blob: 720342a22970cdf9b0759323d9dfb09fa14cbfd6 [file] [log] [blame]
// RUN: %clang_cc1 -triple i386-apple-darwin9 -analyze -analyzer-experimental-internal-checks -analyzer-check-objc-mem -analyzer-store=region -verify -fblocks -analyzer-opt-analyze-nested-blocks %s
// RUN: %clang_cc1 -triple x86_64-apple-darwin9 -DTEST_64 -analyze -analyzer-experimental-internal-checks -analyzer-check-objc-mem -analyzer-store=region -verify -fblocks -analyzer-opt-analyze-nested-blocks %s
typedef long unsigned int size_t;
void *memcpy(void *, const void *, size_t);
void *alloca(size_t);
typedef struct objc_selector *SEL;
typedef signed char BOOL;
typedef int NSInteger;
typedef unsigned int NSUInteger;
typedef struct _NSZone NSZone;
@class NSInvocation, NSMethodSignature, NSCoder, NSString, NSEnumerator;
@protocol NSObject - (BOOL)isEqual:(id)object; @end
@protocol NSCopying - (id)copyWithZone:(NSZone *)zone; @end
@protocol NSMutableCopying - (id)mutableCopyWithZone:(NSZone *)zone; @end
@protocol NSCoding - (void)encodeWithCoder:(NSCoder *)aCoder; @end
@interface NSObject <NSObject> {} - (id)init; @end
extern id NSAllocateObject(Class aClass, NSUInteger extraBytes, NSZone *zone);
@interface NSString : NSObject <NSCopying, NSMutableCopying, NSCoding>
- (NSUInteger)length;
+ (id)stringWithUTF8String:(const char *)nullTerminatedCString;
@end extern NSString * const NSBundleDidLoadNotification;
@interface NSAssertionHandler : NSObject {}
+ (NSAssertionHandler *)currentHandler;
- (void)handleFailureInMethod:(SEL)selector object:(id)object file:(NSString *)fileName lineNumber:(NSInteger)line description:(NSString *)format,...;
@end
extern NSString * const NSConnectionReplyMode;
#ifdef TEST_64
typedef long long int64_t;
typedef int64_t intptr_t;
#else
typedef int int32_t;
typedef int32_t intptr_t;
#endif
//---------------------------------------------------------------------------
// Test case 'checkaccess_union' differs for region store and basic store.
// The basic store doesn't reason about compound literals, so the code
// below won't fire an "uninitialized value" warning.
//---------------------------------------------------------------------------
// PR 2948 (testcase; crash on VisitLValue for union types)
// http://llvm.org/bugs/show_bug.cgi?id=2948
void checkaccess_union() {
int ret = 0, status;
// Since RegionStore doesn't handle unions yet,
// this branch condition won't be triggered
// as involving an uninitialized value.
if (((((__extension__ (((union { // no-warning
__typeof (status) __in; int __i;}
)
{
.__in = (status)}
).__i))) & 0xff00) >> 8) == 1)
ret = 1;
}
// Check our handling of fields being invalidated by function calls.
struct test2_struct { int x; int y; char* s; };
void test2_help(struct test2_struct* p);
char test2() {
struct test2_struct s;
test2_help(&s);
char *p = 0;
if (s.x > 1) {
if (s.s != 0) {
p = "hello";
}
}
if (s.x > 1) {
if (s.s != 0) {
return *p;
}
}
return 'a';
}
// BasicStore handles this case incorrectly because it doesn't reason about
// the value pointed to by 'x' and thus creates different symbolic values
// at the declarations of 'a' and 'b' respectively. RegionStore handles
// it correctly. See the companion test in 'misc-ps-basic-store.m'.
void test_trivial_symbolic_comparison_pointer_parameter(int *x) {
int a = *x;
int b = *x;
if (a != b) {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
}
// This is a modified test from 'misc-ps.m'. Here we have the extra
// NULL dereferences which are pruned out by RegionStore's symbolic reasoning
// of fields.
