static
void handle_nextstate(state_t *next) {
/* interpolate to a new an eggciting z coordinate */
state_t *cur = copy_state(next);
vec3 origo = state_to_vec(prev);
vec3 pt = state_to_vec(cur);
vec3 dir = normalize(sub(pt, origo));
vec3 offset = scale(dir, max_dist);
while (dist(prev, cur) > max_dist) {
/* printf("split because %f\n", dist(prev, cur)); */
/* print_vec3(offset); */
/* printf("\n"); */
cur->x = prev->x + offset.x;
cur->y = prev->y + offset.y;
cur->z = prev->z + offset.z;
write_statement(prev, cur, output);
free(prev);
prev = cur;
cur = copy_state(next);
}
write_statement(prev, next, output);
free(prev);
free(cur);
prev = next;
}
/************************************************************************
* See .h file for description.
************************************************************************/
void copy_mhmm
(MHMM_T* an_mhmm,
MHMM_T* new_mhmm)
{
int i_state;
/* Copy the top-level data. */
new_mhmm->type = an_mhmm->type;
new_mhmm->log_odds = an_mhmm->log_odds;
new_mhmm->num_motifs = an_mhmm->num_motifs;
new_mhmm->num_states = an_mhmm->num_states;
new_mhmm->num_spacers = an_mhmm->num_spacers;
new_mhmm->spacer_states = an_mhmm->spacer_states;
new_mhmm->alph = alph_hold(an_mhmm->alph);
new_mhmm->background = allocate_array(alph_size_full(an_mhmm->alph));
copy_array(an_mhmm->background, new_mhmm->background);
copy_string(&(new_mhmm->description), an_mhmm->description);
copy_string(&(new_mhmm->motif_file), an_mhmm->motif_file);
copy_string(&(new_mhmm->sequence_file), an_mhmm->sequence_file);
// FIXME: Copy hot states array.
new_mhmm->num_hot_states = an_mhmm->num_hot_states;
/* Copy each state. */
for (i_state = 0; i_state < an_mhmm->num_states; i_state++) {
copy_state(&(an_mhmm->states[i_state]),
&(new_mhmm->states[i_state]));
}
/* Copy the transition matrix. */
copy_matrix(an_mhmm->trans, new_mhmm->trans);
}
wf_framebuffer_base& wf_framebuffer_base::operator = (wf_framebuffer_base&& other)
{
if (this == &other)
return *this;
release();
copy_state(std::move(other));
return *this;
}
/* In reality no need to return nothing, the move was already checked */
int game_state_transition(const struct state *s0, struct move *currMove, struct state *s1, struct game *myGame){
/* store the player */
store_curr_player(myGame, currMove);
/* create s1 */
create_table(myGame,s1);
/* copy s0 into s1*/
copy_state(s1,s0,myGame);
/* free old state */
free(s0->table);
/* update the new state */
myGame->state = *s1;
myGame->state.table[currMove->row - 1][currMove->column - 1] = currMove->player;
return 0;
}
int op_lfork(t_vm *vm, t_process *process, int *params, int len)
{
t_process *fork;
unsigned char *addr;
addr = vm->memory + ((((short)params[0]) +
(process->next_instr - vm->memory)) % MEM_SIZE);
if (!(fork = new_process(addr, vm->current_cycle -
get_cycles_for_opcode(*process->next_instr))))
return (len);
if (!(fork->registres = copy_regs(process->registres)))
exit(1);
copy_state(fork, process);
ft_lstadd(&vm->processes, ft_lstnew(fork, sizeof(t_process)));
return (len);
}
//gestore degli interrupt
void int_handler(){
interruptStart = getTODLO(); //tempo in cui comincia la gestione dell'interrupt, da
//assegnare poi ad un eventuale processo svegliato dall'interrupt
