static void build_coloring_cstr(ilp_env_t *ienv)
{
- local_env_t *lenv = ienv->env;
+ local_env_t *lenv = (local_env_t*)ienv->env;
be_ifg_t *ifg = ienv->co->cenv->ifg;
unsigned n_regs = arch_register_class_n_regs(ienv->co->cls);
const unsigned *allocatable_colors = lenv->allocatable_colors;
static void build_interference_cstr(ilp_env_t *ienv)
{
lpp_t *lpp = ienv->lp;
- local_env_t *lenv = ienv->env;
+ local_env_t *lenv = (local_env_t*)ienv->env;
be_ifg_t *ifg = ienv->co->cenv->ifg;
unsigned n_colors = arch_register_class_n_regs(ienv->co->cls);
ir_node **clique = ALLOCAN(ir_node*, n_colors);
static void build_affinity_cstr(ilp_env_t *ienv)
{
unsigned n_colors = arch_register_class_n_regs(ienv->co->cls);
- unit_t *curr;
/* for all optimization units */
list_for_each_entry(unit_t, curr, &ienv->co->units, units) {
static int compare_edge_t(const void *k1, const void *k2, size_t size)
{
- const edge_t *e1 = k1;
- const edge_t *e2 = k2;
+ const edge_t *e1 = (const edge_t*)k1;
+ const edge_t *e2 = (const edge_t*)k2;
(void) size;
return ! (e1->n1 == e2->n1 && e1->n2 == e2->n2);
new_edge.n2 = n1;
}
(*counter)++;
- return set_insert(edges, &new_edge, sizeof(new_edge), HASH_EDGE(&new_edge));
+ return set_insert(edge_t, edges, &new_edge, sizeof(new_edge), HASH_EDGE(&new_edge));
}
static inline edge_t *find_edge(set *edges, ir_node *n1, ir_node *n2)
new_edge.n1 = n2;
new_edge.n2 = n1;
}
- return set_find(edges, &new_edge, sizeof(new_edge), HASH_EDGE(&new_edge));
+ return set_find(edge_t, edges, &new_edge, sizeof(new_edge), HASH_EDGE(&new_edge));
}
static inline void remove_edge(set *edges, ir_node *n1, ir_node *n2, size_t *counter)
new_edge.n1 = n2;
new_edge.n2 = n1;
}
- e = set_find(edges, &new_edge, sizeof(new_edge), HASH_EDGE(&new_edge));
+ e = set_find(edge_t, edges, &new_edge, sizeof(new_edge), HASH_EDGE(&new_edge));
if (e) {
e->n1 = NULL;
e->n2 = NULL;
}
}
-#define pset_foreach(pset, irn) for (irn=pset_first(pset); irn; irn=pset_next(pset))
+#define pset_foreach(pset, irn) foreach_pset((pset), ir_node, (irn))
/**
* Search for an interference clique and an external node
*/
static void build_clique_star_cstr(ilp_env_t *ienv)
{
- affinity_node_t *aff;
-
/* for each node with affinity edges */
co_gs_foreach_aff_node(ienv->co, aff) {
struct obstack ob;
- neighb_t *nbr;
const ir_node *center = aff->irn;
ir_node **nodes;
set *edges;
++n_nodes;
}
}
- nodes = obstack_finish(&ob);
+ nodes = (ir_node**)obstack_finish(&ob);
/* get all interference edges between these */
n_edges = 0;
bool growed;
/* get 2 starting nodes to form a clique */
- for (e=set_first(edges); !e->n1; e=set_next(edges)) {
- }
+ for (e = set_first(edge_t, edges); !e->n1; e = set_next(edge_t, edges)) {}
/* we could be stepped out of the loop before the set iterated to the end */
set_break(edges);
/* search for a candidate to extend the clique */
for (i=0; i<n_nodes; ++i) {
ir_node *cand = nodes[i];
- ir_node *member;
bool is_cand;
/* if its already in the clique try the next */
/* now the clique is maximal. Finally add the constraint */
{
- ir_node *member;
- int var_idx;
- int cst_idx;
- char buf[32];
+ int var_idx;
+ int cst_idx;
+ char buf[32];
cst_idx = lpp_add_cst(ienv->lp, NULL, lpp_greater_equal, pset_count(clique)-1);
int i, len;
ir_node **curr_path;
affinity_node_t *aff;
- neighb_t *nbr;
/* do not walk backwards or in circles */
if (pdeq_contains(path, irn))
*/
static void build_path_cstr(ilp_env_t *ienv)
{
- affinity_node_t *aff_info;
-
/* for each node with affinity edges */
co_gs_foreach_aff_node(ienv->co, aff_info) {
pdeq *path = new_pdeq();
static void ilp2_apply(ilp_env_t *ienv)
{
- local_env_t *lenv = ienv->env;
+ local_env_t *lenv = (local_env_t*)ienv->env;
ir_graph *irg = ienv->co->irg;
/* first check if there was sth. to optimize */