntPair() {};
   ~IntPair() {x = x/y;}; //expected-warning {{Division by zero}}
 };

 void testCallToDestructor() {
   IntPair *b = new IntPair();
   b->x = 1;
   b->y = 0;
   delete b; // This results in divide by zero in destructor
 }

 // Test Deleting a value that's passed as an argument.
 class DerefClass{
 public:
   int *x;
   DerefClass() {};
   ~DerefClass() {*x = 1;}; //expected-warning {{Dereference of null pointer (loaded from field 'x')}}
 };

 void testDestCall(DerefClass *arg) {
   delete arg;
 }

 void test_delete_dtor_Arg() {
   DerefClass *pair = new DerefClass();
   pair->x = 0;
   testDestCall(pair);
 }

 //Deleting the address of a local variable, null pointer
 void abort(void) __attribute__((noreturn));

 class NoReturnDtor {
 public:
   NoReturnDtor() {}
   ~NoReturnDtor() {abort();}
 };

 void test_delete_dtor_LocalVar() {
   NoReturnDtor test;
   delete &test; // no warn or crash
 }

 class DerivedNoReturn:public NoReturnDtor {
 public:
   DerivedNoReturn() {};
   ~DerivedNoReturn() {};
 };

 void testNullDtorDerived() {
   DerivedNoReturn *p = new DerivedNoReturn();
   delete p; // Calls the base destructor which aborts, checked below
   clang_analyzer_eval(true); // no warn
 }

 //Deleting a non-class pointer should not crash/warn
 void test_var_delete() {
   int *v = new int;
   delete v;  // no crash/warn
   clang_analyzer_eval(true); // expected-warning{{TRUE}}
 }

 void testDeleteNull() {
   NoReturnDtor *foo = 0;
   delete foo; // should not call destructor, checked below
   clang_analyzer_eval(true); // expected-warning{{TRUE}}
 }

 void testNullAssigneddtor() {
   NoReturnDtor *p = 0;
   NoReturnDtor *s = p;
   delete s; // should not call destructor, checked below
   clang_analyzer_eval(true); // expected-warning{{TRUE}}
 }

 void deleteArg(NoReturnDtor *test) {
   delete test;
 }

 void testNulldtorArg() {
   NoReturnDtor *p = 0;
   deleteArg(p);
   clang_analyzer_eval(true); // expected-warning{{TRUE}}
 }

 void testDeleteUnknown(NoReturnDtor *foo) {
   delete foo; // should assume non-null and call noreturn destructor
   clang_analyzer_eval(true); // no-warning
 }

 void testArrayNull() {
   NoReturnDtor *fooArray = 0;
   delete[] fooArray; // should not call destructor, checked below
   clang_analyzer_eval(true); // expected-warning{{TRUE}}
 }

 void testArrayDestr() {
   NoReturnDtor *p = new NoReturnDtor[2];
   delete[] p; // Calls the base destructor which aborts, checked below
   //TODO: clang_analyzer_eval should not be called
   clang_analyzer_eval(true); // expected-warning{{TRUE}}
 }

 // Invalidate Region even in case of default destructor
 class InvalidateDestTest {
 public:
   int x;
   int *y;
   ~InvalidateDestTest();
 };

 int test_member_invalidation() {

   //test invalidation of member variable
   InvalidateDestTest *test = new InvalidateDestTest();
   test->x = 5;
   int *k = &(test->x);
   clang_analyzer_eval(*k == 5); // expected-warning{{TRUE}}
   delete test;
   clang_analyzer_eval(*k == 5); // expected-warning{{UNKNOWN}}

   //test invalidation of member pointer
   int localVar = 5;
   test = new InvalidateDestTest();
   test->y = &localVar;
   delete test;
   clang_analyzer_eval(localVar == 5); // expected-warning{{UNKNOWN}}

   // Test aray elements are invalidated.
   int Var1 = 5;
   int Var2 = 5;
   InvalidateDestTest *a = new InvalidateDestTest[2];
   a[0].y = &Var1;
   a[1].y = &Var2;
   delete[] a;
   clang_analyzer_eval(Var1 == 5); // expected-warning{{UNKNOWN}}
   clang_analyzer_eval(Var2 == 5); // expected-warning{{UNKNOWN}}
   return 0;
 }
	// RUN: %clang_cc1 -analyze -analyzer-checker=core,unix.Malloc,debug.ExprInspection -analyzer-store region -std=c++11 -verify %s
	#include "Inputs/system-header-simulator-cxx.h"

	void clang_analyzer_eval(bool);

	typedef __typeof__(sizeof(int)) size_t;
	extern "C" void *malloc(size_t);
	extern "C" void free(void *);

	int someGlobal;

	class SomeClass {
	public:
	void f(int *p);
	};

	void testImplicitlyDeclaredGlobalNew() {
	if (someGlobal != 0)
	return;

