llvm-project/clang/test/Analysis/misc-ps.m

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// NOTE: Use '-fobjc-gc' to test the analysis being run twice, and multiple reports are not issued.
// RUN: %clang_analyze_cc1 -triple i386-apple-darwin10 -analyzer-checker=core,alpha.core,osx.cocoa.AtSync -analyzer-store=region -Wno-strict-prototypes -Wno-pointer-to-int-cast -verify -fblocks -Wno-unreachable-code -Wno-null-dereference -Wno-objc-root-class %s
// RUN: %clang_analyze_cc1 -triple x86_64-apple-darwin10 -analyzer-checker=core,alpha.core,osx.cocoa.AtSync -analyzer-store=region -Wno-strict-prototypes -Wno-pointer-to-int-cast -verify -fblocks -Wno-unreachable-code -Wno-null-dereference -Wno-objc-root-class %s
#ifndef __clang_analyzer__
#error __clang_analyzer__ not defined
#endif
This is a fairly large patch, which resulted from a cascade of changes made to RegionStore (and related classes) in order to handle some analyzer failures involving casts and manipulation of symbolic memory. The root of the change is in StoreManager::CastRegion(). Instead of using ad hoc heuristics to decide when to layer an ElementRegion on a casted MemRegion, we now always layer an ElementRegion when the cast type is different than the original type of the region. This carries the current cast information associated with a region around without resorting to the error prone recording of "casted types" in GRState. Along with this new policy of layering ElementRegions, I added a new algorithm to strip away existing ElementRegions when they simply represented casts of a base memory object. This algorithm computes the raw "byte offset" that an ElementRegion represents from the base region, and allows the new ElementRegion to be based off that offset. The added benefit is that this naturally handles a series of casts of a MemRegion without building up a set of redundant ElementRegions (thus canonicalizing the region view). Other related changes that cascaded from this one (as tests were failing in RegionStore): - Revamped RegionStoreManager::InvalidateRegion() to completely remove all bindings and default values from a region and all subregions. Now invalidated fields are not bound directly to new symbolic values; instead the base region has a "default" symbol value from which "derived symbols" can be created. The main advantage of this approach is that it allows us to invalidate a region hierarchy and then lazily instantiate new values no matter how deep the hierarchy went (i.e., regardless of the number of field accesses, e.g. x->f->y->z->...). The previous approach did not do this. - Slightly reworked RegionStoreManager::RemoveDeadBindings() to also incorporate live symbols and live regions that do not have direct bindings but also have "default values" used for lazy instantiation. The changes to 'InvalidateRegion' revealed that these were necessary in order to achieve lazy instantiation of values in the region store with those bindings being removed too early. - The changes to InvalidateRegion() and RemoveDeadBindings() revealed a serious bug in 'getSubRegionMap()' where not all region -> subregion relationships involved in actually bindings (explicit and implicit) were being recorded. This has been fixed by using a worklist algorithm to iteratively fill in the region map. - Added special support to RegionStoreManager::Bind()/Retrieve() to handle OSAtomicCompareAndSwap in light of the new 'CastRegion' changes and the layering of ElementRegions. - Fixed a bug in SymbolReaper::isLive() where derived symbols were not being marked live if the symbol they were derived from was also live. This fix was critical for getting lazy instantiation in RegionStore to work. - Tidied up the implementation of ValueManager::getXXXSymbolVal() methods to use SymbolManager::canSymbolicate() to decide whether or not a symbol should be symbolicated. - 'test/Analysis/misc-ps-xfail.m' now passes; that test case has been moved to 'test/Analysis/misc-ps.m'. - Tweaked some pretty-printing of MemRegions, and implemented 'ElementRegion::getRawOffset()' for use with the CastRegion changes. llvm-svn: 77782
2009-08-01 14:17:29 +08:00
typedef struct objc_ivar *Ivar;
typedef struct objc_selector *SEL;
typedef signed char BOOL;
typedef int NSInteger;
typedef unsigned int NSUInteger;
typedef struct _NSZone NSZone;
@class NSInvocation, NSArray, NSMethodSignature, NSCoder, NSString, NSEnumerator;
This is a fairly large patch, which resulted from a cascade of changes made to RegionStore (and related classes) in order to handle some analyzer failures involving casts and manipulation of symbolic memory. The root of the change is in StoreManager::CastRegion(). Instead of using ad hoc heuristics to decide when to layer an ElementRegion on a casted MemRegion, we now always layer an ElementRegion when the cast type is different than the original type of the region. This carries the current cast information associated with a region around without resorting to the error prone recording of "casted types" in GRState. Along with this new policy of layering ElementRegions, I added a new algorithm to strip away existing ElementRegions when they simply represented casts of a base memory object. This algorithm computes the raw "byte offset" that an ElementRegion represents from the base region, and allows the new ElementRegion to be based off that offset. The added benefit is that this naturally handles a series of casts of a MemRegion without building up a set of redundant ElementRegions (thus canonicalizing the region view). Other related changes that cascaded from this one (as tests were failing in RegionStore): - Revamped RegionStoreManager::InvalidateRegion() to completely remove all bindings and default values from a region and all subregions. Now invalidated fields are not bound directly to new symbolic values; instead the base region has a "default" symbol value from which "derived symbols" can be created. The main advantage of this approach is that it allows us to invalidate a region hierarchy and then lazily instantiate new values no matter how deep the hierarchy went (i.e., regardless of the number of field accesses, e.g. x->f->y->z->...). The previous approach did not do this. - Slightly reworked RegionStoreManager::RemoveDeadBindings() to also incorporate live symbols and live regions that do not have direct bindings but also have "default values" used for lazy instantiation. The changes to 'InvalidateRegion' revealed that these were necessary in order to achieve lazy instantiation of values in the region store with those bindings being removed too early. - The changes to InvalidateRegion() and RemoveDeadBindings() revealed a serious bug in 'getSubRegionMap()' where not all region -> subregion relationships involved in actually bindings (explicit and implicit) were being recorded. This has been fixed by using a worklist algorithm to iteratively fill in the region map. - Added special support to RegionStoreManager::Bind()/Retrieve() to handle OSAtomicCompareAndSwap in light of the new 'CastRegion' changes and the layering of ElementRegions. - Fixed a bug in SymbolReaper::isLive() where derived symbols were not being marked live if the symbol they were derived from was also live. This fix was critical for getting lazy instantiation in RegionStore to work. - Tidied up the implementation of ValueManager::getXXXSymbolVal() methods to use SymbolManager::canSymbolicate() to decide whether or not a symbol should be symbolicated. - 'test/Analysis/misc-ps-xfail.m' now passes; that test case has been moved to 'test/Analysis/misc-ps.m'. - Tweaked some pretty-printing of MemRegions, and implemented 'ElementRegion::getRawOffset()' for use with the CastRegion changes. llvm-svn: 77782
2009-08-01 14:17:29 +08:00
@protocol NSObject
- (BOOL)isEqual:(id)object;
- (id)autorelease;
@end
@protocol NSCopying
- (id)copyWithZone:(NSZone *)zone;
