int add_defined (struct fsm *net, char *string) {
struct defined *defined, *defined_prev;
int redefine;
redefine = 0;
if (net == NULL) { return 0; }
fsm_count(net);
if (defines == NULL) {
defined = xxmalloc(sizeof(struct defined));
defines = defined;
defined->next = NULL;
} else {
for (defined = defines; defined != NULL; defined = defined->next) {
defined_prev = defined;
if (strcmp(defined->name, string) == 0) {
redefine = 1;
break;
}
}
if (redefine == 0) {
defined_prev->next = xxmalloc(sizeof(struct defined));
defined = defined_prev->next;
defined->next = NULL;
}
}
if (redefine) {
fsm_destroy(defined->net);
xxfree(defined->name);
}
defined->name = xxstrdup(string);
defined->net = net;
return(redefine);
}
struct apply_handle *apply_init(struct fsm *net) {
struct apply_handle *h;
srand((unsigned int) time(NULL));
h = malloc(sizeof(struct apply_handle));
/* Init */
h->iterate_old = 0;
h->iterator = 0;
h->instring = NULL;
h->flag_list = NULL;
h->flag_lookup = NULL;
h->last_net = net;
h->outstring = xxmalloc(sizeof(char)*DEFAULT_OUTSTRING_SIZE);
h->outstringtop = DEFAULT_OUTSTRING_SIZE;
*(h->outstring) = '\0';
h->gstates = net->states;
h->gsigma = net->sigma;
h->printcount = 1;
apply_create_statemap(h, net);
h->searchstack = xxmalloc(sizeof(struct searchstack) * DEFAULT_STACK_SIZE);
h->apply_stack_top = DEFAULT_STACK_SIZE;
apply_stack_clear(h);
apply_create_sigarray(h, net);
return(h);
}
static void * my_memalign_hook (size_t size, size_t alignment, const void *) {
// Check for non power-of-two alignment, or mistake in size.
if ((alignment == 0) ||
(alignment & (alignment - 1)))
{
return NULL;
}
// Try to just allocate an object of the requested size.
// If it happens to be aligned properly, just return it.
void * ptr = xxmalloc (size);
if (((size_t) ptr & (alignment - 1)) == (size_t) ptr) {
// It is already aligned just fine; return it.
return ptr;
}
// It was not aligned as requested: free the object.
xxfree (ptr);
// Now get a big chunk of memory and align the object within it.
// NOTE: this REQUIRES that the underlying allocator be able
// to free the aligned object, or ignore the free request.
void * buf = xxmalloc (2 * alignment + size);
void * alignedPtr = (void *) (((size_t) buf + alignment - 1) & ~(alignment - 1));
return alignedPtr;
}
static void sigma_to_pairs(struct fsm *net) {
int i, j, x, y, z, next_x = 0;
struct fsm_state *fsm;
fsm = net->states;
epsilon_symbol = -1;
maxsigma = sigma_max(net->sigma);
maxsigma++;
single_sigma_array = xxmalloc(2*maxsigma*maxsigma*sizeof(int));
double_sigma_array = xxmalloc(maxsigma*maxsigma*sizeof(int));
for (i=0; i < maxsigma; i++) {
for (j=0; j< maxsigma; j++) {
*(double_sigma_array+maxsigma*i+j) = -1;
}
}
/* f(x) -> y,z sigma pair */
/* f(y,z) -> x simple entry */
/* if exists f(n) <-> EPSILON, EPSILON, save n */
/* symbol(x) x>=1 */
/* Forward mapping: */
/* *(double_sigma_array+maxsigma*in+out) */
/* Backmapping: */
/* *(single_sigma_array+(symbol*2) = in(symbol) */
/* *(single_sigma_array+(symbol*2+1) = out(symbol) */
/* Table for checking whether a state is final */
x = 0;
net->arity = 1;
for (i=0; (fsm+i)->state_no != -1; i++) {
y = (fsm+i)->in;
z = (fsm+i)->out;
if ((y == -1) || (z == -1))
continue;
if (y != z || y == UNKNOWN || z == UNKNOWN)
