src/third_party/llvm-project/clang-tools-extra/test/clang-tidy/readability-non-const-parameter.cpp - cobalt - Git at Google

 // RUN: %check_clang_tidy %s readability-non-const-parameter %t

 // Currently the checker only warns about pointer arguments.
 //
 // It can be defined both that the data is const and that the pointer is const,
 // the checker only checks if the data can be const-specified.
 //
 // It does not warn about pointers to records or function pointers.

 // Some external function where first argument is nonconst and second is const.
 char *strcpy1(char *dest, const char *src);
 unsigned my_strcpy(char *buf, const char *s);
 unsigned my_strlen(const char *buf);

 // CHECK-MESSAGES: :[[@LINE+1]]:29: warning: pointer parameter 'last' can be pointer to const [readability-non-const-parameter]
 void warn1(int *first, int *last) {
   // CHECK-FIXES: {{^}}void warn1(int *first, const int *last) {{{$}}
   *first = 0;
   if (first < last) {
   } // <- last can be const
 }

 // TODO: warning should be written here
 void warn2(char *p) {
   char buf[10];
   strcpy1(buf, p);
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:19: warning: pointer parameter 'p' can be
 void assign1(int *p) {
   // CHECK-FIXES: {{^}}void assign1(const int *p) {{{$}}
   const int *q;
   q = p;
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:19: warning: pointer parameter 'p' can be
 void assign2(int *p) {
   // CHECK-FIXES: {{^}}void assign2(const int *p) {{{$}}
   const int *q;
   q = p + 1;
 }

 void assign3(int *p) {
   *p = 0;
 }

 void assign4(int *p) {
   *p += 2;
 }

 void assign5(char *p) {
   p[0] = 0;
 }

 void assign6(int *p) {
   int *q;
   q = p++;
 }

 void assign7(char *p) {
   char *a, *b;
   a = b = p;
 }

 void assign8(char *a, char *b) {
   char *x;
   x = (a ? a : b);
 }

 void assign9(unsigned char *str, const unsigned int i) {
   unsigned char *p;
   for (p = str + i; *p;) {
   }
 }

 void assign10(int *buf) {
   int i, *p;
   for (i = 0, p = buf; i < 10; i++, p++) {
     *p = 1;
   }
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:17: warning: pointer parameter 'p' can be
 void init1(int *p) {
   // CHECK-FIXES: {{^}}void init1(const int *p) {{{$}}
   const int *q = p;
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:17: warning: pointer parameter 'p' can be
 void init2(int *p) {
   // CHECK-FIXES: {{^}}void init2(const int *p) {{{$}}
   const int *q = p + 1;
 }

 void init3(int *p) {
   int *q = p;
 }

 void init4(float *p) {
   int *q = (int *)p;
 }

 void init5(int *p) {
   int *i = p ? p : 0;
 }

 void init6(int *p) {
   int *a[] = {p, p, 0};
 }

 void init7(int *p, int x) {
   for (int *q = p + x - 1; 0; q++)
     ;
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:18: warning: pointer parameter 'p' can be
 int return1(int *p) {
   // CHECK-FIXES: {{^}}int return1(const int *p) {{{$}}
   return *p;
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:25: warning: pointer parameter 'p' can be
 const int *return2(int *p) {
   // CHECK-FIXES: {{^}}const int *return2(const int *p) {{{$}}
   return p;
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:25: warning: pointer parameter 'p' can be
 const int *return3(int *p) {
   // CHECK-FIXES: {{^}}const int *return3(const int *p) {{{$}}
   return p + 1;
 }

 // CHECK-MESSAGES: :[[@LINE+1]]:27: warning: pointer parameter 'p' can be
 const char *return4(char *p) {
   // CHECK-FIXES: {{^}}const char *return4(const char *p) {{{$}}
   return p ? p : "";
 }

 char *return5(char *s) {
   return s;
 }

 char *return6(char *s) {
   return s + 1;
 }

 char *return7(char *a, char *b) {
   return a ? a : b;
 }

 char return8(int *p) {
   return ++(*p);
 }

 void dontwarn1(int *p) {
   ++(*p);
 }

 void dontwarn2(int *p) {
   (*p)++;
 }

 int dontwarn3(_Atomic(int) * p) {
   return *p;
 }

 void callFunction1(char *p) {
   strcpy1(p, "abc");
 }

 void callFunction2(char *p) {
   strcpy1(&p[0], "abc");
 }

 void callFunction3(char *p) {
   strcpy1(p + 2, "abc");
 }

 char *callFunction4(char *p) {
   return strcpy1(p, "abc");
 }

 unsigned callFunction5(char *buf) {
   unsigned len = my_strlen(buf);
   return len + my_strcpy(buf, "abc");
 }

 void f6(int **p);
 void callFunction6(int *p) { f6(&p); }

 typedef union { void *v; } t;
 void f7(t obj);
 void callFunction7(int *p) {
   f7((t){p});
 }

 void f8(int &x);
 void callFunction8(int *p) {
   f8(*p);
 }

 // Don't warn about nonconst function pointers that can be const.
 void functionpointer(double f(double), int x) {
   f(x);
 }