@end
@protocol NSMutableCopying - (id)mutableCopyWithZone:(NSZone *)zone; @end
This is a fairly large patch, which resulted from a cascade of changes made to RegionStore (and related classes) in order to handle some analyzer failures involving casts and manipulation of symbolic memory. The root of the change is in StoreManager::CastRegion(). Instead of using ad hoc heuristics to decide when to layer an ElementRegion on a casted MemRegion, we now always layer an ElementRegion when the cast type is different than the original type of the region. This carries the current cast information associated with a region around without resorting to the error prone recording of "casted types" in GRState. Along with this new policy of layering ElementRegions, I added a new algorithm to strip away existing ElementRegions when they simply represented casts of a base memory object. This algorithm computes the raw "byte offset" that an ElementRegion represents from the base region, and allows the new ElementRegion to be based off that offset. The added benefit is that this naturally handles a series of casts of a MemRegion without building up a set of redundant ElementRegions (thus canonicalizing the region view). Other related changes that cascaded from this one (as tests were failing in RegionStore): - Revamped RegionStoreManager::InvalidateRegion() to completely remove all bindings and default values from a region and all subregions. Now invalidated fields are not bound directly to new symbolic values; instead the base region has a "default" symbol value from which "derived symbols" can be created. The main advantage of this approach is that it allows us to invalidate a region hierarchy and then lazily instantiate new values no matter how deep the hierarchy went (i.e., regardless of the number of field accesses, e.g. x->f->y->z->...). The previous approach did not do this. - Slightly reworked RegionStoreManager::RemoveDeadBindings() to also incorporate live symbols and live regions that do not have direct bindings but also have "default values" used for lazy instantiation. The changes to 'InvalidateRegion' revealed that these were necessary in order to achieve lazy instantiation of values in the region store with those bindings being removed too early. - The changes to InvalidateRegion() and RemoveDeadBindings() revealed a serious bug in 'getSubRegionMap()' where not all region -> subregion relationships involved in actually bindings (explicit and implicit) were being recorded. This has been fixed by using a worklist algorithm to iteratively fill in the region map. - Added special support to RegionStoreManager::Bind()/Retrieve() to handle OSAtomicCompareAndSwap in light of the new 'CastRegion' changes and the layering of ElementRegions. - Fixed a bug in SymbolReaper::isLive() where derived symbols were not being marked live if the symbol they were derived from was also live. This fix was critical for getting lazy instantiation in RegionStore to work. - Tidied up the implementation of ValueManager::getXXXSymbolVal() methods to use SymbolManager::canSymbolicate() to decide whether or not a symbol should be symbolicated. - 'test/Analysis/misc-ps-xfail.m' now passes; that test case has been moved to 'test/Analysis/misc-ps.m'. - Tweaked some pretty-printing of MemRegions, and implemented 'ElementRegion::getRawOffset()' for use with the CastRegion changes. llvm-svn: 77782
2009-08-01 14:17:29 +08:00
@protocol NSCoding
- (void)encodeWithCoder:(NSCoder *)aCoder;
@end
@interface NSObject <NSObject> {}
- (id)init;
+ (id)allocWithZone:(NSZone *)zone;
@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;
This is a fairly large patch, which resulted from a cascade of changes made to RegionStore (and related classes) in order to handle some analyzer failures involving casts and manipulation of symbolic memory. The root of the change is in StoreManager::CastRegion(). Instead of using ad hoc heuristics to decide when to layer an ElementRegion on a casted MemRegion, we now always layer an ElementRegion when the cast type is different than the original type of the region. This carries the current cast information associated with a region around without resorting to the error prone recording of "casted types" in GRState. Along with this new policy of layering ElementRegions, I added a new algorithm to strip away existing ElementRegions when they simply represented casts of a base memory object. This algorithm computes the raw "byte offset" that an ElementRegion represents from the base region, and allows the new ElementRegion to be based off that offset. The added benefit is that this naturally handles a series of casts of a MemRegion without building up a set of redundant ElementRegions (thus canonicalizing the region view). Other related changes that cascaded from this one (as tests were failing in RegionStore): - Revamped RegionStoreManager::InvalidateRegion() to completely remove all bindings and default values from a region and all subregions. Now invalidated fields are not bound directly to new symbolic values; instead the base region has a "default" symbol value from which "derived symbols" can be created. The main advantage of this approach is that it allows us to invalidate a region hierarchy and then lazily instantiate new values no matter how deep the hierarchy went (i.e., regardless of the number of field accesses, e.g. x->f->y->z->...). The previous approach did not do this. - Slightly reworked RegionStoreManager::RemoveDeadBindings() to also incorporate live symbols and live regions that do not have direct bindings but also have "default values" used for lazy instantiation. The changes to 'InvalidateRegion' revealed that these were necessary in order to achieve lazy instantiation of values in the region store with those bindings being removed too early. - The changes to InvalidateRegion() and RemoveDeadBindings() revealed a serious bug in 'getSubRegionMap()' where not all region -> subregion relationships involved in actually bindings (explicit and implicit) were being recorded. This has been fixed by using a worklist algorithm to iteratively fill in the region map. - Added special support to RegionStoreManager::Bind()/Retrieve() to handle OSAtomicCompareAndSwap in light of the new 'CastRegion' changes and the layering of ElementRegions. - Fixed a bug in SymbolReaper::isLive() where derived symbols were not being marked live if the symbol they were derived from was also live. This fix was critical for getting lazy instantiation in RegionStore to work. - Tidied up the implementation of ValueManager::getXXXSymbolVal() methods to use SymbolManager::canSymbolicate() to decide whether or not a symbol should be symbolicated. - 'test/Analysis/misc-ps-xfail.m' now passes; that test case has been moved to 'test/Analysis/misc-ps.m'. - Tweaked some pretty-printing of MemRegions, and implemented 'ElementRegion::getRawOffset()' for use with the CastRegion changes. llvm-svn: 77782
2009-08-01 14:17:29 +08:00
@interface NSValue : NSObject <NSCopying, NSCoding>
- (void)getValue:(void *)value;
@end
@interface NSNumber : NSValue
- (char)charValue;
- (id)initWithBool:(BOOL)value;
@end
@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;
typedef float CGFloat;
typedef struct _NSPoint {
CGFloat x;
CGFloat y;
} NSPoint;
typedef struct _NSSize {
CGFloat width;
CGFloat height;
} NSSize;
typedef struct _NSRect {
NSPoint origin;
NSSize size;
} NSRect;
2008-10-01 13:05:46 +08:00
// Reduced test case from crash in <rdar://problem/6253157>
@interface A @end
@implementation A
- (void)foo:(void (^)(NSObject *x))block {
if (!((block != ((void *)0)))) {}
}
@end
// Reduced test case from crash in PR 2796;
// http://llvm.org/bugs/show_bug.cgi?id=2796
unsigned foo(unsigned x) { return __alignof__((x)) + sizeof(x); }
// Improvement to path-sensitivity involving compound assignments.
