#include "xmalloc.h"
#include "becopyopt.h"
#include "becopystat.h"
+#include "bitset.h"
#define DEBUG_LVL 0 //SET_LEVEL_1
static firm_dbg_module_t *dbg = NULL;
const unit_t *ou; /**< the opt unit this qnode belongs to */
int color; /**< target color */
set *conflicts; /**< contains conflict_t's. All internal conflicts */
- int mis_size; /**< number of nodes in the mis. */
+ int mis_costs; /**< costs of nodes/copies in the mis. */
+ int mis_size; /**< size of the array below */
ir_node **mis; /**< the nodes of unit_t->nodes[] being part of the max independent set */
set *changed_nodes; /**< contains node_stat_t's. */
} qnode_t;
}
/**
- * Determines a maximum independent set with respect to the interference and
- * conflict edges of all nodes in a qnode.
+ * Determines a maximum weighted independent set with respect to
+ * the interference and conflict edges of all nodes in a qnode.
*/
static INLINE void qnode_max_ind_set(qnode_t *qn, const unit_t *ou) {
- int all_size, curr_size, i, o;
- int *which;
- ir_node **curr, **all = alloca(ou->node_count * sizeof(*all));
+ ir_node **irns;
+ int max, next, pos, curr_weight, best_weight = 0;
+ bitset_t *best, *curr;
+
+ irns = alloca((ou->node_count-1) * sizeof(*irns));
+ best = bitset_alloca(ou->node_count-1);
+ curr = bitset_alloca(ou->node_count-1);
+
+ /* brute force the best set */
+ bitset_set_all(curr);
+ while ((max = bitset_popcnt(curr)) != 0) {
+ /* check if curr is a stable set */
+ int i, o, is_stable_set = 1;
+ bitset_foreach(curr, pos)
+ irns[pos] = ou->nodes[1+pos];
+ for(i=0; i<max; ++i)
+ for(o=i; o<max; ++o) /* !!!!! difference to ou_max_ind_set_costs(): NOT o=i+1 */
+ if (qnode_are_conflicting(qn, irns[i], irns[o])) {
+ is_stable_set = 0;
+ break;
+ }
- /* all contains all nodes not removed in this qn */
- all_size = 0;
- for (i=0; i<ou->node_count; ++i)
- if (!qnode_are_conflicting(qn, ou->nodes[i], ou->nodes[i]))
- all[all_size++] = ou->nodes[i];
-
- /* which[i] says which element to take out of all[] and put into curr[i] */
- which = alloca(all_size*sizeof(*which));
- for (curr_size=0; curr_size<all_size; ++curr_size)
- which[curr_size] = curr_size;
-
- /* stores the currently examined set */
- curr = alloca(all_size*sizeof(*curr));
-
- while (1) { /* this loop will terminate because at least a single node will be a max indep. set */
- /* build current set */
- for (i=0; i<curr_size; ++i)
- curr[i] = all[which[all_size-curr_size+i]];
-
- /* check current set */
- for (i=0; i<curr_size; ++i)
- for (o=i+1; o<curr_size; ++o)
- if (qnode_are_conflicting(qn, curr[i], curr[o]))
- goto conflict_found;
-
- /* We had no conflict. This is the max indep. set */
- qn->mis_size = curr_size;
- for (i=0; i<curr_size; ++i)
- qn->mis[i] = curr[i];
- return;
+ if (is_stable_set) {
+ /* calc current weigth */
+ curr_weight = 0;
+ bitset_foreach(curr, pos)
+ curr_weight += ou->costs[1+pos];
-conflict_found:
- /* We had a conflict. Generate next set */
- if (which[all_size-curr_size+1] == all_size-curr_size+1) {
- curr_size--;
- for (i=0; i<curr_size; ++i)
- which[all_size-curr_size+i] = i;
- } else {
- int redo = 1;
- while (redo) {
- int pos = all_size;
- do {
- pos--;
- } while (!(which[pos] = (which[pos]+1) % all_size));
-
- for (i=pos+1; i<all_size; ++i)
- which[i] = MIN(which[i-1]+1, all_size-1);
-
- redo = 0;
- for (i=all_size-curr_size; i<all_size-1; ++i)
- if (which[i]>=which[i+1]) {
- redo = 1;
- break;
- }
+ /* any better ? */
+ if (curr_weight > best_weight) {
+ best_weight = curr_weight;
+ bitset_copy(best, curr);
}
}
+
+ bitset_minus1(curr);
}
+
+ /* transfer the best set into the qn */
+ qn->mis_size = bitset_popcnt(best);
+ qn->mis_costs = best_weight;
+ next = 0;
+ bitset_foreach(best, pos)
+ qn->mis[next++] = ou->nodes[1+pos];
}
/**
qnode_max_ind_set(qn, ou);
/* do the insertion */
- DBG((dbg, LEVEL_4, "\t Insert qnode color %d with size %d\n", qn->color, qn->mis_size));
+ DBG((dbg, LEVEL_4, "\t Insert qnode color %d with cost %d\n", qn->color, qn->mis_costs));
lh = &ou->queue;
while (lh->next != &ou->queue) {
qnode_t *curr = list_entry_queue(lh->next);
- if (curr->mis_size <= qn->mis_size)
+ if (curr->mis_costs <= qn->mis_costs)
break;
lh = lh->next;
}
}
/**
- * Tries to re-allocate colors of nodes in this opt unit, to achieve a lower
- * number of copy instructions placed during SSA-destruction and lowering.
