Writing warning-free code

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We are currently on the way towards a completely warning-free OOo C/C++ code base. And once we have reached that, we want to keep the code clean!

We reached a first milestone by integrating CWS warnings01 into SRC680m173. Since then, and at least on the unxlngi6, unxsoli4, unxsols4, and wntmsci10 platforms, the C/C++ compilers are used with rather aggressive warning levels, and in most CVS modules warnings are treated as errors that break the build. Some CVS modules have not yet been made warning-free.

What changed?

Since SRC680m173, any new or modified C/C++ code that produces warnings will break the build. (Unless, of course, you fail to pass --enable-werror to configure.) Ideally, to be sure that integrating a CWS will not break the build, the CWS should now be built on every warning-free platform (i.e., at least unxlngi6, unxsoli4, unxsols4, and wntmsci10), with all supported compiler versions, in both product and non-product variants, and with and without the debug=x build switch before nominating it for integration. Practically, a reasonable subset of these will have to suffice.

For unxlngi6, we concentrated on GCC 3.4.1, GCC 4.0.2/4.0.3, and GCC 4.1.1, while other GCC versions probably produce slightly different warnings (that could break the build now on those GCC versions).

Porters are encouraged to make additional platforms warning-free. Since most ports are using GCC, there should not be too many surprises. Any necessary changes to the platform-specific .mk file in solenv/inc can be modelled after solenv/inc/unxlngi6.mk. In short, you need a bunch of CFLAGSxxx (see interface-announce C/C++ compiler warnings) and MODULES_WITH_WARNINGS or COMPILER_WARN_ERRORS (see interface-announce MODULES_WITH_WARNINGS).

The wall=x build switch no longer has any effect on the warning-free platforms. Once all platforms are warning-free, we can remove it completely.

The missing modules

If your job is to clean up a given CVS module, here are some practical guidelines:

  • Remove the module from the MODULES_WITH_WARNINGS list in the platform-specific .mk files in solenv/inc.
  • Make sure your module builds and delivers successfully with build && deliver (and all the variants mentioned above).
  • If your module contains external code which we do not want to clean up, set EXTERNAL_WARNINGS_NOT_ERRORS := TRUE at the beginning of the corresponding makefile.mk, so that warnings do not lead to errors there.
  • In any case, for any header file delivered from your module, make sure that testhxx on the delivered header file is successful. (Note that testhxx only works for headers delivered to the solver, not for local headers within a CVS module, as it calls the compiler with only a fixed set of include directories.)
  • If you encounter a warning that cannot reasonably be worked around, discuss that problem on dev@openoffice.org. One outcome of that discussion can be that we globally disable that particular warning. To see which warnings are already globally disabled on a given platform, look at the settings for CFLAGSWARNCC, CFLAGSWARNCXX, CFLAGSWALLCC, and/or CFLAGSWALLCXX in the platform-specific .mk file in solenv/inc (unxlngi6.mk, unxsoli4.mk, unxsols4.mk, and wntmsci10.mk).

See the current warning-free code status.

Tips for Warning-free code

The following is a list of issues you might come across when making existing code warning-free, or when writing new, warning-free code:

Integral conversions

Sometimes, a cast between integral types is needed to avoid a warning. In such a case, use sal::static_int_cast (C++) or SAL_INT_CAST (C) to make that cast stick out—it will need to be adapted when the type of any of the involved expressions changes later on:

sal_Int32 n;
std::vector<char> v;
if (n >= 0 && sal::static_int_cast<sal_uInt32>(n) == v.size()) ...

Note that you might get the warning C4244 (possible loss of data) on Windows also for the following situation:

short a = 0, b = 0;
a += b;  // warning C4244 on Windows

This is because a and b are converted to int, then added and the result is then again cast back to short. This is especially nasty, as it also happens when you use xub_StrLen, but only if it is a typedf to USHORT and not to sal_uInt32, i.e. only as long as STRING32 is not defined in solar.h. The warning does not occur when you use operator+ instead of operator+=.

short a = 0, b = 0;
a = a + b;

Invalid enum case values

Code like

enum E { A=1, B=2, C=4 } e;
switch (e) {
case A: ...
case B|C: ...
}

will cause wntmsci11 to complain with warning C4063: case '6' is not a valid value for switch of enum 'E'. The cause of the warning is that E is not meant be an enumerated type, but a bit field type. enum is commonly used in C and C++ to initialize constants; in this case, constants for individual bits.

A better way to write this would be to typedef E to be an unsigned int (a better type for bit fields); and then define the constants for the individual bits using an anonymous enum. (A downside is that the documentation for the type E will not contain the constants the user needs to use.)

typedef unsigned int E;
E e;
enum { A=1, B=2, C=4 };
switch (e) {
case A: ...
case B|C: ...
}

If you do not have access to the definition of the type E, it can still be worked around by promoting e to its underlying integral type:

...
switch (+e) {
...

