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601 lines
16 KiB
C
601 lines
16 KiB
C
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/* Copyright (C) 2006 MySQL AB
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; version 2 of the License.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
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MA 02111-1301, USA
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Library for providing TAP support for testing C and C++ was written
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by Mats Kindahl <mats@mysql.com>.
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*/
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#include "tap.h"
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#include "ma_global.h"
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#include <stdlib.h>
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#include <stdarg.h>
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#include <stdio.h>
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#include <string.h>
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#include <signal.h>
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/*
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Visual Studio 2003 does not know vsnprintf but knows _vsnprintf.
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We don't put this #define in config-win.h because we prefer
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ma_vsnprintf everywhere instead, except when linking with libmysys
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is not desirable - the case here.
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*/
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#if defined(_MSC_VER) && ( _MSC_VER == 1310 )
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#define vsnprintf _vsnprintf
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#endif
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/**
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@defgroup MyTAP_Internal MyTAP Internals
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Internal functions and data structures for the MyTAP implementation.
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*/
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/**
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Test data structure.
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Data structure containing all information about the test suite.
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@ingroup MyTAP_Internal
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*/
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static TEST_DATA g_test = { 0, 0, 0, "" };
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/**
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Output stream for test report message.
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The macro is just a temporary solution.
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@ingroup MyTAP_Internal
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*/
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#define tapout stdout
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/**
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Emit the beginning of a test line, that is: "(not) ok", test number,
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and description.
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To emit the directive, use the emit_dir() function
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@ingroup MyTAP_Internal
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@see emit_dir
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@param pass 'true' if test passed, 'false' otherwise
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@param fmt Description of test in printf() format.
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@param ap Vararg list for the description string above.
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*/
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static void
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vemit_tap(int pass, char const *fmt, va_list ap)
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{
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fprintf(tapout, "%sok %d%s",
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pass ? "" : "not ",
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++g_test.last,
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(fmt && *fmt) ? " - " : "");
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if (fmt && *fmt)
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vfprintf(tapout, fmt, ap);
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}
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/**
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Emit a TAP directive.
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TAP directives are comments after that have the form:
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@code
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ok 1 # skip reason for skipping
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not ok 2 # todo some text explaining what remains
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@endcode
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@ingroup MyTAP_Internal
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@param dir Directive as a string
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@param why Explanation string
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*/
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static void
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emit_dir(const char *dir, const char *why)
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{
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fprintf(tapout, " # %s %s", dir, why);
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}
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/**
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Emit a newline to the TAP output stream.
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@ingroup MyTAP_Internal
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*/
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static void
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emit_endl()
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{
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fprintf(tapout, "\n");
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}
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static void
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handle_core_signal(int signo)
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{
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BAIL_OUT("Signal %d thrown", signo);
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}
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void
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BAIL_OUT(char const *fmt, ...)
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{
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va_list ap;
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va_start(ap, fmt);
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fprintf(tapout, "Bail out! ");
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vfprintf(tapout, fmt, ap);
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emit_endl();
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va_end(ap);
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exit(255);
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}
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void
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diag(char const *fmt, ...)
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{
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va_list ap;
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va_start(ap, fmt);
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fprintf(tapout, "# ");
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vfprintf(tapout, fmt, ap);
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emit_endl();
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va_end(ap);
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}
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typedef struct signal_entry {
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int signo;
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void (*handler)(int);
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} signal_entry;
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static signal_entry install_signal[]= {
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#ifdef SIGQUIT
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{ SIGQUIT, handle_core_signal },
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#endif
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{ SIGILL, handle_core_signal },
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{ SIGABRT, handle_core_signal },
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{ SIGFPE, handle_core_signal },
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{ SIGSEGV, handle_core_signal }
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#ifdef SIGBUS
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, { SIGBUS, handle_core_signal }
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#endif
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#ifdef SIGXCPU
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, { SIGXCPU, handle_core_signal }
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#endif
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#ifdef SIGXCPU
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, { SIGXFSZ, handle_core_signal }
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#endif
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#ifdef SIGXCPU
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, { SIGSYS, handle_core_signal }
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#endif
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#ifdef SIGXCPU
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, { SIGTRAP, handle_core_signal }
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#endif
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};
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int skip_big_tests= 1;
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void
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plan(int const count)
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{
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char *config= getenv("MYTAP_CONFIG");
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size_t i;
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if (config)
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skip_big_tests= strcmp(config, "big");
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setvbuf(tapout, 0, _IONBF, 0); /* provide output at once */
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/*
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Install signal handler
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*/
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for (i= 0; i < sizeof(install_signal)/sizeof(*install_signal); ++i)
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signal(install_signal[i].signo, install_signal[i].handler);
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g_test.plan= count;
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switch (count)
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{
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case NO_PLAN:
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break;
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default:
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if (count > 0)
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fprintf(tapout, "1..%d\n", count);
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break;
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}
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}
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void
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skip_all(char const *reason, ...)