typedef struct _BStruct { void *grue; } BStruct;
void testB_aux(void *ptr);
void testB(BStruct *b) {
{
int *__gruep__ = ((int *)&((b)->grue));
int __gruev__ = *__gruep__;
int __gruev2__ = *__gruep__;
if (__gruev__ != __gruev2__) {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
testB_aux(__gruep__);
}
{
int *__gruep__ = ((int *)&((b)->grue));
int __gruev__ = *__gruep__;
int __gruev2__ = *__gruep__;
if (__gruev__ != __gruev2__) {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
if (~0 != __gruev__) {}
}
}
void testB_2(BStruct *b) {
{
int **__gruep__ = ((int **)&((b)->grue));
int *__gruev__ = *__gruep__;
testB_aux(__gruep__);
}
{
int **__gruep__ = ((int **)&((b)->grue));
int *__gruev__ = *__gruep__;
if ((int*)~0 != __gruev__) {}
}
}
// This test case is a reduced case of a caching bug discovered by an
// assertion failure in RegionStoreManager::BindArray. Essentially the
// DeclStmt is evaluated twice, but on the second loop iteration the
// engine caches out. Previously a false transition would cause UnknownVal
// to bind to the variable, firing an assertion failure. This bug was fixed
// in r76262.
void test_declstmt_caching() {
again:
{
const char a[] = "I like to crash";
goto again;
}
}
//===----------------------------------------------------------------------===//
// Reduced test case from <rdar://problem/7114618>.
// Basically a null check is performed on the field value, which is then
// assigned to a variable and then checked again.
//===----------------------------------------------------------------------===//
struct s_7114618 { int *p; };
void test_rdar_7114618(struct s_7114618 *s) {
if (s->p) {
int *p = s->p;
if (!p) {
// Infeasible
int *dead = 0;
*dead = 0xDEADBEEF; // no-warning
}
}
}
// Test pointers increment correctly.
void f() {
int a[2];
a[1] = 3;
int *p = a;
p++;
if (*p != 3) {
int *q = 0;
*q = 3; // no-warning
}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7185607>
// Bit-fields of a struct should be invalidated when blasting the entire
// struct with an integer constant.
//===----------------------------------------------------------------------===//
struct test_7185607 {
int x : 10;
int y : 22;
};
int rdar_test_7185607() {
struct test_7185607 s; // Uninitialized.
*((unsigned *) &s) = 0U;
return s.x; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7242006> [RegionStore] compound literal assignment with
// floats not honored
// This test case is mirrored in misc-ps.m, but this case is a negative.
//===----------------------------------------------------------------------===//
typedef float CGFloat;
typedef struct _NSSize {
CGFloat width;
CGFloat height;
} NSSize;
CGFloat rdar7242006_negative(CGFloat x) {
NSSize y;
return y.width; // expected-warning{{garbage}}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7249340> - Allow binding of values to symbolic regions.
// This test case shows how RegionStore tracks the value bound to 'x'
// after the assignment.
//===----------------------------------------------------------------------===//
typedef int* ptr_rdar_7249340;
void rdar_7249340(ptr_rdar_7249340 x) {
*x = 1;
if (*x)
return;
int *p = 0; // This is unreachable.
*p = 0xDEADBEEF; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7249327> - This test case tests both value tracking of
// array values and that we handle symbolic values that are casted
// between different integer types. Note the assignment 'n = *a++'; here
// 'n' is and 'int' and '*a' is 'unsigned'. Previously we got a false positive
// at 'x += *b++' (undefined value) because we got a false path.
//===----------------------------------------------------------------------===//
int rdar_7249327_aux(void);
void rdar_7249327(unsigned int A[2*32]) {
int B[2*32];
int *b;
unsigned int *a;
int x = 0;
int n;
a = A;
b = B;
n = *a++;
if (n)
*b++ = rdar_7249327_aux();
a = A;
b = B;
n = *a++; // expected-warning{{Assigned value is always the same as the existing value}}
if (n)
x += *b++; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/6914474> - Check that 'x' is invalidated because its
// address is passed in as a value to a struct.