+ * Tries to re-allocate colors of nodes in this opt unit, to achieve lower
+ * costs of copy instructions placed during SSA-destruction and lowering.
* Works only for opt units with exactly 1 root node, which is the
- * case for approximately 80% of all phi classes and all register constrained
+ * case for approximately 80% of all phi classes and 100% of register constrained
* nodes. (All other phi classes are reduced to this case.)
*/
static void ou_optimize(unit_t *ou) {
/* get head of queue */
curr = list_entry_queue(ou->queue.next);
list_del(&curr->queue);
- DBG((dbg, LEVEL_2, "\t Examine qnode color %d with size %d\n", curr->color, curr->mis_size));
+ DBG((dbg, LEVEL_2, "\t Examine qnode color %d with cost %d\n", curr->color, curr->mis_costs));
/* try */
if (qnode_try_color(curr))
if (curr->mis_size >= 2) {
node_stat_t *ns;
- DBG((dbg, LEVEL_1, "\t Best color: %d Copies: %d/%d\n", curr->color, ou->interf+ou->node_count-curr->mis_size, ou->interf+ou->node_count-1));
+ DBG((dbg, LEVEL_1, "\t Best color: %d Costs: %d/%d\n", curr->color, ou->complete_costs - curr->mis_costs, ou->complete_costs));
/* globally pin root and eventually others */
pset_insert_ptr(pinned_global, ou->nodes[0]);
for (i=1; i<ou->node_count; ++i) {
#define EPSILON 0.00001
#define SLOTS_LIVING 32
-/**
- * Represents the _costs_ if node n and m have different colors.
- * Must be >=0.
- **/
-#define get_weight(n,m) 1
-
typedef struct _simpl_t {
struct list_head chain;
if_node_t *ifn;
DBG((dbg, LEVEL_2, "Add E constraints...\n"));
/* for all roots of optimization units */
list_for_each_entry(unit_t, curr, &pi->co->units, units) {
- const ir_node *root, *arg;
+ ir_node *root, *arg;
int rootnr, argnr, color;
int y_idx, i;
char buf[32];
/* Introduce new variable and set factor in objective function */
mangle_var(buf, 'y', rootnr, argnr);
- y_idx = lpp_add_var(pi->curr_lp, buf, continous, get_weight(root, arg));
+ y_idx = lpp_add_var(pi->curr_lp, buf, continous, curr->costs[i]);
+
/* set starting value */
//lpp_set_start_value(pi->curr_lp, y_idx, (get_irn_col(pi->co, root) != get_irn_col(pi->co, arg)));
int cst_idx, y_idx, i;
char buf[32];
- if (curr->ifg_mis_size == curr->node_count)
+ if (curr->minimal_costs == 0)
continue;
root = curr->nodes[0];
rootnr = get_irn_graph_nr(root);
mangle_cst(buf, 'M', cst_counter++);
- cst_idx = lpp_add_cst(pi->curr_lp, buf, greater, curr->node_count - curr->ifg_mis_size);
+ cst_idx = lpp_add_cst(pi->curr_lp, buf, greater, curr->minimal_costs);
/* for all arguments */
for (i = 1; i < curr->node_count; ++i) {
/* problem size reduction */
pi_find_simplicials(pi);
- //TODO dump_ifg_w/o_removed
+ //TODO If you wish to see it: dump_ifg_w/o_removed
if (pi->all_simplicial)
return pi;
#endif
#include "irprog.h"
+#include "irloop_t.h"
#include "xmalloc.h"
#include "bechordal_t.h"
#define MIN(a,b) ((a<b)?(a):(b))
/**
- * Computes a 'max independent set' wrt. ifg-edges only (no coloring conflicts, no register constraints)
- * @return The size of such a mis
+ * Computes the weight of a 'max independent set' wrt. ifg-edges only
+ * (no coloring conflicts, no register constraints)
+ * @return The costs of such a mis
* NOTE: Code adapted from becopyheur
- * BETTER: Here we can be sure having a chordal graph to work on, so for 'larger' opt-units we
- * could use a special algorithm.
