-/**
- * This is the C implementation of the trivial mst algo
- * originally written in Java by Sebastian Hack.
- * Performs simple copy minimzation.
+/*
+ * Copyright (C) 1995-2007 University of Karlsruhe. All right reserved.
+ *
+ * This file is part of libFirm.
+ *
+ * This file may be distributed and/or modified under the terms of the
+ * GNU General Public License version 2 as published by the Free Software
+ * Foundation and appearing in the file LICENSE.GPL included in the
+ * packaging of this file.
*
- * @author Christian Wuerdig
- * @date 27.04.2007
- * @id $Id$
+ * Licensees holding valid libFirm Professional Edition licenses may use
+ * this file in accordance with the libFirm Commercial License.
+ * Agreement provided with the Software.
+ *
+ * This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE
+ * WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR
+ * PURPOSE.
*/
+/**
+ * @file
+ * @brief Simple copy minimization heuristics.
+ * @author Christian Wuerdig
+ * @date 27.04.2007
+ * @version $Id$
+ *
+ * This is the C implementation of the mst algorithm
+ * originally written in Java by Sebastian Hack.
+ * (also known as "heur3" :)
+ * Performs simple copy minimization.
+ */
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif /* HAVE_CONFIG_H */
#include <float.h>
#include "array.h"
-#include "irnode.h"
+#include "irnode_t.h"
#include "bitset.h"
#include "raw_bitset.h"
#include "irphase_t.h"
#include "pset_new.h"
#include "xmalloc.h"
#include "pdeq.h"
+#include "irprintf.h"
+#include "irbitset.h"
#include "bearch.h"
#include "beifg.h"
#include "be_t.h"
#include "becopyopt_t.h"
-#include "irbitset.h"
#define COL_COST_INFEASIBLE DBL_MAX
#define AFF_NEIGHBOUR_FIX_BENEFIT 128.0
#define NEIGHBOUR_CONSTR_COSTS 64.0
+#define DBG_AFF_CHUNK(env, level, chunk) DEBUG_ONLY(if (firm_dbg_get_mask((env)->dbg) & (level)) dbg_aff_chunk((env), (chunk));)
+#define DBG_COL_COST(env, level, cost) DEBUG_ONLY(if (firm_dbg_get_mask((env)->dbg) & (level)) dbg_col_cost((env), (cost));)
+
+static int last_chunk_id = 0;
+
typedef struct _col_cost_t {
int col;
double cost;
typedef struct _aff_chunk_t {
bitset_t *nodes;
- double weight;
+ int weight;
unsigned weight_consistent : 1;
+ int id;
} aff_chunk_t;
typedef struct _aff_edge_t {
be_ifg_t *ifg; /**< the interference graph */
const arch_env_t *aenv; /**< the arch environment */
copy_opt_t *co; /**< the copy opt object */
+ DEBUG_ONLY(firm_dbg_module_t *dbg);
} co_mst_env_t;
/* stores coalescing related information for a node */
typedef struct _co_mst_irn_t {
- ir_node *irn;
- aff_chunk_t *chunk;
- bitset_t *adm_colors;
- int int_neigh;
- int col;
- int tmp_col;
- unsigned fixed : 1;
- unsigned tmp_fixed : 1;
+ ir_node *irn; /**< the irn this information belongs to */
+ aff_chunk_t *chunk; /**< the chunk this irn belongs to */
+ bitset_t *adm_colors; /**< set of admissible colors for this irn */
+ ir_node **int_neighs; /**< ARR_D of all interfering neighbours (cached for speed reasons) */
+ int int_aff_neigh; /**< number of interfering affinity neighbours */
+ int col; /**< color currently assigned */
+ int init_col; /**< the initial color */
+ int tmp_col; /**< a temporary assigned color */
+ unsigned fixed : 1; /**< the color is fixed */
+ unsigned tmp_fixed : 1; /**< the color is temporary fixed */
} co_mst_irn_t;
-
#define get_co_mst_irn(mst_env, irn) (phase_get_or_set_irn_data(&(mst_env)->ph, (irn)))
typedef int decide_func_t(co_mst_irn_t *node, int col);
+#ifdef DEBUG_libfirm
+
+/**
+ * Write a chunk to stderr for debugging.