//===----------------------------------------------------------------------===//
struct doodad_6914474 { int *v; };
extern void prod_6914474(struct doodad_6914474 *d);
int rdar_6914474(void) {
int x;
struct doodad_6914474 d;
d.v = &x;
prod_6914474(&d);
return x; // no-warning
}
// Test invalidation of a single field.
struct s_test_field_invalidate {
int x;
};
extern void test_invalidate_field(int *x);
int test_invalidate_field_test() {
struct s_test_field_invalidate y;
test_invalidate_field(&y.x);
return y.x; // no-warning
}
int test_invalidate_field_test_positive() {
struct s_test_field_invalidate y;
return y.x; // expected-warning{{garbage}}
}
// This test case illustrates how a typeless array of bytes casted to a
// struct should be treated as initialized. RemoveDeadBindings previously
// had a bug that caused 'x' to lose its default symbolic value after the
// assignment to 'p', thus causing 'p->z' to evaluate to "undefined".
struct ArrayWrapper { unsigned char y[16]; };
struct WrappedStruct { unsigned z; };
int test_handle_array_wrapper() {
struct ArrayWrapper x;
test_handle_array_wrapper(&x);
struct WrappedStruct *p = (struct WrappedStruct*) x.y; // expected-warning{{Casting a non-structure type to a structure type and accessing a field can lead to memory access errors or data corruption.}}
return p->z; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7261075> [RegionStore] crash when
// handling load: '*((unsigned int *)"????")'
//===----------------------------------------------------------------------===//
int rdar_7261075(void) {
unsigned int var = 0;
if (var == *((unsigned int *)"????"))
return 1;
return 0;
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7275774> false path due to limited pointer
// arithmetic constraints
//===----------------------------------------------------------------------===//
void rdar_7275774(void *data, unsigned n) {
if (!(data || n == 0))
return;
unsigned short *p = (unsigned short*) data;
unsigned short *q = p + (n / 2);
if (p < q) {
// If we reach here, 'p' cannot be null. If 'p' is null, then 'n' must
// be '0', meaning that this branch is not feasible.
*p = *q; // no-warning
}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7312221>
//
// Test that Objective-C instance variables aren't prematurely pruned
// from the analysis state.
//===----------------------------------------------------------------------===//
struct rdar_7312221_value { int x; };
@interface RDar7312221
{
struct rdar_7312221_value *y;
}
- (void) doSomething_7312221;
@end
extern struct rdar_7312221_value *rdar_7312221_helper();
extern int rdar_7312221_helper_2(id o);
extern void rdar_7312221_helper_3(int z);
@implementation RDar7312221
- (void) doSomething_7312221 {
if (y == 0) {
y = rdar_7312221_helper();
if (y != 0) {
y->x = rdar_7312221_helper_2(self);
// The following use of 'y->x' previously triggered a null dereference, as the value of 'y'
// before 'y = rdar_7312221_helper()' would be used.
rdar_7312221_helper_3(y->x); // no-warning
}
}
}
@end
struct rdar_7312221_container {
struct rdar_7312221_value *y;
};
extern int rdar_7312221_helper_4(struct rdar_7312221_container *s);
// This test case essentially matches the one in [RDar7312221 doSomething_7312221].
void doSomething_7312221_with_struct(struct rdar_7312221_container *Self) {
if (Self->y == 0) {
Self->y = rdar_7312221_helper();
if (Self->y != 0) {
Self->y->x = rdar_7312221_helper_4(Self);
rdar_7312221_helper_3(Self->y->x); // no-warning
}
}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7332673> - Just more tests cases for regions
//===----------------------------------------------------------------------===//
void rdar_7332673_test1() {
char value[1];
if ( *(value) != 1 ) {} // expected-warning{{The left operand of '!=' is a garbage value}}
}
int rdar_7332673_test2_aux(char *x);
void rdar_7332673_test2() {
char *value;
if ( rdar_7332673_test2_aux(value) != 1 ) {} // expected-warning{{Function call argument is an uninitialized value}}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7347252>: Because of a bug in
// RegionStoreManager::RemoveDeadBindings(), the symbol for s->session->p
// would incorrectly be pruned from the state after the call to
// rdar7347252_malloc1(), and would incorrectly result in a warning about
// passing a null pointer to rdar7347252_memcpy().
