clang/test/Analysis/mig.mm - llvm-project - Git at Google

 // RUN: %clang_analyze_cc1 -w -analyzer-checker=core,osx.MIG -std=c++14 \
 // RUN:                       -analyzer-output=text -fblocks -verify %s

 typedef unsigned uint32_t;

 // XNU APIs.

 typedef int kern_return_t;
 #define KERN_SUCCESS 0
 #define KERN_ERROR 1
 #define MIG_NO_REPLY (-305)

 typedef unsigned mach_port_name_t;
 typedef unsigned vm_address_t;
 typedef unsigned vm_size_t;
 typedef void *ipc_space_t;
 typedef unsigned long io_user_reference_t;
 typedef struct ipc_port *ipc_port_t;
 typedef unsigned mach_port_t;
 typedef uint32_t UInt32;

 struct os_refcnt {};
 typedef struct os_refcnt os_refcnt_t;

 struct thread {
   os_refcnt_t ref_count;
 };
 typedef struct thread *thread_t;

 kern_return_t vm_deallocate(mach_port_name_t, vm_address_t, vm_size_t);
 kern_return_t mach_vm_deallocate(mach_port_name_t, vm_address_t, vm_size_t);
 void mig_deallocate(vm_address_t, vm_size_t);
 kern_return_t mach_port_deallocate(ipc_space_t, mach_port_name_t);
 void ipc_port_release(ipc_port_t);
 void thread_deallocate(thread_t);

 static void os_ref_retain(struct os_refcnt *rc);

 #define thread_reference_internal(thread) os_ref_retain(&(thread)->ref_count);

 #define MIG_SERVER_ROUTINE __attribute__((mig_server_routine))

 // IOKit wrappers.

 class OSObject;
 typedef kern_return_t IOReturn;
 #define kIOReturnError 1

 enum {
   kOSAsyncRef64Count = 8,
 };

 typedef io_user_reference_t OSAsyncReference64[kOSAsyncRef64Count];

 struct IOExternalMethodArguments {
   io_user_reference_t *asyncReference;
 };

 struct IOExternalMethodDispatch {};

 class IOUserClient {
 public:
   static IOReturn releaseAsyncReference64(OSAsyncReference64);
   static IOReturn releaseNotificationPort(mach_port_t port);

   MIG_SERVER_ROUTINE
   virtual IOReturn externalMethod(
       uint32_t selector, IOExternalMethodArguments *arguments,
       IOExternalMethodDispatch *dispatch = 0, OSObject *target = 0,
       void *reference = 0);

   MIG_SERVER_ROUTINE
   virtual IOReturn registerNotificationPort(mach_port_t, UInt32, UInt32);
 };

 // Tests.

 MIG_SERVER_ROUTINE
 kern_return_t basic_test(mach_port_name_t port, vm_address_t address, vm_size_t size) {
   vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
   if (size > 10) { // expected-note{{Assuming 'size' is > 10}}
                    // expected-note@-1{{Taking true branch}}
     return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
 											 // expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
   }
   return KERN_SUCCESS;
 }

 MIG_SERVER_ROUTINE
 kern_return_t test_unknown_return_value(mach_port_name_t port, vm_address_t address, vm_size_t size) {
   extern kern_return_t foo();

   vm_deallocate(port, address, size);
   // We don't know if it's a success or a failure.
   return foo(); // no-warning
 }

 // Make sure we don't crash when they forgot to write the return statement.
 MIG_SERVER_ROUTINE
 kern_return_t no_crash(mach_port_name_t port, vm_address_t address, vm_size_t size) {
   vm_deallocate(port, address, size);
 }

 // When releasing two parameters, add a note for both of them.
 // Also when returning a variable, explain why do we think that it contains
 // a non-success code.
 MIG_SERVER_ROUTINE
 kern_return_t release_twice(mach_port_name_t port, vm_address_t addr1, vm_address_t addr2, vm_size_t size) {
   kern_return_t ret = KERN_ERROR; // expected-note{{'ret' initialized to 1}}
   vm_deallocate(port, addr1, size); // expected-note{{Value passed through parameter 'addr1' is deallocated}}
   vm_deallocate(port, addr2, size); // expected-note{{Value passed through parameter 'addr2' is deallocated}}
   return ret; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
                      // expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
 }