net->arity = 2;
if (*(double_sigma_array+maxsigma*y+z) == -1) {
*(double_sigma_array+maxsigma*y+z) = x;
*(single_sigma_array+next_x) = y;
next_x++;
*(single_sigma_array+next_x) = z;
next_x++;
if (y == EPSILON && z == EPSILON) {
epsilon_symbol = x;
}
x++;
}
}
num_symbols = x;
}
static void memoize_e_closure(struct fsm_state *fsm) {
int i, state, laststate, *redcheck;
struct e_closure_memo *ptr;
e_closure_memo = xxcalloc(num_states,sizeof(struct e_closure_memo));
marktable = xxcalloc(num_states,sizeof(int));
/* Table for avoiding redundant epsilon arcs in closure */
redcheck = xxmalloc(num_states*sizeof(int));
for (i=0; i < num_states; i++) {
ptr = e_closure_memo+i;
ptr->state = i;
ptr->target = NULL;
*(redcheck+i) = -1;
}
laststate = -1;
for (i=0; ;i++) {
state = (fsm+i)->state_no;
if (state != laststate) {
if (!int_stack_isempty()) {
deterministic = 0;
ptr = e_closure_memo+laststate;
ptr->target = e_closure_memo+int_stack_pop();
while (!int_stack_isempty()) {
ptr->next = xxmalloc(sizeof(struct e_closure_memo));
ptr->next->state = laststate;
ptr->next->target = e_closure_memo+int_stack_pop();
ptr->next->next = NULL;
ptr = ptr->next;
}
}
}
if (state == -1) {
break;
}
if ((fsm+i)->target == -1) {
continue;
}
/* Check if we have a redundant epsilon arc */
if ((fsm+i)->in == EPSILON && (fsm+i)->out == EPSILON) {
if (*(redcheck+((fsm+i)->target)) != (fsm+i)->state_no) {
if ((fsm+i)->target != (fsm+i)->state_no) {
int_stack_push((fsm+i)->target);
*(redcheck+((fsm+i)->target)) = (fsm+i)->state_no;
}
}
laststate = state;
}
}
xxfree(redcheck);
}
void apply_create_sigarray(struct apply_handle *h, struct fsm *net) {
struct sigma *sig;
struct fsm_state *fsm;
int i, maxsigma;
fsm = net->states;
maxsigma = sigma_max(net->sigma);
// Default size created at init, resized later if necessary
h->sigmatch_array = xxcalloc(1024,sizeof(struct sigmatch_array));
h->sigmatch_array_size = 1024;
h->sigs = xxmalloc(sizeof(char **)*(maxsigma+1));
h->has_flags = 0;
h->flag_list = NULL;
/* Malloc first array of trie and store trie ptrs to free later */
h->sigma_trie = xxcalloc(256,sizeof(struct sigma_trie));
h->sigma_trie_arrays = xxmalloc(sizeof(struct sigma_trie_arrays));
h->sigma_trie_arrays->arr = h->sigma_trie;
h->sigma_trie_arrays->next = NULL;
for (i=0;i<256;i++)
(h->sigma_trie+i)->next = NULL;
for (sig = h->gsigma; sig != NULL && sig->number != -1; sig = sig->next) {
if (flag_check(sig->symbol)) {
h->has_flags = 1;
apply_add_flag(h, flag_get_name(sig->symbol));
}
*(h->sigs+(sig->number)) = sig->symbol;
/* Add sigma entry to trie */
if (sig->number > IDENTITY) {
apply_add_sigma_trie(h, sig->number, sig->symbol);
}
}
if (h->has_flags) {
h->flag_lookup = xxmalloc(sizeof(struct flag_lookup)*(maxsigma+1));
for (i=0; i <= maxsigma; i++) {
(h->flag_lookup+i)->type = 0;
(h->flag_lookup+i)->name = NULL;
(h->flag_lookup+i)->value = NULL;
}
for (sig = h->gsigma; sig != NULL ; sig = sig->next) {
if (flag_check(sig->symbol)) {
(h->flag_lookup+sig->number)->type = flag_get_type(sig->symbol);
(h->flag_lookup+sig->number)->name = flag_get_name(sig->symbol);
(h->flag_lookup+sig->number)->value = flag_get_value(sig->symbol);
}
}
}
}
static void * my_realloc_hook (void * ptr, size_t sz, const void *) {
// NULL ptr = malloc.