+ * BETTER: Here we can be sure having a chordal graph to work on,
+ * so, for 'larger' opt-units we could use a special algorithm.
*/
-static int get_ifg_mis_size(unit_t *ou) {
- int all_size, curr_size, i, o;
- int *which;
- ir_node **curr, **all = alloca(ou->node_count * sizeof(*all));
-
- /* all contains all nodes */
- all_size = 0;
- for (i=0; i<ou->node_count; ++i)
- all[all_size++] = ou->nodes[i];
-
- /* which[i] says which element to take out of all[] and put into curr[i] */
- which = alloca(all_size*sizeof(*which));
- for (curr_size=0; curr_size<all_size; ++curr_size)
- which[curr_size] = curr_size;
-
- /* stores the currently examined set */
- curr = alloca(all_size*sizeof(*curr));
-
- while (1) { /* this loop will terminate because at least a single node will be a max indep. set */
- /* build current set */
- for (i=0; i<curr_size; ++i)
- curr[i] = all[which[all_size-curr_size+i]];
-
- /* check current set */
- for (i=0; i<curr_size; ++i)
- for (o=i+1; o<curr_size; ++o)
- if (nodes_interfere(ou->co->chordal_env, curr[i], curr[o]))
- goto conflict_found;
-
- /* We had no conflict. This is the (one) max indep. set */
- return curr_size;
-
-conflict_found:
- /* We had a conflict. Generate next set */
- if (which[all_size-curr_size+1] == all_size-curr_size+1) {
- curr_size--;
- for (i=0; i<curr_size; ++i)
- which[all_size-curr_size+i] = i;
- } else {
- int redo = 1;
- while (redo) {
- int pos = all_size;
- do {
- pos--;
- } while (!(which[pos] = (which[pos]+1) % all_size));
-
- for (i=pos+1; i<all_size; ++i)
- which[i] = MIN(which[i-1]+1, all_size-1);
-
- redo = 0;
- for (i=all_size-curr_size; i<all_size-1; ++i)
- if (which[i]>=which[i+1]) {
- redo = 1;
- break;
- }
- }
+static int ou_max_ind_set_costs(unit_t *ou) {
+ ir_node **irns;
+ int max, pos, curr_weight, best_weight = 0;
+ bitset_t *curr;
+
+ irns = alloca((ou->node_count-1) * sizeof(*irns));
+ curr = bitset_alloca(ou->node_count-1);
+
+ /* brute force the best set */
+ bitset_set_all(curr);
+ while ((max = bitset_popcnt(curr)) != 0) {
+ /* check if curr is a stable set */
+ int i, o, is_stable_set = 1;
+ bitset_foreach(curr, pos)
+ irns[pos] = ou->nodes[1+pos];
+ for(i=0; i<max; ++i)
+ for(o=i+1; o<max; ++o) /* !!!!! difference to qnode_max_ind_set(): NOT o=i */
+ if (nodes_interfere(ou->co->chordal_env, irns[i], irns[o])) {
+ is_stable_set = 0;
+ break;
+ }
+
+ if (is_stable_set) {
+ /* calc current weigth */
+ curr_weight = 0;
+ bitset_foreach(curr, pos)
+ curr_weight += ou->costs[1+pos];
+
+ /* any better ? */
+ if (curr_weight > best_weight)
+ best_weight = curr_weight;
}
+
+ bitset_minus1(curr);
}
- assert(0 && "How did you get here?");
+ return best_weight;
}
/**
static void co_append_unit(copy_opt_t *co, ir_node *root) {
int i, arity;
unit_t *unit;
+ struct list_head *tmp;
+
DBG((dbg, LEVEL_1, "\t Root: %n %N\n", root, root));
/* check if we encountered this root earlier */
if (pset_find_ptr(co->roots, root))
arity = get_irn_arity(root);
unit = xcalloc(1, sizeof(*unit));
unit->co = co;
- unit->interf = 0;
unit->node_count = 1;
unit->nodes = xmalloc((arity+1) * sizeof(*unit->nodes));
+ unit->costs = xmalloc((arity+1) * sizeof(*unit->costs));
