Miscellaneous Coding Conventions
PostgreSQL 9.6.2 Documentation | |||
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52.4.1. C Standard
Code in PostgreSQL should only rely on language features available in the C89 standard. That means a conforming C89 compiler has to be able to compile postgres, at least aside from a few platform dependent pieces. Features from later revision of the C standard or compiler specific features can be used, if a fallback is provided.
For example static inline and _StaticAssert() are currently used, even though they are from newer revisions of the C standard. If not available we respectively fall back to defining the functions without inline, and to using a C89 compatible replacement that performs the same checks, but emits rather cryptic messages.
52.4.2. Function-Like Macros and Inline Functions
Both, macros with arguments and static inline functions, may be used. The latter are preferable if there are multiple-evaluation hazards when written as a macro, as e.g. the case with
#define Max(x, y) ((x) > (y) ? (x) : (y))
or when the macro would be very long. In other cases it's only possible to use macros, or at least easier. For example because expressions of various types need to be passed to the macro.
When the definition of an inline function references symbols (i.e. variables, functions) that are only available as part of the backend, the function may not be visible when included from frontend code.
#ifndef FRONTEND static inline MemoryContext MemoryContextSwitchTo(MemoryContext context) { MemoryContext old = CurrentMemoryContext; CurrentMemoryContext = context; return old; } #endif /* FRONTEND */
In this example CurrentMemoryContext , which is only available in the backend, is referenced and the function thus hidden with a #ifndef FRONTEND . This rule exists because some compilers emit references to symbols contained in inline functions even if the function is not used.
52.4.3. Writing Signal Handlers
To be suitable to run inside a signal handler code has to be written very carefully. The fundamental problem is that, unless blocked, a signal handler can interrupt code at any time. If code inside the signal handler uses the same state as code outside chaos may ensue. As an example consider what happens if a signal handler tries to acquire a lock that's already held in the interrupted code.
Barring special arrangements code in signal handlers may only
call async-signal safe functions (as defined in POSIX) and access
variables of type
volatile sig_atomic_t
. A few
functions in
postgres
are also deemed signal safe, importantly
SetLatch()
.
In most cases signal handlers should do nothing more than note that a signal has arrived, and wake up code running outside of the handler using a latch. An example of such a handler is the following:
static void handle_sighup(SIGNAL_ARGS) { int save_errno = errno; got_SIGHUP = true; SetLatch(MyLatch); errno = save_errno; }
errno
is saved and restored because
SetLatch()
might change it. If that were not done
interrupted code that's currently inspecting
errno
might see the wrong
value.