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{
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va_list ap;
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va_start(ap, reason);
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fprintf(tapout, "1..0 # skip ");
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vfprintf(tapout, reason, ap);
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va_end(ap);
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exit(0);
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}
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void
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ok(int const pass, char const *fmt, ...)
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{
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va_list ap;
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va_start(ap, fmt);
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if (!pass && *g_test.todo == '\0')
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++g_test.failed;
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vemit_tap(pass, fmt, ap);
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va_end(ap);
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if (*g_test.todo != '\0')
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emit_dir("todo", g_test.todo);
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emit_endl();
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}
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void
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skip(int how_many, char const *const fmt, ...)
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{
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char reason[80];
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if (fmt && *fmt)
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{
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va_list ap;
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va_start(ap, fmt);
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vsnprintf(reason, sizeof(reason), fmt, ap);
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va_end(ap);
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}
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else
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reason[0] = '\0';
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while (how_many-- > 0)
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{
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va_list ap;
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memset((char*) &ap, 0, sizeof(ap)); /* Keep compiler happy */
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vemit_tap(1, NULL, ap);
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emit_dir("skip", reason);
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emit_endl();
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}
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}
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void
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todo_start(char const *message, ...)
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{
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va_list ap;
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va_start(ap, message);
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vsnprintf(g_test.todo, sizeof(g_test.todo), message, ap);
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va_end(ap);
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}
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void
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todo_end()
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{
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*g_test.todo = '\0';
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}
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int exit_status() {
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/*
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If there were no plan, we write one last instead.
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*/
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if (g_test.plan == NO_PLAN)
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plan(g_test.last);
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if (g_test.plan != g_test.last)
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{
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diag("%d tests planned but%s %d executed",
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g_test.plan, (g_test.plan > g_test.last ? " only" : ""), g_test.last);
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return EXIT_FAILURE;
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}
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if (g_test.failed > 0)
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{
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diag("Failed %d tests!", g_test.failed);
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return EXIT_FAILURE;
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}
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return EXIT_SUCCESS;
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}
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/**
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@mainpage Testing C and C++ using MyTAP
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@section IntroSec Introduction
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Unit tests are used to test individual components of a system. In
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contrast, functional tests usually test the entire system. The
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rationale is that each component should be correct if the system is
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to be correct. Unit tests are usually small pieces of code that
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tests an individual function, class, a module, or other unit of the
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code.
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Observe that a correctly functioning system can be built from
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"faulty" components. The problem with this approach is that as the
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system evolves, the bugs surface in unexpected ways, making
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maintenance harder.
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The advantages of using unit tests to test components of the system
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are several:
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- The unit tests can make a more thorough testing than the
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functional tests by testing correctness even for pathological use
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(which shouldn't be present in the system). This increases the
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overall robustness of the system and makes maintenance easier.
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- It is easier and faster to find problems with a malfunctioning
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component than to find problems in a malfunctioning system. This
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shortens the compile-run-edit cycle and therefore improves the
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overall performance of development.
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- The component has to support at least two uses: in the system and
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in a unit test. This leads to more generic and stable interfaces
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and in addition promotes the development of reusable components.
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For example, the following are typical functional tests:
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- Does transactions work according to specifications?
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- Can we connect a client to the server and execute statements?
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In contrast, the following are typical unit tests:
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- Can the 'String' class handle a specified list of character sets?
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- Does all operations for 'my_bitmap' produce the correct result?
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- Does all the NIST test vectors for the AES implementation encrypt
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correctly?