unit->nodes[0] = root;
+ unit->complete_costs = 0;
+ unit->avg_costs = 0;
INIT_LIST_HEAD(&unit->queue);
/* check all args */
ir_node *arg = get_irn_n(root, i);
assert(is_curr_reg_class(arg) && "Argument not in same register class.");
if (arg != root) {
- if (!nodes_interfere(co->chordal_env, root, arg)) {
- DBG((dbg, LEVEL_1, "\t Member: %n %N\n", arg, arg));
+ int o, arg_pos = 0;
+ if (nodes_interfere(co->chordal_env, root, arg))
+ assert(0 && "root and arg interfere");
+ //TODO do not insert duplicate args
+ DBG((dbg, LEVEL_1, "\t Member: %n %N\n", arg, arg));
+
+ /* check if arg has occurred at a prior position in the arg/list */
+ for (o=0; o<unit->node_count; ++o)
+ if (unit->nodes[o] == arg) {
+ arg_pos = o;
+ break;
+ }
+
+ if (!arg_pos) { /* a new argument */
+ /* TODO Think about the next 2 lines. (inserting in arg-order) */
if (is_optimizable(co->chordal_env->arch_env, arg))
co_append_unit(co, arg);
- unit->nodes[unit->node_count++] = arg;
- } else
- unit->interf++;
+ /* insert node, set costs */
+ unit->nodes[unit->node_count] = arg;
+ unit->costs[unit->node_count] = co->get_costs(root, arg, i);
+ unit->node_count++;
+ } else { /* arg has occured before in same phi */
+ /* increase costs for existing arg */
+ unit->costs[arg_pos] = co->get_costs(root, arg, i);
+ }
}
}
unit->nodes = xrealloc(unit->nodes, unit->node_count * sizeof(*unit->nodes));
+ unit->costs = xrealloc(unit->costs, unit->node_count * sizeof(*unit->costs));
} else if (is_Copy(co->chordal_env->arch_env, root)) {
assert(!nodes_interfere(co->chordal_env, root, get_Copy_src(root)));
- unit->nodes[unit->node_count++] = get_Copy_src(root);
+ unit->nodes[1] = get_Copy_src(root);
+ unit->costs[1] = co->get_costs(root, unit->nodes[1], -1);
+ unit->node_count = 2;
unit->nodes = xrealloc(unit->nodes, 2 * sizeof(*unit->nodes));
+ unit->costs = xrealloc(unit->costs, 2 * sizeof(*unit->costs));
} else
assert(0 && "This is not an optimizable node!");
+ /* TODO add ou's for 2-addr-code instructions */
+
+
+ for(i=1; i<unit->node_count; ++i)
+ unit->complete_costs += unit->costs[i];
+
+ assert(unit->node_count > 1);
+ unit->avg_costs = (100 * unit->complete_costs) / (unit->node_count-1);
+
+ /* insert according to average costs */
+ tmp = &co->units;
+ while (tmp->next != &co->units && list_entry_units(tmp->next)->avg_costs > unit->avg_costs)
+ tmp = tmp->next;
+ list_add(&unit->units, tmp);
- list_add_tail(&unit->units, &co->units);
/* Init ifg_mis_size to node_count. So get_lower_bound returns correct results. */
- unit->ifg_mis_size = get_ifg_mis_size(unit);
+ unit->minimal_costs = unit->complete_costs - ou_max_ind_set_costs(unit);
}
static void co_collect_in_block(ir_node *block, void *env) {
del_pset(co->roots);
}
-copy_opt_t *new_copy_opt(be_chordal_env_t *chordal_env) {
+copy_opt_t *new_copy_opt(be_chordal_env_t *chordal_env, int (*get_costs)(ir_node*, ir_node*, int)) {
const char *s1, *s2, *s3;
int len;
- copy_opt_t *co;
+ copy_opt_t *co;
dbg = firm_dbg_register("ir.be.copyopt");
firm_dbg_set_mask(dbg, DEBUG_LVL);
co = xcalloc(1, sizeof(*co));
co->chordal_env = chordal_env;
+ co->get_costs = get_costs;
s1 = get_irp_prog_name();
