test/Analysis/plist-macros-with-expansion.cpp - clang - Git at Google

 // RUN: %clang_analyze_cc1 -analyzer-checker=core -verify %s
 //
 // RUN: %clang_analyze_cc1 -analyzer-checker=core %s  \
 // RUN:   -analyzer-output=plist -o %t.plist \
 // RUN:   -analyzer-config expand-macros=true
 //
 // Check the actual plist output.
 //   RUN: %normalize_plist <%t.plist | diff -ub \
 //   RUN:   %S/Inputs/expected-plists/plist-macros-with-expansion.cpp.plist -
 //
 // Check the macro expansions from the plist output here, to make the test more
 // understandable.
 //   RUN: FileCheck --input-file=%t.plist %s

 void print(const void*);

 //===----------------------------------------------------------------------===//
 // Tests for non-function-like macro expansions.
 //===----------------------------------------------------------------------===//

 #define SET_PTR_VAR_TO_NULL \
   ptr = 0

 void nonFunctionLikeMacroTest() {
   int *ptr;
   SET_PTR_VAR_TO_NULL;
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>SET_PTR_VAR_TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr = 0</string>

 #define NULL 0
 #define SET_PTR_VAR_TO_NULL_WITH_NESTED_MACRO \
   ptr = NULL

 void nonFunctionLikeNestedMacroTest() {
   int *ptr;
   SET_PTR_VAR_TO_NULL_WITH_NESTED_MACRO;
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>SET_PTR_VAR_TO_NULL_WITH_NESTED_MACRO</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr =0</string>

 //===----------------------------------------------------------------------===//
 // Tests for function-like macro expansions.
 //===----------------------------------------------------------------------===//

 void setToNull(int **vptr) {
   *vptr = nullptr;
 }

 #define TO_NULL(x) \
   setToNull(x)

 void functionLikeMacroTest() {
   int *ptr;
   TO_NULL(&ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>setToNull(&amp;ptr)</string>

 #define DOES_NOTHING(x) \
   {                     \
     int b;              \
     b = 5;              \
   }                     \
   print(x)

 #define DEREF(x)   \
   DOES_NOTHING(x); \
   *x

 void functionLikeNestedMacroTest() {
   int *a;
   TO_NULL(&a);
   DEREF(a) = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>setToNull(&amp;a)</string>

 // CHECK: <key>name</key><string>DEREF</string>
 // CHECK-NEXT: <key>expansion</key><string>{ int b; b = 5; } print(a); *a</string>

 //===----------------------------------------------------------------------===//
 // Tests for undefining and/or redifining macros.
 //===----------------------------------------------------------------------===//

 #define WILL_UNDEF_SET_NULL_TO_PTR(ptr) \
   ptr = nullptr;

 void undefinedMacroByTheEndOfParsingTest() {
   int *ptr;
   WILL_UNDEF_SET_NULL_TO_PTR(ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 #undef WILL_UNDEF_SET_NULL_TO_PTR

 // CHECK: <key>name</key><string>WILL_UNDEF_SET_NULL_TO_PTR</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr = nullptr;</string>

 #define WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr) \
   /* Nothing */
 #undef WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL
 #define WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr) \
   ptr = nullptr;

 void macroRedefinedMultipleTimesTest() {
   int *ptr;
   WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr)
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 #undef WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL
 #define WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr)                      \
   print("This string shouldn't be in the plist file at all. Or anywhere, " \
         "but here.");

 // CHECK: <key>name</key><string>WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr = nullptr;</string>

 #define WILL_UNDEF_SET_NULL_TO_PTR_2(ptr) \
   ptr = nullptr;

 #define PASS_PTR_TO_MACRO_THAT_WILL_BE_UNDEFD(ptr) \
   WILL_UNDEF_SET_NULL_TO_PTR_2(ptr)

 void undefinedMacroInsideAnotherMacroTest() {
   int *ptr;
   PASS_PTR_TO_MACRO_THAT_WILL_BE_UNDEFD(ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // TODO: Expand arguments.
 // CHECK: <key>name</key><string>PASS_PTR_TO_MACRO_THAT_WILL_BE_UNDEFD</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr = nullptr;</string>