//===----------------------------------------------------------------------===//
struct rdar7347252_AA { char *p;};
typedef struct {
struct rdar7347252_AA *session;
int t;
char *q;
} rdar7347252_SSL1;
int rdar7347252_f(rdar7347252_SSL1 *s);
char *rdar7347252_malloc1(int);
char *rdar7347252_memcpy1(char *d, char *s, int n) __attribute__((nonnull (1,2)));
int rdar7347252(rdar7347252_SSL1 *s) {
rdar7347252_f(s); // the SymbolicRegion of 's' is set a default binding of conjured symbol
if (s->session->p == ((void*)0)) {
if ((s->session->p = rdar7347252_malloc1(10)) == ((void*)0)) {
return 0;
}
rdar7347252_memcpy1(s->session->p, "aa", 2); // no-warning
}
return 0;
}
//===----------------------------------------------------------------------===//
// PR 5316 - "crash when accessing field of lazy compound value"
// Previously this caused a crash at the MemberExpr '.chr' when loading
// a field value from a LazyCompoundVal
//===----------------------------------------------------------------------===//
typedef unsigned int pr5316_wint_t;
typedef pr5316_wint_t pr5316_REFRESH_CHAR;
typedef struct {
pr5316_REFRESH_CHAR chr;
}
pr5316_REFRESH_ELEMENT;
static void pr5316(pr5316_REFRESH_ELEMENT *dst, const pr5316_REFRESH_ELEMENT *src) {
while ((*dst++ = *src++).chr != L'\0') ;
}
//===----------------------------------------------------------------------===//
// Exercise creating ElementRegion with symbolic super region.
//===----------------------------------------------------------------------===//
void element_region_with_symbolic_superregion(int* p) {
int *x;
int a;
if (p[0] == 1)
x = &a;
if (p[0] == 1)
(void)*x; // no-warning
}
//===----------------------------------------------------------------------===//
// Test returning an out-of-bounds pointer (CWE-466)
//===----------------------------------------------------------------------===//
static int test_cwe466_return_outofbounds_pointer_a[10];
int *test_cwe466_return_outofbounds_pointer() {
int *p = test_cwe466_return_outofbounds_pointer_a+10;
return p; // expected-warning{{Returned pointer value points outside the original object}}
}
//===----------------------------------------------------------------------===//
// PR 3135 - Test case that shows that a variable may get invalidated when its
// address is included in a structure that is passed-by-value to an unknown function.
//===----------------------------------------------------------------------===//
typedef struct { int *a; } pr3135_structure;
int pr3135_bar(pr3135_structure *x);
int pr3135() {
int x;
pr3135_structure y = { &x };
// the call to pr3135_bar may initialize x
if (pr3135_bar(&y) && x) // no-warning
return 1;
return 0;
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7403269> - Test that we handle compound initializers with
// partially unspecified array values. Previously this caused a crash.
//===----------------------------------------------------------------------===//
typedef struct RDar7403269 {
unsigned x[10];
unsigned y;
} RDar7403269;
void rdar7403269() {
RDar7403269 z = { .y = 0 };
if (z.x[4] == 0)
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
typedef struct RDar7403269_b {
struct zorg { int w; int k; } x[10];
unsigned y;
} RDar7403269_b;
void rdar7403269_b() {
RDar7403269_b z = { .y = 0 };
if (z.x[5].w == 0)
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
void rdar7403269_b_pos() {
RDar7403269_b z = { .y = 0 };
if (z.x[5].w == 1)
return;
int *p = 0;
*p = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
//===----------------------------------------------------------------------===//
// Test that incrementing a non-null pointer results in a non-null pointer.
// (<rdar://problem/7191542>)
//===----------------------------------------------------------------------===//
void test_increment_nonnull_rdar_7191542(const char *path) {
const char *alf = 0;
for (;;) {
// When using basic-store, we get a null dereference here because we lose information
// about path after the pointer increment.
char c = *path++; // no-warning
if (c == 'a') {
alf = path;
}
if (alf)
return;
}
}
//===----------------------------------------------------------------------===//
// Test that the store (implicitly) tracks values for doubles/floats that are
// uninitialized (<rdar://problem/6811085>)
//===----------------------------------------------------------------------===//
double rdar_6811085(void) {
double u;
return u + 10; // expected-warning{{The left operand of '+' is a garbage value}}
}
//===----------------------------------------------------------------------===//
// Path-sensitive tests for blocks.