// Addresses false positive in <rdar://problem/6268365>
//
unsigned r6268365Aux(void);
void r6268365(void) {
unsigned x = 0;
x &= r6268365Aux();
unsigned j = 0;
if (x == 0) ++j;
if (x == 0) x = x / j;
}
void divzeroassume(unsigned x, unsigned j) {
x /= j;
if (j == 0) x /= 0; // no static-analyzer warning expected-warning {{division by zero is undefined}}
if (j == 0) x /= j; // no static-analyzer warning
if (j == 0) x = x / 0; // no static-analyzer warning expected-warning {{division by zero is undefined}}
}
void divzeroassumeB(unsigned x, unsigned j) {
x = x / j;
if (j == 0) x /= 0; // no static-analyzer warning expected-warning {{division by zero is undefined}}
if (j == 0) x /= j; // no static-analyzer warning
if (j == 0) x = x / 0; // no static-analyzer warning expected-warning {{division by zero is undefined}}
}
// InitListExpr processing
typedef float __m128 __attribute__((__vector_size__(16), __may_alias__));
__m128 return128(void) {
// This compound literal has a Vector type. We currently just
// return UnknownVal.
return __extension__(__m128) { 0.0f, 0.0f, 0.0f, 0.0f };
}
typedef long long __v2di __attribute__ ((__vector_size__ (16)));
typedef long long __m128i __attribute__ ((__vector_size__ (16), __may_alias__));
__m128i vec128i(long long __q1, long long __q0) {
// This compound literal returns true for both isVectorType() and
// isIntegerType().
return __extension__ (__m128i)(__v2di){ __q0, __q1 };
}
// sizeof(void)
// - Tests a regression reported in PR 3211: http://llvm.org/bugs/show_bug.cgi?id=3211
void handle_sizeof_void(unsigned flag) {
int* p = 0;
if (flag) {
if (sizeof(void) == 1)
return;
// Infeasible.
*p = 1; // no-warning
}
void* q;
if (!flag) {
if (sizeof(*q) == 1)
return;
// Infeasibe.
*p = 1; // no-warning
}
// Infeasible.
*p = 1; // no-warning
}
// check deference of undefined values
void check_deref_undef(void) {
int *p;
*p = 0xDEADBEEF; // expected-warning{{Dereference of undefined pointer value}}
}
// PR 3422
void pr3422_helper(char *p);
void pr3422(void) {
char buf[100];
char *q = &buf[10];
pr3422_helper(&q[1]);
}
// PR 3543 (handle empty statement expressions)
2009-07-22 02:59:16 +08:00
void pr_3543(void) {
({});
}
// <rdar://problem/6611677>
// This test case test the use of a vector type within an array subscript
// expression.
typedef long long __a64vector __attribute__((__vector_size__(8)));
typedef long long __a128vector __attribute__((__vector_size__(16)));
static inline __a64vector __attribute__((__always_inline__, __nodebug__))
my_test_mm_movepi64_pi64(__a128vector a) {
return (__a64vector)a[0];
}
// Test basic tracking of ivars associated with 'self'.
@interface SelfIvarTest : NSObject {
int flag;
}
- (void)test_self_tracking;
@end
@implementation SelfIvarTest
- (void)test_self_tracking {
char *p = 0;
char c;
if (flag)
p = "hello";
if (flag)
c = *p; // no-warning
}
@end
// PR 3770
char pr3770(int x) {
int y = x & 0x2;
char *p = 0;
if (y == 1)
p = "hello";
if (y == 1)
return p[0]; // no-warning
return 'a';
}
// PR 3772
// - We just want to test that this doesn't crash the analyzer.
typedef struct st ST;
struct st { char *name; };
extern ST *Cur_Pu;
void pr3772(void)
{
static ST *last_Cur_Pu;
if (last_Cur_Pu == Cur_Pu) {
return;
}
}
// PR 3780 - This tests that StmtIterator isn't broken for VLAs in DeclGroups.
void pr3780(int sz) { typedef double MAT[sz][sz]; }
// <rdar://problem/6695527> - Test that we don't symbolicate doubles before
// we are ready to do something with them.
int rdar6695527(double x) {
if (!x) { return 0; }
return 1;
}
// <rdar://problem/6708148> - Test that we properly invalidate structs
// passed-by-reference to a function.
void pr6708148_invalidate(NSRect *x);
void pr6708148_use(NSRect x);
void pr6708148_test(void) {
NSRect x;
pr6708148_invalidate(&x);
pr6708148_use(x); // no-warning
}
// Handle both kinds of noreturn attributes for pruning paths.
void rdar_6777003_noret(void) __attribute__((noreturn));
void rdar_6777003_analyzer_noret(void) __attribute__((analyzer_noreturn));
void rdar_6777003(int x) {
int *p = 0;
if (x == 1) {
rdar_6777003_noret();
*p = 1; // no-warning;
}
if (x == 2) {
rdar_6777003_analyzer_noret();
*p = 1; // no-warning;
}
*p = 1; // expected-warning{{Dereference of null pointer}}
}
// Check that the pointer-to-conts arguments do not get invalidated by Obj C
// interfaces. radar://10595327
int rdar_10595327(char *str) {
char fl = str[0];
int *p = 0;
NSString *s = [NSString stringWithUTF8String:str];
if (str[0] != fl)
return *p; // no-warning
return 0;
}
// For pointer arithmetic, --/++ should be treated as preserving non-nullness,
// regardless of how well the underlying StoreManager reasons about pointer
// arithmetic.