	// This used to crash because the global operator new is being implicitly
	// declared and it does not have a valid source location. (PR13090)
	void *x = ::operator new(0);
	::operator delete(x);

	// Check that the new/delete did not invalidate someGlobal;
	clang_analyzer_eval(someGlobal == 0); // expected-warning{{TRUE}}
	}

	void *testPlacementNew() {
	int x = (int )malloc(sizeof(int));
	*x = 1;
	clang_analyzer_eval(*x == 1); // expected-warning{{TRUE}};

	void *y = new (x) int;
	clang_analyzer_eval(x == y); // expected-warning{{TRUE}};
	clang_analyzer_eval(*x == 1); // expected-warning{{UNKNOWN}};

	return y;
	}

	void operator new(size_t, size_t, int );
	void *testCustomNew() {
	int x[1] = {1};
	clang_analyzer_eval(*x == 1); // expected-warning{{TRUE}};

	void *y = new (0, x) int;
	clang_analyzer_eval(*x == 1); // expected-warning{{UNKNOWN}};

	return y; // no-warning
	}

	void operator new(size_t, void , void *);
	void *testCustomNewMalloc() {
	int x = (int )malloc(sizeof(int));

	// Should be no-warning (the custom allocator could have freed x).
	void *y = new (0, x) int; // no-warning

	return y;
	}

	void testScalarInitialization() {
	int *n = new int(3);
	clang_analyzer_eval(*n == 3); // expected-warning{{TRUE}}

	new (n) int();
	clang_analyzer_eval(*n == 0); // expected-warning{{TRUE}}

	new (n) int{3};
	clang_analyzer_eval(*n == 3); // expected-warning{{TRUE}}

	new (n) int{};
	clang_analyzer_eval(*n == 0); // expected-warning{{TRUE}}
	}

	struct PtrWrapper {
	int *x;

	PtrWrapper(int *input) : x(input) {}
	};

	PtrWrapper *testNewInvalidation() {
	// Ensure that we don't consider this a leak.
	return new PtrWrapper(static_cast<int *>(malloc(4))); // no-warning
	}

	void testNewInvalidationPlacement(PtrWrapper *w) {
	// Ensure that we don't consider this a leak.
	new (w) PtrWrapper(static_cast<int *>(malloc(4))); // no-warning
	}

	int **testNewInvalidationScalar() {
	// Ensure that we don't consider this a leak.
	return new (int )(static_cast<int >(malloc(4))); // no-warning
	}

	void testNewInvalidationScalarPlacement(int **p) {
	// Ensure that we don't consider this a leak.
	new (p) (int )(static_cast<int >(malloc(4))); // no-warning
	}

	void testCacheOut(PtrWrapper w) {
	extern bool coin();
	if (coin())
	w.x = 0;
	new (&w.x) (int*)(0); // we cache out here; don't crash
	}

	void testUseAfter(int *p) {
	SomeClass *c = new SomeClass;
	free(p);
	c->f(p); // expected-warning{{Use of memory after it is freed}}
	delete c;
	}

	//--------------------------------------------------------------------
	// Check for intersection with other checkers from MallocChecker.cpp
	// bounded with unix.Malloc
	//--------------------------------------------------------------------

	// new/delete oparators are subjects of cplusplus.NewDelete.
	void testNewDeleteNoWarn() {
	int i;
	delete &i; // no-warning

	int *p1 = new int;
	delete ++p1; // no-warning

	int *p2 = new int;
	delete p2;
	delete p2; // no-warning

	int *p3 = new int; // no-warning
	}

	// unix.Malloc does not know about operators new/delete.
	void testDeleteMallocked() {
	int x = (int )malloc(sizeof(int));
	delete x; // FIXME: Shoud detect pointer escape and keep silent after 'delete' is modeled properly.
	} // expected-warning{{Potential leak of memory pointed to by 'x'}}

	void testDeleteOpAfterFree() {
	int p = (int )malloc(sizeof(int));
	free(p);
	operator delete(p); // expected-warning{{Use of memory after it is freed}}
	}

	void testDeleteAfterFree() {
	int p = (int )malloc(sizeof(int));
	free(p);
	delete p; // expected-warning{{Use of memory after it is freed}}
	}

	void testStandardPlacementNewAfterFree() {
	int p = (int )malloc(sizeof(int));
	free(p);
	p = new(p) int; // expected-warning{{Use of memory after it is freed}}
	}

	void testCustomPlacementNewAfterFree() {
	int p = (int )malloc(sizeof(int));
	free(p);
	p = new(0, p) int; // expected-warning{{Use of memory after it is freed}}
	}

	void testUsingThisAfterDelete() {
	SomeClass *c = new SomeClass;
	delete c;
	c->f(0); // no-warning
	}

	void testAggregateNew() {
	struct Point { int x, y; };
	new Point{1, 2}; // no crash

	Point p;
	new (&p) Point{1, 2}; // no crash
	clang_analyzer_eval(p.x == 1); // expected-warning{{TRUE}}
	clang_analyzer_eval(p.y == 2); // expected-warning{{TRUE}}
	}

