* @date 14.04.2006
*/
+#ifdef HAVE_CONFIG_H
+#include "config.h"
+#endif
+
+#ifdef WITH_LIBCORE
+#include <libcore/lc_opts.h>
+#include <libcore/lc_opts_enum.h>
+#endif /* WITH_LIBCORE */
+
#include <stdlib.h>
#include <limits.h>
#include "list.h"
+#include "pdeq.h"
#include "bitset.h"
+
#include "debug.h"
+#include "bitfiddle.h"
#include "irphase_t.h"
#include "irgraph_t.h"
#include "irnode_t.h"
#include "irprintf.h"
+#include "irtools.h"
+#include "bemodule.h"
#include "beabi.h"
#include "benode_t.h"
#include "becopyopt.h"
#include "becopyopt_t.h"
#include "bechordal_t.h"
+#define DUMP_BEFORE 1
+#define DUMP_AFTER 2
+#define DUMP_CLOUD 4
+#define DUMP_ALL 2 * DUMP_CLOUD - 1
+
+static unsigned dump_flags = 0;
+static int subtree_iter = 4;
+static int max_depth = 20;
+static double constr_factor = 0.9;
+
+/* Options using libcore */
+#ifdef WITH_LIBCORE
+
+static const lc_opt_enum_mask_items_t dump_items[] = {
+ { "before", DUMP_BEFORE },
+ { "after", DUMP_AFTER },
+ { "cloud", DUMP_CLOUD },
+ { "all", DUMP_ALL },
+ { NULL, 0 }
+};
+
+static lc_opt_enum_mask_var_t dump_var = {
+ &dump_flags, dump_items
+};
+
+static const lc_opt_table_entry_t options[] = {
+ LC_OPT_ENT_ENUM_MASK("dump", "dump ifg cloud", &dump_var),
+ LC_OPT_ENT_INT ("iter", "iterations for subtree nodes", &subtree_iter),
+ LC_OPT_ENT_DBL ("cf", "factor of constraint importance (between 0.0 and 1.0)", &constr_factor),
+ LC_OPT_ENT_INT ("max", "maximum recursion depth", &max_depth),
+ { NULL }
+};
+
+void be_init_copyheur2(void)
+{
+ lc_opt_entry_t *be_grp = lc_opt_get_grp(firm_opt_get_root(), "be");
+ lc_opt_entry_t *ra_grp = lc_opt_get_grp(be_grp, "ra");
+ lc_opt_entry_t *chordal_grp = lc_opt_get_grp(ra_grp, "chordal");
+ lc_opt_entry_t *co2_grp = lc_opt_get_grp(chordal_grp, "co2");
+
+ lc_opt_add_table(co2_grp, options);
+}
+
+BE_REGISTER_MODULE_CONSTRUCTOR(be_init_copyheur2);
+#endif
+
+/*
+ ____ _ _
+ / ___|| |_ __ _ _ __| |_
+ \___ \| __/ _` | '__| __|
+ ___) | || (_| | | | |_
+ |____/ \__\__,_|_| \__|
+
+*/
+
+#define INFEASIBLE(cost) ((cost) == INT_MAX)
+
+static be_ifg_dump_dot_cb_t ifg_dot_cb;
+
typedef unsigned col_t;
-typedef struct _co2_irn_t co2_irn_t;
+typedef struct _co2_irn_t co2_irn_t;
+typedef struct _co2_cloud_t co2_cloud_t;
+typedef struct _co2_cloud_irn_t co2_cloud_irn_t;
typedef struct {
- phase_t ph;
+ col_t col;
+ int costs;
+} col_cost_pair_t;
+
+typedef struct {
+ phase_t ph;
copy_opt_t *co;
- bitset_t *ignore_regs;
- co2_irn_t *touched;
+ bitset_t *ignore_regs;
+ co2_irn_t *touched;
+ int visited;
+ int n_regs;
+ struct list_head cloud_head;
DEBUG_ONLY(firm_dbg_module_t *dbg;)
} co2_t;
struct _co2_irn_t {
- ir_node *irn;
- co2_irn_t *touched_next;
- int costs;
- col_t tmp_col;
- col_t orig_col;
- unsigned fixed : 1;
- unsigned tmp_fixed : 1;
+ ir_node *irn;
+ affinity_node_t *aff;
+ co2_irn_t *touched_next;
+ col_t tmp_col;
+ col_t orig_col;
+ int last_color_change;
+ bitset_t *adm_cache;
+ unsigned fixed : 1;
+ unsigned tmp_fixed : 1;
+ unsigned is_constrained : 1;
struct list_head changed_list;
};
-#define get_co2_irn(co2, irn) ((co2_irn_t *) phase_get_or_set_irn_data(&co2->ph, irn))
+struct _co2_cloud_irn_t {
+ struct _co2_irn_t inh;
+ co2_cloud_t *cloud;
+ int visited;
+ int index;
+ co2_cloud_irn_t *mst_parent;
+ int mst_costs;
+ int mst_n_childs;
+ co2_cloud_irn_t **mst_childs;
+ int *col_costs;
+ int costs;
+ int *fronts;
+ int *color_badness;
+ col_cost_pair_t *tmp_coloring;
+ struct list_head cloud_list;
+ struct list_head mst_list;
+};
+
+struct _co2_cloud_t {
+ co2_t *env;
+ struct obstack obst;
+ int costs;
+ int mst_costs;
+ int inevit;
+ int best_costs;
+ int n_memb;
+ int n_constr;
+ int max_degree;
+ int ticks;
+ double freedom;
+ co2_cloud_irn_t *master;
+ co2_cloud_irn_t *mst_root;
+ co2_cloud_irn_t **seq;
+ struct list_head members_head;
+ struct list_head list;
+};
-static void co2_irn_init(phase_t *ph, ir_node *irn, void *data)
+typedef struct {
+ co2_cloud_irn_t *src, *tgt;
+ int costs;
+} edge_t;
+
+#define FRONT_BASE(ci,col) ((ci)->fronts + col * (ci)->mst_n_childs)
+
+#define get_co2_irn(co2, irn) ((co2_irn_t *) phase_get_or_set_irn_data(&co2->ph, irn))
+#define get_co2_cloud_irn(co2, irn) ((co2_cloud_irn_t *) phase_get_or_set_irn_data(&co2->ph, irn))
+
+static void *co2_irn_init(phase_t *ph, ir_node *irn, void *data)
{
- co2_t *env = (co2_t *) ph;
- co2_irn_t *ci = data;
+ co2_t *env = (co2_t *) ph;
+ affinity_node_t *a = get_affinity_info(env->co, irn);
+ size_t size = a ? sizeof(co2_cloud_irn_t) : sizeof(co2_irn_t);
+ co2_irn_t *ci = data ? data : phase_alloc(ph, size);
- memset(ci, 0, sizeof(ci[0]));
+ memset(ci, 0, size);
INIT_LIST_HEAD(&ci->changed_list);
- ci->irn = irn;
ci->touched_next = env->touched;
ci->orig_col = get_irn_col(env->co, irn);
env->touched = ci;
+ ci->irn = irn;
+ ci->aff = a;
+
+ if(a) {
+ co2_cloud_irn_t *cci = (co2_cloud_irn_t *) ci;
+ INIT_LIST_HEAD(&cci->cloud_list);
+ cci->mst_parent = cci;
+ }
+
+ return ci;
}
+#define CLOUD_WEIGHT(c) ((1 - constr_factor) * (c)->costs + constr_factor * (c)->freedom)
-static int co2_irn_cmp(const void *a, const void *b)
+static int cmp_clouds_gt(const void *a, const void *b)
{
- const co2_irn_t **p = a;
- const co2_irn_t **q = b;
- return (*q)->costs - (*p)->costs;
+ const co2_cloud_t * const *p = a;
+ const co2_cloud_t * const *q = b;
+ double c = CLOUD_WEIGHT(*p);
+ double d = CLOUD_WEIGHT(*q);
+ return QSORT_CMP(d, c);
}
-typedef struct {
- col_t col;
- int costs;
-} col_cost_pair_t;
-
/**
* An order on color/costs pairs.
