clang-1/test/Analysis/inline.cpp

370 строки
8.4 KiB
C++

// RUN: %clang_cc1 -analyze -analyzer-checker=core,unix.Malloc,debug.ExprInspection -analyzer-ipa=inlining -verify %s
void clang_analyzer_eval(bool);
void clang_analyzer_checkInlined(bool);
typedef __typeof__(sizeof(int)) size_t;
extern "C" void *malloc(size_t);
// This is the standard placement new.
inline void* operator new(size_t, void* __p) throw()
{
return __p;
}
class A {
public:
int getZero() { return 0; }
virtual int getNum() { return 0; }
};
void test(A &a) {
clang_analyzer_eval(a.getZero() == 0); // expected-warning{{TRUE}}
clang_analyzer_eval(a.getNum() == 0); // expected-warning{{UNKNOWN}}
A copy(a);
clang_analyzer_eval(copy.getZero() == 0); // expected-warning{{TRUE}}
clang_analyzer_eval(copy.getNum() == 0); // expected-warning{{TRUE}}
}
class One : public A {
public:
virtual int getNum() { return 1; }
};
void testPathSensitivity(int x) {
A a;
One b;
A *ptr;
switch (x) {
case 0:
ptr = &a;
break;
case 1:
ptr = &b;
break;
default:
return;
}
// This should be true on both branches.
clang_analyzer_eval(ptr->getNum() == x); // expected-warning {{TRUE}}
}
namespace PureVirtualParent {
class Parent {
public:
virtual int pureVirtual() const = 0;
int callVirtual() const {
return pureVirtual();
}
};
class Child : public Parent {
public:
virtual int pureVirtual() const {
clang_analyzer_checkInlined(true); // expected-warning{{TRUE}}
return 42;
}
};
void testVirtual() {
Child x;
clang_analyzer_eval(x.pureVirtual() == 42); // expected-warning{{TRUE}}
clang_analyzer_eval(x.callVirtual() == 42); // expected-warning{{TRUE}}
}
}
namespace PR13569 {
class Parent {
protected:
int m_parent;
virtual int impl() const = 0;
Parent() : m_parent(0) {}
public:
int interface() const {
clang_analyzer_checkInlined(true); // expected-warning{{TRUE}}
return impl();
}
};
class Child : public Parent {
protected:
virtual int impl() const {
clang_analyzer_checkInlined(true); // expected-warning{{TRUE}}
return m_parent + m_child;
}
public:
Child() : m_child(0) {}
int m_child;
};
void testVirtual() {
Child x;
x.m_child = 42;
// Don't crash when inlining and devirtualizing.
x.interface();
}
class Grandchild : public Child {};
void testDevirtualizeToMiddle() {
Grandchild x;
x.m_child = 42;
// Don't crash when inlining and devirtualizing.
x.interface();
}
}
namespace PR13569_virtual {
class Parent {
protected:
int m_parent;
virtual int impl() const = 0;
Parent() : m_parent(0) {}
public:
int interface() const {
clang_analyzer_checkInlined(true); // expected-warning{{TRUE}}
return impl();
}
};
class Child : virtual public Parent {
protected:
virtual int impl() const {
clang_analyzer_checkInlined(true); // expected-warning{{TRUE}}
return m_parent + m_child;
}
public:
Child() : m_child(0) {}
int m_child;
};
void testVirtual() {
Child x;
x.m_child = 42;
// Don't crash when inlining and devirtualizing.
x.interface();
}
class Grandchild : virtual public Child {};
void testDevirtualizeToMiddle() {
Grandchild x;
x.m_child = 42;
// Don't crash when inlining and devirtualizing.
x.interface();
}
}
namespace Invalidation {
struct X {
void touch(int &x) const {
x = 0;
}
void touch2(int &x) const;
virtual void touchV(int &x) const {
x = 0;
}
virtual void touchV2(int &x) const;
int test() const {
// We were accidentally not invalidating under -analyzer-ipa=inlining
// at one point for virtual methods with visible definitions.
int a, b, c, d;
touch(a);
touch2(b);
touchV(c);
touchV2(d);
return a + b + c + d; // no-warning
}
};
}
namespace DefaultArgs {
int takesDefaultArgs(int i = 42) {
return -i;
}
void testFunction() {
clang_analyzer_eval(takesDefaultArgs(1) == -1); // expected-warning{{TRUE}}
clang_analyzer_eval(takesDefaultArgs() == -42); // expected-warning{{TRUE}}
}
class Secret {
public:
static const int value = 42;
int get(int i = value) {
return i;
}
};
void testMethod() {
Secret obj;
clang_analyzer_eval(obj.get(1) == 1); // expected-warning{{TRUE}}
// FIXME: Should be 'TRUE'. See PR13673 or <rdar://problem/11720796>.
clang_analyzer_eval(obj.get() == 42); // expected-warning{{UNKNOWN}}
// FIXME: Even if we constrain the variable, we still have a problem.