 #undef WILL_UNDEF_SET_NULL_TO_PTR_2

 //===----------------------------------------------------------------------===//
 // Tests for macro arguments containing commas and parantheses.
 //
 // As of writing these tests, the algorithm expands macro arguments by lexing
 // the macro's expansion location, and relies on finding tok::comma and
 // tok::l_paren/tok::r_paren.
 //===----------------------------------------------------------------------===//

 // Note that this commas, parantheses in strings aren't parsed as tok::comma or
 // tok::l_paren/tok::r_paren, but why not test them.

 #define TO_NULL_AND_PRINT(x, str) \
   x = 0; \
   print(str)

 void macroArgContainsCommaInStringTest() {
   int *a;
   TO_NULL_AND_PRINT(a, "Will this , cause a crash?");
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
 // CHECK-NEXT: <key>expansion</key><string>a = 0; print( &quot;Will this , cause a crash?&quot;)</string>

 void macroArgContainsLParenInStringTest() {
   int *a;
   TO_NULL_AND_PRINT(a, "Will this ( cause a crash?");
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
 // CHECK-NEXT: <key>expansion</key><string>a = 0; print( &quot;Will this ( cause a crash?&quot;)</string>

 void macroArgContainsRParenInStringTest() {
   int *a;
   TO_NULL_AND_PRINT(a, "Will this ) cause a crash?");
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
 // CHECK-NEXT: <key>expansion</key><string>a = 0; print( &quot;Will this ) cause a crash?&quot;)</string>

 #define CALL_FUNCTION(funcCall)   \
   funcCall

 // Function calls do contain both tok::comma and tok::l_paren/tok::r_paren.

 void macroArgContainsLParenRParenTest() {
   int *a;
   CALL_FUNCTION(setToNull(&a));
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>CALL_FUNCTION</string>
 // CHECK-NEXT: <key>expansion</key><string>setToNull(&amp;a)</string>

 void setToNullAndPrint(int **vptr, const char *str) {
   setToNull(vptr);
   print(str);
 }

 void macroArgContainsCommaLParenRParenTest() {
   int *a;
   CALL_FUNCTION(setToNullAndPrint(&a, "Hello!"));
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>CALL_FUNCTION</string>
 // CHECK-NEXT: <key>expansion</key><string>setToNullAndPrint(&amp;a, &quot;Hello!&quot;)</string>

 #define CALL_FUNCTION_WITH_TWO_PARAMS(funcCall, param1, param2) \
   funcCall(param1, param2)

 void macroArgContainsCommaLParenRParenTest2() {
   int *a;
   CALL_FUNCTION_WITH_TWO_PARAMS(setToNullAndPrint, &a, "Hello!");
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>CALL_FUNCTION_WITH_TWO_PARAMS</string>
 // CHECK-NEXT: <key>expansion</key><string>setToNullAndPrint( &amp;a, &quot;Hello!&quot;)</string>

 #define CALL_LAMBDA(l) \
   l()

 void commaInBracketsTest() {
   int *ptr;
   const char str[] = "Hello!";
   // You need to add parantheses around a lambda expression to compile this,
   // else the comma in the capture will be parsed as divider of macro args.
   CALL_LAMBDA(([&ptr, str] () mutable { TO_NULL(&ptr); }));
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>CALL_LAMBDA</string>
 // CHECK-NEXT: <key>expansion</key><string>([&amp;ptr, str] () mutable { setToNull(&amp;ptr); })()</string>

 #define PASTE_CODE(code) \
   code

 void commaInBracesTest() {
   PASTE_CODE({ // expected-warning{{Dereference of null pointer}}
     // NOTE: If we were to add a new variable here after a comma, we'd get a
     // compilation error, so this test is mainly here to show that this was also
     // investigated.