* If the costs are equal, we use the color as a kind of normalization.
{
const col_cost_pair_t *p = a;
const col_cost_pair_t *q = b;
- int cost_diff = p->costs - q->costs;
+ int c = p->costs;
+ int d = q->costs;
+ return QSORT_CMP(c, d);
+}
- return cost_diff;
- // return cost_diff != 0 ? cost_diff : p->col - q->col;
+int cmp_edges(const void *a, const void *b)
+{
+ const edge_t *p = a;
+ const edge_t *q = b;
+ return QSORT_CMP(q->costs, p->costs);
}
static col_t get_col(co2_t *env, ir_node *irn)
return ci->tmp_fixed ? ci->tmp_col : ci->orig_col;
}
-static INLINE color_is_fix(co2_t *env, ir_node *irn)
+static INLINE int color_is_fix(co2_t *env, ir_node *irn)
{
co2_irn_t *ci = get_co2_irn(env, irn);
return ci->fixed || ci->tmp_fixed;
}
+static INLINE bitset_t *get_adm(co2_t *env, co2_irn_t *ci)
+{
+ if(!ci->adm_cache) {
+ arch_register_req_t req;
+ ci->adm_cache = bitset_obstack_alloc(phase_obst(&env->ph), env->n_regs);
+ arch_get_register_req(env->co->aenv, &req, ci->irn, BE_OUT_POS(0));
+ if(arch_register_req_is(&req, limited)) {
+ req.limited(req.limited_env, ci->adm_cache);
+ ci->is_constrained = 1;
+ }
+ else {
+ bitset_copy(ci->adm_cache, env->ignore_regs);
+ bitset_flip_all(ci->adm_cache);
+ }
+ }
+
+ return ci->adm_cache;
+}
+
+static INLINE bitset_t *admissible_colors(co2_t *env, co2_irn_t *ci, bitset_t *bs)
+{
+ bitset_copy(bs, get_adm(env, ci));
+ return bs;
+}
+
+static INLINE int is_color_admissible(co2_t *env, co2_irn_t *ci, col_t col)
+{
+ bitset_t *bs = get_adm(env, ci);
+ return bitset_is_set(bs, col);
+}
+
+static INLINE int is_constrained(co2_t *env, co2_irn_t *ci)
+{
+ if(!ci->adm_cache)
+ get_adm(env, ci);
+ return ci->is_constrained;
+}
+
static void incur_constraint_costs(co2_t *env, ir_node *irn, col_cost_pair_t *col_costs, int costs)
{
bitset_t *aux = bitset_alloca(env->co->cls->n_regs);
req.limited(req.limited_env, aux);
n_constr = bitset_popcnt(aux);
- bitset_foreach(aux, elm)
- col_costs[elm].costs += costs / n_constr;
+ bitset_foreach(aux, elm) {
+ col_costs[elm].costs = add_saturated(col_costs[elm].costs, costs / n_constr);
+ }
}
}
* @param irn The node.
* @param col_costs An array of colors x costs where the costs are written to.