// <rdar://problem/6777209>
void rdar_6777209(char *p) {
if (p == 0)
return;
++p;
// This branch should always be infeasible.
if (p == 0)
*p = 'c'; // no-warning
}
// PR 4033. A symbolic 'void *' pointer can be used as the address for a
// computed goto.
typedef void *Opcode;
Opcode pr_4033_getOpcode(void);
void pr_4033(void) {
void *lbl = &&next_opcode;
next_opcode:
{
Opcode op = pr_4033_getOpcode();
if (op) goto *op;
}
}
// Test invalidating pointers-to-pointers with slightly different types. This
// example came from a recent false positive due to a regression where the
// branch condition was falsely reported as being uninitialized.
void invalidate_by_ref(char **x);
int test_invalidate_by_ref(void) {
unsigned short y;
invalidate_by_ref((char**) &y);
if (y) // no-warning
return 1;
return 0;
}
// Test for <rdar://problem/7027684>. This just tests that the CFG is
// constructed correctly. Previously, the successor block of the entrance
// was the block containing the merge for '?', which would trigger an
// assertion failure.
int rdar_7027684_aux(void);
int rdar_7027684_aux_2(void) __attribute__((noreturn));
void rdar_7027684(int x, int y) {
{}; // this empty compound statement is critical.
(rdar_7027684_aux() ? rdar_7027684_aux_2() : (void) 0);
}
// Test that we handle casts of string literals to arbitrary types.
unsigned const char *string_literal_test1(void) {
return (const unsigned char*) "hello";
}
const float *string_literal_test2(void) {
return (const float*) "hello";
}
// Test that we handle casts *from* incomplete struct types.
extern const struct _FooAssertStruct _cmd;
void test_cast_from_incomplete_struct_aux(volatile const void *x);
void test_cast_from_incomplete_struct(void) {
test_cast_from_incomplete_struct_aux(&_cmd);
}
// Test for <rdar://problem/7034511>
// "ValueManager::makeIntVal(uint64_t X, QualType T) should return a 'Loc'
// when 'T' is a pointer"
//
// Previously this case would crash.
void test_rdar_7034511(NSArray *y) {
NSObject *x;
for (x in y) {}
if (x == ((void*) 0)) {}
}
// Handle casts of function pointers (CodeTextRegions) to arbitrary pointer
// types. This was previously causing a crash in CastRegion.
void handle_funcptr_voidptr_casts(void) {
void **ptr;
typedef void *PVOID;
typedef void *PCHAR;
typedef long INT_PTR, *PINT_PTR;
typedef INT_PTR (*FARPROC)(void);
FARPROC handle_funcptr_voidptr_casts_aux(void);
PVOID handle_funcptr_voidptr_casts_aux_2(PVOID volatile *x);
PVOID handle_funcptr_voidptr_casts_aux_3(PCHAR volatile *x);
ptr = (void**) handle_funcptr_voidptr_casts_aux();
handle_funcptr_voidptr_casts_aux_2(ptr);
handle_funcptr_voidptr_casts_aux_3(ptr);
}
// RegionStore::Retrieve previously crashed on this example. This example
// was previously in the test file 'xfail_regionstore_wine_crash.c'.
void testA(void) {
long x = 0;
char *y = (char *) &x;
if (!*y)
return;
}
// RegionStoreManager previously crashed on this example. The problem is that
// the value bound to the field of b->grue after the call to testB_aux is
// a symbolic region. The second '*__gruep__' involves performing a load
// from a 'int*' that really is a 'void**'. The loaded location must be
// implicitly converted to an integer that wraps a location. Previosly we would
// get a crash here due to an assertion failure.
typedef struct _BStruct { void *grue; } BStruct;
void testB_aux(void *ptr);
void testB(BStruct *b) {
{
int *__gruep__ = ((int *)&((b)->grue));
int __gruev__ = *__gruep__;
testB_aux(__gruep__);
}
{
int *__gruep__ = ((int *)&((b)->grue));
int __gruev__ = *__gruep__;
if (~0 != __gruev__) {}
}
}
void test_trivial_symbolic_comparison(int *x) {
int test_trivial_symbolic_comparison_aux(void);
int a = test_trivial_symbolic_comparison_aux();
int b = a;
if (a != b) {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
a = a == 1;
b = b == 1;
if (a != b) {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
}
// Test for:
// <rdar://problem/7062158> false positive null dereference due to
// BasicStoreManager not tracking *static* globals
//
// This just tests the proper tracking of symbolic values for globals (both
// static and non-static).
//
static int* x_rdar_7062158;
void rdar_7062158(void) {
int *current = x_rdar_7062158;
if (current == x_rdar_7062158)
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
int* x_rdar_7062158_2;
void rdar_7062158_2(void) {
int *current = x_rdar_7062158_2;
if (current == x_rdar_7062158_2)
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
// This test reproduces a case for a crash when analyzing ClamAV using
// RegionStoreManager (the crash doesn't exhibit in BasicStoreManager because
// it isn't doing anything smart about arrays). The problem is that on the
// second line, 'p = &p[i]', p is assigned an ElementRegion whose index
// is a 16-bit integer. On the third line, a new ElementRegion is created
// based on the previous region, but there the region uses a 32-bit integer,
// resulting in a clash of values (an assertion failure at best). We resolve
// this problem by implicitly converting index values to 'int' when the
// ElementRegion is created.
unsigned char test_array_index_bitwidth(const unsigned char *p) {
unsigned short i = 0;
for (i = 0; i < 2; i++) p = &p[i];
return p[i+1];
}
// This case tests that CastRegion handles casts involving BlockPointerTypes.
// It should not crash.
void test_block_cast(void) {
id test_block_cast_aux(void);
(void (^)(void *))test_block_cast_aux(); // expected-warning{{expression result unused}}
}
int OSAtomicCompareAndSwap32Barrier();
2009-07-21 05:00:55 +08:00
// Test comparison of 'id' instance variable to a null void* constant after
// performing an OSAtomicCompareAndSwap32Barrier.
// This previously was a crash in RegionStoreManager.
@interface TestIdNull {
id x;
}
-(int)foo;
@end
@implementation TestIdNull
-(int)foo {
OSAtomicCompareAndSwap32Barrier(0, (signed)2, (signed*)&x);
if (x == (void*) 0) { return 0; }
return 1;
}
@end
// Do not crash when performing compare and swap on symbolic values.
typedef int int32_t;
typedef int int32;
typedef int32 Atomic32;
int OSAtomicCompareAndSwap32( int32_t __oldValue, int32_t __newValue, volatile int32_t *__theValue);
void radar11390991_NoBarrier_CompareAndSwap(volatile Atomic32 *ptr,
Atomic32 old_value,
Atomic32 new_value) {
OSAtomicCompareAndSwap32(old_value, new_value, ptr);
}
// PR 4594 - This was a crash when handling casts in SimpleSValuator.
void PR4594(void) {
char *buf[1];
char **foo = buf;
*foo = "test";
}
// Test invalidation logic where an integer is casted to an array with a
// different sign and then invalidated.