state_t *returnState = (state_t*) INT_OLDAREA;
returnState->pc -= 4;
if( current_process != NULL){
copy_state( returnState, ¤t_process->p_s );
current_process->userTime += interruptStart - userTimeStart;//se c'è un processo aggiorno il suo userTime
current_process->CPUTime += interruptStart - CPUTimeStart;
}
int cause = getCAUSE();
if(CAUSE_IP_GET(cause, IL_TIMER)){
if( current_timer == PSEUDO_CLOCK ){
while( devSem[CLOCK_SEM] < 0 ){ //Ad ogni pseudo clock tick mi assicuro che il semaforo sia sempre a zero
verhogen( &devSem[CLOCK_SEM], 1, 0, getTODLO() - interruptStart);
}
}
else if(current_timer == TIME_SLICE ){
if( current_process != NULL ){
insertProcQ( priority_queue(current_process->priority), current_process);
current_process->CPUTime += getTODLO() - interruptStart; //se metto in pausa il processo aggiorno anche il suo CPUTime
current_process = NULL;
}
}
}
else if(CAUSE_IP_GET(cause, IL_DISK)){
dtnp_interrupt(IL_DISK);
}
else if(CAUSE_IP_GET(cause, IL_TAPE)){
dtnp_interrupt(IL_TAPE);
}
else if(CAUSE_IP_GET(cause, IL_ETHERNET)){
dtnp_interrupt(IL_ETHERNET);
}
else if(CAUSE_IP_GET(cause, IL_PRINTER)){
dtnp_interrupt(IL_PRINTER);
}
else if(CAUSE_IP_GET(cause, IL_TERMINAL)){
terminal_interrupt();
}
scheduler();
}
/**
* @brief Lookups state and hash table, adding new if none was found.
*
* New state is immediately pushed to BFS.
*
* @param state state structure
* @param add_action Action to perform when adding state to hash
*
* @return 1 if new state was added, 0 if it was present.
*/
int state_hash_add(struct State *state, enum HashAddAction add_action)
{
state_hash_t hash0 = STATE_TABLE_HASH(state, 0);
state_hash_t hash = hash0;
int found = 0;
hash_dprintf("State hash (" HASH_FMT ")", hash0);
dump_dprintf(" ");
hexdump_state(state);
/*
* Check each bit, setting it to 1.
*/
for (int i = 0; i < BITSTATE_HASH_COUNT;
++i, hash = STATE_TABLE_HASH(state, i)) {
hash_dprintf(" (" HASH_FMT ")", hash);
if (BIT_TEST(state_hashtable, hash))
++found;
else
BIT_SET(state_hashtable, hash);
}
if (found < BITSTATE_HASH_COUNT) {
/*
* Not all bits set -- new state
*/
if (found > 0) {
/*
* ... but some bits set -- possible collision
*/
hash_dprintf(" {COLLISION: %d/%d bits set}", found, BITSTATE_HASH_COUNT);
hash_collisions++;
hash_collision_shifts += found;
}
switch (add_action) {
case BfsAddCopy:
state = copy_state(state);
case BfsAdd:
BFS_ADD(state);
if (max_bfs_state_size < BFS_CUR_SIZE())
max_bfs_state_size = BFS_CUR_SIZE();
case BfsNoAdd:
break;
}
total_state_size += BITSTATE_HASH_COUNT*STATESIZE(state);
min_state_size = (min_state_size < STATESIZE(state)) ? min_state_size : STATESIZE(state);
max_state_size = (max_state_size > STATESIZE(state)) ? max_state_size : STATESIZE(state);
#ifndef DEBUG
if (dump_new_states)
edump_state(state);
#endif
hash_dprintf(" - ADDED");
used_hash_entries += BITSTATE_HASH_COUNT;
}
else
/*
* All bits set -- old state
*/
hash_dprintf(" - OLD");
dprintf("\n");
return (found < BITSTATE_HASH_COUNT);
}
/**
* @brief Lookups state and hash table, adding new if none was found.
*
* New state is immediately pushed to BFS.
*
* @param state state structure
* @param add_action Action to perform when adding state to hash
*
* @return 1 if new state was added, 0 if it was present.