*/
-static void determine_color_costs(co2_t *env, ir_node *irn, col_cost_pair_t *col_costs)
+static void determine_color_costs(co2_t *env, co2_irn_t *ci, col_cost_pair_t *col_costs)
{
+ ir_node *irn = ci->irn;
be_ifg_t *ifg = env->co->cenv->ifg;
int n_regs = env->co->cls->n_regs;
bitset_t *forb = bitset_alloca(n_regs);
- affinity_node_t *a = get_affinity_info(env->co, irn);
+ affinity_node_t *a = ci->aff;
- arch_register_req_t req;
bitset_pos_t elm;
ir_node *pos;
void *it;
int i;
/* Put all forbidden colors into the aux bitset. */
- arch_get_register_req(env->co->aenv, &req, irn, BE_OUT_POS(0));
- if(arch_register_req_is(&req, limited)) {
- req.limited(req.limited_env, forb);
- bitset_flip_all(forb);
- }
- else
- bitset_copy(forb, env->ignore_regs);
+ admissible_colors(env, ci, forb);
+ bitset_flip_all(forb);
for(i = 0; i < n_regs; ++i) {
col_costs[i].col = i;
neighb_t *n;
co_gs_foreach_neighb(a, n) {
- co2_irn_t *ni = get_co2_irn(env, n->irn);
-
- if(ni->fixed) {
+ if(color_is_fix(env, n->irn)) {
col_t col = get_col(env, n->irn);
- col_costs[col].costs -= 100 * n->costs;
+ col_costs[col].costs = add_saturated(col_costs[col].costs, -n->costs * 128);
}
incur_constraint_costs(env, n->irn, col_costs, -n->costs);
it = be_ifg_neighbours_iter_alloca(ifg);
be_ifg_foreach_neighbour(ifg, it, irn, pos) {
col_t col = get_col(env, pos);
- if(color_is_fix(env, pos))
- col_costs[col].costs = INT_MAX;
+ if(color_is_fix(env, pos)) {
+ col_costs[col].costs = INT_MAX;
+ }
else {
incur_constraint_costs(env, pos, col_costs, INT_MAX);
- col_costs[col].costs++;
+ col_costs[col].costs = add_saturated(col_costs[col].costs, 8 * be_ifg_degree(ifg, pos));
}
}
+ be_ifg_neighbours_break(ifg, it);
/* Set the costs to infinity for each color which is not allowed at this node. */
- bitset_foreach(forb, elm)
- col_costs[elm].costs = INT_MAX;
+ bitset_foreach(forb, elm) {
+ col_costs[elm].costs = INT_MAX;
+ }
}
-static int curr_costs(co2_t *env, affinity_node_t *a)
+static void single_color_cost(co2_t *env, co2_irn_t *ci, col_t col, col_cost_pair_t *seq)
{
- col_t a_col = get_col(env, a->irn);
- int costs = 0;
- neighb_t *n;
+ int n_regs = env->co->cls->n_regs;
+ int i;
- co_gs_foreach_neighb(a, n) {
- col_t n_col = get_col(env, n->irn);
- costs += n_col != a_col ? n->costs : 0;
+ for(i = 0; i < n_regs; ++i) {
+ seq[i].col = i;
+ seq[i].costs = INT_MAX;
}
- return costs;
+ assert(is_color_admissible(env, ci, col));
+ seq[col].col = 0;
+ seq[0].col = col;
+ seq[0].costs = 0;
}
static void reject_coloring(struct list_head *h)
pos->tmp_fixed = 0;
}
-static void materialize_coloring(co2_t *env, struct list_head *h)
+static void materialize_coloring(struct list_head *h)
{
- const arch_register_class_t *cls = env->co->cls;
- const arch_env_t *aenv = env->co->aenv;
co2_irn_t *pos;
list_for_each_entry(co2_irn_t, pos, h, changed_list) {
- pos->orig_col = pos->tmp_col;
+ pos->orig_col = pos->tmp_col;
pos->tmp_fixed = 0;
}
}
static int change_color_not(co2_t *env, ir_node *irn, col_t not_col, struct list_head *parent_changed, int depth);
-
-static INLINE int recolor(co2_t *env, ir_node *irn, col_cost_pair_t *col_list, int n_regs, struct list_head *parent_changed, int depth)
+static int recolor(co2_t *env, ir_node *irn, col_cost_pair_t *col_list, struct list_head *parent_changed, int depth)
{
- be_ifg_t *ifg = env->co->cenv->ifg;
- co2_irn_t *ci = get_co2_irn(env, irn);
- int res = 0;
+ int n_regs = env->co->cls->n_regs;
+ be_ifg_t *ifg = env->co->cenv->ifg;
+ co2_irn_t *ci = get_co2_irn(env, irn);
+ int res = 0;
int i;
+ if(depth >= max_depth)
+ return 0;
+
for(i = 0; i < n_regs; ++i) {
col_t tgt_col = col_list[i].col;
unsigned costs = col_list[i].costs;
ir_node *n;
void *it;
- DBG((env->dbg, LEVEL_2, "\t%2Dtrying color %d(%d) on %+F\n", depth, tgt_col, costs, irn));
+ DBG((env->dbg, LEVEL_3, "\t\t%2{firm:indent}trying color %d(%d) on %+F\n", depth, tgt_col, costs, irn));
/* If the costs for that color (and all successive) are infinite, bail out we won't make it anyway. */
- if(costs == INT_MAX) {
+ if(INFEASIBLE(costs)) {
+ DB((env->dbg, LEVEL_4, "\t\t%2{firm:indent}color %d infeasible\n", depth, tgt_col));
ci->tmp_fixed = 0;
return 0;
}
/* Set the new color of the node and mark the node as temporarily fixed. */
- ci->tmp_col = tgt_col;
- ci->tmp_fixed = 1;
+ ci->tmp_col = tgt_col;
+ ci->tmp_fixed = 1;
/*
If that color has costs > 0, there's at least one neighbor having that color,
break;
}
}
-
+ be_ifg_neighbours_break(ifg, it);
/*
We managed to assign the target color to all neighbors, so from the perspective
of the current node, every thing was ok and we can return safely.
*/
if(neigh_ok) {
- DBG((env->dbg, LEVEL_2, "\t%2Dcolor %d(%d) was ok\n", depth, tgt_col, costs));
+ DBG((env->dbg, LEVEL_3, "\t\t%2{firm:indent}color %d(%d) was ok\n", depth, tgt_col, costs));
list_splice(&changed, parent_changed);
res = 1;
break;
int res = 0;
col_t col = get_col(env, irn);
- DBG((env->dbg, LEVEL_2, "\t%2Dclearing %+F(%d) of color %d\n", depth, irn, col, not_col));
+ DBG((env->dbg, LEVEL_3, "\t\t%2{firm:indent}clearing %+F(%d) of color %d\n", depth, irn, col, not_col));
/* the node does not have to forbidden color. That's fine, mark it as visited and return. */
if(col != not_col) {
if(!ci->tmp_fixed) {
- ci->tmp_col = col;
- ci->tmp_fixed = 1;
+ ci->tmp_col = col;
+ ci->tmp_fixed = 1;
}
list_add(&ci->changed_list, parent_changed);
col_cost_pair_t *csts = alloca(n_regs * sizeof(csts[0]));
/* Get the costs for giving the node a specific color. */
- determine_color_costs(env, irn, csts);
+ determine_color_costs(env, ci, csts);
/* Since the node must not have the not_col, set the costs for that color to "infinity" */
csts[not_col].costs = INT_MAX;
qsort(csts, n_regs, sizeof(csts[0]), col_cost_pair_lt);
/* Try recoloring the node using the color list. */
- res = recolor(env, irn, csts, n_regs, parent_changed, depth);
+ res = recolor(env, irn, csts, parent_changed, depth);
}
/* If we came here, everything went ok. */
return res;
}
+static int change_color_single(co2_t *env, ir_node *irn, col_t tgt_col, struct list_head *parent_changed, int depth)
+{
+ co2_irn_t *ci = get_co2_irn(env, irn);
+ col_t col = get_col(env, irn);
+ int res = 0;
+
+ DBG((env->dbg, LEVEL_3, "\t\t%2{firm:indent}trying to set %+F(%d) to color %d\n", depth, irn, col, tgt_col));
+
+ /* the node has the wanted color. That's fine, mark it as visited and return. */
+ if(col == tgt_col) {
+ if(!ci->tmp_fixed) {
+ ci->tmp_col = col;
+ ci->tmp_fixed = 1;
+ list_add(&ci->changed_list, parent_changed);
+ }
+
+ res = 1;
+ goto end;
+ }
+
+ if(!color_is_fix(env, irn) && is_color_admissible(env, ci, tgt_col)) {
+ int n_regs = env->co->cls->n_regs;
+ col_cost_pair_t *seq = alloca(n_regs * sizeof(seq[0]));
+
+ /* Get the costs for giving the node a specific color. */
+ single_color_cost(env, ci, tgt_col, seq);
+
+ /* Try recoloring the node using the color list. */
+ res = recolor(env, irn, seq, parent_changed, depth);
+
+ }
+
+end:
+ DB((env->dbg, LEVEL_3, "\t\t%2{firm:indent}color %d %s for %+F\n", depth, tgt_col, res ? "was ok" : "failed", irn));
+ return res;
+}
+
/**
- * Try to bring a node to a certain color.