	//--------------------------------
	// Incorrectly-modelled behavior
	//--------------------------------

	int testNoInitialization() {
	int *n = new int;

	// Should warn that *n is uninitialized.
	if (*n) { // no-warning
	delete n;
	return 0;
	}
	delete n;
	return 1;
	}

	int testNoInitializationPlacement() {
	int n;
	new (&n) int;

	// Should warn that n is uninitialized.
	if (n) { // no-warning
	return 0;
	}
	return 1;
	}

	// Test modelling destructor call on call to delete
	class IntPair{
	public:
	int x;
	int y;
	IntPair() {};
	~IntPair() {x = x/y;}; //expected-warning {{Division by zero}}
	};

	void testCallToDestructor() {
	IntPair *b = new IntPair();
	b->x = 1;
	b->y = 0;
	delete b; // This results in divide by zero in destructor
	}

	// Test Deleting a value that's passed as an argument.
	class DerefClass{
	public:
	int *x;
	DerefClass() {};
	~DerefClass() {*x = 1;}; //expected-warning {{Dereference of null pointer (loaded from field 'x')}}
	};

	void testDestCall(DerefClass *arg) {
	delete arg;
	}

	void test_delete_dtor_Arg() {
	DerefClass *pair = new DerefClass();
	pair->x = 0;
	testDestCall(pair);
	}

	//Deleting the address of a local variable, null pointer
	void abort(void) __attribute__((noreturn));

	class NoReturnDtor {
	public:
	NoReturnDtor() {}
	~NoReturnDtor() {abort();}
	};

	void test_delete_dtor_LocalVar() {
	NoReturnDtor test;
	delete &test; // no warn or crash
	}

	class DerivedNoReturn:public NoReturnDtor {
	public:
	DerivedNoReturn() {};
	~DerivedNoReturn() {};
	};

	void testNullDtorDerived() {
	DerivedNoReturn *p = new DerivedNoReturn();
	delete p; // Calls the base destructor which aborts, checked below
	clang_analyzer_eval(true); // no warn
	}

	//Deleting a non-class pointer should not crash/warn
	void test_var_delete() {
	int *v = new int;
	delete v; // no crash/warn
	clang_analyzer_eval(true); // expected-warning{{TRUE}}
	}

	void testDeleteNull() {
	NoReturnDtor *foo = 0;
	delete foo; // should not call destructor, checked below
	clang_analyzer_eval(true); // expected-warning{{TRUE}}
	}

	void testNullAssigneddtor() {
	NoReturnDtor *p = 0;
	NoReturnDtor *s = p;
	delete s; // should not call destructor, checked below
	clang_analyzer_eval(true); // expected-warning{{TRUE}}
	}

	void deleteArg(NoReturnDtor *test) {
	delete test;
	}

	void testNulldtorArg() {
	NoReturnDtor *p = 0;
	deleteArg(p);
	clang_analyzer_eval(true); // expected-warning{{TRUE}}
	}

	void testDeleteUnknown(NoReturnDtor *foo) {
	delete foo; // should assume non-null and call noreturn destructor
	clang_analyzer_eval(true); // no-warning
	}

	void testArrayNull() {
	NoReturnDtor *fooArray = 0;
	delete[] fooArray; // should not call destructor, checked below
	clang_analyzer_eval(true); // expected-warning{{TRUE}}
	}

	void testArrayDestr() {
	NoReturnDtor *p = new NoReturnDtor[2];
	delete[] p; // Calls the base destructor which aborts, checked below
	//TODO: clang_analyzer_eval should not be called
	clang_analyzer_eval(true); // expected-warning{{TRUE}}
	}

	// Invalidate Region even in case of default destructor
	class InvalidateDestTest {
	public:
	int x;
	int *y;
	~InvalidateDestTest();
	};

	int test_member_invalidation() {

	//test invalidation of member variable
	InvalidateDestTest *test = new InvalidateDestTest();
	test->x = 5;
	int *k = &(test->x);
	clang_analyzer_eval(*k == 5); // expected-warning{{TRUE}}
	delete test;
	clang_analyzer_eval(*k == 5); // expected-warning{{UNKNOWN}}

	//test invalidation of member pointer
	int localVar = 5;
	test = new InvalidateDestTest();
	test->y = &localVar;
	delete test;
	clang_analyzer_eval(localVar == 5); // expected-warning{{UNKNOWN}}

	// Test aray elements are invalidated.
	int Var1 = 5;
	int Var2 = 5;
	InvalidateDestTest *a = new InvalidateDestTest[2];
	a[0].y = &Var1;
	a[1].y = &Var2;
	delete[] a;
	clang_analyzer_eval(Var1 == 5); // expected-warning{{UNKNOWN}}
	clang_analyzer_eval(Var2 == 5); // expected-warning{{UNKNOWN}}
	return 0;
	}