//===----------------------------------------------------------------------===//
void indirect_block_call(void (^f)());
int blocks_1(int *p, int z) {
__block int *q = 0;
void (^bar)() = ^{ q = p; };
if (z == 1) {
// The call to 'bar' might cause 'q' to be invalidated.
bar();
*q = 0x1; // no-warning
}
else if (z == 2) {
// The function 'indirect_block_call' might invoke bar, thus causing
// 'q' to possibly be invalidated.
indirect_block_call(bar);
*q = 0x1; // no-warning
}
else {
*q = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
return z;
}
int blocks_2(int *p, int z) {
int *q = 0;
void (^bar)(int **) = ^(int **r){ *r = p; };
if (z) {
// The call to 'bar' might cause 'q' to be invalidated.
bar(&q);
*q = 0x1; // no-warning
}
else {
*q = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
return z;
}
// Test that the value of 'x' is considered invalidated after the block
// is passed as an argument to the message expression.
typedef void (^RDar7582031CB)(void);
@interface RDar7582031
- rdar7582031:RDar7582031CB;
- rdar7582031_b:RDar7582031CB;
@end
// Test with one block.
unsigned rdar7582031(RDar7582031 *o) {
__block unsigned x;
[o rdar7582031:^{ x = 1; }];
return x; // no-warning
}
// Test with two blocks.
unsigned long rdar7582031_b(RDar7582031 *o) {
__block unsigned y;
__block unsigned long x;
[o rdar7582031:^{ y = 1; }];
[o rdar7582031_b:^{ x = 1LL; }];
return x + (unsigned long) y; // no-warning
}
// Show we get an error when 'o' is null because the message
// expression has no effect.
unsigned long rdar7582031_b2(RDar7582031 *o) {
__block unsigned y;
__block unsigned long x;
if (o)
return 1;
[o rdar7582031:^{ y = 1; }];
[o rdar7582031_b:^{ x = 1LL; }];
return x + (unsigned long) y; // expected-warning{{The left operand of '+' is a garbage value}}
}
// Show that we handle static variables also getting invalidated.
void rdar7582031_aux(void (^)(void));
RDar7582031 *rdar7582031_aux_2();
unsigned rdar7582031_static() {
static RDar7582031 *o = 0;
rdar7582031_aux(^{ o = rdar7582031_aux_2(); });
__block unsigned x;
[o rdar7582031:^{ x = 1; }];
return x; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7462324> - Test that variables passed using __blocks
// are not treated as being uninitialized.
//===----------------------------------------------------------------------===//
typedef void (^RDar_7462324_Callback)(id obj);
@interface RDar7462324
- (void) foo:(id)target;
- (void) foo_positive:(id)target;
@end
@implementation RDar7462324
- (void) foo:(id)target {
__block RDar_7462324_Callback builder = ((void*) 0);
builder = ^(id object) {
if (object) {
builder(self); // no-warning
}
};
builder(target);
}
- (void) foo_positive:(id)target {
__block RDar_7462324_Callback builder = ((void*) 0);
builder = ^(id object) {
id x;
if (object) {
builder(x); // expected-warning{{Function call argument is an uninitialized value}}
}
};
builder(target);
}
@end
//===----------------------------------------------------------------------===//
// <rdar://problem/7468209> - Scanning for live variables within a block should
// not crash on variables passed by reference via __block.
//===----------------------------------------------------------------------===//
int rdar7468209_aux();
void rdar7468209_aux_2();
void rdar7468209() {
__block int x = 0;
^{
x = rdar7468209_aux();
// We need a second statement so that 'x' would be removed from the store if it wasn't
// passed by reference.
rdar7468209_aux_2();
}();
}
//===----------------------------------------------------------------------===//
// PR 5857 - Test loading an integer from a byte array that has also been
// reinterpreted to be loaded as a field.
//===----------------------------------------------------------------------===//
typedef struct { int x; } TestFieldLoad;
int pr5857(char *src) {
TestFieldLoad *tfl = (TestFieldLoad *) (intptr_t) src;
int y = tfl->x;
long long *z = (long long *) (intptr_t) src;
long long w = 0;
int n = 0;
for (n = 0; n < y; ++n) {
// Previously we crashed analyzing this statement.
w = *z++;
}
return 1;
}
//===----------------------------------------------------------------------===//
// PR 4358 - Without field-sensitivity, this code previously triggered
// a false positive that 'uninit' could be uninitialized at the call
// to pr4358_aux().