Casting between pointer and integer types

C++

  • From pointer-to-(possibly-cv-qualified-)void-or-object type P to unsigned integral type U:
P p;
U u = sal::static_int_cast<U>(reinterpret_cast<sal_uIntPtr>(p));
  • From unsigned integral type U to pointer-to-(possibly-cv-qualified-)void-or-object type P:
U u;
P p = reinterpret_cast<P>(sal::static_int_cast<sal_uIntPtr>(u));
  • From pointer-to-(possibly-cv-qualified-)void-or-object type P to signed integral type S:
P p;
S s = sal::static_int_cast<S>(reinterpret_cast<sal_IntPtr>(p));
  • From signed integral type S to pointer-to-(possibly-cv-qualified-)void-or-object type P:
S s;
P p = reinterpret_cast<P>(sal::static_int_cast<sal_IntPtr>(s));

C

  • From pointer-to-(possibly-qualified-)void-or-object type P to unsigned integer type U:
P p;
U u = SAL_INT_CAST(U, (sal_uIntPtr) p);
  • From unsigned integer type U to pointer-to-(possibly-qualified-)void-or-object type P:
U u;
P p = (P) SAL_INT_CAST(sal_uIntPtr, u);
  • From pointer-to-(possibly-qualified-)void-or-object type P to signed integer type S:
P p;
S s = SAL_INT_CAST(S, (sal_IntPtr) p);
  • From signed integer type S to pointer-to-(possibly-qualified-)void-or-object type P:
S s;
P p = (P) SAL_INT_CAST(sal_IntPtr, s);

Pointer to function

A pointer to function is not compatible with a pointer to object, so code like

void * osl::Module::getSymbol(rtl::OUString const &);
typedef void (* MyFunc)();
MyFunc f = module.getSymbol("myFunc");

will not compile. The only places were converting between pointer to function and pointer to object (typically void *) should be necessary are osl::Module::getSymbol and osl::Module::getUrlFromAddress, and in both cases there are additional functions (osl::Module::getFunctionSymbol and an overload with oslGenericFunction of osl::Module::getUrlFromAddress) that handle the problem internally. Use them!

Name hiding

In C++, use a using declaration to make visible (virtual) function declarations from a base clase that would be hidden by a function declaration in a derived class:

class Base {
public:
  virtual void f(int);
  virtual void f(double);
};
class Derived: public Base {
public:
  using Base::f;
  virtual void f(int);
};

Make sure to apply the correct access control to the using declaration:

class Base {
protected:
  void f();
};
class Derived: public Base {
public:
  void f(int);
protected:
  using Base::f;
};

If you can, avoid such constructs as in the above example, by choosing different names for the two functions f. If, on the other hand, the function f is clearly meant to be overloaded, then make all instances of f virtual in the base class.

Unused parameters

There are three cases where a parameter of a function is not actually used in the definition of the function:

  • The function has to have a certain signature (it is a virtual function, shall be used with a certain function pointer type, or is part of a stable API that cannot be changed). In those cases, leave out the parameter name in the function definition (C++) or use
(void) paramName; /* avoid warning about unused parameter */

at the start of the function body (C).

  • The function is created by the Macro IMPL_LINK( Class, Method, ArgType, ArgName ) from tools/inc/link.hxx or similar. Use EMPTYARG as Parametername as in
IMPL_LINK( Class, Method, ArgType, EMPTYARG )

EMPTYARG is defined empty, so this will result in leaving out the parameter name as suggested above.

  • The function uses the parameter only in an #ifdef-block, or only in OSL_ASSERT etc. debug code. If the first case occurs in C++ code, fix it by using the same #ifdef around the parameter name in the function header. In all other cases, fix it by using
(void) paramName; /* avoid warning about unused parameter */

at the start of the function body.

  • The function once used the parameter, but does no longer do so. In that case, clean up the function declaration and all uses of the function.

When all else fails

There are cases where the only sensible solution is to suppress warnings for a given chunk of code:

  • As explained above, in external code which we do not want to clean up, use EXTERNAL_WARNINGS_NOT_ERRORS := TRUE so that warnings do not lead to errors there.
  • Header files included directly from the system, or header files delivered from external code included in the OOo code base but which we cannot reasonably make testhxx-clean: Surround that code (e.g., the #include-directives for those headers) by
#if defined __GNUC__
#pragma GCC system_header
#elif defined __SUNPRO_CC
#pragma disable_warn
#elif defined _MSC_VER
#pragma warning(push, 1)
#endif

and

#if defined __SUNPRO_CC
#pragma enable_warn
#elif defined _MSC_VER
#pragma warning(pop)
#endif

(probably together with an explanatory comment). Due to the nature of the GCC solution, this does not work directly within the compilation unit's main (.c, .cxx) file, only within a (.h, .hxx) file included directly or indirectly. Even more important, because the system_header pragma affects the rest of the current header, the entire warnings guard mechanism should be separated into a header file on its own, including just the file in question. From the original file then include that wrapper file.

  • Code generated by flex or bison: The solution here is similar to the solution in the previous item—disable all warnings in the generated code. However, this has two implications: For one, it means that also all warnings from our client code integrated into the flex/bison output are suppressed; this is not really that large an issue, given the relatively small number of flex/bison files we use. For another, due to the nature of the GCC solution, it means that you need to introduce a wrapper file. The individual steps for a given flex/bison file named example.ly, translated to $(MISC)$/example.cxx, are as follows: First, change example.ly by adding
#if defined __GNUC__
#pragma GCC system_header
#elif defined __SUNPRO_CC
#pragma disable_warn
#elif defined _MSC_VER
#pragma warning(push, 1)
#endif

(probably together with an explanatory comment) at the very end of the initial %{...%} section (for _MSC_VER, #pragma warning(push, 1) might not disable all the warnings that occur; in that case, add #pragma warning(disable: NNN1 NNN2 ...) after it to disable specific warnings NNN1, NNN2, etc.). Second, create a new file named wrap_example.cxx in the same source directory as exmaple.ly, containing

#include "example.cxx"

Third, change the corresponding makefile.mk by adding [] INCPRE=$(MISC) to the top, by changing occurrences of example.obj to wrap_example.obj, and by adding [] $(OBJ)$/wrap_example.obj: $(MISC)$/example.cxx and/or [] $(SLO)$/wrap_example.obj: $(MISC)$/example.cxx at the bottom.

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