// RUN: %clang_cc1 -std=c++20 -Wunsafe-buffer-usage \
// RUN: -fsafe-buffer-usage-suggestions \
// RUN: -fdiagnostics-parseable-fixits %s 2>&1 | FileCheck %s
typedef int * Int_ptr_t;
typedef int Int_t;
void local_array_subscript_simple() {
int tmp;
int *p = new int[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int> "
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:12-[[@LINE-2]]:12}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:23-[[@LINE-3]]:23}:", 10}"
const int *q = new int[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:14}:"std::span<int const> "
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:18-[[@LINE-2]]:18}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:29-[[@LINE-3]]:29}:", 10}"
tmp = p[5];
tmp = q[5];
// We do not fix the following declaration. Because if the
// definition of `Int_ptr_t` gets changed, the fixed code becomes
// incorrect and may NOT be noticed.
// FIXME: Fix with std::span<std::remove_pointer_t<Int_ptr_t>>?
Int_ptr_t x = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
Int_t * z = new int[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:10}:"std::span<Int_t>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:15-[[@LINE-2]]:15}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:26-[[@LINE-3]]:26}:", 10}"
Int_t * w = new Int_t[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:10}:"std::span<Int_t>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:15-[[@LINE-2]]:15}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:28-[[@LINE-3]]:28}:", 10}"
tmp = x[5];
tmp = z[5];
tmp = w[5];
}
void local_array_subscript_auto() {
int tmp;
// We do not fix the following declaration because
// that'd cause us to hardcode the element type.
// FIXME: Can we use the C++17 class template argument deduction
// to avoid spelling out the element type?
auto p = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
tmp = p[5];
}
void local_variable_qualifiers_specifiers() {
int a[10];
const int * p = a;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:14}:"std::span<int const>"
const int * const q = a;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:14}:"std::span<int const>"
int tmp;
tmp = p[5];
tmp = q[5];
[[deprecated]] const int * x = a;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:18-[[@LINE-1]]:29}:"std::span<int const>"
const int * y [[deprecated]];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:14}:"std::span<int const>"
tmp = x[5];
tmp = y[5];
}
void local_variable_unsupported_specifiers() {
int a[10];
const int * p [[deprecated]] = a; // not supported because the attribute overlaps the source range of the declaration
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]:
static const int * q = a; // storage specifier not supported yet
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]:
extern int * x; // storage specifier not supported yet
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]:
constexpr int * y = 0; // `constexpr` specifier not supported yet
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]:
int tmp;
tmp = p[5];
tmp = q[5];
tmp = x[5];
tmp = y[5];
}
void local_array_subscript_variable_extent() {
int n = 10;
int tmp;
int *p = new int[n];
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int> "
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:12-[[@LINE-2]]:12}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:22-[[@LINE-3]]:22}:", n}"
// If the extent expression does not have a constant value, we cannot fill the extent for users...
int *q = new int[n++];
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int> "
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:12-[[@LINE-2]]:12}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:24-[[@LINE-3]]:24}:", <# placeholder #>}"
tmp = p[5];
tmp = q[5];
}
void local_ptr_to_array() {
int tmp;
int n = 10;
int a[10];
int b[n]; // If the extent expression does not have a constant value, we cannot fill the extent for users...
int *p = a;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int> "
int *q = b;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int> "
// No way to know if `n` is ever mutated since `int b[n];`, so no way to figure out the extent
tmp = p[5];
tmp = q[5];
}
void local_ptr_addrof_init() {
int var;
int * q = &var;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:17-[[@LINE-3]]:17}:", 1}"
// This expression involves unsafe buffer accesses, which will crash
// at runtime after applying the fix-it,
var = q[5];
}
void decl_without_init() {
int tmp;
int * p;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-2]]:{{^3}}
Int_t * q;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:10}:"std::span<Int_t>"
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-2]]:{{^3}}
tmp = p[5];
tmp = q[5];
}
// Explicit casts are required in the following cases. No way to
// figure out span extent for them automatically.
