ir_snprintf(buf, sizeof(buf), "%s%s_%F_%s%s", prefix, tu_name, env->irg, env->cls->name, suffix);
xfree(tu_name);
result = fopen(buf, "wt");
- if(result == NULL) {
+ if (result == NULL) {
panic("Couldn't open '%s' for writing.", buf);
}
continue;
// insert proj node into priority queue (descending by their degree in ifg)
- if(bitset_is_set(pbqp_co->restricted_nodes, get_irn_idx(proj))) {
+ if (bitset_is_set(pbqp_co->restricted_nodes, get_irn_idx(proj))) {
pqueue_put(restrictedNodesQueue,proj, be_ifg_degree(pbqp_co->ifg,proj));
}
else {
}
/* first insert all restricted nodes */
- while(!pqueue_empty(restrictedNodesQueue)) {
+ while (!pqueue_empty(restrictedNodesQueue)) {
plist_insert_back(pbqp_co->rpeo, get_node(pbqp_co->pbqp, get_irn_idx(pqueue_pop_front(restrictedNodesQueue))));
}
/* insert proj nodes into reverse perfect elimination order (descending by their degree in ifg) */
- while(!pqueue_empty(queue)) {
+ while (!pqueue_empty(queue)) {
plist_insert_back(pbqp_co->rpeo, get_node(pbqp_co->pbqp, get_irn_idx(pqueue_pop_front(queue))));
}
/* set costs */
unsigned int cnt;
- for(cnt = 0; cnt < costs_vector->len; cnt++) {
+ for (cnt = 0; cnt < costs_vector->len; cnt++) {
if (bitset_is_set(pbqp_co.ignore_reg,cnt)) {
vector_set(costs_vector, cnt, INF_COSTS);
}
/* add costs vector to node */
add_node_costs(pbqp_co.pbqp, get_irn_idx(ifg_node), costs_vector);
- if(cntFreeChoosableRegs <= 4) {
+ if (cntFreeChoosableRegs <= 4) {
/* node is restricted */
bitset_set(pbqp_co.restricted_nodes, get_irn_idx(ifg_node));
}
/* create costs matrix for interference edges */
struct pbqp_matrix *ife_matrix = pbqp_matrix_alloc(pbqp_co.pbqp, number_registers, number_registers);
/* set costs */
- for(row = 0; row < number_registers; row++) {
+ for (row = 0; row < number_registers; row++) {
pbqp_matrix_set(ife_matrix, row, row, INF_COSTS);
}
/* create costs matrix for affinity edges */
struct pbqp_matrix *afe_matrix = pbqp_matrix_alloc(pbqp_co.pbqp, number_registers, number_registers);
/* set costs */
- for(row = 0; row < number_registers; row++) {
- for(col = 0; col < number_registers; col++) {
- if(row == col) {
+ for (row = 0; row < number_registers; row++) {
+ for (col = 0; col < number_registers; col++) {
+ if (row == col) {
pbqp_matrix_set(afe_matrix, row, col, 0);
}
else {
be_ifg_foreach_node(co->cenv->ifg, nodes_it, ifg_node) {
/* add costs matrix between nodes (interference edge) */
be_ifg_foreach_neighbour(co->cenv->ifg, neigh_it, ifg_node, if_neighb_node) {
- if(get_edge(pbqp_co.pbqp,get_irn_idx(ifg_node), get_irn_idx(if_neighb_node)) == NULL) {
+ if (get_edge(pbqp_co.pbqp,get_irn_idx(ifg_node), get_irn_idx(if_neighb_node)) == NULL) {
/* copy matrix */
struct pbqp_matrix *matrix = pbqp_matrix_copy(pbqp_co.pbqp, ife_matrix);
/* add costs matrix between nodes (affinity edge) */
affinity_node_t *aff_node = get_affinity_info(co, ifg_node);
neighb_t *aff_neighb_node;
- if(aff_node != NULL) {
+ if (aff_node != NULL) {
co_gs_foreach_neighb(aff_node, aff_neighb_node) {
/* ignore Unknowns */
- if(get_node(pbqp_co.pbqp, get_irn_idx(aff_neighb_node->irn)) == NULL)
+ if (get_node(pbqp_co.pbqp, get_irn_idx(aff_neighb_node->irn)) == NULL)
continue;
- if(get_edge(pbqp_co.pbqp, get_irn_idx(aff_node->irn), get_irn_idx(aff_neighb_node->irn)) == NULL) {
+ if (get_edge(pbqp_co.pbqp, get_irn_idx(aff_node->irn), get_irn_idx(aff_neighb_node->irn)) == NULL) {
/* copy matrix */
struct pbqp_matrix *matrix = pbqp_matrix_copy(pbqp_co.pbqp, afe_matrix);