 MIG_SERVER_ROUTINE
 kern_return_t no_unrelated_notes(mach_port_name_t port, vm_address_t address, vm_size_t size) {
   vm_deallocate(port, address, size); // no-note
   1 / 0; // expected-warning{{Division by zero}}
          // expected-note@-1{{Division by zero}}
   return KERN_SUCCESS;
 }

 // Make sure we find the bug when the object is destroyed within an
 // automatic destructor.
 MIG_SERVER_ROUTINE
 kern_return_t test_vm_deallocate_in_automatic_dtor(mach_port_name_t port, vm_address_t address, vm_size_t size) {
   struct WillDeallocate {
     mach_port_name_t port;
     vm_address_t address;
     vm_size_t size;
     ~WillDeallocate() {
       vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
     }
   } will_deallocate{port, address, size};

  if (size > 10) {
     // expected-note@-1{{Assuming 'size' is > 10}}
     // expected-note@-2{{Taking true branch}}
     return KERN_ERROR;
     // expected-note@-1{{Calling '~WillDeallocate'}}
     // expected-note@-2{{Returning from '~WillDeallocate'}}
     // expected-warning@-3{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
     // expected-note@-4   {{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
   }
   return KERN_SUCCESS;
 }

 // Check that we work on Objective-C messages and blocks.
 @interface I
 - (kern_return_t)fooAtPort:(mach_port_name_t)port withAddress:(vm_address_t)address ofSize:(vm_size_t)size;
 @end

 @implementation I
 - (kern_return_t)fooAtPort:(mach_port_name_t)port
                withAddress:(vm_address_t)address
                     ofSize:(vm_size_t)size MIG_SERVER_ROUTINE {
   vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
   return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
                      // expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
 }
 @end

 void test_block() {
   kern_return_t (^block)(mach_port_name_t, vm_address_t, vm_size_t) =
       ^MIG_SERVER_ROUTINE (mach_port_name_t port,
                            vm_address_t address, vm_size_t size) {
         vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
         return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
                            // expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
       };
 }

 void test_block_with_weird_return_type() {
   struct Empty {};

   // The block is written within a function so that it was actually analyzed as
   // a top-level function during analysis. If we were to write it as a global
   // variable of block type instead, it would not have been analyzed, because
   // ASTConsumer won't find the block's code body within the VarDecl.
   // At the same time, we shouldn't call it from the function, because otherwise
   // it will be analyzed as an inlined function rather than as a top-level
   // function.
   Empty (^block)(mach_port_name_t, vm_address_t, vm_size_t) =
       ^MIG_SERVER_ROUTINE(mach_port_name_t port,
                           vm_address_t address, vm_size_t size) {
         vm_deallocate(port, address, size);
         return Empty{}; // no-crash
       };
 }

 // Test various APIs.
 MIG_SERVER_ROUTINE
 kern_return_t test_mach_vm_deallocate(mach_port_name_t port, vm_address_t address, vm_size_t size) {
   mach_vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
   return KERN_ERROR;                 // expected-warning{{MIG callback fails with error after deallocating argument value}}
                                      // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
 }

 MIG_SERVER_ROUTINE
 kern_return_t test_mach_port_deallocate(ipc_space_t space,
                                         mach_port_name_t port) {
   mach_port_deallocate(space, port); // expected-note{{Value passed through parameter 'port' is deallocated}}
   return KERN_ERROR;                 // expected-warning{{MIG callback fails with error after deallocating argument value}}
                                      // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
 }

 MIG_SERVER_ROUTINE
 kern_return_t test_mig_deallocate(vm_address_t address, vm_size_t size) {
   mig_deallocate(address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
   return KERN_ERROR;             // expected-warning{{MIG callback fails with error after deallocating argument value}}
                                  // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
 }

