// RUN: clang-tidy %s -checks=-*,google-readability-casting -- \
// RUN: -xobjective-c++ -fobjc-abi-version=2 -fobjc-arc | count 0
// Note: this test expects no diagnostics, but FileCheck cannot handle that,
// hence the use of | count 0.
bool g() { return false; }
enum Enum { Enum1 };
struct X {};
struct Y : public X {};
void f(int a, double b, const char *cpc, const void *cpv, X *pX) {
typedef const char *Typedef1;
typedef const char *Typedef2;
Typedef1 t1;
(Typedef2)t1;
(const char*)t1;
(Typedef1)cpc;
typedef char Char;
char *pc;
Char *pChar = (Char*)pc;
(Char)*cpc;
(char)*pChar;
(const char*)cpv;
char *pc2 = (char*)(cpc + 33);
const char &crc = *cpc;
char &rc = (char&)crc;
char &rc2 = (char&)*cpc;
char ** const* const* ppcpcpc;
char ****ppppc = (char****)ppcpcpc;
char ***pppc = (char***)*(ppcpcpc);
char ***pppc2 = (char***)(*ppcpcpc);
char *pc5 = (char*)(const char*)(cpv);
int b1 = (int)b;
b1 = (const int&)b;
b1 = (int) b;
b1 = (int) b;
b1 = (int) (b);
b1 = (int) (b);
Y *pB = (Y*)pX;
Y &rB = (Y&)*pX;
const char *pc3 = (const char*)cpv;
char *pc4 = (char*)cpv;
b1 = (int)Enum1;
Enum e = (Enum)b1;
int b2 = int(b);
int b3 = static_cast<double>(b);
int b4 = b;
double aa = a;
(void)b2;
return (void)g();
}
template <typename T>
void template_function(T t, int n) {
int i = (int)t;
}
template <typename T>
struct TemplateStruct {
void f(T t, int n) {
int k = (int)t;
}
};
void test_templates() {
template_function(1, 42);
template_function(1.0, 42);
TemplateStruct<int>().f(1, 42);
TemplateStruct<double>().f(1.0, 42);
}
extern "C" {
void extern_c_code(const char *cpc) {
char *pc = (char*)cpc;
}
}
#define CAST(type, value) (type)(value)
void macros(double d) {
int i = CAST(int, d);
}
enum E { E1 = 1 };
template <E e>
struct A {
// Usage of template argument e = E1 is represented as (E)1 in the AST for
// some reason. We have a special treatment of this case to avoid warnings
// here.
static const E ee = e;
};
struct B : public A<E1> {};
void overloaded_function();
void overloaded_function(int);
template<typename Fn>
void g(Fn fn) {
fn();
}
void function_casts() {
typedef void (*FnPtrVoid)();
typedef void (&FnRefVoid)();
typedef void (&FnRefInt)(int);
g((void (*)())overloaded_function);
g((void (*)())&overloaded_function);
g((void (&)())overloaded_function);
g((FnPtrVoid)overloaded_function);
g((FnPtrVoid)&overloaded_function);
g((FnRefVoid)overloaded_function);
FnPtrVoid fn0 = (void (*)())&overloaded_function;
FnPtrVoid fn1 = (void (*)())overloaded_function;
FnPtrVoid fn1a = (FnPtrVoid)overloaded_function;
FnRefInt fn2 = (void (&)(int))overloaded_function;
auto fn3 = (void (*)())&overloaded_function;
auto fn4 = (void (*)())overloaded_function;
auto fn5 = (void (&)(int))overloaded_function;
void (*fn6)() = (void (*)())&overloaded_function;
void (*fn7)() = (void (*)())overloaded_function;
void (*fn8)() = (FnPtrVoid)overloaded_function;
void (&fn9)(int) = (void (&)(int))overloaded_function;
void (*correct1)() = static_cast<void (*)()>(overloaded_function);
FnPtrVoid correct2 = static_cast<void (*)()>(&overloaded_function);
FnRefInt correct3 = static_cast<void (&)(int)>(overloaded_function);
}
struct S {
S(const char *);
};
struct ConvertibleToS {
operator S() const;
};
struct ConvertibleToSRef {
operator const S&() const;
};
void conversions() {
//auto s1 = (const S&)"";
auto s2 = (S)"";
auto s2a = (struct S)"";
auto s2b = (const S)"";
ConvertibleToS c;
auto s3 = (const S&)c;
auto s4 = (S)c;
ConvertibleToSRef cr;
auto s5 = (const S&)cr;
auto s6 = (S)cr;
}