     // int *ptr = nullptr, a;
     int *ptr = nullptr;
     *ptr = 5;
   })
 }

 // CHECK: <key>name</key><string>PASTE_CODE</string>
 // CHECK-NEXT: <key>expansion</key><string>{ int *ptr = nullptr; *ptr = 5; }</string>

 // Example taken from
 // https://gcc.gnu.org/onlinedocs/cpp/Macro-Arguments.html#Macro-Arguments.

 #define POTENTIALLY_EMPTY_PARAM(x, y) \
   x;                                  \
   y = nullptr

 void emptyParamTest() {
   int *ptr;

   POTENTIALLY_EMPTY_PARAM(,ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>POTENTIALLY_EMPTY_PARAM</string>
 // CHECK-NEXT: <key>expansion</key><string>;ptr = nullptr</string>

 #define NESTED_EMPTY_PARAM(a, b) \
   POTENTIALLY_EMPTY_PARAM(a, b);


 void nestedEmptyParamTest() {
   int *ptr;

   NESTED_EMPTY_PARAM(, ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>NESTED_EMPTY_PARAM</string>
 // CHECK-NEXT: <key>expansion</key><string>; ptr = nullptr;</string>

 #define CALL_FUNCTION_WITH_ONE_PARAM_THROUGH_MACRO(func, param) \
   CALL_FUNCTION(func(param))

 void lParenRParenInNestedMacro() {
   int *ptr;
   CALL_FUNCTION_WITH_ONE_PARAM_THROUGH_MACRO(setToNull, &ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>CALL_FUNCTION_WITH_ONE_PARAM_THROUGH_MACRO</string>
 // CHECK-NEXT: <key>expansion</key><string>setToNull( &amp;ptr)</string>

 //===----------------------------------------------------------------------===//
 // Tests for variadic macro arguments.
 //===----------------------------------------------------------------------===//

 template <typename ...Args>
 void variadicFunc(Args ...args);

 #define VARIADIC_SET_TO_NULL(ptr, ...) \
   ptr = nullptr;                       \
   variadicFunc(__VA_ARGS__)

 void variadicMacroArgumentTest() {
   int *ptr;
   VARIADIC_SET_TO_NULL(ptr, 1, 5, "haha!");
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>VARIADIC_SET_TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr = nullptr; variadicFunc( 1, 5, &quot;haha!&quot;)</string>

 void variadicMacroArgumentWithoutAnyArgumentTest() {
   int *ptr;
   // Not adding a single parameter to ... is silly (and also causes a
   // preprocessor warning), but is not an excuse to crash on it.
   VARIADIC_SET_TO_NULL(ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>VARIADIC_SET_TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>ptr = nullptr; variadicFunc()</string>

 //===----------------------------------------------------------------------===//
 // Tests for # and ##.
 //===----------------------------------------------------------------------===//

 #define DECLARE_FUNC_AND_SET_TO_NULL(funcName, ptr) \
   void generated_##funcName();                      \
   ptr = nullptr;

 void hashHashOperatorTest() {
   int *ptr;
   DECLARE_FUNC_AND_SET_TO_NULL(whatever, ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>DECLARE_FUNC_AND_SET_TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>void generated_whatever(); ptr = nullptr;</string>

 void macroArgContainsHashHashInStringTest() {
   int *a;
   TO_NULL_AND_PRINT(a, "Will this ## cause a crash?");
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
 // CHECK-NEXT: <key>expansion</key><string>a = 0; print( &quot;Will this ## cause a crash?&quot;)</string>

 #define PRINT_STR(str, ptr) \
   print(#str);              \
   ptr = nullptr

 void hashOperatorTest() {
   int *ptr;
   PRINT_STR(Hello, ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>PRINT_STR</string>
 // CHECK-NEXT: <key>expansion</key><string>print(&quot;Hello&quot;); ptr = nullptr</string>

 void macroArgContainsHashInStringTest() {
   int *a;
   TO_NULL_AND_PRINT(a, "Will this # cause a crash?");
   *a = 5; // expected-warning{{Dereference of null pointer}}
 }

 // CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
 // CHECK-NEXT: <key>expansion</key><string>a = 0; print( &quot;Will this # cause a crash?&quot;)</string>

 //===----------------------------------------------------------------------===//
 // Tests for more complex macro expansions.
 //
 // We won't cover anything that wasn't covered up to this point, but rather
 // show more complex, macros with deeper nesting, more arguments (some unused)
 // and so on.
 //===----------------------------------------------------------------------===//

 #define IF(Condition) \
   if ( Condition )

 #define L_BRACE {
 #define R_BRACE }
 #define LESS <
 #define GREATER >
 #define EQUALS =
 #define SEMICOLON ;
 #define NEGATIVE -
 #define RETURN return
 #define ZERO 0

 #define EUCLIDEAN_ALGORITHM(A, B)                                              \
   IF(A LESS ZERO) L_BRACE                                                      \
     A EQUALS NEGATIVE A SEMICOLON                                              \
   R_BRACE                                                                      \
   IF(B LESS ZERO) L_BRACE                                                      \
     B EQUALS NEGATIVE B SEMICOLON                                              \
   R_BRACE                                                                      \
                                                                                \
   /* This is where a while loop would be, but that seems to be too complex */  \
   /* for the analyzer just yet. Let's just pretend that this algorithm     */  \
   /* works.                                                                */  \
                                                                                \
   RETURN B / (B - B) SEMICOLON

 int getLowestCommonDenominator(int A, int B) {
   EUCLIDEAN_ALGORITHM(A, B) // expected-warning{{Division by zero}}
 }

 void testVeryComplexAlgorithm() {
   int tmp = 8 / (getLowestCommonDenominator(5, 7) - 1);
   print(&tmp);
 }
 // CHECK: <key>name</key><string>EUCLIDEAN_ALGORITHM</string>
 // CHECK-NEXT: <key>expansion</key><string>if (A&lt;0 ){A=-A;} if ( B&lt;0 ){ B=- B;}return B / ( B - B);</string>

 #define YET_ANOTHER_SET_TO_NULL(x, y, z)   \
   print((void *) x);                       \
   print((void *) y);                       \
   z = nullptr;

 #define DO_NOTHING(str) str
 #define DO_NOTHING2(str2) DO_NOTHING(str2)

 void test() {
   int *ptr;
   YET_ANOTHER_SET_TO_NULL(5, DO_NOTHING2("Remember the Vasa"), ptr);
   *ptr = 5; // expected-warning{{Dereference of null pointer}}
 }
 // CHECK: <key>name</key><string>YET_ANOTHER_SET_TO_NULL</string>
 // CHECK-NEXT: <key>expansion</key><string>print((void *)5); print((void *)&quot;Remember the Vasa&quot;); ptr = nullptr;</string>

 int garbage_value;

 #define REC_MACRO_FUNC(REC_MACRO_PARAM) garbage_##REC_MACRO_PARAM
 #define value REC_MACRO_FUNC(value)

 void recursiveMacroUser() {
   if (value == 0)
     1 / value; // expected-warning{{Division by zero}}
                // expected-warning@-1{{expression result unused}}
 }

 #define FOO(x) int foo() { return x; }
 #define APPLY_ZERO1(function) function(0)

 APPLY_ZERO1(FOO)
 void useZeroApplier1() { (void)(1 / foo()); } // expected-warning{{Division by zero}}

 // CHECK: <key>name</key><string>APPLY_ZERO1</string>
 // CHECK-NEXT: <key>expansion</key><string>int foo() { return x; }(0)</string>

 #define BAR(x) int bar() { return x; }
 #define APPLY_ZERO2 BAR(0)

 APPLY_ZERO2
 void useZeroApplier2() { (void)(1 / bar()); } // expected-warning{{Division by zero}}