 MIG_SERVER_ROUTINE
 kern_return_t test_ipc_port_release(ipc_port_t port) {
   ipc_port_release(port); // expected-note{{Value passed through parameter 'port' is deallocated}}
   return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value}}
 							       // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
 }

 // Let's try the C++11 attribute spelling syntax as well.
 [[clang::mig_server_routine]]
 IOReturn test_releaseAsyncReference64(IOExternalMethodArguments *arguments) {
   IOUserClient::releaseAsyncReference64(arguments->asyncReference); // expected-note{{Value passed through parameter 'arguments' is deallocated}}
   return kIOReturnError;                                            // expected-warning{{MIG callback fails with error after deallocating argument value}}
                                                                     // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
 }

 MIG_SERVER_ROUTINE
 kern_return_t test_no_reply(ipc_space_t space, mach_port_name_t port) {
   mach_port_deallocate(space, port);
   return MIG_NO_REPLY; // no-warning
 }

 class MyClient: public IOUserClient {
   // The MIG_SERVER_ROUTINE annotation is intentionally skipped.
   // It should be picked up from the superclass.
   IOReturn externalMethod(uint32_t selector, IOExternalMethodArguments *arguments,
                           IOExternalMethodDispatch *dispatch = 0, OSObject *target = 0, void *reference = 0) override {

     releaseAsyncReference64(arguments->asyncReference); // expected-note{{Value passed through parameter 'arguments' is deallocated}}
     return kIOReturnError;                              // expected-warning{{MIG callback fails with error after deallocating argument value}}
                                                         // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
   }

   IOReturn registerNotificationPort(mach_port_t port, UInt32 x, UInt32 y) {
     releaseNotificationPort(port); // expected-note{{Value passed through parameter 'port' is deallocated}}
     return kIOReturnError; // expected-warning{{MIG callback fails with error after deallocating argument value}}
                            // expected-note@-1{{MIG callback fails with error after deallocating argument value}}
   }
 };

 MIG_SERVER_ROUTINE
 kern_return_t test_os_ref_retain(thread_t thread) {
   thread_reference_internal(thread);
   thread_deallocate(thread);
   return KERN_ERROR; // no-warning
 }
	// RUN: %clang_analyze_cc1 -w -analyzer-checker=core,osx.MIG -std=c++14 \
	// RUN: -analyzer-output=text -fblocks -verify %s

	typedef unsigned uint32_t;

	// XNU APIs.

	typedef int kern_return_t;
	#define KERN_SUCCESS 0
	#define KERN_ERROR 1
	#define MIG_NO_REPLY (-305)

	typedef unsigned mach_port_name_t;
	typedef unsigned vm_address_t;
	typedef unsigned vm_size_t;
	typedef void *ipc_space_t;
	typedef unsigned long io_user_reference_t;
	typedef struct ipc_port *ipc_port_t;
	typedef unsigned mach_port_t;
	typedef uint32_t UInt32;

	struct os_refcnt {};
	typedef struct os_refcnt os_refcnt_t;

	struct thread {
	os_refcnt_t ref_count;
	};
	typedef struct thread *thread_t;

	kern_return_t vm_deallocate(mach_port_name_t, vm_address_t, vm_size_t);
	kern_return_t mach_vm_deallocate(mach_port_name_t, vm_address_t, vm_size_t);
	void mig_deallocate(vm_address_t, vm_size_t);
	kern_return_t mach_port_deallocate(ipc_space_t, mach_port_name_t);
	void ipc_port_release(ipc_port_t);
	void thread_deallocate(thread_t);

	static void os_ref_retain(struct os_refcnt *rc);

	#define thread_reference_internal(thread) os_ref_retain(&(thread)->ref_count);

	#define MIG_SERVER_ROUTINE __attribute__((mig_server_routine))

	// IOKit wrappers.