+ * Examine the costs of the current coloring concerning a MST subtree.
+ * @param ci The subtree root.
+ * @param col The color of @p ci.
+ * @return The best coloring for that subtree under the assumption that @p ci has color @p col.
*/
-static int try_color(co2_t *env, ir_node *irn, col_t tgt_col, struct list_head *changed)
+static int examine_subtree_coloring(co2_cloud_irn_t *ci, col_t col)
{
- co2_irn_t *ci = get_co2_irn(env, irn);
- be_ifg_t *ifg = env->co->cenv->ifg;
+ int *front = FRONT_BASE(ci, col);
+ int cost = 0;
+ int i;
- ir_node *n;
+ for(i = 0; i < ci->mst_n_childs; ++i) {
+ co2_cloud_irn_t *chld = ci->mst_childs[i];
+ col_t chld_col = front[i];
+
+ cost += examine_subtree_coloring(chld, chld_col);
+ cost += col != chld_col ? chld->mst_costs : 0;
+ }
+
+ return cost;
+}
+
+/**
+ * Determine color badnesses of a node.
+ * Badness means that it is unlikely that the node in question can
+ * obtain a color. The higher the badness, the more unlikely it is that
+ * the node can be assigned that color.
+ * @param ci The node.
+ * @param badness An integer array as long as there are registers.
+ * @note The array <code>badness</code> is not cleared.
+ */
+static void node_color_badness(co2_cloud_irn_t *ci, int *badness)
+{
+ co2_t *env = ci->cloud->env;
+ co2_irn_t *ir = &ci->inh;
+ int n_regs = env->n_regs;
+ be_ifg_t *ifg = env->co->cenv->ifg;
+ bitset_t *bs = bitset_alloca(n_regs);
+
+ bitset_pos_t elm;
+ ir_node *irn;
void *it;
- ci->tmp_fixed = 1;
- ci->tmp_col = tgt_col;
- list_add(&ci->changed_list, changed);
+ admissible_colors(env, &ci->inh, bs);
+ bitset_flip_all(bs);
+ bitset_foreach(bs, elm)
+ badness[elm] = ci->costs;
+ /* Use constrained/fixed interfering neighbors to influence the color badness */
it = be_ifg_neighbours_iter_alloca(ifg);
- be_ifg_foreach_neighbour(ifg, it, irn, n) {
- col_t c = get_col(env, n);
-
- /* If the neighbor has the target color, re-color the neighbor. */
- if(c == tgt_col) {
- int ok = change_color_not(env, n, tgt_col, changed, 1);
- if(!ok)
- return 0;
+ be_ifg_foreach_neighbour(ifg, it, ir->irn, irn) {
+ co2_irn_t *ni = get_co2_irn(env, irn);
+
+ admissible_colors(env, ni, bs);
+ if(bitset_popcnt(bs) == 1) {
+ bitset_pos_t c = bitset_next_set(bs, 0);
+ badness[c] += ci->costs;
}
- }
- return 1;
+ else if(ni->fixed) {
+ col_t c = get_col(env, ni->irn);
+ badness[c] += ci->costs;
+ }
+ }
+ be_ifg_neighbours_break(ifg, it);
}
-static INLINE int costs_sufficient(co2_irn_t *irn, int costs)
+/**
+ * Determine the badness of a MST subtree.
+ * The badness is written into the <code>color_badness</code> array of each node and accumulated in the parents.
+ * @see node_color_badness() for a definition of badness.
+ * @param ci The root of the subtree.
+ * @param depth Depth for debugging purposes.
+ */
+static void determine_color_badness(co2_cloud_irn_t *ci, int depth)
{
- return costs == -irn->costs;
+ co2_t *env = ci->cloud->env;
+ int i, j;
+
+ node_color_badness(ci, ci->color_badness);
+
+ /* Collect the color badness for the whole subtree */
+ for(i = 0; i < ci->mst_n_childs; ++i) {
+ co2_cloud_irn_t *child = ci->mst_childs[i];
+ determine_color_badness(child, depth + 1);
+
+ for(j = 0; j < env->n_regs; ++j)
+ ci->color_badness[j] += child->color_badness[j];
+ }
+
+ for(j = 0; j < env->n_regs; ++j)
+ DBG((env->dbg, LEVEL_2, "%2{firm:indent}%+F col %d badness %d\n", depth, ci->inh.irn, j, ci->color_badness[j]));
}
-static void process_affinity_node(co2_t *env, co2_irn_t *ci)
+/**
+ * Unfix all nodes in a MST subtree.