 // TODO: This is a false positive.
 // CHECK-MESSAGES: :[[@LINE+1]]:27: warning: pointer parameter 'p' can be
 int functionpointer2(int *p) {
   return *p;
 }
 void use_functionpointer2() {
   int (*fp)(int *) = functionpointer2; // <- the parameter 'p' can't be const
 }

 // Don't warn about nonconst record pointers that can be const.
 struct XY {
   int *x;
   int *y;
 };
 void recordpointer(struct XY *xy) {
   *(xy->x) = 0;
 }

 class C {
 public:
   C(int *p) : p(p) {}

 private:
   int *p;
 };

 class C2 {
 public:
   // CHECK-MESSAGES: :[[@LINE+1]]:11: warning: pointer parameter 'p' can be
   C2(int *p) : p(p) {}
   // CHECK-FIXES: {{^}}  C2(const int *p) : p(p) {}{{$}}

 private:
   const int *p;
 };

 void tempObject(int *p) {
   C c(p);
 }

 // avoid fp for const pointer array
 void constPointerArray(const char *remapped[][2]) {
   const char *name = remapped[0][0];
 }

 class Warn {
 public:
   // CHECK-MESSAGES: :[[@LINE+1]]:21: warning: pointer parameter 'p' can be
   void doStuff(int *p) {
     // CHECK-FIXES: {{^}}  void doStuff(const int *p) {{{$}}
     x = *p;
   }

 private:
   int x;
 };

 class Base {
 public:
   // Ensure there is no false positive for this method. It is virtual.
   virtual void doStuff(int *p) {
     int x = *p;
   }
 };

 class Derived : public Base {
 public:
   // Ensure there is no false positive for this method. It overrides a method.
   void doStuff(int *p) override {
     int x = *p;
   }
 };

 extern char foo(char *s); // 1
 // CHECK-FIXES: {{^}}extern char foo(const char *s); // 1{{$}}
 // CHECK-MESSAGES: :[[@LINE+1]]:16: warning: pointer parameter 's' can be
 char foo(char *s) {
   // CHECK-FIXES: {{^}}char foo(const char *s) {{{$}}
   return *s;
 }
 char foo(char *s); // 2
 // CHECK-FIXES: {{^}}char foo(const char *s); // 2{{$}}
	// RUN: %check_clang_tidy %s readability-non-const-parameter %t

	// Currently the checker only warns about pointer arguments.
	//
	// It can be defined both that the data is const and that the pointer is const,
	// the checker only checks if the data can be const-specified.
	//
	// It does not warn about pointers to records or function pointers.

	// Some external function where first argument is nonconst and second is const.
	char strcpy1(char dest, const char *src);
	unsigned my_strcpy(char buf, const char s);
	unsigned my_strlen(const char *buf);

	// CHECK-MESSAGES: :[[@LINE+1]]:29: warning: pointer parameter 'last' can be pointer to const [readability-non-const-parameter]
	void warn1(int first, int last) {
	// CHECK-FIXES: {{^}}void warn1(int first, const int last) {{{$}}
	*first = 0;
	if (first < last) {
	} // <- last can be const
	}

	// TODO: warning should be written here
	void warn2(char *p) {
	char buf[10];
	strcpy1(buf, p);
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:19: warning: pointer parameter 'p' can be
	void assign1(int *p) {
	// CHECK-FIXES: {{^}}void assign1(const int *p) {{{$}}
	const int *q;
	q = p;
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:19: warning: pointer parameter 'p' can be
	void assign2(int *p) {
	// CHECK-FIXES: {{^}}void assign2(const int *p) {{{$}}
	const int *q;
	q = p + 1;
	}

	void assign3(int *p) {
	*p = 0;
	}

	void assign4(int *p) {
	*p += 2;
	}

	void assign5(char *p) {
	p[0] = 0;
	}

	void assign6(int *p) {
	int *q;
	q = p++;
	}

	void assign7(char *p) {
	char a, b;
	a = b = p;
	}

	void assign8(char a, char b) {
	char *x;
	x = (a ? a : b);
	}

	void assign9(unsigned char *str, const unsigned int i) {
	unsigned char *p;
	for (p = str + i; *p;) {
	}
	}

	void assign10(int *buf) {
	int i, *p;
	for (i = 0, p = buf; i < 10; i++, p++) {
	*p = 1;
	}
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:17: warning: pointer parameter 'p' can be
	void init1(int *p) {
	// CHECK-FIXES: {{^}}void init1(const int *p) {{{$}}
	const int *q = p;
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:17: warning: pointer parameter 'p' can be
	void init2(int *p) {
	// CHECK-FIXES: {{^}}void init2(const int *p) {{{$}}
	const int *q = p + 1;
	}