//===----------------------------------------------------------------------===//
struct pr4358 {
int bar;
int baz;
};
void pr4358_aux(int x);
void pr4358(struct pr4358 *pnt) {
int uninit;
if (pnt->bar < 3) {
uninit = 1;
} else if (pnt->baz > 2) {
uninit = 3;
} else if (pnt->baz <= 2) {
uninit = 2;
}
pr4358_aux(uninit); // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7526777>
// Test handling fields of values returned from function calls or
// message expressions.
//===----------------------------------------------------------------------===//
typedef struct testReturn_rdar_7526777 {
int x;
int y;
} testReturn_rdar_7526777;
@interface TestReturnStruct_rdar_7526777
- (testReturn_rdar_7526777) foo;
@end
int test_return_struct(TestReturnStruct_rdar_7526777 *x) {
return [x foo].x;
}
testReturn_rdar_7526777 test_return_struct_2_aux_rdar_7526777();
int test_return_struct_2_rdar_7526777() {
return test_return_struct_2_aux_rdar_7526777().x;
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7527292> Assertion failed: (Op == BinaryOperator::Add ||
// Op == BinaryOperator::Sub)
// This test case previously triggered an assertion failure due to a discrepancy
// been the loaded/stored value in the array
//===----------------------------------------------------------------------===//
_Bool OSAtomicCompareAndSwapPtrBarrier( void *__oldValue, void *__newValue, void * volatile *__theValue );
void rdar_7527292() {
static id Cache7527292[32];
for (signed long idx = 0;
idx < 32;
idx++) {
id v = Cache7527292[idx];
if (v && OSAtomicCompareAndSwapPtrBarrier(v, ((void*)0), (void * volatile *)(Cache7527292 + idx))) {
}
}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7515938> - Handle initialization of incomplete arrays
// in structures using a compound value. Previously this crashed.
//===----------------------------------------------------------------------===//
struct rdar_7515938 {
int x;
int y[];
};
const struct rdar_7515938 *rdar_7515938() {
static const struct rdar_7515938 z = { 0, { 1, 2 } };
if (z.y[0] != 1) {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
return &z;
}
struct rdar_7515938_str {
int x;
char y[];
};
const struct rdar_7515938_str *rdar_7515938_str() {
static const struct rdar_7515938_str z = { 0, "hello" };
return &z;
}
//===----------------------------------------------------------------------===//
// Assorted test cases from PR 4172.
//===----------------------------------------------------------------------===//
struct PR4172A_s { int *a; };
void PR4172A_f2(struct PR4172A_s *p);
int PR4172A_f1(void) {
struct PR4172A_s m;
int b[4];
m.a = b;
PR4172A_f2(&m);
return b[3]; // no-warning
}
struct PR4172B_s { int *a; };
void PR4172B_f2(struct PR4172B_s *p);
int PR4172B_f1(void) {
struct PR4172B_s m;
int x;
m.a = &x;
PR4172B_f2(&m);
return x; // no-warning
}
//===----------------------------------------------------------------------===//
// Test invalidation of values in struct literals.
//===----------------------------------------------------------------------===//
struct s_rev96062 { int *x; int *y; };
struct s_rev96062_nested { struct s_rev96062 z; };
void test_a_rev96062_aux(struct s_rev96062 *s);
void test_a_rev96062_aux2(struct s_rev96062_nested *s);
int test_a_rev96062() {
int a, b;
struct s_rev96062 x = { &a, &b };
test_a_rev96062_aux(&x);
return a + b; // no-warning
}
int test_b_rev96062() {
int a, b;
struct s_rev96062 x = { &a, &b };
struct s_rev96062 z = x;
test_a_rev96062_aux(&z);
return a + b; // no-warning
}
int test_c_rev96062() {
int a, b;
struct s_rev96062 x = { &a, &b };
struct s_rev96062_nested w = { x };
struct s_rev96062_nested z = w;
test_a_rev96062_aux2(&z);
return a + b; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7242010> - The access to y[0] at the bottom previously
// was reported as an uninitialized value.