+ */
+static void unfix_subtree(co2_cloud_irn_t *ci)
{
- int n_regs = env->co->cls->n_regs;
- col_cost_pair_t *col_seq = alloca(n_regs * sizeof(col_seq[0]));
- affinity_node_t *a = get_affinity_info(env->co, ci->irn);
- int best_cost = curr_costs(env, a);
- col_t best_col = ci->orig_col;
-
- neighb_t *n;
int i;
- assert(a != NULL && "This node must be an affinity node");
+ ci->inh.fixed = 0;
+ for(i = 0; i < ci->mst_n_childs; ++i)
+ unfix_subtree(ci->mst_childs[i]);
+}
- /* If that node has already been fixed, leave it alone. */
- if(ci->fixed)
- return;
+static int coalesce_top_down(co2_cloud_irn_t *ci, int child_nr, int depth)
+{
+ co2_t *env = ci->cloud->env;
+ col_cost_pair_t *seq = alloca(env->n_regs * sizeof(seq[0]));
+ int is_root = ci->mst_parent == ci;
+ col_t parent_col = is_root ? -1 : get_col(env, ci->mst_parent->inh.irn);
+ int min_badness = INT_MAX;
+ int best_col_costs = INT_MAX;
+ int best_col = -1;
+ int n_regs = env->n_regs;
+ int n_iter = is_root ? MIN(n_regs, subtree_iter) : 1;
+
+ struct list_head changed;
+ int ok, i, j;
- DB((env->dbg, LEVEL_1, "affinity node %+F cost %d\n", ci->irn, ci->costs));
+ for(i = 0; i < n_regs; ++i) {
+ int badness = ci->color_badness[i];
- /* determine the order in which the colors shall be tried. */
- determine_color_costs(env, ci->irn, col_seq);
- qsort(col_seq, n_regs, sizeof(col_seq[0]), col_cost_pair_lt);
+ seq[i].col = i;
+ seq[i].costs = is_color_admissible(env, &ci->inh, i) ? badness : INT_MAX;
- /* Try the colors. */
- for(i = 0; i < n_regs; ++i) {
- col_t col = col_seq[i].col;
- int costs = col_seq[i].costs;
+ min_badness = MIN(min_badness, badness);
+ }
- struct list_head changed;
- int ok;
+ /* If we are not the root and the parent's color is allowed for this node give it top prio. */
+ if(!is_root && is_color_admissible(env, &ci->inh, parent_col))
+ seq[parent_col].costs = min_badness - 1;
- DB((env->dbg, LEVEL_2, "\tbest color %d incurring costs %d\n", best_col, best_cost));
+ /* Sort the colors. The will be processed in that ordering. */
+ qsort(seq, env->n_regs, sizeof(seq[0]), col_cost_pair_lt);
- /* Also, if the costs are not more optimizable, we do not try additional colors and finish this node. */
- if(best_cost == 0)
- break;
+ DBG((env->dbg, LEVEL_2, "\t%2{firm:indent}starting top-down coalesce for %+F\n", depth, ci->inh.irn));
+ INIT_LIST_HEAD(&changed);
+ for(i = 0; i < (best_col < 0 ? n_regs : n_iter); ++i) {
+ col_t col = seq[i].col;
+ int add_cost = !is_root && col != parent_col ? ci->mst_costs : 0;
- if(costs == INT_MAX) {
- DB((env->dbg, LEVEL_1, "\tall following colors after %d will be infeasible\n", col));
- break;
- }
+ int subtree_costs, sum_costs;
+
+ DBG((env->dbg, LEVEL_2, "\t%2{firm:indent}%+F trying color %d\n", depth, ci->inh.irn, col));
+ unfix_subtree(ci);
INIT_LIST_HEAD(&changed);
+ ok = change_color_single(env, ci->inh.irn, col, &changed, depth);
+ if(ok) {
+ materialize_coloring(&changed);
+ ci->inh.fixed = 1;
+ }
- DB((env->dbg, LEVEL_1, "\ttrying color %d costing %d\n", col, costs));
+ else
+ continue;
- /* try to assign the same color to the node and all its neighbors. */
- ok = try_color(env, a->irn, col, &changed);
+ for(j = 0; j < ci->mst_n_childs; ++j) {
+ co2_cloud_irn_t *child = ci->mst_childs[j];
+ ok = coalesce_top_down(child, j, depth + 1) >= 0;
+ if(ok)
+ child->inh.fixed = 1;
+ else
+ break;
+ }
- if(!ok) {
- DBG((env->dbg, LEVEL_2, "\t-> failed.\n"));
- reject_coloring(&changed);
+ /* If the subtree could not be colored, we have to try another color. */
+ if(!ok)
continue;
+
+ subtree_costs = examine_subtree_coloring(ci, col);
+ sum_costs = subtree_costs + add_cost;
+ DBG((env->dbg, LEVEL_2, "\t%2{firm:indent}-> %+F costing %d + %d is ok.\n", depth, ci->inh.irn, subtree_costs, add_cost));
+
+ if(sum_costs < best_col_costs) {
+ best_col = col;
+ best_col_costs = sum_costs;
+ ci->col_costs[col] = subtree_costs;
}
- /*
- Evaluate the recoloring and mark it is as new best if it was better
- as the best current known solution.
- */
- costs = curr_costs(env, a);
- DBG((env->dbg, LEVEL_2, "\t-> cost: %d\n", costs));
+ if(sum_costs == 0)
+ break;
+ }
+
+ if(!is_root) {
+ int *front = FRONT_BASE(ci->mst_parent, parent_col);
+ front[child_nr] = best_col;
+ }
+
+ return best_col;
+}
+
+static void populate_cloud(co2_t *env, co2_cloud_t *cloud, affinity_node_t *a, int curr_costs)
+{
+ be_ifg_t *ifg = env->co->cenv->ifg;
+ co2_cloud_irn_t *ci = get_co2_cloud_irn(env, a->irn);
+ int costs = 0;
+ neighb_t *n;
+
+ if(ci->cloud)
+ return;
+
+ /* mark the node as visited and add it to the cloud. */
+ ci->cloud = cloud;
+ list_add(&ci->cloud_list, &cloud->members_head);
+
+ DB((env->dbg, LEVEL_2, "\t%+F\n", ci->inh.irn));
+
+ /* determine the nodes costs */
+ co_gs_foreach_neighb(a, n) {