void test_invalidate_cast_int(void) {
void test_invalidate_cast_int_aux(unsigned *i);
signed i;
test_invalidate_cast_int_aux((unsigned*) &i);
if (i < 0)
return;
}
int ivar_getOffset();
This is a fairly large patch, which resulted from a cascade of changes made to RegionStore (and related classes) in order to handle some analyzer failures involving casts and manipulation of symbolic memory. The root of the change is in StoreManager::CastRegion(). Instead of using ad hoc heuristics to decide when to layer an ElementRegion on a casted MemRegion, we now always layer an ElementRegion when the cast type is different than the original type of the region. This carries the current cast information associated with a region around without resorting to the error prone recording of "casted types" in GRState. Along with this new policy of layering ElementRegions, I added a new algorithm to strip away existing ElementRegions when they simply represented casts of a base memory object. This algorithm computes the raw "byte offset" that an ElementRegion represents from the base region, and allows the new ElementRegion to be based off that offset. The added benefit is that this naturally handles a series of casts of a MemRegion without building up a set of redundant ElementRegions (thus canonicalizing the region view). Other related changes that cascaded from this one (as tests were failing in RegionStore): - Revamped RegionStoreManager::InvalidateRegion() to completely remove all bindings and default values from a region and all subregions. Now invalidated fields are not bound directly to new symbolic values; instead the base region has a "default" symbol value from which "derived symbols" can be created. The main advantage of this approach is that it allows us to invalidate a region hierarchy and then lazily instantiate new values no matter how deep the hierarchy went (i.e., regardless of the number of field accesses, e.g. x->f->y->z->...). The previous approach did not do this. - Slightly reworked RegionStoreManager::RemoveDeadBindings() to also incorporate live symbols and live regions that do not have direct bindings but also have "default values" used for lazy instantiation. The changes to 'InvalidateRegion' revealed that these were necessary in order to achieve lazy instantiation of values in the region store with those bindings being removed too early. - The changes to InvalidateRegion() and RemoveDeadBindings() revealed a serious bug in 'getSubRegionMap()' where not all region -> subregion relationships involved in actually bindings (explicit and implicit) were being recorded. This has been fixed by using a worklist algorithm to iteratively fill in the region map. - Added special support to RegionStoreManager::Bind()/Retrieve() to handle OSAtomicCompareAndSwap in light of the new 'CastRegion' changes and the layering of ElementRegions. - Fixed a bug in SymbolReaper::isLive() where derived symbols were not being marked live if the symbol they were derived from was also live. This fix was critical for getting lazy instantiation in RegionStore to work. - Tidied up the implementation of ValueManager::getXXXSymbolVal() methods to use SymbolManager::canSymbolicate() to decide whether or not a symbol should be symbolicated. - 'test/Analysis/misc-ps-xfail.m' now passes; that test case has been moved to 'test/Analysis/misc-ps.m'. - Tweaked some pretty-printing of MemRegions, and implemented 'ElementRegion::getRawOffset()' for use with the CastRegion changes. llvm-svn: 77782
2009-08-01 14:17:29 +08:00
// Reduced from a crash involving the cast of an Objective-C symbolic region to
// 'char *'
static NSNumber *test_ivar_offset(id self, SEL _cmd, Ivar inIvar) {
return [[[NSNumber allocWithZone:((void*)0)] initWithBool:*(_Bool *)((char *)self + ivar_getOffset(inIvar))] autorelease];
}
// Reduced from a crash in StoreManager::CastRegion involving a divide-by-zero.
// This resulted from not properly handling region casts to 'const void*'.
void test_cast_const_voidptr(void) {
char x[10];
char *p = &x[1];
const void* q = p;
}
// Reduced from a crash when analyzing Wine. This test handles loads from
// function addresses.
typedef long (*FARPROC)(void);
FARPROC test_load_func(FARPROC origfun) {
if (!*(unsigned char*) origfun)
return origfun;
return 0;
}
// Test passing-by-value an initialized struct variable.
struct test_pass_val {
int x;
int y;
};
void test_pass_val_aux(struct test_pass_val s);
void test_pass_val(void) {
struct test_pass_val s;
s.x = 1;
2009-08-04 08:58:45 +08:00
s.y = 2;
test_pass_val_aux(s);
}
// This is a reduced test case of a false positive that previously appeared
// in RegionStoreManager. Previously the array access resulted in dereferencing
// an undefined value.
int test_array_compound(int *q, int *r, int *z) {
int *array[] = { q, r, z };
int j = 0;
for (unsigned i = 0; i < 3 ; ++i)
if (*array[i]) ++j; // no-warning
return j;
}
// symbolic value stored in 'x' wouldn't be implicitly casted to a signed value
// during the comparison.
int rdar_7124210(unsigned int x) {
enum { SOME_CONSTANT = 123 };
int compare = ((signed) SOME_CONSTANT) == *((signed *) &x);
return compare ? 0 : 1; // Forces the evaluation of the symbolic constraint.
}
void pr4781(unsigned long *raw1) {
unsigned long *cook, *raw0;
unsigned long dough[32];
int i;
cook = dough;
for( i = 0; i < 16; i++, raw1++ ) {
raw0 = raw1++;
*cook = (*raw0 & 0x00fc0000L) << 6;
*cook |= (*raw0 & 0x00000fc0L) << 10;
}
}
// <rdar://problem/7185647> - 'self' should be treated as being non-null
// upon entry to an objective-c method.
@interface RDar7185647
- (id)foo;
@end
@implementation RDar7185647
- (id) foo {
if (self)
return self;
*((volatile int *) 0x0) = 0xDEADBEEF; // no-warning
return self;
}
@end
// Test reasoning of __builtin_offsetof;
struct test_offsetof_A {
int x;
int y;
};
struct test_offsetof_B {
int w;
int z;
};
void test_offsetof_1(void) {
if (__builtin_offsetof(struct test_offsetof_A, x) ==
__builtin_offsetof(struct test_offsetof_B, w))
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
void test_offsetof_2(void) {
if (__builtin_offsetof(struct test_offsetof_A, y) ==
__builtin_offsetof(struct test_offsetof_B, z))
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
void test_offsetof_3(void) {
if (__builtin_offsetof(struct test_offsetof_A, y) -
__builtin_offsetof(struct test_offsetof_A, x)
==
__builtin_offsetof(struct test_offsetof_B, z) -
__builtin_offsetof(struct test_offsetof_B, w))
return;
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
void test_offsetof_4(void) {
if (__builtin_offsetof(struct test_offsetof_A, y) ==
__builtin_offsetof(struct test_offsetof_B, w))
return;
int *p = 0;
*p = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
// <rdar://problem/6829164> "nil receiver" false positive: make tracking
// of the MemRegion for 'self' path-sensitive
@interface RDar6829164 : NSObject {
double x; int y;
}
- (id) init;
@end
id rdar_6829164_1(void);
double rdar_6829164_2(void);
@implementation RDar6829164
- (id) init {
if((self = [super init]) != 0) {
id z = rdar_6829164_1();
y = (z != 0);
if (y)
x = rdar_6829164_2();
}
return self;
}
@end
// <rdar://problem/7242015> - Invalidate values passed-by-reference
// to functions when the pointer to the value is passed as an integer.
void test_7242015_aux(unsigned long);
int rdar_7242015(void) {
int x;
test_7242015_aux((unsigned long) &x); // no-warning
return x; // Previously we return and uninitialized value when
// using RegionStore.