void explict_cast() {
int tmp;
int * p = (int*) new int[10][10];
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:35-[[@LINE-3]]:35}:", <# placeholder #>}"
tmp = p[5];
int a;
char * q = (char *)&a;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:9}:"std::span<char>"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:14-[[@LINE-2]]:14}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:24-[[@LINE-3]]:24}:", <# placeholder #>}"
tmp = (int) q[5];
void * r = &a;
char * s = (char *) r;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:9}:"std::span<char>"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:14-[[@LINE-2]]:14}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:24-[[@LINE-3]]:24}:", <# placeholder #>}"
tmp = (int) s[5];
}
void null_init() {
#define NULL 0
int tmp;
int * my_null = 0;
int * p = 0;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-2]]:{{^3}}
int * g = NULL; // cannot handle fix-its involving macros for now
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]:
int * f = nullptr;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-2]]:{{^3}}
// In case of value dependencies, we give up
int * q = my_null;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:20-[[@LINE-3]]:20}:", <# placeholder #>}"
int * r = my_null + 0;
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:24-[[@LINE-3]]:24}:", <# placeholder #>}"
tmp = p[5]; // `p[5]` will cause crash after `p` being transformed to be a `std::span`
tmp = q[5]; // Similar for the rests.
tmp = r[5];
tmp = g[5];
tmp = f[5];
#undef NULL
}
void unsupported_multi_decl(int * x) {
int * p = x, * q = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
*p = q[5];
}
void macroVariableIdentifier() {
#define MY_NAME p
#define MY_NAME_ARG(x) q
// Although fix-its include macros, the macros do not overlap with
// the bounds of the source range of these fix-its. So these fix-its
// are valid.
int * MY_NAME = new int[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:19-[[@LINE-2]]:19}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:30-[[@LINE-3]]:30}:", 10}"
int * MY_NAME_ARG( 'x' ) = new int[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:30-[[@LINE-2]]:30}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:41-[[@LINE-3]]:41}:", 10}"
p[5] = 5;
q[5] = 5;
#undef MY_NAME
#undef MY_NAME_ARG
}
void unsupported_fixit_overlapping_macro(int * x) {
int tmp;
// In the case below, a tentative fix-it replaces `MY_INT * p =` with `std::span<MY_INT> p `.
// The bounds of the source range of the fix-it overlap with the use of the macro
// `MY_INT`. The fix-it is discarded then.
// FIXME: we do not have to discard a fix-it if its begin location
// overlaps with the begin location of a macro. Similar for end
// locations.
#define MY_INT int
MY_INT * p = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
tmp = p[5];
#define MY_VAR(name) int * name
MY_VAR(q) = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
tmp = q[5];
// In cases where fix-its do not change the original code where
// macros are used, those fix-its will be emitted. For example,
// fixits are inserted before and after `new MY_INT[MY_TEN]` below.
#define MY_TEN 10
int * g = new MY_INT[MY_TEN];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:31-[[@LINE-3]]:31}:", MY_TEN}"
tmp = g[5];
#undef MY_INT
#undef MY_VAR
#undef MY_TEN
}
void unsupported_subscript_negative(int i, unsigned j, unsigned long k) {
int tmp;
int * p = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
tmp = p[-1]; // If `p` is made a span, this `[]` operation is wrong,
// so no fix-it emitted.
int * q = new int[10];
// CHECK-NOT: fix-it:"{{.*}}":{[[@LINE-1]]
tmp = q[5];
tmp = q[i]; // If `q` is made a span, this `[]` operation may be
// wrong as we do not know if `i` is non-negative, so
// no fix-it emitted.
int * r = new int[10];
// CHECK: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK: fix-it:"{{.*}}":{[[@LINE-3]]:24-[[@LINE-3]]:24}:", 10}"
tmp = r[j] + r[k]; // both `j` and `k` are unsigned so they must be non-negative
tmp = r[(unsigned int)-1]; // a cast-to-unsigned-expression is also non-negative
}
#define DEFINE_PTR(X) int* ptr = (X);
void all_vars_in_macro() {
int* local;
DEFINE_PTR(local)
ptr[1] = 0;
}
void few_vars_in_macro() {
int* local;
DEFINE_PTR(local)
ptr[1] = 0;
int tmp;
ptr[2] = 30;
int * p = new int[10];
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:3-[[@LINE-1]]:8}:"std::span<int>"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:13-[[@LINE-2]]:13}:"{"
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-3]]:24-[[@LINE-3]]:24}:", 10}"
tmp = p[5];
int val = *p;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:13-[[@LINE-1]]:14}:""
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:15-[[@LINE-2]]:15}:"[0]"
val = *p + 30;
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-1]]:9-[[@LINE-1]]:10}:""
// CHECK-DAG: fix-it:"{{.*}}":{[[@LINE-2]]:11-[[@LINE-2]]:11}:"[0]"
}