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3    <title> libsm : Assert and Abort </title>
4</head>
5<body>
6
7<a href="index.html">Back to libsm overview</a>
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9<center>
10    <h1> libsm : Assert and Abort </h1>
11    <br> $Id: assert.html,v 1.6 2001-08-27 21:47:03 ca Exp $
12</center>
13
14<h2> Introduction </h2>
15
16This package contains abstractions
17for assertion checking and abnormal program termination.
18
19<h2> Synopsis </h2>
20
21<pre>
22#include &lt;sm/assert.h&gt;
23
24/*
25**  abnormal program termination
26*/
27
28void sm_abort_at(char *filename, int lineno, char *msg);
29typedef void (*SM_ABORT_HANDLER)(char *filename, int lineno, char *msg);
30void sm_abort_sethandler(SM_ABORT_HANDLER);
31void sm_abort(char *fmt, ...)
32
33/*
34**  assertion checking
35*/
36
37SM_REQUIRE(expression)
38SM_ASSERT(expression)
39SM_ENSURE(expression)
40
41extern SM_DEBUG_T SmExpensiveRequire;
42extern SM_DEBUG_T SmExpensiveAssert;
43extern SM_DEBUG_T SmExpensiveEnsure;
44
45#if SM_CHECK_REQUIRE
46#if SM_CHECK_ASSERT
47#if SM_CHECK_ENSURE
48
49cc -DSM_CHECK_ALL=0 -DSM_CHECK_REQUIRE=1 ...
50</pre>
51
52<h2> Abnormal Program Termination </h2>
53
54The functions sm_abort and sm_abort_at are used to report a logic
55bug and terminate the program.  They can be invoked directly,
56and they are also used by the assertion checking macros.
57
58<dl>
59<dt>
60    void sm_abort_at(char *filename, int lineno, char *msg)
61<dd>
62	This is the low level interface for causing abnormal program
63	termination.  It is intended to be invoked from a
64	macro, such as the assertion checking macros.
65
66	If filename != NULL then filename and lineno specify the line
67	of source code on which the logic bug is detected.  These
68	arguments are normally either set to __FILE__ and __LINE__
69	from an assertion checking macro, or they are set to NULL and 0.
70
71	The default action is to print an error message to smioerr
72	using the arguments, and then call abort().  This default
73	behaviour can be changed by calling sm_abort_sethandler.
74<p>
75<dt>
76    void sm_abort_sethandler(SM_ABORT_HANDLER handler)
77<dd>
78	Install 'handler' as the callback function that is invoked
79	by sm_abort_at.  This callback function is passed the same
80	arguments as sm_abort_at, and is expected to log an error
81	message and terminate the program.  The callback function should
82	not raise an exception or perform cleanup: see Rationale.
83
84	sm_abort_sethandler is intended to be called once, from main(),
85	before any additional threads are created: see Rationale.
86	You should not use sm_abort_sethandler to
87	switch back and forth between several handlers;
88	this is particularly dangerous when there are
89	multiple threads, or when you are in a library routine.
90<p>
91<dt>
92    void sm_abort(char *fmt, ...)
93<dd>
94	This is the high level interface for causing abnormal program
95	termination.  It takes printf arguments.  There is no need to
96	include a trailing newline in the format string; a trailing newline
97	will be printed if appropriate by the handler function.
98</dl>
99
100<h2> Assertions </h2>
101
102    The assertion handling package
103    supports a style of programming in which assertions are used
104    liberally throughout the code, both as a form of documentation,
105    and as a way of detecting bugs in the code by performing runtime checks.
106<p>
107    There are three kinds of assertion:
108<dl>
109<dt>
110    SM_REQUIRE(expr)
111<dd>
112	This is an assertion used at the beginning of a function
113	to check that the preconditions for calling the function
114	have been satisfied by the caller.
115<p>
116<dt>
117    SM_ENSURE(expr)
118<dd>
119	This is an assertion used just before returning from a function
120	to check that the function has satisfied all of the postconditions
121	that it is required to satisfy by its contract with the caller.
122<p>
123<dt>
124    SM_ASSERT(expr)
125<dd>
126	This is an assertion that is used in the middle of a function,
127	to check loop invariants, and for any other kind of check that is
128	not a "require" or "ensure" check.
129</dl>
130    If any of the above assertion macros fail, then sm_abort_at
131    is called.  By default, a message is printed to stderr and the
132    program is aborted.  For example, if SM_REQUIRE(arg &gt; 0) fails
133    because arg &lt;= 0, then the message
134<blockquote><pre>
135foo.c:47: SM_REQUIRE(arg &gt; 0) failed
136</pre></blockquote>
137    is printed to stderr, and abort() is called.