+ costs += n->costs;
+ DB((env->dbg, LEVEL_3, "\t\tneigh %+F cost %d\n", n->irn, n->costs));
+ if(be_ifg_connected(ifg, a->irn, n->irn))
+ cloud->inevit += n->costs;
+ }
+
+ /* add the node's cost to the total costs of the cloud. */
+ ci->costs = costs;
+ cloud->costs += costs;
+ cloud->n_constr += is_constrained(env, &ci->inh);
+ cloud->freedom += bitset_popcnt(get_adm(env, &ci->inh));
+ cloud->max_degree = MAX(cloud->max_degree, ci->inh.aff->degree);
+ cloud->n_memb++;
+
+ /* If this is the heaviest node in the cloud, set it as the cloud's master. */
+ if(costs >= curr_costs) {
+ curr_costs = costs;
+ cloud->master = ci;
+ }
+
+ /* add all the neighbors of the node to the cloud. */
+ co_gs_foreach_neighb(a, n) {
+ affinity_node_t *an = get_affinity_info(env->co, n->irn);
+ assert(an);
+ populate_cloud(env, cloud, an, curr_costs);
+ }
+}
+
+static co2_cloud_t *new_cloud(co2_t *env, affinity_node_t *a)
+{
+ co2_cloud_t *cloud = phase_alloc(&env->ph, sizeof(cloud[0]));
+ co2_cloud_irn_t *ci;
+ int i;
+
+ DBG((env->dbg, LEVEL_2, "new cloud with %+F\n", a->irn));
+ memset(cloud, 0, sizeof(cloud[0]));
+ INIT_LIST_HEAD(&cloud->members_head);
+ INIT_LIST_HEAD(&cloud->list);
+ list_add(&cloud->list, &env->cloud_head);
+ cloud->best_costs = INT_MAX;
+ cloud->env = env;
+ env->visited++;
+ populate_cloud(env, cloud, a, 0);
+ cloud->freedom = (cloud->n_memb * env->n_regs) / cloud->freedom;
+
+ /* Also allocate space for the node sequence and compute that sequence. */
+ cloud->seq = phase_alloc(&env->ph, cloud->n_memb * sizeof(cloud->seq[0]));
+
+ i = 0;
+ list_for_each_entry(co2_cloud_irn_t, ci, &cloud->members_head, cloud_list) {
+ ci->index = i;
+ cloud->seq[i++] = ci;
+ }
+ DBG((env->dbg, LEVEL_2, "cloud cost %d, freedom %f\n", cloud->costs, cloud->freedom));
+
+ return cloud;
+}
+
+static void apply_coloring(co2_cloud_irn_t *ci, col_t col, int depth)
+{
+ ir_node *irn = ci->inh.irn;
+ int *front = FRONT_BASE(ci, col);
+ int i, ok;
+ struct list_head changed;
+
+ INIT_LIST_HEAD(&changed);
- if(costs < best_cost) {
- best_cost = costs;
- best_col = col;
+ DBG((ci->cloud->env->dbg, LEVEL_2, "%2{firm:indent}setting %+F to %d\n", depth, irn, col));
+ ok = change_color_single(ci->cloud->env, irn, col, &changed, depth);
+ // assert(ok && "Color changing may not fail while committing the coloring");
+ materialize_coloring(&changed);
+
+ for(i = 0; i < ci->mst_n_childs; ++i) {
+ apply_coloring(ci->mst_childs[i], front[i], depth + 1);
+ }
+}
+
+static co2_cloud_irn_t *find_mst_root(co2_cloud_irn_t *ci)
+{
+ while(ci != ci->mst_parent)
+ ci = ci->mst_parent;
+ return ci;
+}
+
+
+static void process_cloud(co2_cloud_t *cloud)
+{
+ co2_t *env = cloud->env;
+ int n_regs = env->n_regs;
+ int n_edges = 0;
+ int *mst_edges = xmalloc(cloud->n_memb * cloud->n_memb * sizeof(mst_edges[0]));
+ pdeq *q;
- materialize_coloring(env, &changed);
+ edge_t *edges;
+ int i;
+ int best_col;
+
+ memset(mst_edges, 0, cloud->n_memb * cloud->n_memb * sizeof(mst_edges[0]));
+
+ /* Collect all edges in the cloud on an obstack and sort the increasingly */
+ obstack_init(&cloud->obst);
+ for(i = 0; i < cloud->n_memb; ++i) {
+ co2_cloud_irn_t *ci = cloud->seq[i];
+ neighb_t *n;
+
+ co_gs_foreach_neighb(ci->inh.aff, n) {
+ co2_cloud_irn_t *ni = get_co2_cloud_irn(cloud->env, n->irn);
+ if(ci->index < ni->index) {
+ edge_t e;
+ e.src = ci;
+ e.tgt = ni;
+ e.costs = n->costs;
+ obstack_grow(&cloud->obst, &e, sizeof(e));
+ n_edges++;
+ }
+ }
+ }
+ edges = obstack_finish(&cloud->obst);
+ qsort(edges, n_edges, sizeof(edges[0]), cmp_edges);
+
+ /* Compute the maximum spanning tree using Kruskal/Union-Find */
+ DBG((env->dbg, LEVEL_2, "computing spanning tree of cloud with master %+F\n", cloud->master->inh.irn));
+ for(i = 0; i < n_edges; ++i) {
+ edge_t *e = &edges[i];
+ co2_cloud_irn_t *rs = find_mst_root(e->src);
+ co2_cloud_irn_t *rt = find_mst_root(e->tgt);
+
+ /* if the union/find roots are different */
+ if(rs != rt) {
+ int si = e->src->index;
+ int ti = e->tgt->index;
+
+ /* unify the sets */
+ rs->mst_parent = rt;
+ DBG((env->dbg, LEVEL_2, "\tadding edge %+F -- %+F cost %d\n", rs->inh.irn, rt->inh.irn, e->costs));
+
+ /* this edge is in the MST, so set it in the bitset. */
+ mst_edges[si * cloud->n_memb + ti] = e->costs;
+ mst_edges[ti * cloud->n_memb + si] = e->costs;
+ }
+ }
+ obstack_free(&cloud->obst, edges);
+
+ cloud->master->mst_parent = cloud->master;
+ cloud->mst_root = cloud->master;
+ q = new_pdeq1(cloud->master);
+ while(!pdeq_empty(q)) {
+ co2_cloud_irn_t *ci = pdeq_getl(q);
+ int ofs = ci->index * cloud->n_memb;
+ int end = ofs + cloud->n_memb;
+ int i;
+
+ ci->mst_n_childs = 0;
+ for(i = ofs; i < end; ++i) {
+ if(mst_edges[i] != 0) {
+ int other = i - ofs;
+ co2_cloud_irn_t *child = cloud->seq[i - ofs];