 // CHECK: <key>name</key><string>APPLY_ZERO2</string>
 // CHECK-NEXT: <key>expansion</key><string>int bar() { return 0; }</string>
	// RUN: %clang_analyze_cc1 -analyzer-checker=core -verify %s
	//
	// RUN: %clang_analyze_cc1 -analyzer-checker=core %s \
	// RUN: -analyzer-output=plist -o %t.plist \
	// RUN: -analyzer-config expand-macros=true
	//
	// Check the actual plist output.
	// RUN: %normalize_plist <%t.plist \| diff -ub \
	// RUN: %S/Inputs/expected-plists/plist-macros-with-expansion.cpp.plist -
	//
	// Check the macro expansions from the plist output here, to make the test more
	// understandable.
	// RUN: FileCheck --input-file=%t.plist %s

	void print(const void*);

	//===----------------------------------------------------------------------===//
	// Tests for non-function-like macro expansions.
	//===----------------------------------------------------------------------===//

	#define SET_PTR_VAR_TO_NULL \
	ptr = 0

	void nonFunctionLikeMacroTest() {
	int *ptr;
	SET_PTR_VAR_TO_NULL;
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>SET_PTR_VAR_TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr = 0</string>

	#define NULL 0
	#define SET_PTR_VAR_TO_NULL_WITH_NESTED_MACRO \
	ptr = NULL

	void nonFunctionLikeNestedMacroTest() {
	int *ptr;
	SET_PTR_VAR_TO_NULL_WITH_NESTED_MACRO;
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>SET_PTR_VAR_TO_NULL_WITH_NESTED_MACRO</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr =0</string>

	//===----------------------------------------------------------------------===//
	// Tests for function-like macro expansions.
	//===----------------------------------------------------------------------===//

	void setToNull(int **vptr) {
	*vptr = nullptr;
	}

	#define TO_NULL(x) \
	setToNull(x)

	void functionLikeMacroTest() {
	int *ptr;
	TO_NULL(&ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>setToNull(&ptr)</string>

	#define DOES_NOTHING(x) \
	{ \
	int b; \
	b = 5; \
	} \
	print(x)

	#define DEREF(x) \
	DOES_NOTHING(x); \
	*x

	void functionLikeNestedMacroTest() {
	int *a;
	TO_NULL(&a);
	DEREF(a) = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>setToNull(&a)</string>

	// CHECK: <key>name</key><string>DEREF</string>
	// CHECK-NEXT: <key>expansion</key><string>{ int b; b = 5; } print(a); *a</string>

	//===----------------------------------------------------------------------===//
	// Tests for undefining and/or redifining macros.
	//===----------------------------------------------------------------------===//

	#define WILL_UNDEF_SET_NULL_TO_PTR(ptr) \
	ptr = nullptr;

	void undefinedMacroByTheEndOfParsingTest() {
	int *ptr;
	WILL_UNDEF_SET_NULL_TO_PTR(ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	#undef WILL_UNDEF_SET_NULL_TO_PTR

	// CHECK: <key>name</key><string>WILL_UNDEF_SET_NULL_TO_PTR</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr = nullptr;</string>

	#define WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr) \
	/* Nothing */
	#undef WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL
	#define WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr) \
	ptr = nullptr;

	void macroRedefinedMultipleTimesTest() {
	int *ptr;
	WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr)
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	#undef WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL
	#define WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL(ptr) \
	print("This string shouldn't be in the plist file at all. Or anywhere, " \
	"but here.");

	// CHECK: <key>name</key><string>WILL_REDIFINE_MULTIPLE_TIMES_SET_TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr = nullptr;</string>

	#define WILL_UNDEF_SET_NULL_TO_PTR_2(ptr) \
	ptr = nullptr;