138    You can change this default behaviour using sm_abort_sethandler.
139
140<h2> How To Disable Assertion Checking At Compile Time </h2>
141
142    You can use compile time macros to selectively enable or disable
143    each of the three kinds of assertions, for performance reasons.
144    For example, you might want to enable SM_REQUIRE checking
145    (because it finds the most bugs), but disable the other two types.
146<p>
147    By default, all three types of assertion are enabled.
148    You can selectively disable individual assertion types
149    by setting one or more of the following cpp macros to 0
150    before &lt;sm/assert.h&gt; is included for the first time:
151<blockquote>
152	SM_CHECK_REQUIRE<br>
153	SM_CHECK_ENSURE<br>
154	SM_CHECK_ASSERT<br>
155</blockquote>
156    Or, you can define SM_CHECK_ALL as 0 to disable all assertion
157    types, then selectively define one or more of SM_CHECK_REQUIRE,
158    SM_CHECK_ENSURE or SM_CHECK_ASSERT as 1.  For example,
159    to disable all assertions except for SM_REQUIRE, you can use
160    these C compiler flags:
161<blockquote>
162	-DSM_CHECK_ALL=0 -DSM_CHECK_REQUIRE=1
163</blockquote>
164
165    After &lt;sm/assert.h&gt; is included, the macros
166    SM_CHECK_REQUIRE, SM_CHECK_ENSURE and SM_CHECK_ASSERT
167    are each set to either 0 or 1.
168
169<h2> How To Write Complex or Expensive Assertions </h2>
170
171    Sometimes an assertion check requires more code than a simple
172    boolean expression.
173    For example, it might require an entire statement block
174    with its own local variables.
175    You can code such assertion checks by making them conditional on
176    SM_CHECK_REQUIRE, SM_CHECK_ENSURE or SM_CHECK_ASSERT,
177    and using sm_abort to signal failure.
178<p>
179    Sometimes an assertion check is significantly more expensive
180    than one or two comparisons.
181    In such cases, it is not uncommon for developers to comment out
182    the assertion once the code is unit tested.
183    Please don't do this: it makes it hard to turn the assertion
184    check back on for the purposes of regression testing.
185    What you should do instead is make the assertion check conditional
186    on one of these predefined debug objects:
187<blockquote>
188	SmExpensiveRequire<br>
189	SmExpensiveAssert<br>
190	SmExpensiveEnsure
191</blockquote>
192    By doing this, you bring the cost of the assertion checking code
193    back down to a single comparison, unless expensive assertion checking
194    has been explicitly enabled.
195    By the way, the corresponding debug category names are
196<blockquote>
197	sm_check_require<br>
198	sm_check_assert<br>
199	sm_check_ensure
200</blockquote>
201    What activation level should you check for?
202    Higher levels correspond to more expensive assertion checks.
203    Here are some basic guidelines:
204<blockquote>
205	level 1: &lt; 10 basic C operations<br>
206	level 2: &lt; 100 basic C operations<br>
207	level 3: &lt; 1000 basic C operations<br>
208	...
209</blockquote>
210
211<p>
212    Here's a contrived example of both techniques:
213<blockquote><pre>
214void
215w_munge(WIDGET *w)
216{
217    SM_REQUIRE(w != NULL);
218#if SM_CHECK_REQUIRE
219    /*
220    **  We run this check at level 3 because we expect to check a few hundred
221    **  table entries.
222    */
223
224    if (sm_debug_active(&SmExpensiveRequire, 3))
225    {
226        int i;
227
228        for (i = 0; i &lt; WIDGET_MAX; ++i)
229        {
230            if (w[i] == NULL)
231                sm_abort("w_munge: NULL entry %d in widget table", i);
232        }
233    }
234#endif /* SM_CHECK_REQUIRE */
235</pre></blockquote>
236
237<h2> Other Guidelines </h2>
238
239    You should resist the urge to write SM_ASSERT(0) when the code has
240    reached an impossible place.  It's better to call sm_abort, because
241    then you can generate a better error message.  For example,
242<blockquote><pre>
243switch (foo)
244{
245    ...
246  default:
247    sm_abort("impossible value %d for foo", foo);
248}
249</pre></blockquote>
250    Note that I did not bother to guard the default clause of the switch
251    statement with #if SM_CHECK_ASSERT ... #endif, because there is
252    probably no performance gain to be had by disabling this particular check.
253<p>
254    Avoid including code that has side effects inside of assert macros,
255    or inside of SM_CHECK_* guards.  You don't want the program to stop
256    working if assertion checking is disabled.
257
258<h2> Rationale for Logic Bug Handling </h2>
259
260    When a logic bug is detected, our philosophy is to log an error message
261    and terminate the program, dumping core if possible.
262    It is not a good idea to raise an exception, attempt cleanup,
263    or continue program execution.  Here's why.