*/
int state_hash_add(struct State *state, enum HashAddAction add_action)
{
state_hash_t hash = STATE_TABLE_HASH(state, 0);
state_hash_t offset = 0;
struct State *st;
int found = 0;
int had_collisions = 0;
hash_dprintf("State hash (" HASH_FMT ")", hash);
dump_dprintf(" ");
hexdump_state(state);
for (st = state_hashtable[hash];
st != NULL
&& (STATESIZE(state) != STATESIZE(st) ||
memcmp(state, st, STATESIZE(state)));
st = state_hashtable[hash]) {
/*
* Hash slot already occupied by a state address (not NULL)
* which is not the same as new state
*/
hash_dprintf(" {COLLISION IN SLOT " HASH_FMT, SQR(offset));
++hash_collision_shifts;
had_collisions = 1;
/*
* Open addressing with quadratic probes: slot, slot+1, slot+3, slot+6,..
*/
hash += ++offset;
hash %= HASHTABLE_LENGTH;
hash_dprintf(", NEXT " HASH_FMT "}", hash);
dump_dprintf(" := ");
hexdump_state(st);
}
if (had_collisions)
hash_collisions++;
/*
* If last slot value was NULL -- empty slot has been found,
* otherwise same state was found in hash.
*/
if (st == NULL) {
switch (add_action) {
case BfsAddCopy:
state = copy_state(state);
case BfsAdd:
BFS_ADD(state);
case BfsNoAdd:
state_hashtable[hash] = state;
}
total_state_size += STATESIZE(state);
min_state_size = (min_state_size < STATESIZE(state)) ? min_state_size : STATESIZE(state);
max_state_size = (max_state_size > STATESIZE(state)) ? max_state_size : STATESIZE(state);
#ifndef DEBUG
if (dump_new_states)
edump_state(state);
#endif
hash_dprintf(" - ADDED");
++used_hash_entries;
} else {
found = 1;
hash_dprintf(" - OLD");
}
dprintf("\n");
return !found;
}
//----------------------------DRAW---------------------------
void draw(Display * dpy, Window win, int s_width, int s_height) {
copy_state(state, state_buffer, 1);
lock_state(state);
glViewport(0, 0, s_width, s_height);
glClearColor(0.0, 0.0, 0.0, 0.0);
glClear(GL_COLOR_BUFFER_BIT);
Dimension d = get_grid_for_num_instruments(state->num_instruments, s_width, s_height);
int i;
for (i = 0; i < state->num_instruments; ++i) {
float left = s_width / d.x * (i % d.x);
float bottom = s_height / d.y * (d.y - 1 - i / d.x);
float width = s_width / d.x;
float height = s_height / d.y;
glViewport(left, bottom, width, height);
Instrument_State * is = &state->instruments[i];
GLfloat brightness = pow(1 - pow((float)is->draw_state / MAX_DRAW_STATE * 2 - 1, 2), 0.5);
if (is->draw_state) --is->draw_state;
GLfloat up[] = {
-T_BOUND, -T_BOUND, 0.0, T_BOTTOM_BRIGHTNESS, 0.0, brightness,
0.0, T_BOUND, 0.0, 1.0, 0.0, brightness,
T_BOUND, -T_BOUND, 0.0, T_BOTTOM_BRIGHTNESS, 0.0, brightness
};
GLfloat down[] = {
-T_BOUND, T_BOUND, T_BOTTOM_BRIGHTNESS, 0.0, 0.0, brightness,
0.0, -T_BOUND, 1.0, 0.0, 0.0, brightness,
T_BOUND, T_BOUND, T_BOTTOM_BRIGHTNESS, 0.0, 0.0, brightness
};
glBindBuffer(GL_ARRAY_BUFFER, gla.array_buffer);
if (is->direction == 'u') {
glBufferData(GL_ARRAY_BUFFER, sizeof(up), up, GL_STATIC_DRAW);
