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unit_testing.c
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unit_testing.c
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#include <unistd.h>
#include <sys/types.h>
#include <sys/wait.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <fcntl.h>
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stddef.h>
#include <error.h>
#include <mqueue.h>
#include <limits.h>
#include <pthread.h>
#include <poll.h>
#include <argp.h>
#include <ctype.h>
#include <assert.h>
#include <stdarg.h>
#include "unit_testing.h"
#include "util.h"
/*
Global variables
*/
struct program_arguments ARGS = {
.show_tests = 0,
.verbose = 0,
.use_color = 1,
.fork = 1,
.ncore_list = 1 , .core_list = { 1, },
.nterm_list = 1 , .term_list = { 0, },
.ntests = 0,
.tests = { }
};
#define INDENT_STACK_MAX 128
#define INDENT_STEP 8 /* How much INDENT increases the space */
#define BLACK "\033[30;7m"
#define RED "\033[31;1m"
#define GREEN "\033[32;1m"
#define YELLOW "\033[33;1m"
#define BLUE "\033[34;1m"
#define MAGENTA "\033[35;1m"
#define CYAN "\033[36;1m"
#define WHITE "\033[37;1m"
#define NORMAL "\033[0m"
static int INDENT_STACK[INDENT_STACK_MAX]; /* Saved indents */
static int INDENT_STACK_SIZE=0; /* Current no fo saved indents */
static int INDENT_POS = 0; /* Current indent */
static int CURRENT_POS = 0; /* Current print pos beyond the indent */
static int EMIT_INDENT = 1; /* Whether wwe should emit an indent */
int FLAG_FAILURE=0; /* Flag failure in assert macros. */
static inline void INDENT() {
assert(INDENT_STACK_SIZE < INDENT_STACK_MAX);
INDENT_STACK[INDENT_STACK_SIZE++] = INDENT_POS;
INDENT_POS += INDENT_STEP;
}
static inline void UNINDENT() {
assert(INDENT_STACK_SIZE>0);
INDENT_POS = INDENT_STACK[--INDENT_STACK_SIZE];
}
static inline void TAB() {
assert(INDENT_STACK_SIZE < INDENT_STACK_MAX);
INDENT_STACK[INDENT_STACK_SIZE++] = INDENT_POS;
INDENT_POS += CURRENT_POS;
}
static inline const char* COLOR(const char* msg, const char* color)
{
static char buffer[256];
int tty = ARGS.use_color && isatty(fileno(stderr));
snprintf(buffer,256, "%s%s%s",
tty? color : "",
msg,
tty ? "\033[0m" : "");
return buffer;
}
void MSG(const char* format, ...)
{
/* put the output in a memory buffer */
char* buffer = NULL;
size_t buffer_size;
FILE* output = open_memstream(&buffer, &buffer_size);
va_list ap;
va_start (ap, format);
vfprintf (output, format, ap);
va_end (ap);
fclose(output);
/* Now, write to stderr */
for(size_t i=0;i<buffer_size;i++) {
if(EMIT_INDENT) {
for(int c=0; c< INDENT_POS; c++)
fputc(' ', stderr);
EMIT_INDENT = 0;
}
if(buffer[i]=='\n') {
EMIT_INDENT=1;
CURRENT_POS = 0;
} else {
CURRENT_POS ++;
}
fputc(buffer[i], stderr);
}
free(buffer);
}
/*
Execution utilities
*/
/*
Terminal proxy.
---------------
This class is used to test terminals. Usage in a test:
term_proxy tp;
term_proxy_init(&tp, 1); // test proxy terminal 1
file1 = OpenTerminal(1); // open terminal 1
sendme(&tp, "hello");
char buffer[5];
Read(file1, buffer, 5);
ASSERT( memcmp(buffer, "hello", 5) == 0 );
expect(&tp, "hi there");
Write(file1, "hi there", 8);
term_proxy_close(&tp); // will signal errror if expect(...) failed.