	#define PASS_PTR_TO_MACRO_THAT_WILL_BE_UNDEFD(ptr) \
	WILL_UNDEF_SET_NULL_TO_PTR_2(ptr)

	void undefinedMacroInsideAnotherMacroTest() {
	int *ptr;
	PASS_PTR_TO_MACRO_THAT_WILL_BE_UNDEFD(ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// TODO: Expand arguments.
	// CHECK: <key>name</key><string>PASS_PTR_TO_MACRO_THAT_WILL_BE_UNDEFD</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr = nullptr;</string>

	#undef WILL_UNDEF_SET_NULL_TO_PTR_2

	//===----------------------------------------------------------------------===//
	// Tests for macro arguments containing commas and parantheses.
	//
	// As of writing these tests, the algorithm expands macro arguments by lexing
	// the macro's expansion location, and relies on finding tok::comma and
	// tok::l_paren/tok::r_paren.
	//===----------------------------------------------------------------------===//

	// Note that this commas, parantheses in strings aren't parsed as tok::comma or
	// tok::l_paren/tok::r_paren, but why not test them.

	#define TO_NULL_AND_PRINT(x, str) \
	x = 0; \
	print(str)

	void macroArgContainsCommaInStringTest() {
	int *a;
	TO_NULL_AND_PRINT(a, "Will this , cause a crash?");
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
	// CHECK-NEXT: <key>expansion</key><string>a = 0; print( "Will this , cause a crash?")</string>

	void macroArgContainsLParenInStringTest() {
	int *a;
	TO_NULL_AND_PRINT(a, "Will this ( cause a crash?");
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
	// CHECK-NEXT: <key>expansion</key><string>a = 0; print( "Will this ( cause a crash?")</string>

	void macroArgContainsRParenInStringTest() {
	int *a;
	TO_NULL_AND_PRINT(a, "Will this ) cause a crash?");
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
	// CHECK-NEXT: <key>expansion</key><string>a = 0; print( "Will this ) cause a crash?")</string>

	#define CALL_FUNCTION(funcCall) \
	funcCall

	// Function calls do contain both tok::comma and tok::l_paren/tok::r_paren.

	void macroArgContainsLParenRParenTest() {
	int *a;
	CALL_FUNCTION(setToNull(&a));
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>CALL_FUNCTION</string>
	// CHECK-NEXT: <key>expansion</key><string>setToNull(&a)</string>

	void setToNullAndPrint(int *vptr, const char str) {
	setToNull(vptr);
	print(str);
	}

	void macroArgContainsCommaLParenRParenTest() {
	int *a;
	CALL_FUNCTION(setToNullAndPrint(&a, "Hello!"));
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>CALL_FUNCTION</string>
	// CHECK-NEXT: <key>expansion</key><string>setToNullAndPrint(&a, "Hello!")</string>

	#define CALL_FUNCTION_WITH_TWO_PARAMS(funcCall, param1, param2) \
	funcCall(param1, param2)

	void macroArgContainsCommaLParenRParenTest2() {
	int *a;
	CALL_FUNCTION_WITH_TWO_PARAMS(setToNullAndPrint, &a, "Hello!");
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>CALL_FUNCTION_WITH_TWO_PARAMS</string>
	// CHECK-NEXT: <key>expansion</key><string>setToNullAndPrint( &a, "Hello!")</string>

	#define CALL_LAMBDA(l) \
	l()

	void commaInBracketsTest() {
	int *ptr;
	const char str[] = "Hello!";
	// You need to add parantheses around a lambda expression to compile this,
	// else the comma in the capture will be parsed as divider of macro args.
	CALL_LAMBDA(([&ptr, str] () mutable { TO_NULL(&ptr); }));
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>CALL_LAMBDA</string>
	// CHECK-NEXT: <key>expansion</key><string>([&ptr, str] () mutable { setToNull(&ptr); })()</string>

	#define PASTE_CODE(code) \
	code

	void commaInBracesTest() {
	PASTE_CODE({ // expected-warning{{Dereference of null pointer}}
	// NOTE: If we were to add a new variable here after a comma, we'd get a
	// compilation error, so this test is mainly here to show that this was also
	// investigated.