	class OSObject;
	typedef kern_return_t IOReturn;
	#define kIOReturnError 1

	enum {
	kOSAsyncRef64Count = 8,
	};

	typedef io_user_reference_t OSAsyncReference64[kOSAsyncRef64Count];

	struct IOExternalMethodArguments {
	io_user_reference_t *asyncReference;
	};

	struct IOExternalMethodDispatch {};

	class IOUserClient {
	public:
	static IOReturn releaseAsyncReference64(OSAsyncReference64);
	static IOReturn releaseNotificationPort(mach_port_t port);

	MIG_SERVER_ROUTINE
	virtual IOReturn externalMethod(
	uint32_t selector, IOExternalMethodArguments *arguments,
	IOExternalMethodDispatch dispatch = 0, OSObject target = 0,
	void *reference = 0);

	MIG_SERVER_ROUTINE
	virtual IOReturn registerNotificationPort(mach_port_t, UInt32, UInt32);
	};

	// Tests.

	MIG_SERVER_ROUTINE
	kern_return_t basic_test(mach_port_name_t port, vm_address_t address, vm_size_t size) {
	vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
	if (size > 10) { // expected-note{{Assuming 'size' is > 10}}
	// expected-note@-1{{Taking true branch}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	}
	return KERN_SUCCESS;
	}

	MIG_SERVER_ROUTINE
	kern_return_t test_unknown_return_value(mach_port_name_t port, vm_address_t address, vm_size_t size) {
	extern kern_return_t foo();

	vm_deallocate(port, address, size);
	// We don't know if it's a success or a failure.
	return foo(); // no-warning
	}

	// Make sure we don't crash when they forgot to write the return statement.
	MIG_SERVER_ROUTINE
	kern_return_t no_crash(mach_port_name_t port, vm_address_t address, vm_size_t size) {
	vm_deallocate(port, address, size);
	}

	// When releasing two parameters, add a note for both of them.
	// Also when returning a variable, explain why do we think that it contains
	// a non-success code.
	MIG_SERVER_ROUTINE
	kern_return_t release_twice(mach_port_name_t port, vm_address_t addr1, vm_address_t addr2, vm_size_t size) {
	kern_return_t ret = KERN_ERROR; // expected-note{{'ret' initialized to 1}}
	vm_deallocate(port, addr1, size); // expected-note{{Value passed through parameter 'addr1' is deallocated}}
	vm_deallocate(port, addr2, size); // expected-note{{Value passed through parameter 'addr2' is deallocated}}
	return ret; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	}

	MIG_SERVER_ROUTINE
	kern_return_t no_unrelated_notes(mach_port_name_t port, vm_address_t address, vm_size_t size) {
	vm_deallocate(port, address, size); // no-note
	1 / 0; // expected-warning{{Division by zero}}
	// expected-note@-1{{Division by zero}}
	return KERN_SUCCESS;
	}

	// Make sure we find the bug when the object is destroyed within an
	// automatic destructor.
	MIG_SERVER_ROUTINE
	kern_return_t test_vm_deallocate_in_automatic_dtor(mach_port_name_t port, vm_address_t address, vm_size_t size) {
	struct WillDeallocate {
	mach_port_name_t port;
	vm_address_t address;
	vm_size_t size;
	~WillDeallocate() {
	vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
	}
	} will_deallocate{port, address, size};

	if (size > 10) {
	// expected-note@-1{{Assuming 'size' is > 10}}
	// expected-note@-2{{Taking true branch}}
	return KERN_ERROR;
	// expected-note@-1{{Calling '~WillDeallocate'}}
	// expected-note@-2{{Returning from '~WillDeallocate'}}
	// expected-warning@-3{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	// expected-note@-4 {{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	}
	return KERN_SUCCESS;
	}

	// Check that we work on Objective-C messages and blocks.
	@interface I
	- (kern_return_t)fooAtPort:(mach_port_name_t)port withAddress:(vm_address_t)address ofSize:(vm_size_t)size;
	@end