*/
/* Open a terminal fifo: e.g., open_fifo("con",2) */
int open_fifo(const char* name, uint n)
{
char fname[NAME_MAX];
snprintf(fname, NAME_MAX, "%s%d", name, n);
int fd;
CHECK(fd = open(fname, O_RDWR|O_NONBLOCK));
/* drain fifo */
char buf[256];
while(1) {
int rc = read(fd, buf, 256);
if(rc==-1) {
if(errno==EAGAIN)
break;
else {
assert(errno==EINTR);
continue;
}
}
}
return fd;
}
struct proxy_daemon;
typedef void (*PatternProc)(struct proxy_daemon*, const char*);
/* A thread that "uses" the terminal fifos */
typedef struct proxy_daemon {
pthread_t thread; /* Daemon thread */
PatternProc proc; /* Pattern processor function */
int complete; /* Flag that the VM will not access the terminal any more. */
int fd; /* The fd */
rlnode pattern; /* The pattern list */
pthread_mutex_t mx; /* Monitor mutex */
pthread_cond_t pat; /* Signal that there is a new pattern, or that the VM is done. */
} proxy_daemon;
/* A proxy has a terminal and a keyboard daemon */
typedef struct term_proxy
{
uint term;
proxy_daemon con, kbd;
} term_proxy;
void* term_proxy_daemon(void*);
void term_proxy_daemon_init(proxy_daemon* this, const char* fifoname, uint fifono, PatternProc proc)
{
this->proc = proc;
this->complete = 0;
this->fd = open_fifo(fifoname, fifono);
rlnode_init(&this->pattern, NULL);
CHECKRC(pthread_mutex_init(& this->mx, NULL));
CHECKRC(pthread_cond_init(& this->pat, NULL));
/* Create daemon thread with a full signal mask */
sigset_t fullmask, oldmask;
CHECK(sigfillset(&fullmask));
CHECKRC(pthread_sigmask(SIG_SETMASK, &fullmask, &oldmask));
CHECKRC(pthread_create(& this->thread, NULL, term_proxy_daemon, this));
char thread_name[16];
CHECK(snprintf(thread_name, 16, "%s%d",fifoname,fifono));
CHECKRC(pthread_setname_np(this->thread, thread_name));
/* Restore signal mask */
CHECKRC(pthread_sigmask(SIG_SETMASK, &oldmask, NULL));
}
void term_proxy_daemon_add(proxy_daemon* this, const char* pattern)
{
CHECKRC(pthread_mutex_lock(& this->mx));
assert(pattern!=NULL);
assert(! this->complete);
rlnode* newnode = (rlnode*)malloc(sizeof(rlnode));
if(newnode==NULL) FATAL("Out of memory!");
rlnode_init(newnode, strdup(pattern));
rlist_push_back(& this->pattern , newnode);
CHECKRC(pthread_cond_signal(& this->pat));
CHECKRC(pthread_mutex_unlock(& this->mx));
}
char* term_proxy_daemon_get(proxy_daemon* this)
{
char* pattern = NULL;
CHECKRC(pthread_mutex_lock(& this->mx));
/* Wait for pattern(s) or completion */
while( (! this->complete) && is_rlist_empty(& this->pattern) )
CHECKRC(pthread_cond_wait(&this->pat, &this->mx));
/* If there is a pattern, return it */
if(! is_rlist_empty(& this->pattern)) {
rlnode* node = rlist_pop_front(& this->pattern);
pattern = (char*) (node->obj);
free(node);
}
CHECKRC(pthread_mutex_unlock(& this->mx));
return pattern;
}
void term_proxy_daemon_close(proxy_daemon* this)
{
CHECKRC(pthread_mutex_lock(& this->mx));
this->complete = 1;
CHECKRC(pthread_cond_signal(& this->pat));
CHECKRC(pthread_mutex_unlock(& this->mx));
CHECKRC(pthread_join(this->thread, NULL));
}
void* term_proxy_daemon(void* arg)
{
proxy_daemon* this = (proxy_daemon*)arg;
while(1) {
char* pattern = term_proxy_daemon_get(this);
if(pattern==NULL) break;
this->proc(this, pattern);
free(pattern);
}
CHECK(close(this->fd));
return NULL;
}
void term_proxy_close(term_proxy* this)
{
term_proxy_daemon_close(& this->con);
term_proxy_daemon_close(& this->kbd);
}
void term_proxy_expect(term_proxy* this, const char* pattern)
{
term_proxy_daemon_add(& this->con, pattern);
}
void term_proxy_sendme(term_proxy* this, const char* pattern)
{
term_proxy_daemon_add(& this->kbd, pattern);
}
int term_proxy_daemon_complete(proxy_daemon* this)
{
int complete;
CHECKRC(pthread_mutex_lock(& this->mx));
complete = this->complete;
CHECKRC(pthread_mutex_unlock(& this->mx));
return complete;
}
/*
Read fd and check that it matches pattern.