if (ptr == NULL) {
return xxmalloc(sz);
}
if (sz == 0) {
xxfree (ptr);
#if defined(__APPLE__)
// 0 size = free. We return a small object. This behavior is
// apparently required under Mac OS X and optional under POSIX.
return xxmalloc(1);
#else
// For POSIX, don't return anything.
return NULL;
#endif
}
size_t objSize = xxmalloc_usable_size(ptr);
#if 0
// Custom logic here to ensure we only do a logarithmic number of
// reallocations (with a constant space overhead).
// Don't change size if the object is shrinking by less than half.
if ((objSize / 2 < sz) && (sz <= objSize)) {
// Do nothing.
return ptr;
}
// If the object is growing by less than 2X, double it.
if ((objSize < sz) && (sz < objSize * 2)) {
sz = objSize * 2;
}
#endif
void * buf = xxmalloc(sz);
if (buf != NULL) {
// Successful malloc.
// Copy the contents of the original object
// up to the size of the new block.
size_t minSize = (objSize < sz) ? objSize : sz;
memcpy (buf, ptr, minSize);
xxfree (ptr);
}
// Return a pointer to the new one.
return buf;
}
struct nvpair *nvpair_create()
{
struct nvpair *n;
n = xxmalloc(sizeof(*n));
n->table = hash_table_create(7, hash_string);
return n;
}
void pfs_resolve_add_entry( const char *prefix, const char *redirect, mode_t mode )
{
assert(prefix);
assert(redirect);
char real_redirect[PFS_PATH_MAX];
struct pfs_mount_entry *ns = pfs_process_current_ns();
if (!ns) ns = mount_list;
assert(ns);
debug(D_RESOLVE,"resolving %s in parent ns",redirect);
switch (pfs_resolve_ns(find_parent_ns(ns), redirect, real_redirect, mode, 0)) {
case PFS_RESOLVE_CHANGED:
case PFS_RESOLVE_UNCHANGED:
break;
default:
debug(D_NOTICE,"couldn't resolve redirect %s",prefix);
return;
}
struct pfs_mount_entry *m = (struct pfs_mount_entry *) xxmalloc(sizeof(*m));
memcpy(m, ns, sizeof(*m));
memset(ns, 0, sizeof(*ns));
strcpy(ns->prefix, prefix);
strcpy(ns->redirect, real_redirect);
ns->mode = mode;
ns->next = m;
ns->refcount = m->refcount;
m->refcount = 1;
pfs_resolve_cache_flush();
}
struct work_queue_master *duplicate_work_queue_master(struct work_queue_master *master)
{
struct work_queue_master *m;
m = xxmalloc(sizeof(struct work_queue_master));
if(!m) return NULL;
strncpy(m->addr, master->addr, LINK_ADDRESS_MAX);
strncpy(m->proj, master->proj, WORK_QUEUE_NAME_MAX);
m->port = master->port;
m->priority = master->priority;
m->capacity = master->capacity;
m->tasks_waiting = master->tasks_waiting;
m->tasks_running = master->tasks_running;
m->tasks_complete = master-> tasks_complete;
m->total_tasks_dispatched = master-> total_tasks_dispatched;
m->workers_init = master->workers_init;
m->workers_ready = master->workers_ready;
m->workers_busy = master->workers_busy;
m->workers_full = master->workers_full;
m->workers = master->workers;
if(master->workers_by_pool) {
m->workers_by_pool = xxstrdup(master->workers_by_pool);
} else {
m->workers_by_pool = NULL;
}
strncpy(m->owner, master->owner, USERNAME_MAX);
return m;
}