//===----------------------------------------------------------------------===//
char *rdar_7242010(int count, char **y) {
char **x = alloca((count + 4) * sizeof(*x));
x[0] = "hi";
x[1] = "there";
x[2] = "every";
x[3] = "body";
memcpy(x + 4, y, count * sizeof(*x));
y = x;
return y[0]; // no-warning
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7770737>
//===----------------------------------------------------------------------===//
struct rdar_7770737_s { intptr_t p; };
void rdar_7770737_aux(struct rdar_7770737_s *p);
int rdar_7770737(void)
{
int x;
// Previously 'f' was not properly invalidated, causing the use of
// an uninitailized value below.
struct rdar_7770737_s f = { .p = (intptr_t)&x };
rdar_7770737_aux(&f);
return x; // no-warning
}
int rdar_7770737_pos(void)
{
int x;
struct rdar_7770737_s f = { .p = (intptr_t)&x };
return x; // expected-warning{{Undefined or garbage value returned to caller}}
}
//===----------------------------------------------------------------------===//
// Test handling of the implicit 'isa' field. For now we don't do anything
// interesting.
//===----------------------------------------------------------------------===//
void pr6302(id x, Class y) {
// This previously crashed the analyzer (reported in PR 6302)
x->isa = y;
}
//===----------------------------------------------------------------------===//
// Specially handle global variables that are declared constant. In the
// example below, this forces the loop to take exactly 2 iterations.
//===----------------------------------------------------------------------===//
const int pr6288_L_N = 2;
void pr6288_(void) {
int x[2];
int *px[2];
int i;
for (i = 0; i < pr6288_L_N; i++)
px[i] = &x[i];
*(px[0]) = 0; // no-warning
}
void pr6288_pos(int z) {
int x[2];
int *px[2];
int i;
for (i = 0; i < z; i++)
px[i] = &x[i]; // expected-warning{{Access out-of-bound array element (buffer overflow)}}
*(px[0]) = 0; // expected-warning{{Dereference of undefined pointer value}}
}
void pr6288_b(void) {
const int L_N = 2;
int x[2];
int *px[2];
int i;
for (i = 0; i < L_N; i++)
px[i] = &x[i];
*(px[0]) = 0; // no-warning
}
// <rdar://problem/7817800> - A bug in RemoveDeadBindings was causing instance variable bindings
// to get prematurely pruned from the state.
@interface Rdar7817800 {
char *x;
}
- (void) rdar7817800_baz;
@end
char *rdar7817800_foobar();
void rdar7817800_qux(void*);
@implementation Rdar7817800
- (void) rdar7817800_baz {
if (x)
rdar7817800_qux(x);
x = rdar7817800_foobar();
// Previously this triggered a bogus null dereference warning.
x[1] = 'a'; // no-warning
}
@end
// PR 6036 - This test case triggered a crash inside StoreManager::CastRegion because the size
// of 'unsigned long (*)[0]' is 0.
struct pr6036_a { int pr6036_b; };
struct pr6036_c;
void u132monitk (struct pr6036_c *pr6036_d) {
(void) ((struct pr6036_a *) (unsigned long (*)[0]) ((char *) pr6036_d - 1))->pr6036_b; // expected-warning{{Casting a non-structure type to a structure type and accessing a field can lead to memory access errors or data corruption}}
}
// <rdar://problem/7813989> - ?-expressions used as a base of a member expression should be treated as an lvalue
typedef struct rdar7813989_NestedVal { int w; } rdar7813989_NestedVal;
typedef struct rdar7813989_Val { rdar7813989_NestedVal nv; } rdar7813989_Val;
int rdar7813989(int x, rdar7813989_Val *a, rdar7813989_Val *b) {
// This previously crashed with an assertion failure.
int z = (x ? a->nv : b->nv).w;
return z + 1;
}
// PR 6844 - Don't crash on vaarg expression.
typedef __builtin_va_list va_list;
void map(int srcID, ...) {
va_list ap;
int i;
for (i = 0; i < srcID; i++) {
int v = __builtin_va_arg(ap, int);
}
}
// PR 6854 - crash when casting symbolic memory address to a float
// Handle casting from a symbolic region to a 'float'. This isn't
// really all that intelligent, but previously this caused a crash
// in SimpleSValuator.