Return when there is a mismatch, or there is no available
input and the daemon is marked 'complete'.
*/
void con_proc(proxy_daemon* this, const char* pattern)
{
const char* pat = pattern;
int plen = strlen(pat);
int patlen = plen;
int complete = 0;
struct pollfd fdp = { .fd = this->fd, .events = POLLIN };
char coninput[1024];
int rc;
/* completion is stable, so we only need to check it if it is false */
#define COMPLETE (complete || (complete=term_proxy_daemon_complete(this)))
while(plen > 0) {
/* Poll and if we are not complete poll again, for 100ms */
int have_data;
not_ready:
have_data = 0;
do {
int timeout = (COMPLETE)?0:100;
poll(&fdp, 1, timeout);
assert( (fdp.revents & (POLLERR|POLLHUP|POLLNVAL)) == 0 );
have_data = fdp.revents & POLLIN;
} while(! (have_data || COMPLETE ));
if(! have_data) {
break;
}
assert(have_data);
/* Read input and check it, skipping EINTR */
while( (rc = read(this->fd, coninput, (plen<1024)? plen : 1024)) == -1
&& errno==EINTR) ;
if(rc==-1 && errno==EAGAIN)
goto not_ready;
CHECK(rc); /* This is fatal on error! */
assert(rc>0); /* We should not get rc==0 ! */
assert(rc<=1024); /* We should not get rc>1024 ! */
/* Mismatch ? */
int matched = (memcmp(pat, coninput, rc) == 0);
if(! matched) {
break_mismatch: __attribute__((unused));
break;
}
/* ok, either we are not 'complete' or we are matched */
pat += rc;
plen -= rc;
}
checking_time: __attribute__((unused));
ASSERT_MSG(plen==0, "Mismatched expect(\"%.20s%s\") at pos %d\n",
pattern,
(strlen(pattern)>20)?"...":"",
patlen - plen
);
#undef COMPLETE
}
/* Write pattern to fd, check that the whole thing is written before 'complete'. */
void kbd_proc(proxy_daemon* this, const char* pattern)
{
size_t lpattern = strlen(pattern);
const char* pat = pattern;
size_t lpat = lpattern;
struct pollfd fdp = { .fd = this->fd, .events = POLLOUT };
while(*pat != '\0') {
/* If we are not complete, poll the fd for reading, for 100ms */
while(! term_proxy_daemon_complete(this)) {
poll(&fdp, 1, 100);
assert( (fdp.revents & (POLLERR|POLLHUP|POLLNVAL)) == 0 );
if(fdp.revents & POLLOUT) break;
}
/* Save complete status */
int oldcomplete = term_proxy_daemon_complete(this);
/* Write output, skipping EINTR, until EAGAIN, or input exhausted. */
while(*pat != '\0') {
int rc;
while( (rc = write(this->fd, pat, lpat))==-1 && errno==EINTR );
if(rc>0) {
pat += rc;
lpat -= rc;
}
else {
assert(rc==-1);
assert(errno==EAGAIN || errno==EPIPE);
if(errno==EPIPE) {
ASSERT_MSG(0, "The kbd fifo was closed!\n");
abort();
}
assert(errno==EAGAIN);
if(oldcomplete) goto finish;
break;
}
}
}
finish:
ASSERT_MSG(*pat=='\0', "Sendme(\"%.50s%s\") failed\n",
pattern,
(lpattern>50)?"...":"");
}
void term_proxy_init(term_proxy* this, uint term)
{
assert(term < MAX_TERMINALS);
this->term = term;
/* Start the daemons */
term_proxy_daemon_init(&this->con, "con", term, con_proc);
term_proxy_daemon_init(&this->kbd, "kbd", term, kbd_proc);
}
term_proxy PROXY[MAX_TERMINALS];
void expect(uint term, const char* pattern)
{
assert(term<bios_serial_ports());
term_proxy_expect(& PROXY[term], pattern);
}
void sendme(uint term, const char* pattern)
{
assert(term<bios_serial_ports());
term_proxy_sendme(& PROXY[term], pattern);
}
/* Execute procfunc in a subprocess, return
1 if it exited normally, 0 otherwise.