int add_defined(struct defined_networks *def, struct fsm *net, char *string) {
struct defined_networks *d;
if (net == NULL)
return 0;
fsm_count(net);
for (d = def; d != NULL; d = d->next) {
if (d->name != NULL && strcmp(d->name, string) == 0) {
xxfree(d->net);
xxfree(d->name);
d->net = net;
d->name = xxstrdup(string);
return 1;
}
}
if (def->name == NULL) {
d = def;
} else {
d = xxmalloc(sizeof(struct defined_networks));
d->next = def->next;
def->next = d;
}
d->name = xxstrdup(string);
d->net = net;
return 0;
}
char *chirp_ticket_tostring(struct chirp_ticket *ct)
{
size_t n;
const char *s;
char *result;
buffer_t *B;
B = buffer_create();
buffer_printf(B, "subject \"%s\"\n", ct->subject);
buffer_printf(B, "ticket \"%s\"\n", ct->ticket);
buffer_printf(B, "expiration \"%lu\"\n", (unsigned long) ct->expiration);
for(n = 0; n < ct->nrights; n++) {
buffer_printf(B, "rights \"%s\" \"%s\"\n", ct->rights[n].directory, ct->rights[n].acl);
}
s = buffer_tostring(B, &n);
result = xxmalloc(n + 1);
memset(result, 0, n + 1);
memcpy(result, s, n);
buffer_delete(B);
return result;
}
void fsm_construct_add_arc(struct fsm_construct_handle *handle, int source, int target, char *in, char *out) {
struct fsm_state_list *sl;
struct fsm_trans_list *tl;
int symin, symout;
fsm_construct_check_size(handle, source);
fsm_construct_check_size(handle, target);
if (source > handle->maxstate)
handle->maxstate = source;
if (target > handle->maxstate)
handle->maxstate = target;
sl = (handle->fsm_state_list)+target;
sl->used = 1;
sl = (handle->fsm_state_list)+source;
sl->used = 1;
tl = xxmalloc(sizeof(struct fsm_trans_list));
tl->next = sl->fsm_trans_list;
sl->fsm_trans_list = tl;
if ((symin = fsm_construct_check_symbol(handle,in)) == -1)
symin = fsm_construct_add_symbol(handle,in);
if ((symout = fsm_construct_check_symbol(handle,out)) == -1)
symout = fsm_construct_add_symbol(handle,out);
tl->in = symin;
tl->out = symout;
tl->target = target;
}
static int ticket_translate(const char *name, char *ticket_subject)
{
char command[PATH_MAX * 2 + 4096];
const char *dummy;
if(chirp_ticket_isticketsubject(name, &dummy)) {
strcpy(ticket_subject, name);
return 1;
}
char *pk = xxmalloc(65536); /* max size of public key */
sprintf(command, "sed '/^\\s*#/d' < '%s' | openssl rsa -pubout 2> /dev/null", name);
FILE *pkf = popen(command, "r");
int length = fread(pk, sizeof(char), 65536, pkf);
if(length <= 0) {
pclose(pkf);
return 0;
}
pk[length] = 0;
pclose(pkf);
/* load the digest */
const char *digest = chirp_ticket_digest(pk);
sprintf(ticket_subject, "ticket:%s", digest);
return 1;
}
static INT64_T do_ticket_get(int argc, char **argv)
{
char *subject;
char *ticket;
time_t duration;
char **rights;
INT64_T result = chirp_reli_ticket_get(current_host, argv[1], &subject, &ticket, &duration, &rights, stoptime);
if(result == 0) {
printf("%s\n", subject);
free(subject);
/* base64 encode the ticket so it fits on one line */
char *bticket = xxmalloc(sizeof(char) * strlen(ticket) * 2 + 10); /* double is more than 4/3 needed */