+
+ /* put the child to the worklist */
+ pdeq_putr(q, child);
+
+ /* make ci the parent of the child and add the child to the children array of the parent */
+ child->mst_parent = ci;
+ child->mst_costs = mst_edges[i];
+ ci->mst_n_childs++;
+ obstack_ptr_grow(&cloud->obst, child);
+
+ mst_edges[other * cloud->n_memb + ci->index] = 0;
+ mst_edges[i] = 0;
+ }
}
- /* If we had a better coloring already, reject the current one. */
- else
- reject_coloring(&changed);
+ obstack_ptr_grow(&cloud->obst, NULL);
+ ci->mst_childs = obstack_finish(&cloud->obst);
+ }
+ del_pdeq(q);
+ free(mst_edges);
+
+ DBG((env->dbg, LEVEL_3, "mst:\n"));
+ for(i = 0; i < cloud->n_memb; ++i) {
+ DEBUG_ONLY(co2_cloud_irn_t *ci = cloud->seq[i]);
+ DBG((env->dbg, LEVEL_3, "\t%+F -> %+F\n", ci->inh.irn, ci->mst_parent->inh.irn));
}
- /* We found the definite color for this node, so fix it. */
- ci->fixed = 1;
+ for(i = 0; i < cloud->n_memb; ++i) {
+ co2_cloud_irn_t *ci = cloud->seq[i];
+ int n_childs = ci->mst_n_childs;
+ int j;
- DB((env->dbg, LEVEL_1, "\tusing %d(%d)\n", best_col, best_cost));
+ ci->col_costs = obstack_alloc(&cloud->obst, n_regs * sizeof(ci->col_costs[0]));
+ ci->tmp_coloring = obstack_alloc(&cloud->obst, n_regs * sizeof(ci->tmp_coloring[0]));
+ ci->fronts = obstack_alloc(&cloud->obst, n_regs * n_childs * sizeof(ci->fronts[0]));
+ ci->color_badness = obstack_alloc(&cloud->obst, n_regs * sizeof(ci->fronts[0]));
+ memset(ci->color_badness, 0, n_regs * sizeof(ci->color_badness[0]));
+ memset(ci->col_costs, 0, n_regs * sizeof(ci->col_costs[0]));
+ memset(ci->tmp_coloring, 0, n_regs * sizeof(ci->tmp_coloring[0]));
+ memset(ci->fronts, 0, n_regs * n_childs * sizeof(ci->fronts[0]));
- /* Now, investigate all affinity neighbors of this node. */
- if(0) {
- co2_irn_t **neighbors = alloca(a->degree * sizeof(neighbors[0]));
+ for(j = 0; j < env->n_regs; j++)
+ ci->col_costs[j] = INT_MAX;
+
+ }
- i = 0;
- co_gs_foreach_neighb(a, n)
- neighbors[i++] = get_co2_irn(env, n->irn);
+ determine_color_badness(cloud->mst_root, 0);
+ best_col = coalesce_top_down(cloud->mst_root, -1, 0);
+ unfix_subtree(cloud->mst_root);
+ apply_coloring(cloud->mst_root, best_col, 0);
- qsort(neighbors, a->degree, sizeof(neighbors[0]), co2_irn_cmp);
- for(i = 0; i < a->degree; ++i)
- process_affinity_node(env, neighbors[i]);
+ /* The coloring should represent the one with the best costs. */
+ //materialize_coloring(&changed);
+ DBG((env->dbg, LEVEL_2, "\tbest coloring for root %+F was %d costing %d\n",
+ cloud->mst_root->inh.irn, best_col, examine_subtree_coloring(cloud->mst_root, best_col)));
+
+ /* Fix all nodes in the cloud. */
+ for(i = 0; i < cloud->n_memb; ++i)
+ cloud->seq[i]->inh.fixed = 1;
+
+ /* Free all space used while optimizing this cloud. */
+ obstack_free(&cloud->obst, NULL);
+}
+
+static int cloud_costs(co2_cloud_t *cloud)
+{
+ int i, costs = 0;
+ neighb_t *n;
+
+ for(i = 0; i < cloud->n_memb; ++i) {
+ co2_irn_t *ci = (co2_irn_t *) cloud->seq[i];
+ col_t col = get_col(cloud->env, ci->irn);
+ co_gs_foreach_neighb(ci->aff, n) {
+ col_t n_col = get_col(cloud->env, n->irn);
+ costs += col != n_col ? n->costs : 0;
+ }
}
+
+ return costs / 2;
}
static void process(co2_t *env)
{
- struct obstack obst;
- affinity_node_t *an;
- co2_irn_t **nodes;
- int i, n;
+ affinity_node_t *a;
+ co2_cloud_t *pos;
+ co2_cloud_t **clouds;
+ int n_clouds;
+ int i;
+ int init_costs = 0;
+ int all_costs = 0;
+ int final_costs = 0;
- obstack_init(&obst);
+ n_clouds = 0;
+ co_gs_foreach_aff_node(env->co, a) {
+ co2_cloud_irn_t *ci = get_co2_cloud_irn(env, a->irn);
- n = 0;
- co_gs_foreach_aff_node(env->co, an) {
- ir_node *irn = an->irn;
- co2_irn_t *ci = get_co2_irn(env, irn);
+ if(!ci->cloud) {
+ new_cloud(env, a);
+ n_clouds++;
+ }
+ }
- neighb_t *neighb;
+ i = 0;
+ clouds = xmalloc(n_clouds * sizeof(clouds[0]));
+ list_for_each_entry(co2_cloud_t, pos, &env->cloud_head, list)
+ clouds[i++] = pos;
+ qsort(clouds, n_clouds, sizeof(clouds[0]), cmp_clouds_gt);
- co_gs_foreach_neighb(an, neighb)
- ci->costs += neighb->costs;
+ for(i = 0; i < n_clouds; ++i) {
+ init_costs += cloud_costs(clouds[i]);
- obstack_ptr_grow(&obst, ci);
- n++;
- }
+ /* Process the cloud. */
+ process_cloud(clouds[i]);
- nodes = obstack_finish(&obst);
+ all_costs += clouds[i]->costs;
+ final_costs += cloud_costs(clouds[i]);
- /* sort the nodes according to processing order. */
- qsort(nodes, n, sizeof(nodes[0]), co2_irn_cmp);
+ /* Dump the IFG if the user demanded it. */
+ if (dump_flags & DUMP_CLOUD) {
+ char buf[256];
+ FILE *f;
- for(i = 0; i < n; ++i) {
- if(!nodes[i]->fixed)
- process_affinity_node(env, nodes[i]);
+ ir_snprintf(buf, sizeof(buf), "ifg_%F_%s_cloud_%d.dot", env->co->irg, env->co->cls->name, i);
+ f = fopen(buf, "wt");
+ if(f != NULL) {