}
// <rdar://problem/7242006> [RegionStore] compound literal assignment with
// floats not honored
CGFloat rdar7242006(CGFloat x) {
NSSize y = (NSSize){x, 10};
return y.width; // no-warning
}
// PR 4988 - This test exhibits a case where a function can be referenced
// when not explicitly used in an "lvalue" context (as far as the analyzer is
// concerned). This previously triggered a crash due to an invalid assertion.
void pr_4988(void) {
pr_4988; // expected-warning{{expression result unused}}
}
// <rdar://problem/7152418> - A 'signed char' is used as a flag, which is
// implicitly converted to an int.
void *rdar7152418_bar(void);
@interface RDar7152418 {
signed char x;
}
-(char)foo;
@end;
@implementation RDar7152418
-(char)foo {
char *p = 0;
void *result = 0;
if (x) {
result = rdar7152418_bar();
p = "hello";
}
if (!result) {
result = rdar7152418_bar();
if (result && x)
return *p; // no-warning
}
return 1;
}
//===----------------------------------------------------------------------===//
// Test constant-folding of symbolic values, automatically handling type
// conversions of the symbol as necessary.
//===----------------------------------------------------------------------===//
// Previously this would crash once we started eagerly evaluating symbols whose
// values were constrained to a single value.
void test_symbol_fold_1(signed char x) {
while (1) {
if (x == ((signed char) 0)) {}
}
}
// This previously caused a crash because it triggered an assertion in APSInt.
void test_symbol_fold_2(unsigned int * p, unsigned int n,
const unsigned int * grumpkin, unsigned int dn) {
unsigned int i;
unsigned int tempsub[8];
unsigned int *solgrumpkin = tempsub + n;
for (i = 0; i < n; i++)
solgrumpkin[i] = (i < dn) ? ~grumpkin[i] : 0xFFFFFFFF;
for (i <<= 5; i < (n << 5); i++) {}
}
// This previously caused a crash because it triggered an assertion in APSInt.
// 'x' would evaluate to a 8-bit constant (because of the return value of
// test_symbol_fold_3_aux()) which would not get properly promoted to an
// integer.
char test_symbol_fold_3_aux(void);
unsigned test_symbol_fold_3(void) {
unsigned x = test_symbol_fold_3_aux();
if (x == 54)
return (x << 8) | 0x5;
return 0;
}
//===----------------------------------------------------------------------===//
// Tests for the warning of casting a non-struct type to a struct type
//===----------------------------------------------------------------------===//
typedef struct {unsigned int v;} NSSwappedFloat;
NSSwappedFloat test_cast_nonstruct_to_struct(float x) {
struct hodor {
float number;
NSSwappedFloat sf;
};
return ((struct hodor *)&x)->sf; // expected-warning{{Casting a non-structure type to a structure type and accessing a field can lead to memory access errors or data corruption}}
}
NSSwappedFloat test_cast_nonstruct_to_union(float x) {
union bran {
float number;
NSSwappedFloat sf;
};
return ((union bran *)&x)->sf; // no-warning
}
void test_undefined_array_subscript(void) {
int i, a[10];
int *p = &a[i]; // expected-warning{{Array subscript is undefined}}
}
@end
//===----------------------------------------------------------------------===//
// Test using an uninitialized value as a branch condition.
//===----------------------------------------------------------------------===//
int test_uninit_branch(void) {
int x;
if (x) // expected-warning{{Branch condition evaluates to a garbage value}}
return 1;
return 0;
}
int test_uninit_branch_b(void) {
int x;
return x ? 1 : 0; // expected-warning{{Branch condition evaluates to a garbage value}}
}
int test_uninit_branch_c(void) {
int x;
if ((short)x) // expected-warning{{Branch condition evaluates to a garbage value}}
return 1;
return 0;
}
//===----------------------------------------------------------------------===//
// Test passing an undefined value in a message or function call.
//===----------------------------------------------------------------------===//
void test_bad_call_aux(int x);
void test_bad_call(void) {
int y;
test_bad_call_aux(y); // expected-warning{{1st function call argument is an uninitialized value}}
}
@interface TestBadArg {}
- (void) testBadArg:(int) x;
@end
void test_bad_msg(TestBadArg *p) {
int y;
[p testBadArg:y]; // expected-warning{{1st argument in message expression is an uninitialized value}}
}
//===----------------------------------------------------------------------===//
// PR 6033 - Test emitting the correct output in a warning where we use '%'
// with operands that are undefined.
//===----------------------------------------------------------------------===//
int pr6033(int x) {
int y;
return x % y; // expected-warning{{The right operand of '%' is a garbage value}}
}
2010-01-19 20:11:55 +08:00
struct trie {
struct trie* next;
};
struct kwset {
struct trie *trie;
unsigned char y[10];
2010-01-19 20:11:55 +08:00
struct trie* next[10];
int d;
};
typedef struct trie trie_t;
typedef struct kwset kwset_t;
void f(kwset_t *kws, char const *p, char const *q) {
struct trie const *trie;
struct trie * const *next = kws->next;
register unsigned char c;
register char const *end = p;
register char const *lim = q;
register int d = 1;
register unsigned char const *y = kws->y;
2010-01-19 20:11:55 +08:00
d = y[c = (end+=d)[-1]]; // no-warning
2010-01-19 20:11:55 +08:00
trie = next[c];
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7593875> When handling sizeof(VLA) it leads to a hole in
// the ExplodedGraph (causing a false positive)
//===----------------------------------------------------------------------===//
int rdar_7593875_aux(int x);
int rdar_7593875(int n) {
int z[n > 10 ? 10 : n]; // VLA.
int v;
v = rdar_7593875_aux(sizeof(z));
// Previously we got a false positive about 'v' being uninitialized.
return v; // no-warning
}
//===----------------------------------------------------------------------===//
// Handle casts from symbolic regions (packaged as integers) to doubles.