// See PR13385 or <rdar://problem/12156507>.
if (Secret::value != 42)
return;
clang_analyzer_eval(Secret::value == 42); // expected-warning{{TRUE}}
clang_analyzer_eval(obj.get() == 42); // expected-warning{{UNKNOWN}}
}
}
namespace OperatorNew {
class IntWrapper {
public:
int value;
IntWrapper(int input) : value(input) {
// We don't want this constructor to be inlined unless we can actually
// use the proper region for operator new.
// See PR12014 and <rdar://problem/12180598>.
clang_analyzer_checkInlined(false); // no-warning
}
};
void test() {
IntWrapper *obj = new IntWrapper(42);
// should be TRUE
clang_analyzer_eval(obj->value == 42); // expected-warning{{UNKNOWN}}
}
void testPlacement() {
IntWrapper *obj = static_cast<IntWrapper *>(malloc(sizeof(IntWrapper)));
IntWrapper *alias = new (obj) IntWrapper(42);
clang_analyzer_eval(alias == obj); // expected-warning{{TRUE}}
// should be TRUE
clang_analyzer_eval(obj->value == 42); // expected-warning{{UNKNOWN}}
}
}
namespace VirtualWithSisterCasts {
// This entire set of tests exercises casts from sister classes and
// from classes outside the hierarchy, which can very much confuse
// code that uses DynamicTypeInfo or needs to construct CXXBaseObjectRegions.
// These examples used to cause crashes in +Asserts builds.
struct Parent {
virtual int foo();
int x;
};
struct A : Parent {
virtual int foo() { return 42; }
};
struct B : Parent {
virtual int foo();
};
struct Grandchild : public A {};
struct Unrelated {};
void testDowncast(Parent *b) {
A *a = (A *)(void *)b;
clang_analyzer_eval(a->foo() == 42); // expected-warning{{UNKNOWN}}
a->x = 42;
clang_analyzer_eval(a->x == 42); // expected-warning{{TRUE}}
}
void testRelated(B *b) {
A *a = (A *)(void *)b;
clang_analyzer_eval(a->foo() == 42); // expected-warning{{UNKNOWN}}
a->x = 42;
clang_analyzer_eval(a->x == 42); // expected-warning{{TRUE}}
}
void testUnrelated(Unrelated *b) {
A *a = (A *)(void *)b;
clang_analyzer_eval(a->foo() == 42); // expected-warning{{UNKNOWN}}
a->x = 42;
clang_analyzer_eval(a->x == 42); // expected-warning{{TRUE}}
}
void testCastViaNew(B *b) {
Grandchild *g = new (b) Grandchild();
// FIXME: We actually now have perfect type info because of 'new'.
// This should be TRUE.
clang_analyzer_eval(g->foo() == 42); // expected-warning{{UNKNOWN}}
g->x = 42;
clang_analyzer_eval(g->x == 42); // expected-warning{{TRUE}}
}
}
namespace QualifiedCalls {
void test(One *object) {
// This uses the One class from the top of the file.
clang_analyzer_eval(object->getNum() == 1); // expected-warning{{UNKNOWN}}
clang_analyzer_eval(object->One::getNum() == 1); // expected-warning{{TRUE}}
clang_analyzer_eval(object->A::getNum() == 0); // expected-warning{{TRUE}}
// getZero is non-virtual.
clang_analyzer_eval(object->getZero() == 0); // expected-warning{{TRUE}}
clang_analyzer_eval(object->One::getZero() == 0); // expected-warning{{TRUE}}
clang_analyzer_eval(object->A::getZero() == 0); // expected-warning{{TRUE}}
}
}
namespace rdar12409977 {
struct Base {
int x;
};
struct Parent : public Base {
virtual Parent *vGetThis();
Parent *getThis() { return vGetThis(); }
};
struct Child : public Parent {
virtual Child *vGetThis() { return this; }
};
void test() {
Child obj;
obj.x = 42;
// Originally, calling a devirtualized method with a covariant return type
// caused a crash because the return value had the wrong type. When we then
// go to layer a CXXBaseObjectRegion on it, the base isn't a direct base of
// the object region and we get an assertion failure.
clang_analyzer_eval(obj.getThis()->x == 42); // expected-warning{{TRUE}}
}
}