	@implementation I
	- (kern_return_t)fooAtPort:(mach_port_name_t)port
	withAddress:(vm_address_t)address
	ofSize:(vm_size_t)size MIG_SERVER_ROUTINE {
	vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	}
	@end

	void test_block() {
	kern_return_t (^block)(mach_port_name_t, vm_address_t, vm_size_t) =
	^MIG_SERVER_ROUTINE (mach_port_name_t port,
	vm_address_t address, vm_size_t size) {
	vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value. This is a use-after-free vulnerability because the caller will try to deallocate it again}}
	};
	}

	void test_block_with_weird_return_type() {
	struct Empty {};

	// The block is written within a function so that it was actually analyzed as
	// a top-level function during analysis. If we were to write it as a global
	// variable of block type instead, it would not have been analyzed, because
	// ASTConsumer won't find the block's code body within the VarDecl.
	// At the same time, we shouldn't call it from the function, because otherwise
	// it will be analyzed as an inlined function rather than as a top-level
	// function.
	Empty (^block)(mach_port_name_t, vm_address_t, vm_size_t) =
	^MIG_SERVER_ROUTINE(mach_port_name_t port,
	vm_address_t address, vm_size_t size) {
	vm_deallocate(port, address, size);
	return Empty{}; // no-crash
	};
	}

	// Test various APIs.
	MIG_SERVER_ROUTINE
	kern_return_t test_mach_vm_deallocate(mach_port_name_t port, vm_address_t address, vm_size_t size) {
	mach_vm_deallocate(port, address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}

	MIG_SERVER_ROUTINE
	kern_return_t test_mach_port_deallocate(ipc_space_t space,
	mach_port_name_t port) {
	mach_port_deallocate(space, port); // expected-note{{Value passed through parameter 'port' is deallocated}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}

	MIG_SERVER_ROUTINE
	kern_return_t test_mig_deallocate(vm_address_t address, vm_size_t size) {
	mig_deallocate(address, size); // expected-note{{Value passed through parameter 'address' is deallocated}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}

	MIG_SERVER_ROUTINE
	kern_return_t test_ipc_port_release(ipc_port_t port) {
	ipc_port_release(port); // expected-note{{Value passed through parameter 'port' is deallocated}}
	return KERN_ERROR; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}

	// Let's try the C++11 attribute spelling syntax as well.
	[[clang::mig_server_routine]]
	IOReturn test_releaseAsyncReference64(IOExternalMethodArguments *arguments) {
	IOUserClient::releaseAsyncReference64(arguments->asyncReference); // expected-note{{Value passed through parameter 'arguments' is deallocated}}
	return kIOReturnError; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}

	MIG_SERVER_ROUTINE
	kern_return_t test_no_reply(ipc_space_t space, mach_port_name_t port) {
	mach_port_deallocate(space, port);
	return MIG_NO_REPLY; // no-warning
	}

	class MyClient: public IOUserClient {
	// The MIG_SERVER_ROUTINE annotation is intentionally skipped.
	// It should be picked up from the superclass.
	IOReturn externalMethod(uint32_t selector, IOExternalMethodArguments *arguments,
	IOExternalMethodDispatch dispatch = 0, OSObject target = 0, void *reference = 0) override {

	releaseAsyncReference64(arguments->asyncReference); // expected-note{{Value passed through parameter 'arguments' is deallocated}}
	return kIOReturnError; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}

	IOReturn registerNotificationPort(mach_port_t port, UInt32 x, UInt32 y) {
	releaseNotificationPort(port); // expected-note{{Value passed through parameter 'port' is deallocated}}
	return kIOReturnError; // expected-warning{{MIG callback fails with error after deallocating argument value}}
	// expected-note@-1{{MIG callback fails with error after deallocating argument value}}
	}
	};

	MIG_SERVER_ROUTINE
	kern_return_t test_os_ref_retain(thread_t thread) {
	thread_reference_internal(thread);
	thread_deallocate(thread);
	return KERN_ERROR; // no-warning
	}