// RUN: %clang_cc1 -fsyntax-only -verify -Wformat-nonliteral -pedantic -fblocks %s
#include <stdarg.h>
extern "C" {
extern int scanf(const char *restrict, ...);
extern int printf(const char *restrict, ...);
extern int vprintf(const char *restrict, va_list);
}
void f(char **sp, float *fp) {
scanf("%as", sp); // expected-warning{{'a' length modifier is not supported by ISO C}}
// TODO: Warn that the 'a' conversion specifier is a C++11 feature.
printf("%a", 1.0);
scanf("%afoobar", fp);
}
void g() {
printf("%ls", "foo"); // expected-warning{{format specifies type 'wchar_t *' but the argument has type 'const char *'}}
}
// Test that we properly handle format_idx on C++ members.
class Foo {
public:
const char *gettext(const char *fmt) __attribute__((format_arg(2)));
int scanf(const char *, ...) __attribute__((format(scanf, 2, 3)));
int printf(const char *, ...) __attribute__((format(printf, 2, 3)));
int printf2(const char *, ...);
static const char *gettext_static(const char *fmt) __attribute__((format_arg(1)));
static int printf_static(const char *fmt, ...) __attribute__((format(printf, 1, 2)));
};
void h(int *i) {
Foo foo;
foo.scanf("%d"); // expected-warning{{more '%' conversions than data arguments}}
foo.printf("%d", i); // expected-warning{{format specifies type 'int' but the argument has type 'int *'}}
Foo::printf_static("%d", i); // expected-warning{{format specifies type 'int' but the argument has type 'int *'}}
printf(foo.gettext("%d"), i); // expected-warning{{format specifies type 'int' but the argument has type 'int *'}}
printf(Foo::gettext_static("%d"), i); // expected-warning{{format specifies type 'int' but the argument has type 'int *'}}
}
// Test handling __null for format string literal checking.
extern "C" {
int test_null_format(const char *format, ...) __attribute__((__format__ (__printf__, 1, 2)));
}
void rdar8269537(const char *f)
{
test_null_format(false); // expected-warning {{null from a constant boolean}}
test_null_format(0); // no-warning
test_null_format(__null); // no-warning
test_null_format(f); // expected-warning {{not a string literal}}
}
int Foo::printf(const char *fmt, ...) {
va_list ap;
va_start(ap,fmt);
const char * const format = fmt;
vprintf(format, ap); // no-warning
const char *format2 = fmt;
vprintf(format2, ap); // expected-warning{{format string is not a string literal}}
return 0;
}
int Foo::printf2(const char *fmt, ...) {
va_list ap;
va_start(ap,fmt);
vprintf(fmt, ap); // expected-warning{{format string is not a string literal}}
return 0;
}
namespace Templates {
template<typename T>
void my_uninstantiated_print(const T &arg) {
printf("%d", arg); // no-warning
}
template<typename T>
void my_print(const T &arg) {
printf("%d", arg); // expected-warning {{format specifies type 'int' but the argument has type 'const char *'}}
}
void use_my_print() {
my_print("abc"); // expected-note {{requested here}}
}
template<typename T>
class UninstantiatedPrinter {
public:
static void print(const T &arg) {
printf("%d", arg); // no-warning
}
};
template<typename T>
class Printer {
void format(const char *fmt, ...) __attribute__((format(printf,2,3)));
public:
void print(const T &arg) {
format("%d", arg); // expected-warning {{format specifies type 'int' but the argument has type 'const char *'}}
}
};
void use_class(Printer<const char *> &p) {
p.print("abc"); // expected-note {{requested here}}
}
extern void (^block_print)(const char * format, ...) __attribute__((format(printf, 1, 2)));
template<typename T>
void uninstantiated_call_block_print(const T &arg) {
block_print("%d", arg); // no-warning
}
template<typename T>
void call_block_print(const T &arg) {
block_print("%d", arg); // expected-warning {{format specifies type 'int' but the argument has type 'const char *'}}
}
void use_block_print() {
call_block_print("abc"); // expected-note {{requested here}}
}
}