s2 = get_entity_name(get_irg_entity(co->chordal_env->irg));
return 0;
}
-int co_get_copy_count(const copy_opt_t *co) {
+int get_costs_loop_depth(ir_node *root, ir_node* arg, int pos) {
+ int cost = 0;
+ ir_loop *loop;
+ ir_node *root_block = get_nodes_block(root);
+
+ assert(pos==-1 || is_Phi(root));
+ if (pos == -1) {
+ /* a perm places the copy in the same block as it resides */
+ loop = get_irn_loop(root_block);
+ } else {
+ /* for phis the copies are placed in the corresponding pred-block */
+ loop = get_irn_loop(get_Block_cfgpred_block(root_block, pos));
+ }
+ if (loop)
+ cost = 2*get_loop_depth(loop);
+ return cost+1;
+}
+
+int get_costs_all_one(ir_node *root, ir_node* arg, int pos) {
+ return 1;
+}
+
+int co_get_copy_costs(const copy_opt_t *co) {
int i, res = 0;
unit_t *curr;
list_for_each_entry(unit_t, curr, &co->units, units) {
int root_col = get_irn_col(co, curr->nodes[0]);
- res += curr->interf;
- DBG((dbg, LEVEL_1, "%n %N has %d intf\n", curr->nodes[0], curr->nodes[0], curr->interf));
for (i=1; i<curr->node_count; ++i)
if (root_col != get_irn_col(co, curr->nodes[i])) {
DBG((dbg, LEVEL_1, " %n %N\n", curr->nodes[i], curr->nodes[i]));
- res++;
+ res += curr->costs[i];
}
}
return res;
int res = 0;
unit_t *curr;
list_for_each_entry(unit_t, curr, &co->units, units)
- res += curr->interf + curr->node_count - curr->ifg_mis_size;
- return res;
-}
-
-int co_get_interferer_count(const copy_opt_t *co) {
- int res = 0;
- unit_t *curr;
- list_for_each_entry(unit_t, curr, &co->units, units)
- res += curr->interf;
+ res += curr->minimal_costs;
return res;
}
-
-/**
- * Needed for result checking
- */
-static void co_collect_for_checker(ir_node *block, void *env) {
- copy_opt_t *co = env;
- struct list_head *head = get_block_border_head(co->chordal_env, block);
- border_t *curr;
-
- list_for_each_entry_reverse(border_t, curr, head, list)
- if (curr->is_def && curr->is_real && is_curr_reg_class(curr->irn))
- obstack_ptr_grow(&co->ob, curr->irn);
-}
-
-/**
- * This O(n^2) checker checks if
- * two ifg-connected nodes have the same color
- * register constraint are satisfied
- */
-void co_check_allocation(copy_opt_t *co) {
- ir_node **nodes, *n1, *n2;
- int i, o;
-
- obstack_init(&co->ob);
- dom_tree_walk_irg(co->chordal_env->irg, co_collect_for_checker, NULL, co);
- obstack_ptr_grow(&co->ob, NULL);
-
- nodes = (ir_node **) obstack_finish(&co->ob);
- for (i = 0, n1 = nodes[i]; n1; n1 = nodes[++i]) {
- assert(arch_reg_is_allocatable(co->chordal_env->arch_env, n1, arch_pos_make_out(0),
- arch_get_irn_register(co->chordal_env->arch_env, n1, 0)) && "Constraint does not hold");
- for (o = i+1, n2 = nodes[o]; n2; n2 = nodes[++o])
- if (nodes_interfere(co->chordal_env, n1, n2)
- && get_irn_col(co, n1) == get_irn_col(co, n2)) {
- DBG((dbg, 0, "Error in graph %s: %n %d and %n %d have the same color %d.\n", co->name, n1, get_irn_graph_nr(n1), n2, get_irn_graph_nr(n2), get_irn_col(co, n1)));
- assert(0 && "Interfering values have the same color!");
- }
- }
- obstack_free(&co->ob, NULL);
- DBG((dbg, 2, "The checker seems to be happy!\n"));
-}
* Header for copy optimization problem. Analysis and set up of the problem.