+ be_ifg_dump_dot(env->co->cenv->ifg, env->co->irg, f, &ifg_dot_cb, env);
+ fclose(f);
+ }
+ }
}
- obstack_free(&obst, NULL);
+ DB((env->dbg, LEVEL_1, "all costs: %d, init costs: %d, final costs: %d\n", all_costs, init_costs, final_costs));
+
+ xfree(clouds);
}
static void writeback_colors(co2_t *env)
}
}
-void co_solve_heuristic_new(copy_opt_t *co)
+
+/*
+ ___ _____ ____ ____ ___ _____ ____ _
+ |_ _| ___/ ___| | _ \ / _ \_ _| | _ \ _ _ _ __ ___ _ __ (_)_ __ __ _
+ | || |_ | | _ | | | | | | || | | | | | | | | '_ ` _ \| '_ \| | '_ \ / _` |
+ | || _|| |_| | | |_| | |_| || | | |_| | |_| | | | | | | |_) | | | | | (_| |
+ |___|_| \____| |____/ \___/ |_| |____/ \__,_|_| |_| |_| .__/|_|_| |_|\__, |
+ |_| |___/
+*/
+
+static const char *get_dot_color_name(int col)
{
+ static const char *names[] = {
+ "blue",
+ "red",
+ "green",
+ "yellow",
+ "cyan",
+ "magenta",
+ "orange",
+ "chocolate",
+ "beige",
+ "navy",
+ "darkgreen",
+ "darkred",
+ "lightPink",
+ "chartreuse",
+ "lightskyblue",
+ "linen",
+ "pink",
+ "lightslateblue",
+ "mintcream",
+ "red",
+ "darkolivegreen",
+ "mediumblue",
+ "mistyrose",
+ "salmon",
+ "darkseagreen",
+ "mediumslateblue"
+ "moccasin",
+ "tomato",
+ "forestgreen",
+ "darkturquoise",
+ "palevioletred"
+ };
+
+ return col < sizeof(names)/sizeof(names[0]) ? names[col] : "white";
+}
+
+static const char *get_dot_shape_name(co2_t *env, co2_irn_t *ci)
+{
+ arch_register_req_t req;
+
+ arch_get_register_req(env->co->aenv, &req, ci->irn, BE_OUT_POS(0));
+ if(arch_register_req_is(&req, limited))
+ return "diamond";
+
+ if(ci->fixed)
+ return "rectangle";
+
+ if(ci->tmp_fixed)
+ return "hexagon";
+
+ return "ellipse";
+}
+
+static void ifg_dump_graph_attr(FILE *f, void *self)
+{
+ fprintf(f, "overlay=false");
+}
+
+static int ifg_is_dump_node(void *self, ir_node *irn)
+{
+ co2_t *env = self;
+ return !arch_irn_is(env->co->aenv, irn, ignore);
+}
+
+static void ifg_dump_node_attr(FILE *f, void *self, ir_node *irn)
+{
+ co2_t *env = self;
+ co2_irn_t *ci = get_co2_irn(env, irn);
+ int peri = 1;
+
+ char buf[128] = "";
+
+ if(ci->aff) {
+ co2_cloud_irn_t *cci = (void *) ci;
+ if (cci->cloud && cci->cloud->mst_root == cci)
+ peri = 2;
+
+ if(cci->cloud && cci->cloud->mst_root)
+ ir_snprintf(buf, sizeof(buf), "%+F", cci->cloud->mst_root->inh.irn);
+ }
+
+ ir_fprintf(f, "label=\"%+F%s\" style=filled peripheries=%d color=%s shape=%s", irn, buf, peri,
+ get_dot_color_name(get_col(env, irn)), get_dot_shape_name(env, ci));
+}
+
+static void ifg_dump_at_end(FILE *file, void *self)
+{
+ co2_t *env = self;
+ affinity_node_t *a;
+
+ co_gs_foreach_aff_node(env->co, a) {
+ co2_cloud_irn_t *ai = get_co2_cloud_irn(env, a->irn);
+ int idx = get_irn_idx(a->irn);
+ neighb_t *n;
+
+ if(ai->mst_parent != ai)
+ fprintf(file, "\tn%d -- n%d [style=dotted color=blue arrowhead=normal];\n", idx, get_irn_idx(ai->mst_parent->inh.irn));
+
+ co_gs_foreach_neighb(a, n) {
+ int nidx = get_irn_idx(n->irn);
+ co2_cloud_irn_t *ci = get_co2_cloud_irn(env, n->irn);
+
+ if(idx < nidx) {
+ const char *color = get_col(env, a->irn) == get_col(env, n->irn) ? "black" : "red";
+ const char *arr = "arrowhead=dot arrowtail=dot";
+
+ if(ci->mst_parent == ai)
+ arr = "arrowtail=normal";
+ else if(ai->mst_parent == ci)
+ arr = "arrowhead=normal";
+
+ fprintf(file, "\tn%d -- n%d [label=\"%d\" %s style=dashed color=%s weight=0.01];\n", idx, nidx, n->costs, arr, color);
+ }
+ }
+ }
+}
+
+
+static be_ifg_dump_dot_cb_t ifg_dot_cb = {
+ ifg_is_dump_node,
+ ifg_dump_graph_attr,
+ ifg_dump_node_attr,
+ NULL,
+ NULL,
+ ifg_dump_at_end
+};
+
+
+int co_solve_heuristic_new(copy_opt_t *co)
+{
+ char buf[256];
co2_t env;
+ FILE *f;
- phase_init(&env.ph, "co2", co->cenv->birg->irg, sizeof(co2_irn_t), PHASE_DEFAULT_GROWTH, co2_irn_init);
+ phase_init(&env.ph, "co2", co->cenv->birg->irg, PHASE_DEFAULT_GROWTH, co2_irn_init);
env.touched = NULL;
+ env.visited = 0;
env.co = co;
+ env.n_regs = co->cls->n_regs;
env.ignore_regs = bitset_alloca(co->cls->n_regs);
arch_put_non_ignore_regs(co->aenv, co->cls, env.ignore_regs);
bitset_flip_all(env.ignore_regs);
be_abi_put_ignore_regs(co->cenv->birg->abi, co->cls, env.ignore_regs);
FIRM_DBG_REGISTER(env.dbg, "firm.be.co2");
+ INIT_LIST_HEAD(&env.cloud_head);
+
+ if(dump_flags & DUMP_BEFORE) {
+ ir_snprintf(buf, sizeof(buf), "ifg_%F_%s_before.dot", co->irg, co->cls->name);
+ f = fopen(buf, "wt");
+ if (f != NULL) {
+ be_ifg_dump_dot(co->cenv->ifg, co->irg, f, &ifg_dot_cb, &env);
+ fclose(f);
+ }
+ }
process(&env);
+
+ if(dump_flags & DUMP_AFTER) {
+ ir_snprintf(buf, sizeof(buf), "ifg_%F_%s_after.dot", co->irg, co->cls->name);
+ f = fopen(buf, "wt");
+ if (f != NULL) {
+ be_ifg_dump_dot(co->cenv->ifg, co->irg, f, &ifg_dot_cb, &env);
+ fclose(f);
+ }
+ }
+
writeback_colors(&env);
phase_free(&env.ph);
+ return 0;
}