264<p>
265    First of all, to facilitate post-mortem analysis, we want to dump core
266    on detecting a logic bug, disturbing the process image as little as
267    possible before dumping core.  We don't want to raise an exception
268    and unwind the stack, executing cleanup code, before dumping core,
269    because that would obliterate information we need to analyze the cause
270    of the abort.
271<p>
272    Second, it is a bad idea to raise an exception on an assertion failure
273    because this places unacceptable restrictions on code that uses
274    the assertion macros.
275    The reason is this: the sendmail code must be written so that
276    anywhere it is possible for an assertion to be raised, the code
277    will catch the exception and clean up if necessary, restoring
278    data structure invariants and freeing resources as required.
279    If an assertion failure was signalled by raising an exception,
280    then every time you added an assertion, you would need to check
281    both the function containing the assertion and its callers to see
282    if any exception handling code needed to be added to clean up properly
283    on assertion failure.  That is far too great a burden.
284<p>
285    It is a bad idea to attempt cleanup upon detecting a logic bug
286    for several reasons:
287<ul>
288<li>If you need to perform cleanup actions in order to preserve the
289    integrity of the data that the program is handling, then the
290    program is not fault tolerant, and needs to be redesigned.
291    There are several reasons why a program might be terminated unexpectedly:
292    the system might crash, the program might receive a signal 9,
293    the program might be terminated by a memory fault (possibly as a
294    side effect of earlier data structure corruption), and the program
295    might detect a logic bug and terminate itself.  Note that executing
296    cleanup actions is not feasible in most of the above cases.
297    If the program has a fault tolerant design, then it will not lose
298    data even if the system crashes in the middle of an operation.
299<p>
300<li>If the cause of the logic bug is earlier data structure corruption,
301    then cleanup actions intended to preserve the integrity of the data
302    that the program is handling might cause more harm than good: they
303    might cause information to be corrupted or lost.
304<p>
305<li>If the program uses threads, then cleanup is much more problematic.
306    Suppose that thread A is holding some locks, and is in the middle of
307    modifying a shared data structure.  The locks are needed because the
308    data structure is currently in an inconsistent state.  At this point,
309    a logic bug is detected deep in a library routine called by A.
310    How do we get all of the running threads to stop what they are doing
311    and perform their thread-specific cleanup actions before terminating?
312    We may not be able to get B to clean up and terminate cleanly until
313    A has restored the invariants on the data structure it is modifying
314    and releases its locks.  So, we raise an exception and unwind the stack,
315    restoring data structure invariants and releasing locks at each level
316    of abstraction, and performing an orderly shutdown.  There are certainly
317    many classes of error conditions for which using the exception mechanism
318    to perform an orderly shutdown is appropriate and feasible, but there
319    are also classes of error conditions for which exception handling and
320    orderly shutdown is dangerous or impossible.  The abnormal program
321    termination system is intended for this second class of error conditions.
322    If you want to trigger orderly shutdown, don't call sm_abort:
323    raise an exception instead.
324</ul>
325<p>
326    Here is a strategy for making sendmail fault tolerant.
327    Sendmail is structured as a collection of processes.  The "root" process
328    does as little as possible, except spawn children to do all of the real
329    work, monitor the children, and act as traffic cop.
330    We use exceptions to signal expected but infrequent error conditions,
331    so that the process encountering the exceptional condition can clean up
332    and keep going.  (Worker processes are intended to be long lived, in
333    order to minimize forking and increase performance.)  But when a bug
334    is detected in a sendmail worker process, the worker process does minimal
335    or no cleanup and then dies.  A bug might be detected in several ways:
336    the process might dereference a NULL pointer, receive a signal 11,
337    core dump and die, or an assertion might fail, in which case the process
338    commits suicide.  Either way, the root process detects the death of the
339    worker, logs the event, and spawns another worker.
340
341<h2> Rationale for Naming Conventions </h2>
342
343    The names "require" and "ensure" come from the writings of Bertrand Meyer,
344    a prominent evangelist for assertion checking who has written a number of
345    papers about the "Design By Contract" programming methodology,
346    and who created the Eiffel programming language.
347    Many other assertion checking packages for C also have "require" and
348    "ensure" assertion types.  In short, we are conforming to a de-facto
349    standard.
350<p>
351    We use the names <tt>SM_REQUIRE</tt>, <tt>SM_ASSERT</tt>
352    and <tt>SM_ENSURE</tt> in preference to to <tt>REQUIRE</tt>,
353    <tt>ASSERT</tt> and <tt>ENSURE</tt> because at least two other
354    open source libraries (libisc and libnana) define <tt>REQUIRE</tt>
355    and <tt>ENSURE</tt> macros, and many libraries define <tt>ASSERT</tt>.
356    We want to avoid name conflicts with other libraries.
357
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