When the subprocess starts, it runs terminal proxies
on each of the 4 terminals and makes them available to test
code.
The subprocess will be killed after 'timeout' seconds, if it
has not finished already.
*/
int execute_fork(void (*procfunc)(void*), void* arg, unsigned int timeout)
{
pid_t pid;
sigset_t waitmask, oldmask;
/* Block SIGCHLD only */
CHECK(sigemptyset(&waitmask));
CHECK(sigaddset(&waitmask, SIGCHLD));
CHECK(sigprocmask(SIG_BLOCK, &waitmask, &oldmask));
/* Fork */
CHECK(pid = fork());
if(pid==0) {
/* Subprocess */
FLAG_FAILURE=0;
procfunc(arg);
if(FLAG_FAILURE) abort();
exit(129);
}
/* Block SIGALRM also */
CHECK(sigaddset(&waitmask, SIGALRM));
CHECK(sigprocmask(SIG_BLOCK, &waitmask, NULL));
/* Set the alarm */
alarm(timeout);
/* Wait for a signal. If SIGCHLD arrives first, all is ok. */
int signo;
CHECKRC(sigwait(&waitmask, &signo));
/* Cancel pending alarm */
alarm(0);
/* If the time ran out, kill the child. */
if(signo==SIGALRM) {
ASSERT_MSG(0, "Test timed out\n");
kill(pid, SIGTERM);
}
/* Wait the child */
int status;
waitpid(pid, &status, 0);
/* Restore signal mask ?*/
sigprocmask(SIG_SETMASK, &oldmask, NULL);
return status;
}
int execute_nofork(void (*procfunc)(void*), void* arg, unsigned int timeout)
{
FLAG_FAILURE=0;
/* Note: timeout is ignored, we allow the test to run forever!
It is the user's job to interrupt!
*/
procfunc(arg);
/* Here, we could allow tests to continue */
if(FLAG_FAILURE) {
/* Here, we could allow tests to continue, still reporting
failure. However, since --nofork is most often used for
testing in the debugger, actually dumping the process
seems more useful!
*/
abort();
}
return W_EXITCODE(129,0);
}
int execute(void (*procfunc)(void*), void* arg, unsigned int timeout)
{
if(ARGS.fork)
return execute_fork(procfunc, arg, timeout);
else
return execute_nofork(procfunc, arg, timeout);
}
struct boot_test_descriptor
{
int ncores;
int nterm;
Task bootfunc;
int argl;
void* args;
};
void boot_test_wrapper(void* arg)
{
struct boot_test_descriptor* d = arg;
for(uint i=0;i<d->nterm; i++)
term_proxy_init(&PROXY[i], i);
boot(d->ncores, d->nterm, d->bootfunc, d->argl, d->args);
for(uint i=0;i<d->nterm; i++)
term_proxy_close(&PROXY[i]);
}
int execute_boot(int ncores, int nterm, Task bootfunc, int argl, void* args, unsigned int timeout)
{
struct boot_test_descriptor d = {
.ncores=ncores, .nterm=nterm, .bootfunc=bootfunc, .argl=argl, .args=args
};
return execute(boot_test_wrapper, &d, timeout);
}
/* Fill in memory with a weird value: 10101010 or 0xAA */
#define FUDGE(var) memset(&(var), 170, sizeof(var))
/*
Test organization
*/
/* Macros for declaring static arrays of tests */
int run_boot_test(const Test* test, uint ncores, uint nterm, int argl, void* args)
{
int result=1;
int status;
int skipped = ! ((ncores >= test->minimum_cores) && (nterm >= test->minimum_terminals));
assert(test->type == BOOT_FUNC);
if(! skipped) {
status = execute_boot(ncores, nterm, test->boot, argl, args, test->timeout);
result = WIFEXITED(status) && WEXITSTATUS(status)==129 ? 1 : 0;
if(WIFSIGNALED(status))
MSG("Test crashed, signal=%d (%s)\n",
WTERMSIG(status), strsignal(WTERMSIG(status)));
}
MSG("%-52s [cores=%2d,term=%1d]:", COLOR(test->name,WHITE), ncores, nterm);
MSG(" %s\n", skipped ? COLOR("skipped",CYAN) :
(result? COLOR("ok",GREEN) : COLOR("*** FAILED ***",RED)) );
return result;
}
/** @internal */
typedef struct
{
unsigned int number_of_tests;
unsigned int successful;
} Results;