b64_encode(ticket, strlen(ticket), bticket, strlen(ticket) * 2 + 10);
printf("%s\n", bticket);
free(bticket);
free(ticket);
printf("%llu\n", (unsigned long long) duration);
char **tmp = rights;
for(; tmp && tmp[0] && tmp[1]; tmp += 2) {
printf("%s %s\n", tmp[0], tmp[1]);
free(tmp[0]);
free(tmp[1]);
}
free(rights);
}
return result;
}
buffer_t *buffer_create(void)
{
buffer_t *b = xxmalloc(sizeof(buffer_t));
b->buf = NULL;
b->size = 0;
return b;
}
char *file_to_mem(char *name) {
FILE *infile;
size_t numbytes;
char *buffer;
infile = fopen(name, "r");
if(infile == NULL) {
printf("Error opening file '%s'\n",name);
return NULL;
}
fseek(infile, 0L, SEEK_END);
numbytes = ftell(infile);
fseek(infile, 0L, SEEK_SET);
buffer = (char*)xxmalloc((numbytes+1) * sizeof(char));
if(buffer == NULL) {
printf("Error reading file '%s'\n",name);
return NULL;
}
if (fread(buffer, sizeof(char), numbytes, infile) != numbytes) {
printf("Error reading file '%s'\n",name);
return NULL;
}
fclose(infile);
*(buffer+numbytes)='\0';
return(buffer);
}
struct io_buf_handle *io_init() {
struct io_buf_handle *iobh;
iobh = xxmalloc(sizeof(struct io_buf_handle));
(iobh->io_buf) = NULL;
(iobh->io_buf_ptr) = NULL;
return(iobh);
}
static int ast_do_simple( int line, int argc, char **argv, int fds[3], time_t stoptime )
{
char *cmd;
int length=0;
int i;
for( i=0; i<argc; i++ ) {
length+=strlen(argv[i])+1;
}
cmd = xxmalloc(length+1);
cmd[0] = 0;
for( i=0; i<argc; i++ ) {
strcat(cmd,argv[i]);
strcat(cmd," ");
}
ftsh_error(FTSH_ERROR_COMMAND,line,"%s",cmd);
free(cmd);
if(hash_table_lookup(ftable,argv[0]) || builtin_lookup(argv[0]) ) {
return ast_do_internal(line,argc,argv,fds,stoptime);
} else {
return ast_do_external(line,argc,argv,fds,stoptime);
}
}
struct list *get_workload_specs(const char *path) {
struct list *specs = list_create();
if(!specs) {
fprintf(stderr, "Cannot allocate memory for creating list!\n");
return NULL;
}
// Read in new configuration from file
FILE *fp;
fp = fopen(path, "r");
if(!fp) {
fprintf(stderr, "Failed to open workload specification file at %s.\n", path);
return NULL;
}
char *line;
int line_count = 0;
while((line = get_line(fp))) {
line_count++;
string_chomp(line);
if(string_isspace(line)) { // skip empty lines
continue;
}
if(line[0] == '#') { // skip comment lines
continue;
}
int submit, input, exe, output, num;
if(sscanf(line, "%d %d %d %d %d", &submit, &input, &exe, &output, &num) == 5) {
if(submit < 0 || input <=0 || exe <=0 || output <=0 || num <=0) {
fprintf(stderr, "Other than the submit_time field, every other field should be greater than 0.\n");
goto fail;
}
struct task_series *ts = (struct task_series *)xxmalloc(sizeof(struct task_series));
ts->submit_time = submit;
ts->input_size = input;
ts->execution_time = exe;
ts->output_size = output;
ts->num_of_tasks = num;
list_push_priority(specs, ts, ts->submit_time);
} else {
fprintf(stderr, "Line %d is invalid: %s\n", line_count, line);