+ */
+static void dbg_aff_chunk(co_mst_env_t *env, aff_chunk_t *c) {
+ int idx;
+ if (c->weight_consistent)
+ ir_fprintf(stderr, " $%d ", c->weight);
+ ir_fprintf(stderr, "{");
+ bitset_foreach(c->nodes, idx) {
+ ir_node *n = get_idx_irn(env->co->irg, idx);
+ ir_fprintf(stderr, " %+F,", n);
+ }
+ ir_fprintf(stderr, "}");
+}
+
+/**
+ * Dump all admissible colors to stderr.
+ */
+static void dbg_admissible_colors(co_mst_env_t *env, co_mst_irn_t *node) {
+ int idx;
+ if (bitset_popcnt(node->adm_colors) < 1)
+ fprintf(stderr, "no admissible colors?!?");
+ else {
+ bitset_foreach(node->adm_colors, idx)
+ fprintf(stderr, " %d", idx);
+ }
+}
+
+/**
+ * Dump color-cost pairs to stderr.
+ */
+static void dbg_col_cost(co_mst_env_t *env, col_cost_t *cost) {
+ int i;
+ for (i = 0; i < env->n_regs; ++i) {
+ if (cost[i].cost == COL_COST_INFEASIBLE)
+ fprintf(stderr, " (%d, INF)", cost[i].col);
+ else
+ fprintf(stderr, " (%d, %.1f)", cost[i].col, cost[i].cost);
+ }
+}
+
+#endif /* DEBUG_libfirm */
+
static INLINE int get_mst_irn_col(co_mst_irn_t *node) {
return node->tmp_fixed ? node->tmp_col : node->col;
}
return 1;
}
-/* compares two affinity edges */
+/* > compares two affinity edges by its weight */
static int cmp_aff_edge(const void *a, const void *b) {
const aff_edge_t *e1 = a;
const aff_edge_t *e2 = b;
+ if (e2->weight == e1->weight) {
+ if (e2->src->node_idx == e1->src->node_idx)
+ return QSORT_CMP(e2->tgt->node_idx, e1->tgt->node_idx);
+ else
+ return QSORT_CMP(e2->src->node_idx, e1->src->node_idx);
+ }
/* sort in descending order */
- return e1->weight < e2->weight ? 1 : -1;
+ return QSORT_CMP(e2->weight, e1->weight);
}
/* compares to color-cost pairs */
return c1->cost < c2->cost ? -1 : 1;
}
+/**
+ * Creates a new affinity chunk
+ */
+static INLINE aff_chunk_t *new_aff_chunk(co_mst_env_t *env) {
+ aff_chunk_t *c = xmalloc(sizeof(*c));
+ c->weight = -1;
+ c->weight_consistent = 0;
+ c->nodes = bitset_irg_malloc(env->co->irg);
+ c->id = last_chunk_id++;
+ pset_new_insert(&env->chunkset, c);
+ return c;
+}
+
+/**
+ * Frees all memory allocated by an affinity chunk.
+ */
+static INLINE void delete_aff_chunk(co_mst_env_t *env, aff_chunk_t *c) {
+ pset_new_remove(&env->chunkset, c);
+ bitset_free(c->nodes);
+ free(c);
+}
+
+/**
+ * Adds a node to an affinity chunk
+ */
+static INLINE void aff_chunk_add_node(aff_chunk_t *c, co_mst_irn_t *node) {
+ c->weight_consistent = 0;
+ node->chunk = c;
+ bitset_set(c->nodes, get_irn_idx(node->irn));
+}
+
/**
* In case there is no phase information for irn, initialize it.