#define RESULTS_INIT ((Results){ 0, 0 })
/* helper for run_test */
int run_suite(const char* name, const Test** tests, Results* results);
int run_test(const Test* test)
{
int result=1;
int status;
switch(test->type) {
case BOOT_FUNC:
for(int i=0; i<ARGS.ncore_list; i++)
for(int j=0; j<ARGS.nterm_list; j++)
result &= run_boot_test(test, ARGS.core_list[i], ARGS.term_list[j], 0, NULL);
break;
case BARE_FUNC:
status = execute(test->bare, NULL, test->timeout);
result = WIFEXITED(status) && WEXITSTATUS(status)==129 ? 1 : 0;
if(WIFSIGNALED(status))
MSG("Test crashed, signal=%d (%s)\n",
WTERMSIG(status), strsignal(WTERMSIG(status)));
MSG("%-70s:", COLOR(test->name,WHITE));
MSG(" %s\n", (result? COLOR("ok",GREEN) : COLOR("*** FAILED ***",RED)));
break;
case SUITE_FUNC:
result = run_suite(test->name, test->suite, NULL);
MSG("%-70s:", COLOR(test->name,WHITE));
MSG(" %s\n", (result? COLOR("ok",GREEN) : COLOR("*** FAILED ***",RED)));
break;
case NO_FUNC:
return 1;
default:
MSG("Internal error: Test: %s: Unknown test type: %d\n", test->name, test->type);
return 0;
}
if(!result && ARGS.verbose>0) {
/* print doc of failed test */
INDENT();
MSG("description: ");
TAB(); MSG("%s\n", test->description); UNINDENT();
UNINDENT();
}
return result;
}
int run_suite(const char* name, const Test** tests, Results* results)
{
if(results==NULL) {
Results dummy = RESULTS_INIT;
return run_suite(name, tests, &dummy);
}
MSG("running suite: %s\n", COLOR(name,YELLOW));
INDENT();
for(const Test** t = tests; *t!=NULL; t++) {
int testres = run_test(*t);
results->number_of_tests ++;
if(testres) results->successful ++;
}
MSG("suite %s completed [tests=%d, failed=%d]\n", COLOR(name,YELLOW),
results->number_of_tests,
results->number_of_tests - results->successful
);
UNINDENT();
return results->number_of_tests==results->successful;
}
/*
Testing the test framework itself!
*/
BARE_TEST(internal_success,
"A test that succeeds."
)
{
ASSERT(1);
}
BARE_TEST(internal_failure,
"A test that fails by assertion."
)
{
ASSERT(0);
}
BARE_TEST(internal_timeout,
"A test that fails by timeout.",
.timeout = 1
)
{
sleep(5);
}
BARE_TEST(internal_skip,
"A test that is skipped",
.minimum_terminals = UINT_MAX
)
{
}
TEST_SUITE(internal,
"A suite of internal tests, testing the test framework itself."
)
{
&internal_success,
&internal_failure,
&internal_timeout,
&internal_skip,
NULL
};
/*
User tests go into the user_tests suite
*/
extern const Test user_tests;
/* This is the number of nulls in all_tests_available */
#define MAX_TESTS_AVAILABLE 64
static int current_tests_available = 0;
TEST_SUITE(all_tests_available,"Used by find_test()")
{
//&internal,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL,
NULL
};
int register_test(const Test* test)
{
if(current_tests_available < MAX_TESTS_AVAILABLE)
{
__suite_all_tests_available[current_tests_available++] = test;
return 0;
}
return -1;
}
/*
Main: arguments
*/
const char *argp_program_version =
"validate_api 2.1";
const char *argp_program_bug_address =
"<[email protected]>";
/* Program documentation. */
static char doc[] =
"A testing and validation program for the tinyos2 API.\n"
"\vUse this program, by providing a list of cores, a list of terminals and "
"a list of tests. All arguments are optional. "
"For example,\n\n ./validate_api -c 1,2,4 --term=0,2 basic_tests\n\n"
"will execute each test in the 'basic_tests' suite, on 6 different virtual machines, "
"one for each combination of the number of cores and number of terminals."