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@section UnitTest Writing unit tests
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The purpose of writing unit tests is to use them to drive component
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development towards a solution that passes the tests. This means that the
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unit tests has to be as complete as possible, testing at least:
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- Normal input
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- Borderline cases
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- Faulty input
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- Error handling
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- Bad environment
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@subsection NormalSubSec Normal input
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This is to test that the component have the expected behaviour.
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This is just plain simple: test that it works. For example, test
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that you can unpack what you packed, adding gives the sum, pincing
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the duck makes it quack.
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This is what everybody does when they write tests.
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@subsection BorderlineTests Borderline cases
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If you have a size anywhere for your component, does it work for
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size 1? Size 0? Sizes close to <code>UINT_MAX</code>?
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It might not be sensible to have a size 0, so in this case it is
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not a borderline case, but rather a faulty input (see @ref
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FaultyInputTests).
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@subsection FaultyInputTests Faulty input
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Does your bitmap handle 0 bits size? Well, it might not be designed
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for it, but is should <em>not</em> crash the application, but
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rather produce an error. This is called defensive programming.
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Unfortunately, adding checks for values that should just not be
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entered at all is not always practical: the checks cost cycles and
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might cost more than it's worth. For example, some functions are
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designed so that you may not give it a null pointer. In those
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cases it's not sensible to pass it <code>NULL</code> just to see it
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crash.
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Since every experienced programmer add an <code>assert()</code> to
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ensure that you get a proper failure for the debug builds when a
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null pointer passed (you add asserts too, right?), you will in this
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case instead have a controlled (early) crash in the debug build.
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@subsection ErrorHandlingTests Error handling
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This is testing that the errors your component is designed to give
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actually are produced. For example, testing that trying to open a
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non-existing file produces a sensible error code.
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@subsection BadEnvironmentTests Environment
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Sometimes, modules has to behave well even when the environment
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fails to work correctly. Typical examples are when the computer is
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out of dynamic memory or when the disk is full. You can emulate
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this by replacing, e.g., <code>malloc()</code> with your own
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version that will work for a while, but then fail. Some things are
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worth to keep in mind here:
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- Make sure to make the function fail deterministically, so that
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you really can repeat the test.
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- Make sure that it doesn't just fail immediately. The unit might
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have checks for the first case, but might actually fail some time
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in the near future.
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@section UnitTest How to structure a unit test
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In this section we will give some advice on how to structure the
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unit tests to make the development run smoothly. The basic
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structure of a test is:
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- Plan
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- Test
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- Report
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@subsection TestPlanning Plan the test
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Planning the test means telling how many tests there are. In the
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event that one of the tests causes a crash, it is then possible to
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see that there are fewer tests than expected, and print a proper
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error message.
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To plan a test, use the @c plan() function in the following manner:
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@code
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int main(int argc, char *argv[])
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{
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plan(5);
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.
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.
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.
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}
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@endcode
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If you don't call the @c plan() function, the number of tests
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executed will be printed at the end. This is intended to be used
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while developing the unit and you are constantly adding tests. It
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is not indented to be used after the unit has been released.
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@subsection TestRunning Execute the test
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To report the status of a test, the @c ok() function is used in the
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following manner:
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@code
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int main(int argc, char *argv[])
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{
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plan(5);
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ok(ducks == paddling_ducks,
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"%d ducks did not paddle", ducks - paddling_ducks);
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.
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.
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.
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}
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@endcode
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This will print a test result line on the standard output in TAP
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format, which allows TAP handling frameworks (like Test::Harness)
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to parse the status of the test.
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@subsection TestReport Report the result of the test
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At the end, a complete test report should be written, with some
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|
statistics. If the test returns EXIT_SUCCESS, all tests were
|
||
|
successful, otherwise at least one test failed.
|
||
|
|
||
|
To get a TAP compliant output and exit status, report the exit
|
||
|
status in the following manner:
|
||
|
|
||
|
@code
|
||
|
int main(int argc, char *argv[])
|
||
|
{
|
||
|
plan(5);
|
||
|
ok(ducks == paddling_ducks,
|
||
|
"%d ducks did not paddle", ducks - paddling_ducks);
|
||
|
.
|
||
|
.
|
||
|
.
|
||
|
return exit_status();
|
||
|
}
|
||
|
@endcode
|
||
|
|
||
|
@section DontDoThis Ways to not do unit testing
|
||
|
|
||
|
In this section, we'll go through some quite common ways to write
|
||
|
tests that are <em>not</em> a good idea.