	void init3(int *p) {
	int *q = p;
	}

	void init4(float *p) {
	int q = (int )p;
	}

	void init5(int *p) {
	int *i = p ? p : 0;
	}

	void init6(int *p) {
	int *a[] = {p, p, 0};
	}

	void init7(int *p, int x) {
	for (int *q = p + x - 1; 0; q++)
	;
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:18: warning: pointer parameter 'p' can be
	int return1(int *p) {
	// CHECK-FIXES: {{^}}int return1(const int *p) {{{$}}
	return *p;
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:25: warning: pointer parameter 'p' can be
	const int return2(int p) {
	// CHECK-FIXES: {{^}}const int return2(const int p) {{{$}}
	return p;
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:25: warning: pointer parameter 'p' can be
	const int return3(int p) {
	// CHECK-FIXES: {{^}}const int return3(const int p) {{{$}}
	return p + 1;
	}

	// CHECK-MESSAGES: :[[@LINE+1]]:27: warning: pointer parameter 'p' can be
	const char return4(char p) {
	// CHECK-FIXES: {{^}}const char return4(const char p) {{{$}}
	return p ? p : "";
	}

	char return5(char s) {
	return s;
	}

	char return6(char s) {
	return s + 1;
	}

	char return7(char a, char *b) {
	return a ? a : b;
	}

	char return8(int *p) {
	return ++(*p);
	}

	void dontwarn1(int *p) {
	++(*p);
	}

	void dontwarn2(int *p) {
	(*p)++;
	}

	int dontwarn3(_Atomic(int) * p) {
	return *p;
	}

	void callFunction1(char *p) {
	strcpy1(p, "abc");
	}

	void callFunction2(char *p) {
	strcpy1(&p[0], "abc");
	}

	void callFunction3(char *p) {
	strcpy1(p + 2, "abc");
	}

	char callFunction4(char p) {
	return strcpy1(p, "abc");
	}

	unsigned callFunction5(char *buf) {
	unsigned len = my_strlen(buf);
	return len + my_strcpy(buf, "abc");
	}

	void f6(int **p);
	void callFunction6(int *p) { f6(&p); }

	typedef union { void *v; } t;
	void f7(t obj);
	void callFunction7(int *p) {
	f7((t){p});
	}

	void f8(int &x);
	void callFunction8(int *p) {
	f8(*p);
	}

	// Don't warn about nonconst function pointers that can be const.
	void functionpointer(double f(double), int x) {
	f(x);
	}

	// TODO: This is a false positive.
	// CHECK-MESSAGES: :[[@LINE+1]]:27: warning: pointer parameter 'p' can be
	int functionpointer2(int *p) {
	return *p;
	}
	void use_functionpointer2() {
	int (fp)(int ) = functionpointer2; // <- the parameter 'p' can't be const
	}

	// Don't warn about nonconst record pointers that can be const.
	struct XY {
	int *x;
	int *y;
	};
	void recordpointer(struct XY *xy) {
	*(xy->x) = 0;
	}

	class C {
	public:
	C(int *p) : p(p) {}

	private:
	int *p;
	};

	class C2 {
	public:
	// CHECK-MESSAGES: :[[@LINE+1]]:11: warning: pointer parameter 'p' can be
	C2(int *p) : p(p) {}
	// CHECK-FIXES: {{^}} C2(const int *p) : p(p) {}{{$}}

	private:
	const int *p;
	};

	void tempObject(int *p) {
	C c(p);
	}

	// avoid fp for const pointer array
	void constPointerArray(const char *remapped[][2]) {
	const char *name = remapped[0][0];
	}

	class Warn {
	public:
	// CHECK-MESSAGES: :[[@LINE+1]]:21: warning: pointer parameter 'p' can be
	void doStuff(int *p) {
	// CHECK-FIXES: {{^}} void doStuff(const int *p) {{{$}}
	x = *p;
	}

	private:
	int x;
	};

	class Base {
	public:
	// Ensure there is no false positive for this method. It is virtual.
	virtual void doStuff(int *p) {
	int x = *p;
	}
	};

	class Derived : public Base {
	public:
	// Ensure there is no false positive for this method. It overrides a method.
	void doStuff(int *p) override {
	int x = *p;
	}
	};

	extern char foo(char *s); // 1
	// CHECK-FIXES: {{^}}extern char foo(const char *s); // 1{{$}}
	// CHECK-MESSAGES: :[[@LINE+1]]:16: warning: pointer parameter 's' can be
	char foo(char *s) {
	// CHECK-FIXES: {{^}}char foo(const char *s) {{{$}}
	return *s;
	}
	char foo(char *s); // 2
	// CHECK-FIXES: {{^}}char foo(const char *s); // 2{{$}}