;
/* A description of the arguments we accept. */
static char args_doc[] = " TEST ... ";
static struct argp_option options [] = {
{"cores", 'c', "<cores>", 0, "List of number of cores" },
{"nofork", 'f', 0, 0, "Don't fork tests to a different process" },
{"fork", 'F', 0, 0, "Force fork for tests to a different process"},
{"term", 't', "<terminals>", 0, "List of number of terminals" },
{"list", 'l', 0, 0, "Show a list of available tests" },
{"verbose", 'v', 0, 0, "Be verbose: show test descriptions"},
{"nocolor", 'n', 0, 0, "Do not color the output"},
{ NULL }
};
static const struct Test* find_test(const char* name, const struct Test* test)
{
if(strcmp(name, test->name)==0)
return test;
else if(test->type == SUITE_FUNC) {
for(const struct Test** T = test->suite; *T !=NULL; T++ ) {
const struct Test* t = find_test(name, *T);
if(t!=NULL) return t;
}
}
return NULL;
}
/* use this comparator for sorting the numbers */
static int cmpint(const void* ap, const void* bp) {
return *(int*)bp < *(int*)ap;
}
/*
Parse a comma-separated list of small integers, such that
each integer n is n>=from and n<=to.
If sucessful, sort and store the values starting at nlist,
whose length must be big enough (up to to-from+1), but might
be smaller. Duplicate values are only stored once.
On failure (malformed input or out-of-range), do
not disturb the data pointed by nlist.
Return 1 for success and 0 for failure.
*/
static int parse_int_list(char* arg, int* nlen, int* nlist, int from, int to)
{
int args[to-from+1]; /* Temporary storage of data */
int i=0;
for(char* token=strtok(arg,","); token!=NULL; token=strtok(NULL,","))
{
char* endptr;
int num = strtol(token, &endptr, 10 );
/* fail on malformed or out-of-range input */
if(endptr==token || *endptr!='\0') return 0;
if(num<from || num > to) return 0;
/* check for duplicate */
int j;
for(j=0; j<i; j++)
if(num==nlist[j]) break;
if(j < i) continue; /* Duplicates are not an error */
/* store new value */
args[i++] = num;
}
/* Now sort, copy and exit */
qsort(args, i, sizeof(int), cmpint);
*nlen = i;
nlist = memcpy(nlist, args, i*sizeof(int));
return *nlen > 0;
}
static const Test* __default_test;
static error_t
parse_options(int key, char *arg, struct argp_state *state)
{
const struct Test* test;
switch(key)
{
case 'l':
ARGS.show_tests = 1;
break;
case 'v':
ARGS.verbose ++;
break;
case 'n':
ARGS.use_color = 0;
break;
case 'F':
ARGS.fork = 1;
break;
case 'f':
ARGS.fork = 0;
break;
case 'c':
if(! parse_int_list(arg, &ARGS.ncore_list, ARGS.core_list, 1, MAX_CORES))
argp_error(state, "Error in parsing list of cores: %s\n",arg);
break;
case 't':
if(! parse_int_list(arg, &ARGS.nterm_list, ARGS.term_list, 0, MAX_TERMINALS))
argp_error(state, "Error in parsing list of terminals: %s\n",arg);
break;
case ARGP_KEY_ARG:
if(ARGS.ntests >= MAX_TESTS) {
argp_error(state, "Number of tests too large (maximum=%d)",MAX_TESTS);
break;
}
test = find_test(arg, &all_tests_available);
if(test!=NULL)
ARGS.tests[ARGS.ntests++] = test;
else
argp_error(state, "Unknown test: %s\n",arg);
break;
case ARGP_KEY_NO_ARGS:
ARGS.tests[ARGS.ntests++] = __default_test;
break;
#if 0
/* For future versions */
case ARGP_KEY_ARGS:
fprintf(stderr,"ARGS arg=%s\n", arg);
break;
case ARGP_KEY_INIT:
fprintf(stderr,"INIT arg=%s\n", arg);
break;
case ARGP_KEY_END:
fprintf(stderr,"END arg=%s\n", arg);
break;
#endif
default:
return ARGP_ERR_UNKNOWN;
}
return 0;
}
static struct argp argp = { options, parse_options, args_doc, doc };
void show_suite(const Test*);
void show_test(const Test* test)
{
if(test->type == SUITE_FUNC)
show_suite(test);