|
||
|
|
||
|
@subsection BreadthFirstTests Doing breadth-first testing
|
||
|
|
||
|
If you're writing a library with several functions, don't test all
|
||
|
functions using size 1, then all functions using size 2, etc. If a
|
||
|
test for size 42 fails, you have no easy way of tracking down why
|
||
|
it failed.
|
||
|
|
||
|
It is better to concentrate on getting one function to work at a
|
||
|
time, which means that you test each function for all sizes that
|
||
|
you think is reasonable. Then you continue with the next function,
|
||
|
doing the same. This is usually also the way that a library is
|
||
|
developed (one function at a time) so stick to testing that is
|
||
|
appropriate for now the unit is developed.
|
||
|
|
||
|
@subsection JustToBeSafeTest Writing unnecessarily large tests
|
||
|
|
||
|
Don't write tests that use parameters in the range 1-1024 unless
|
||
|
you have a very good reason to believe that the component will
|
||
|
succeed for 562 but fail for 564 (the numbers picked are just
|
||
|
examples).
|
||
|
|
||
|
It is very common to write extensive tests "just to be safe."
|
||
|
Having a test suite with a lot of values might give you a warm
|
||
|
fuzzy feeling, but it doesn't really help you find the bugs. Good
|
||
|
tests fail; seriously, if you write a test that you expect to
|
||
|
succeed, you don't need to write it. If you think that it
|
||
|
<em>might</em> fail, <em>then</em> you should write it.
|
||
|
|
||
|
Don't take this as an excuse to avoid writing any tests at all
|
||
|
"since I make no mistakes" (when it comes to this, there are two
|
||
|
kinds of people: those who admit they make mistakes, and those who
|
||
|
don't); rather, this means that there is no reason to test that
|
||
|
using a buffer with size 100 works when you have a test for buffer
|
||
|
size 96.
|
||
|
|
||
|
The drawback is that the test suite takes longer to run, for little
|
||
|
or no benefit. It is acceptable to do a exhaustive test if it
|
||
|
doesn't take too long to run and it is quite common to do an
|
||
|
exhaustive test of a function for a small set of values.
|
||
|
Use your judgment to decide what is excessive: your milage may
|
||
|
vary.
|
||
|
*/
|
||
|
|
||
|
/**
|
||
|
@example simple.t.c
|
||
|
|
||
|
This is an simple example of how to write a test using the
|
||
|
library. The output of this program is:
|
||
|
|
||
|
@code
|
||
|
1..1
|
||
|
# Testing basic functions
|
||
|
ok 1 - Testing gcs()
|
||
|
@endcode
|
||
|
|
||
|
The basic structure is: plan the number of test points using the
|
||
|
plan() function, perform the test and write out the result of each
|
||
|
test point using the ok() function, print out a diagnostics message
|
||
|
using diag(), and report the result of the test by calling the
|
||
|
exit_status() function. Observe that this test does excessive
|
||
|
testing (see @ref JustToBeSafeTest), but the test point doesn't
|
||
|
take very long time.
|
||
|
*/
|
||
|
|
||
|
/**
|
||
|
@example todo.t.c
|
||
|
|
||
|
This example demonstrates how to use the <code>todo_start()</code>
|
||
|
and <code>todo_end()</code> function to mark a sequence of tests to
|
||
|
be done. Observe that the tests are assumed to fail: if any test
|
||
|
succeeds, it is considered a "bonus".
|
||
|
*/
|
||
|
|
||
|
/**
|
||
|
@example skip.t.c
|
||
|
|
||
|
This is an example of how the <code>SKIP_BLOCK_IF</code> can be
|
||
|
used to skip a predetermined number of tests. Observe that the
|
||
|
macro actually skips the following statement, but it's not sensible
|
||
|
to use anything than a block.
|
||
|
*/
|
||
|
|
||
|
/**
|
||
|
@example skip_all.t.c
|
||
|
|
||
|
Sometimes, you skip an entire test because it's testing a feature
|
||
|
that doesn't exist on the system that you're testing. To skip an
|
||
|
entire test, use the <code>skip_all()</code> function according to
|
||
|
this example.
|
||
|
*/
|