goto fail;
}
}
fclose(fp);
return specs;
fail:
// delete list
list_free(specs);
list_delete(specs);
fclose(fp);
return NULL;
}
void apply_add_sigma_trie(struct apply_handle *h, int number, char *symbol, int len) {
/* Create a trie of sigma symbols (prefixes) so we can */
/* quickly (in O(n)) tokenize an arbitrary string into */
/* integer sequences representing symbols, using longest- */
/* leftmost factorization. */
int i;
struct sigma_trie *st;
struct sigma_trie_arrays *sta;
st = h->sigma_trie;
for (i = 0; i < len; i++) {
st = st+(unsigned char)*(symbol+i);
if (i == (len-1)) {
st->signum = number;
} else {
if (st->next == NULL) {
st->next = xxcalloc(256,sizeof(struct sigma_trie));
st = st->next;
/* store these arrays to free them later */
sta = xxmalloc(sizeof(struct sigma_trie_arrays));
sta->arr = st;
sta->next = h->sigma_trie_arrays;
h->sigma_trie_arrays = sta;
} else {
st = st->next;
}
}
}
}
void apply_add_sigma_trie(struct apply_handle *h, int number, char *symbol) {
int i, len;
struct sigma_trie *st;
struct sigma_trie_arrays *sta;
len = strlen(symbol);
st = h->sigma_trie;
for (i = 0; i < len; i++) {
st = st+(unsigned char)*(symbol+i);
if (i == (len-1)) {
st->signum = number;
} else {
if (st->next == NULL) {
st->next = xxcalloc(256,sizeof(struct sigma_trie));
st = st->next;
/* store these arrays to free them later */
sta = xxmalloc(sizeof(struct sigma_trie_arrays));
sta->arr = st;
sta->next = h->sigma_trie_arrays;
h->sigma_trie_arrays = sta;
} else {
st = st->next;
}
}
}
}
static int nhash_insert(int hashval, int *set, int setsize) {
struct nhash_list *tableptr;
int i, fs = 0;
current_setnum++;
tableptr = table+hashval;
nhash_load++;
for (i = 0; i < setsize; i++) {
if (finals[*(set+i)])
fs = 1;
}
if (tableptr->size == 0) {
tableptr->set_offset = move_set(set, setsize);
tableptr->size = setsize;
tableptr->setnum = current_setnum;
add_T_ptr(current_setnum, setsize, tableptr->set_offset, fs);
return(current_setnum);
}
tableptr = xxmalloc(sizeof(struct nhash_list));
tableptr->next = (table+hashval)->next;
(table+hashval)->next = tableptr;
tableptr->setnum = current_setnum;
tableptr->size = setsize;
tableptr->set_offset = move_set(set, setsize);
add_T_ptr(current_setnum, setsize, tableptr->set_offset, fs);
return(current_setnum);
}
int sigma_sort(struct fsm *net) {
#ifdef ORIGINAL
int(*comp)() = ssortcmp;
#else
int(*comp)(const void*, const void*) = ssortcmp;
#endif
int size, i, max, *replacearray;
struct ssort *ssort;
struct sigma *sigma;
struct fsm_state *fsm_state;
size = sigma_max(net->sigma);
if (size < 0) { return 1; }
ssort = xxmalloc(sizeof(struct ssort)*size);
for (i=0, sigma=net->sigma; sigma != NULL; sigma=sigma->next) {
if (sigma->number > IDENTITY) {
ssort[i].symbol = (char *)sigma->symbol;
ssort[i].number = sigma->number;
i++;
}
}
max = i;
qsort(ssort, max, sizeof(struct ssort), comp);
replacearray = xxmalloc(sizeof(int)*(size+3));
for (i=0; i<max; i++)
replacearray[(ssort+i)->number] = i+3;