	// int *ptr = nullptr, a;
	int *ptr = nullptr;
	*ptr = 5;
	})
	}

	// CHECK: <key>name</key><string>PASTE_CODE</string>
	// CHECK-NEXT: <key>expansion</key><string>{ int ptr = nullptr; ptr = 5; }</string>

	// Example taken from
	// https://gcc.gnu.org/onlinedocs/cpp/Macro-Arguments.html#Macro-Arguments.

	#define POTENTIALLY_EMPTY_PARAM(x, y) \
	x; \
	y = nullptr

	void emptyParamTest() {
	int *ptr;

	POTENTIALLY_EMPTY_PARAM(,ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>POTENTIALLY_EMPTY_PARAM</string>
	// CHECK-NEXT: <key>expansion</key><string>;ptr = nullptr</string>

	#define NESTED_EMPTY_PARAM(a, b) \
	POTENTIALLY_EMPTY_PARAM(a, b);


	void nestedEmptyParamTest() {
	int *ptr;

	NESTED_EMPTY_PARAM(, ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>NESTED_EMPTY_PARAM</string>
	// CHECK-NEXT: <key>expansion</key><string>; ptr = nullptr;</string>

	#define CALL_FUNCTION_WITH_ONE_PARAM_THROUGH_MACRO(func, param) \
	CALL_FUNCTION(func(param))

	void lParenRParenInNestedMacro() {
	int *ptr;
	CALL_FUNCTION_WITH_ONE_PARAM_THROUGH_MACRO(setToNull, &ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>CALL_FUNCTION_WITH_ONE_PARAM_THROUGH_MACRO</string>
	// CHECK-NEXT: <key>expansion</key><string>setToNull( &ptr)</string>

	//===----------------------------------------------------------------------===//
	// Tests for variadic macro arguments.
	//===----------------------------------------------------------------------===//

	template <typename ...Args>
	void variadicFunc(Args ...args);

	#define VARIADIC_SET_TO_NULL(ptr, ...) \
	ptr = nullptr; \
	variadicFunc(__VA_ARGS__)

	void variadicMacroArgumentTest() {
	int *ptr;
	VARIADIC_SET_TO_NULL(ptr, 1, 5, "haha!");
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>VARIADIC_SET_TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr = nullptr; variadicFunc( 1, 5, "haha!")</string>

	void variadicMacroArgumentWithoutAnyArgumentTest() {
	int *ptr;
	// Not adding a single parameter to ... is silly (and also causes a
	// preprocessor warning), but is not an excuse to crash on it.
	VARIADIC_SET_TO_NULL(ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>VARIADIC_SET_TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>ptr = nullptr; variadicFunc()</string>

	//===----------------------------------------------------------------------===//
	// Tests for # and ##.
	//===----------------------------------------------------------------------===//

	#define DECLARE_FUNC_AND_SET_TO_NULL(funcName, ptr) \
	void generated_##funcName(); \
	ptr = nullptr;

	void hashHashOperatorTest() {
	int *ptr;
	DECLARE_FUNC_AND_SET_TO_NULL(whatever, ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>DECLARE_FUNC_AND_SET_TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>void generated_whatever(); ptr = nullptr;</string>

	void macroArgContainsHashHashInStringTest() {
	int *a;
	TO_NULL_AND_PRINT(a, "Will this ## cause a crash?");
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
	// CHECK-NEXT: <key>expansion</key><string>a = 0; print( "Will this ## cause a crash?")</string>

	#define PRINT_STR(str, ptr) \
	print(#str); \
	ptr = nullptr

	void hashOperatorTest() {
	int *ptr;
	PRINT_STR(Hello, ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>PRINT_STR</string>
	// CHECK-NEXT: <key>expansion</key><string>print("Hello"); ptr = nullptr</string>

	void macroArgContainsHashInStringTest() {
	int *a;
	TO_NULL_AND_PRINT(a, "Will this # cause a crash?");
	*a = 5; // expected-warning{{Dereference of null pointer}}
	}