void pr6854(void * arg) {
void * a = arg;
*(void**)a = arg;
float f = *(float*) a;
}
// <rdar://problem/8032791> False positive due to symbolic store not find
// value because of 'const' qualifier
double rdar_8032791_2();
double rdar_8032791_1() {
struct R8032791 { double x[2]; double y; }
data[3] = {
{{1.0, 3.0}, 3.0}, // 1 2 3
{{1.0, 1.0}, 0.0}, // 1 1 2 2 3 3
{{1.0, 3.0}, 1.0} // 1 2 3
};
double x = 0.0;
for (unsigned i = 0 ; i < 3; i++) {
const struct R8032791 *p = &data[i];
x += p->y + rdar_8032791_2(); // no-warning
}
return x;
}
// PR 7450 - Handle pointer arithmetic with __builtin_alloca
void pr_7450_aux(void *x);
void pr_7450() {
void *p = __builtin_alloca(10);
// Don't crash when analyzing the following statement.
pr_7450_aux(p + 8);
}
// <rdar://problem/8243408> - Symbolicate struct values returned by value.
struct s_rdar_8243408 { int x; };
extern struct s_rdar_8243408 rdar_8243408_aux(void);
void rdar_8243408(void) {
struct s_rdar_8243408 a = { 1 }, *b = 0;
while (a.x && !b)
a = rdar_8243408_aux();
// Previously there was a false error here with 'b' being null.
(void) (a.x && b->x); // no-warning
// Introduce a null deref to ensure we are checking this path.
int *p = 0;
*p = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
// <rdar://problem/8258814>
int r8258814()
{
int foo;
int * a = &foo;
a[0] = 10;
// Do not warn that the value of 'foo' is uninitialized.
return foo; // no-warning
}
// PR 8052 - Don't crash when reasoning about loads from a function address.\n
typedef unsigned int __uint32_t;
typedef unsigned long vm_offset_t;
typedef __uint32_t pd_entry_t;
typedef unsigned char u_char;
typedef unsigned int u_int;
typedef unsigned long u_long;
extern int bootMP_size;
void bootMP(void);
static void
pr8052(u_int boot_addr)
{
int x;
int size = *(int *) ((u_long) & bootMP_size);
u_char *src = (u_char *) ((u_long) bootMP);
u_char *dst = (u_char *) boot_addr + ((vm_offset_t) ((((((((1 <<
12) / (sizeof(pd_entry_t))) - 1) - 1) - (260 - 2))) << 22) | ((0) << 12)));
for (x = 0;
x < size;
++x)
*dst++ = *src++;
}
// PR 8015 - don't return undefined values for arrays when using a valid
// symbolic index
int pr8015_A();
void pr8015_B(const char *);
void pr8015_C() {
int number = pr8015_A();
const char *numbers[] = { "zero" };
if (number == 0) {
pr8015_B(numbers[number]); // no-warning
}
}
// Tests that we correctly handle that 'number' is perfectly constrained
// after 'if (nunber == 0)', allowing us to resolve that
// numbers[number] == numbers[0].
void pr8015_D_FIXME() {
int number = pr8015_A();
const char *numbers[] = { "zero" };
if (number == 0) {
if (numbers[number] == numbers[0]) // expected-warning{{Both operands to '==' always have the same value}}
return;
// Unreachable.
int *p = 0;
*p = 0xDEADBEEF; // no-warnng
}
}
void pr8015_E() {
// Similar to pr8015_C, but number is allowed to be a valid range.
unsigned number = pr8015_A();
const char *numbers[] = { "zero", "one", "two" };
if (number < 3) {
pr8015_B(numbers[number]); // no-warning
}
}
void pr8015_F_FIXME() {
// Similar to pr8015_E, but like pr8015_D we check if the pointer
// is the same as one of the string literals. The null dereference
// here is not feasible in practice, so this is a false positive.
int number = pr8015_A();
const char *numbers[] = { "zero", "one", "two" };
if (number < 3) {
const char *p = numbers[number];
if (p == numbers[0] || p == numbers[1] || p == numbers[2])
return;
int *q = 0;
*q = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
}