/* Replace arcs */
for(i=0, fsm_state = net->states; (fsm_state+i)->state_no != -1; i++) {
if ((fsm_state+i)->in > IDENTITY)
(fsm_state+i)->in = replacearray[(fsm_state+i)->in];
if ((fsm_state+i)->out > IDENTITY)
(fsm_state+i)->out = replacearray[(fsm_state+i)->out];
}
/* Replace sigma */
for (i=0, sigma=net->sigma; sigma != NULL; sigma=sigma->next) {
if (sigma->number > IDENTITY) {
sigma->number = i+3;
sigma->symbol = (ssort+i)->symbol;
i++;
}
}
xxfree(replacearray);
xxfree(ssort);
return(1);
}
void sigma_cleanup (struct fsm *net, int force) {
int i,j,first,maxsigma,*attested;
struct fsm_state *fsm;
struct sigma *sig, *sig_prev, *sign;
if (force == 0) {
if (sigma_find_number(IDENTITY, net->sigma) != -1)
return;
if (sigma_find_number(UNKNOWN, net->sigma) != -1)
return;
}
maxsigma = sigma_max(net->sigma);
if (maxsigma < 0) { return; }
attested = xxmalloc(sizeof(int)*(maxsigma+1));
for (i=0; i<=maxsigma; i++)
*(attested+i) = 0;
fsm = net->states;
for (i=0; (fsm+i)->state_no != -1; i++) {
if ((fsm+i)->in >=0)
*(attested+(fsm+i)->in) = 1;
if ((fsm+i)->out >=0)
*(attested+(fsm+i)->out) = 1;
}
for (i=3,j=3; i<=maxsigma;i++ ) {
if (*(attested+i)) {
*(attested+i) = j;
j++;
}
}
for (i=0; (fsm+i)->state_no != -1; i++) {
if ((fsm+i)->in > 2)
(fsm+i)->in = *(attested+(fsm+i)->in);
if ((fsm+i)->out > 2)
(fsm+i)->out = *(attested+(fsm+i)->out);
}
sig_prev = NULL;
for (sig = net->sigma; sig != NULL && sig->number != -1; sig = sign) {
first = 1;
sign = sig->next;
if (!*(attested+(sig->number))) {
xxfree(sig->symbol);
xxfree(sig);
if (sig_prev != NULL) {
sig_prev->next = sign;
first = 0;
} else {
first = 0;
net->sigma = sign;
}
} else {
sig->number = sig->number >= 3 ? *(attested+(sig->number)) : sig->number;
}
if (first)
sig_prev = sig;
}
xxfree(attested);
return;
}
void apply_create_statemap(struct apply_handle *h, struct fsm *net) {
int i;
struct fsm_state *fsm;
fsm = net->states;
h->statemap = xxmalloc(sizeof(int)*net->statecount);
h->marks = xxmalloc(sizeof(int)*net->statecount);
for (i=0; i < net->statecount; i++) {
*(h->statemap+i) = -1;
*(h->marks+i) = 0;
}
for (i=0; (fsm+i)->state_no != -1; i++) {
if (*(h->statemap+(fsm+i)->state_no) == -1) {
*(h->statemap+(fsm+i)->state_no) = i;
}
}
}
static void add_mount_entry( const char *prefix, const char *redirect )
{
struct mount_entry * m = xxmalloc(sizeof(*m));
strcpy(m->prefix,prefix);
strcpy(m->redirect,redirect);
m->next = mount_list;
mount_list = m;
}
void debug_config_fatal(void (*callback) ())
{
struct fatal_callback *f;
f = xxmalloc(sizeof(*f));
f->callback = callback;
f->next = fatal_callback_list;
fatal_callback_list = f;
}
struct sigma *sigma_create() {
struct sigma *sigma;
sigma = xxmalloc(sizeof(struct sigma));
sigma->number = -1; /*Empty sigma*/
sigma->next = NULL;
sigma->symbol = NULL;
return(sigma);
}
void * operator new (size_t sz) throw (std::bad_alloc)
{
void * ptr = xxmalloc (sz);
if (ptr == NULL) {
throw std::bad_alloc();
} else {
return ptr;
}
}