*/
+/*
+ * TODO: get_nodes_block(get_irn_n(get_nodes_block(phi), i)); --> get_ifgblock_nodeblock
+ */
+
#ifndef _BECOPYOPT_H
#define _BECOPYOPT_H
#define DEBUG_LVL_HEUR LEVEL_1
#define DEBUG_LVL_ILP LEVEL_1
+typedef int(*cost_fct_t)(ir_node*, ir_node*, int);
+
/**
* Data representing the problem of copy minimization.
*/
typedef struct _copy_opt_t {
be_chordal_env_t *chordal_env;
- char *name; /**< ProgName__IrgName__RegClass */
- struct list_head units; /**< all units to optimize in right order */
- pset *roots; /**< used only temporary for detecting multiple appends */
+ char *name; /**< ProgName__IrgName__RegClass */
+ struct list_head units; /**< all units to optimize in right order */
+ pset *roots; /**< used only temporary for detecting multiple appends */
+ cost_fct_t get_costs; /**< function ptr used to get costs for copies */
struct obstack ob;
} copy_opt_t;
typedef struct _unit_t {
struct list_head units; /**< chain for all units */
copy_opt_t *co; /**< the copy_opt this unit belongs to */
- int interf; /**< number of nodes dropped due to interference */
int node_count; /**< size of the nodes array */
ir_node **nodes; /**< [0] is the root-node, others are non interfering args of it. */
- int ifg_mis_size; /**< size of a mis considering only ifg (not coloring conflicts) */
+ int *costs; /**< costs[i] are arising, if nodes[i] has a different color */
+ int complete_costs; /**< sum of all costs[i] */
+ int minimal_costs; /**< a lower bound for this ou, considering only ifg (not coloring conflicts) */
+
+ //TODO Think of the ordering.
+ int avg_costs; /**< average costs. controls the order of ou's. */
/* for heuristic */
struct list_head queue; /**< list of (mis/color) sorted by size of mis */
#define get_irn_col(co, irn) \
arch_register_get_index(arch_get_irn_register(co->chordal_env->arch_env, irn, 0))
+#define list_entry_units(lh) list_entry(lh, unit_t, units)
+
/**
* Generate the problem. Collect all infos and optimizable nodes.
*/
-copy_opt_t *new_copy_opt(be_chordal_env_t *chordal_env);
+copy_opt_t *new_copy_opt(be_chordal_env_t *chordal_env, int (*get_costs)(ir_node*, ir_node*, int));
/**
* Free the space...
*/
int is_optimizable_arg(const copy_opt_t *co, ir_node *irn);
+/**
+ * Computes the costs of a copy according to loop depth
+ * @param root, arg: clear.
+ * @param pos: -1 for perm-copies.
+ * Else the argument position of arg in the phi node root.
+ * @return Must be >= 0 in all cases.
+ */
+int get_costs_loop_depth(ir_node *root, ir_node* arg, int pos);
/**
- * Returns the current number of copies needed
+ * All costs equal 1. Using this will reduce the number of copies.
+ * @return Must be >= 0 in all cases.
*/
-int co_get_copy_count(const copy_opt_t *co);
+int get_costs_all_one(ir_node *root, ir_node* arg, int pos);
/**
- * Returns a lower bound for the number of copies needed based on interfering
- * arguments and the size of a max indep. set (only ifg-edges) of the other args.
+ * Returns the current costs the copies are causing
*/
-int co_get_lower_bound(const copy_opt_t *co);
+int co_get_copy_costs(const copy_opt_t *co);
/**
- * Returns the number of arguments interfering with their root node. This also
- * is a (worse) lower bound for the number of copies needed.
+ * Returns a lower bound for the costs of copies based on interfering
+ * arguments and the size of a max indep. set (only ifg-edges) of the other args.
*/
-int co_get_interferer_count(const copy_opt_t *co);
+int co_get_lower_bound(const copy_opt_t *co);
/**
* Solves the problem using a heuristic approach
*/
void co_ilp_opt(copy_opt_t *co);
-/**
- * Checks the register allocation for correctness
- */
-void co_check_allocation(copy_opt_t *co);
-
#endif