// Previously this caused an assertion failure.
//===----------------------------------------------------------------------===//
void *foo_rev95119(void);
void baz_rev95119(double x);
void bar_rev95119(void) {
// foo_rev95119() returns a symbolic pointer. It is then
// cast to an int which is then cast to a double.
int value = (int) foo_rev95119();
baz_rev95119((double)value);
}
//===----------------------------------------------------------------------===//
// Handle loading a symbolic pointer from a symbolic region that was
// invalidated by a call to an unknown function.
//===----------------------------------------------------------------------===//
void bar_rev95192(int **x);
void foo_rev95192(int **x) {
*x = 0;
bar_rev95192(x);
// Not a null dereference.
**x = 1; // no-warning
}
//===----------------------------------------------------------------------===//
// Handle casts of a function to a function pointer with a different return
// value. We don't yet emit an error for such cases, but we now we at least
// don't crash when the return value gets interpreted in a way that
// violates our invariants.
//===----------------------------------------------------------------------===//
void *foo_rev95267(void);
int bar_rev95267(void) {
char (*Callback_rev95267)(void) = (char (*)(void)) foo_rev95267;
if ((*Callback_rev95267)() == (char) 0)
return 1;
return 0;
}
// Same as previous case, but handle casts to 'void'.
int bar_rev95274(void) {
void (*Callback_rev95274)(void) = (void (*)(void)) foo_rev95267;
(*Callback_rev95274)();
return 0;
}
void rdar7582031_test_static_init_zero(void) {
static unsigned x;
if (x == 0)
return;
int *p = 0;
*p = 0xDEADBEEF;
}
void rdar7582031_test_static_init_zero_b(void) {
static void* x;
if (x == 0)
return;
int *p = 0;
*p = 0xDEADBEEF;
}
//===----------------------------------------------------------------------===//
// Test handling of parameters that are structs that contain floats and //
// nested fields. //
//===----------------------------------------------------------------------===//
struct s_rev95547_nested { float x, y; };
struct s_rev95547 {
struct s_rev95547_nested z1;
struct s_rev95547_nested z2;
};
float foo_rev95547(struct s_rev95547 w) {
return w.z1.x + 20.0; // no-warning
}
void foo_rev95547_b(struct s_rev95547 w) {
struct s_rev95547 w2 = w;
w2.z1.x += 20.0; // no-warning
}
//===----------------------------------------------------------------------===//
// Test handling statement expressions that don't populate a CFG block that
// is used to represent the computation of the RHS of a logical operator.
// This previously triggered a crash.
//===----------------------------------------------------------------------===//
void pr6938(void) {
if (1 && ({
while (0);
0;
}) == 0) {
}
}
void pr6938_b(void) {
if (1 && *({ // expected-warning{{Dereference of null pointer}}
while (0) {}
({
(int *) 0;
});
}) == 0) {
}
}
//===----------------------------------------------------------------------===//
// <rdar://problem/7979430> - The CFG for code containing an empty
// @synchronized block was previously broken (and would crash the analyzer).
//===----------------------------------------------------------------------===//
void r7979430(id x) {
@synchronized(x) {}
}
//===----------------------------------------------------------------------===
// PR 7361 - Test that functions wrapped in macro instantiations are analyzed.
//===----------------------------------------------------------------------===
#define MAKE_TEST_FN() \
void test_pr7361 (char a) {\
char* b = 0x0; *b = a;\
}
MAKE_TEST_FN() // expected-warning{{null pointer}}
//===----------------------------------------------------------------------===
// PR 7491 - Test that symbolic expressions can be used as conditions.
//===----------------------------------------------------------------------===
void pr7491 (void) {
extern int getint(void);
int a = getint()-1;
if (a) {
return;
}
if (!a) {
return;
} else {
// Should be unreachable
(void)*(char*)0; // no-warning
}
}
//===----------------------------------------------------------------------===
// PR 7475 - Test that assumptions about global variables are reset after
// calling a global function.
//===----------------------------------------------------------------------===
int *pr7475_someGlobal;
void pr7475_setUpGlobal(void);
void pr7475(void) {
if (pr7475_someGlobal == 0)
pr7475_setUpGlobal();
*pr7475_someGlobal = 0; // no-warning
}
void pr7475_warn(void) {
static int *someStatic = 0;
if (someStatic == 0)
pr7475_setUpGlobal();
*someStatic = 0; // expected-warning{{null pointer}}
}
// <rdar://problem/8202272> - __imag passed non-complex should not crash
float f0(_Complex float x) {
float l0 = __real x;
return __real l0 + __imag l0;
}
//===----------------------------------------------------------------------===
// Test that we can reduce symbols to constants whether they are on the left
// or right side of an expression.
//===----------------------------------------------------------------------===
void reduce_to_constant(int x, int y) {
if (x != 20)
return;
int a = x + y;
int b = y + x;
if (y == -20 && a != 0)
(void)*(char*)0; // no-warning
if (y == -20 && b != 0)
(void)*(char*)0; // no-warning
}
// <rdar://problem/8360854> - Test that code after a switch statement with no
// 'case:' labels is correctly evaluated.
void r8360854(int n) {
switch (n) {
default: ;
}
int *p = 0;
*p = 0xDEADBEEF; // expected-warning{{null pointer}}
}
// PR 8050 - crash in CastSizeChecker when pointee is an incomplete type
typedef long unsigned int __darwin_size_t;
typedef __darwin_size_t size_t;
void *malloc(size_t);
struct PR8050;
void pr8050(struct PR8050 **arg)
{
*arg = malloc(1);
}
// <rdar://problem/5880430> Switch on enum should not consider default case live
// if all enum values are covered
enum Cases { C1, C2, C3, C4 };
void test_enum_cases(enum Cases C) {
switch (C) {
case C1:
case C2:
case C4:
case C3:
return;
}
int *p = 0;
*p = 0xDEADBEEF; // no-warning
}
void test_enum_cases_positive(enum Cases C) {
switch (C) { // expected-warning{{enumeration value 'C4' not handled in switch}}
case C1:
case C2:
case C3:
return;
}
int *p = 0;
*p = 0xDEADBEEF; // expected-warning{{Dereference of null pointer}}
}
// <rdar://problem/6351970> rule request: warn if synchronization mutex can be nil
void rdar6351970(void) {
id x = 0;
@synchronized(x) {} // expected-warning{{Nil value used as mutex for @synchronized() (no synchronization will occur)}}
}
void rdar6351970_b(id x) {
if (!x)
@synchronized(x) {} // expected-warning{{Nil value used as mutex for @synchronized() (no synchronization will occur)}}
}
void rdar6351970_c(void) {
id x;
@synchronized(x) {} // expected-warning{{Uninitialized value used as mutex for @synchronized}}
}
@interface Rdar8578650
- (id) foo8578650;
@end
void rdar8578650(id x) {
@synchronized (x) {
[x foo8578650];
}
// At this point we should assume that 'x' is not nil, not
// the inverse.