} else {
glBufferData(GL_ARRAY_BUFFER, sizeof(down), down, GL_STATIC_DRAW);
}
glEnableVertexAttribArray(gla.position);
glVertexAttribPointer(gla.position, 2, GL_FLOAT, GL_FALSE, 6 * sizeof(GLfloat), 0);
glEnableVertexAttribArray(gla.color);
glVertexAttribPointer(gla.color, 4, GL_FLOAT, GL_FALSE, 6 * sizeof(GLfloat), (void *)(2 * sizeof(GLfloat)));
glDrawArrays(GL_TRIANGLES, 0, 3);
#ifdef SHOW_TEXT
glListBase(gla.font_base);
glColor4f(1.0, 1.0, 1.0, brightness / 2 + 0.5);
float i_length = strlen(is->instrument);
GLfloat i_left = -i_length * gla.font_width / width;
GLfloat i_bottom = 0.9 - gla.font_height / height * 2;
glRasterPos2f(i_left, i_bottom);
glCallLists(i_length, GL_UNSIGNED_BYTE, (unsigned char *)is->instrument);
char price[16] = {0};
sprintf(price, "%f", is->price);
float p_length = strlen(price);
GLfloat p_left = -p_length * gla.font_width / width;
GLfloat p_bottom = -0.9;
glRasterPos2f(p_left, p_bottom);
glCallLists(p_length, GL_UNSIGNED_BYTE, (unsigned char *)price);
#endif
}
unlock_state(state);
glXSwapBuffers(dpy, win);
}
int
zebra_evaluate_rnh_table (vrf_id_t vrfid, int family)
{
struct route_table *ptable;
struct route_table *ntable;
struct route_node *prn;
struct route_node *nrn;
struct rnh *rnh;
struct zserv *client;
struct listnode *node;
struct rib *rib;
ntable = lookup_rnh_table(vrfid, family);
if (!ntable)
{
zlog_debug("evaluate_rnh_table: rnh table not found\n");
return -1;
}
ptable = zebra_vrf_table(family2afi(family), SAFI_UNICAST, vrfid);
if (!ptable)
{
zlog_debug("evaluate_rnh_table: prefix table not found\n");
return -1;
}
for (nrn = route_top (ntable); nrn; nrn = route_next (nrn))
{
if (!nrn->info)
continue;
rnh = nrn->info;
prn = route_node_match(ptable, &nrn->p);
if (!prn)
rib = NULL;
else
{
RNODE_FOREACH_RIB(prn, rib)
{
if (CHECK_FLAG (rib->status, RIB_ENTRY_REMOVED))
continue;
if (! CHECK_FLAG (rib->status, RIB_ENTRY_SELECTED_FIB))
continue;
if (CHECK_FLAG(rnh->flags, ZEBRA_NHT_CONNECTED))
{
if (rib->type == ZEBRA_ROUTE_CONNECT)
break;
if (rib->type == ZEBRA_ROUTE_NHRP)
{
struct nexthop *nexthop;
for (nexthop = rib->nexthop; nexthop; nexthop = nexthop->next)
if (nexthop->type == NEXTHOP_TYPE_IFINDEX ||
nexthop->type == NEXTHOP_TYPE_IFNAME)
break;
if (nexthop)
break;
}
}
else
break;
}
}
if (compare_state(rib, rnh->state))
{
if (IS_ZEBRA_DEBUG_NHT)
{
char bufn[INET6_ADDRSTRLEN];
char bufp[INET6_ADDRSTRLEN];
prefix2str(&nrn->p, bufn, INET6_ADDRSTRLEN);
if (prn)
prefix2str(&prn->p, bufp, INET6_ADDRSTRLEN);
else
strcpy(bufp, "null");
zlog_debug("rnh %s resolved through route %s - sending "
"nexthop %s event to clients", bufn, bufp,
rib ? "reachable" : "unreachable");
}
copy_state(rnh, rib);
for (ALL_LIST_ELEMENTS_RO(rnh->client_list, node, client))
send_client(rnh, client, vrfid);
}
}
return 1;
}
wf_framebuffer_base::wf_framebuffer_base(wf_framebuffer_base&& other)
{
copy_state(std::move(other));
}