	// CHECK: <key>name</key><string>TO_NULL_AND_PRINT</string>
	// CHECK-NEXT: <key>expansion</key><string>a = 0; print( "Will this # cause a crash?")</string>

	//===----------------------------------------------------------------------===//
	// Tests for more complex macro expansions.
	//
	// We won't cover anything that wasn't covered up to this point, but rather
	// show more complex, macros with deeper nesting, more arguments (some unused)
	// and so on.
	//===----------------------------------------------------------------------===//

	#define IF(Condition) \
	if ( Condition )

	#define L_BRACE {
	#define R_BRACE }
	#define LESS <
	#define GREATER >
	#define EQUALS =
	#define SEMICOLON ;
	#define NEGATIVE -
	#define RETURN return
	#define ZERO 0

	#define EUCLIDEAN_ALGORITHM(A, B) \
	IF(A LESS ZERO) L_BRACE \
	A EQUALS NEGATIVE A SEMICOLON \
	R_BRACE \
	IF(B LESS ZERO) L_BRACE \
	B EQUALS NEGATIVE B SEMICOLON \
	R_BRACE \
	\
	/* This is where a while loop would be, but that seems to be too complex */ \
	/* for the analyzer just yet. Let's just pretend that this algorithm */ \
	/* works. */ \
	\
	RETURN B / (B - B) SEMICOLON

	int getLowestCommonDenominator(int A, int B) {
	EUCLIDEAN_ALGORITHM(A, B) // expected-warning{{Division by zero}}
	}

	void testVeryComplexAlgorithm() {
	int tmp = 8 / (getLowestCommonDenominator(5, 7) - 1);
	print(&tmp);
	}
	// CHECK: <key>name</key><string>EUCLIDEAN_ALGORITHM</string>
	// CHECK-NEXT: <key>expansion</key><string>if (A<0 ){A=-A;} if ( B<0 ){ B=- B;}return B / ( B - B);</string>

	#define YET_ANOTHER_SET_TO_NULL(x, y, z) \
	print((void *) x); \
	print((void *) y); \
	z = nullptr;

	#define DO_NOTHING(str) str
	#define DO_NOTHING2(str2) DO_NOTHING(str2)

	void test() {
	int *ptr;
	YET_ANOTHER_SET_TO_NULL(5, DO_NOTHING2("Remember the Vasa"), ptr);
	*ptr = 5; // expected-warning{{Dereference of null pointer}}
	}
	// CHECK: <key>name</key><string>YET_ANOTHER_SET_TO_NULL</string>
	// CHECK-NEXT: <key>expansion</key><string>print((void )5); print((void )"Remember the Vasa"); ptr = nullptr;</string>

	int garbage_value;

	#define REC_MACRO_FUNC(REC_MACRO_PARAM) garbage_##REC_MACRO_PARAM
	#define value REC_MACRO_FUNC(value)

	void recursiveMacroUser() {
	if (value == 0)
	1 / value; // expected-warning{{Division by zero}}
	// expected-warning@-1{{expression result unused}}
	}

	#define FOO(x) int foo() { return x; }
	#define APPLY_ZERO1(function) function(0)

	APPLY_ZERO1(FOO)
	void useZeroApplier1() { (void)(1 / foo()); } // expected-warning{{Division by zero}}

	// CHECK: <key>name</key><string>APPLY_ZERO1</string>
	// CHECK-NEXT: <key>expansion</key><string>int foo() { return x; }(0)</string>

	#define BAR(x) int bar() { return x; }
	#define APPLY_ZERO2 BAR(0)

	APPLY_ZERO2
	void useZeroApplier2() { (void)(1 / bar()); } // expected-warning{{Division by zero}}

	// CHECK: <key>name</key><string>APPLY_ZERO2</string>
	// CHECK-NEXT: <key>expansion</key><string>int bar() { return 0; }</string>