@synchronized (x) { // no-warning
}
}
// <rdar://problem/6352035> rule request: direct structure member access null pointer dereference
@interface RDar6352035 {
int c;
}
- (void)foo;
- (void)bar;
@end
@implementation RDar6352035
- (void)foo {
RDar6352035 *friend = 0;
friend->c = 7; // expected-warning{{Access to instance variable 'c' results in a dereference of a null pointer (loaded from variable 'friend')}}
}
- (void)bar {
self = 0;
c = 7; // expected-warning{{Access to instance variable 'c' results in a dereference of a null pointer (loaded from variable 'self')}}
}
@end
// PR 8149 - GNU statement expression in condition of ForStmt.
// This previously triggered an assertion failure in CFGBuilder.
void pr8149(void) {
for (; ({ do { } while (0); 0; });) { }
}
// PR 8458 - Make sure @synchronized doesn't crash with properties.
@interface PR8458 {}
@property(readonly) id lock;
@end
static
void __PR8458(PR8458 *x) {
@synchronized(x.lock) {} // no-warning
}
// PR 8440 - False null dereference during store to array-in-field-in-global.
// This test case previously resulted in a bogus null deref warning from
// incorrect lazy symbolication logic in RegionStore.
static struct {
int num;
char **data;
} saved_pr8440;
char *foo_pr8440(void);
char **bar_pr8440(void);
void baz_pr8440(int n)
{
saved_pr8440.num = n;
if (saved_pr8440.data)
return;
saved_pr8440.data = bar_pr8440();
for (int i = 0 ; i < n ; i ++)
saved_pr8440.data[i] = foo_pr8440(); // no-warning
}
// Support direct accesses to non-null memory. Reported in:
// PR 5272
// <rdar://problem/6839683>
int test_direct_address_load(void) {
int *p = (int*) 0x4000;
return *p; // no-warning
}
void pr5272_test(void) {
struct pr5272 { int var2; };
(*(struct pr5272*)0xBC000000).var2 = 0; // no-warning
(*(struct pr5272*)0xBC000000).var2 += 2; // no-warning
}
// Support casting the return value of function to another different type
// This previously caused a crash, although we likely need more precise
// reasoning here. <rdar://problem/8663544>
void* rdar8663544(void);
typedef struct {} Val8663544;
Val8663544 bazR8663544(void) {
Val8663544(*func) (void) = (Val8663544(*) (void)) rdar8663544;
return func();
}
// PR 8619 - Handle ternary expressions with a call to a noreturn function.
// This previously resulted in a crash.
void pr8619_noreturn(int x) __attribute__((noreturn));
void pr8619(int a, int b, int c) {
a ?: pr8619_noreturn(b || c);
}
// PR 8646 - crash in the analyzer when handling unions.
union pr8648_union {
signed long long pr8648_union_field;
};
void pr8648(void) {
long long y;
union pr8648_union x = { .pr8648_union_field = 0LL };
y = x.pr8648_union_field;
union pr8648_union z;
z = (union pr8648_union) { .pr8648_union_field = 0LL };
union pr8648_union w;
w = ({ (union pr8648_union) { .pr8648_union_field = 0LL }; });
// crash, no assignment
(void) ({ (union pr8648_union) { .pr8648_union_field = 0LL }; }).pr8648_union_field;
// crash with assignment
y = ({ (union pr8648_union) { .pr8648_union_field = 0LL }; }).pr8648_union_field;
}
// PR 9269 - don't assert when building the following CFG. The for statement
// contains a condition with multiple basic blocks, and the value of the
// statement expression is then indexed as part of a bigger condition expression.
// This example exposed a bug in child traversal in the CFGBuilder.
void pr9269(void) {
struct s { char *bar[10]; } baz[2] = { 0 };
unsigned i = 0;
for (i = 0;
(* ({ while(0); ({ &baz[0]; }); })).bar[0] != 0; // expected-warning {{while loop has empty body}} expected-note {{put the semicolon on a separate line to silence this warning}}
++i) {}
}
// Test evaluation of GNU-style ?:.
int pr9287(int type) { return type ? : 0; } // no-warning
void pr9287_b(int type, int *p) {
int x = type ? : 0;
if (x) {
p = 0;
}
if (type) {
*p = 0xDEADBEEF; // expected-warning {{null pointer}}
}
}
void pr9287_c(int type, int *p) {
int x = type ? : 0;
if (x) {
p = 0;
}
if (!type) {
*p = 0xDEADBEEF; // no-warning
}
}
void test_switch(void) {
switch (4) {
case 1: {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
break;
}
case 4: {
int *p = 0;
*p = 0xDEADBEEF; // expected-warning {{null}}
break;
}
default: {
int *p = 0;
*p = 0xDEADBEEF; // no-warning
break;
}
}
}
// PR 9467. Tests various CFG optimizations. This previously crashed.
static void test(unsigned int bit_mask)
{
unsigned int bit_index;
for (bit_index = 0;
bit_index < 24;
bit_index++) {
switch ((0x01 << bit_index) & bit_mask) {
case 0x100000: ;
}
}
}
// Don't crash on code containing __label__.
int radar9414427_aux(void);
void radar9414427(void) {
__label__ mylabel;
if (radar9414427_aux()) {
mylabel: do {}
while (0);
}
}
// Analyze methods in @implementation (category)
@interface RDar9465344
@end
@implementation RDar9465344 (MyCategory)
- (void) testcategoryImpl {
int *p = 0x0;
*p = 0xDEADBEEF; // expected-warning {{null}}
}
@end
@implementation RDar9465344
@end
// Don't crash when analyzing access to 'self' within a block.
@interface Rdar10380300Base
- (void) foo;
@end
@interface Rdar10380300 : Rdar10380300Base @end
@implementation Rdar10380300
- (void)foo {
^{
[super foo];
}();
}
@end
// Don't crash when a ?: is only preceded by a statement (not an expression)
// in the CFG.
void __assert_fail(void);
enum rdar1196620_e { E_A, E_B, E_C, E_D };
struct rdar1196620_s { int ints[E_D+1]; };
static void rdar1196620_call_assert(struct rdar1196620_s* s) {
int i = 0;
s?(void)0:__assert_fail();
}
static void rdar1196620(struct rdar1196620_s* s) {
rdar1196620_call_assert(s);
}