*/
co_mst_env_t *env = ph->priv;
if (res != old) {
- void *neigh_it = be_ifg_neighbours_iter_alloca(env->ifg);
const arch_register_req_t *req;
- ir_node *m;
+ void *nodes_it = be_ifg_nodes_iter_alloca(env->ifg);
+ ir_node *neigh;
+ unsigned len;
+
+ res->irn = irn;
+ res->chunk = new_aff_chunk(env);
+ res->fixed = 0;
+ res->tmp_fixed = 0;
+ res->tmp_col = -1;
+ res->int_neighs = NULL;
+ res->int_aff_neigh = 0;
+ res->col = arch_register_get_index(arch_get_irn_register(env->aenv, irn));
+ res->init_col = res->col;
+
+ /* add note to new chunk */
+ aff_chunk_add_node(res->chunk, res);
- res->irn = irn;
- res->chunk = NULL;
- res->fixed = 0;
- res->tmp_fixed = 0;
- res->tmp_col = -1;
- res->int_neigh = 0;
- res->col = arch_register_get_index(arch_get_irn_register(env->aenv, irn));
+ DB((env->dbg, LEVEL_4, "Creating phase info for %+F, chunk %d\n", irn, res->chunk->id));
/* set admissible registers */
res->adm_colors = bitset_obstack_alloc(phase_obst(ph), env->n_regs);
req = arch_get_register_req(env->aenv, irn, -1);
if (arch_register_req_is(req, limited))
rbitset_copy_to_bitset(req->limited, res->adm_colors);
+ else
+ bitset_set_all(res->adm_colors);
/* exclude global ignore registers as well */
bitset_andnot(res->adm_colors, env->ignore_regs);
- /* calculate the number of interfering neighbours */
- be_ifg_foreach_neighbour(env->ifg, neigh_it, irn, m) {
- if (! arch_irn_is(env->aenv, m, ignore))
- res->int_neigh++;
- }
-
+ /* set the number of interfering affinity neighbours to -1, they are calculated later */
+ res->int_aff_neigh = -1;
+
+ /* build list of interfering neighbours */
+ len = 0;
+ /* count them first as an obstack array cannot be extended */
+ be_ifg_foreach_neighbour(env->ifg, nodes_it, irn, neigh)
+ len++;
+ res->int_neighs = NEW_ARR_D(ir_node *, phase_obst(ph), len);
+ len = 0;
+ be_ifg_foreach_neighbour(env->ifg, nodes_it, irn, neigh)
+ res->int_neighs[len++] = neigh;
}
-
return res;
}
/**
- * Creates a new affinity chunk
+ * Check if affinity chunk @p chunk interferes with node @p irn.
*/
-static INLINE aff_chunk_t *new_aff_chunk(co_mst_env_t *env) {
- aff_chunk_t *c = xmalloc(sizeof(*c));
- c->weight_consistent = 0;
- c->nodes = bitset_irg_malloc(env->co->irg);
- pset_new_insert(&env->chunkset, c);
- return c;
-}
+static INLINE int aff_chunk_interferes(co_mst_env_t *env, aff_chunk_t *chunk, ir_node *irn) {
+ co_mst_irn_t *node = get_co_mst_irn(env, irn);
+ ir_node *neigh;
+ int i;
-/**
- * Frees all memory allocated by an affinity chunk.
- */
-static INLINE void delete_aff_chunk(co_mst_env_t *env, aff_chunk_t *c) {
- pset_new_remove(&env->chunkset, c);
- bitset_free(c->nodes);
- free(c);
-}
+ for (i = 0; i < ARR_LEN(node->int_neighs); ++i) {
+ neigh = node->int_neighs[i];
+ if (! arch_irn_is(env->aenv, neigh, ignore) && bitset_is_set(chunk->nodes, get_irn_idx(neigh)))
+ return 1;
+ }
-/**
- * Adds a node to an affinity chunk
- */
-static INLINE void aff_chunk_add_node(aff_chunk_t *c, co_mst_irn_t *node) {
- c->weight_consistent = 0;
- node->chunk = c;
- bitset_set(c->nodes, get_irn_idx(node->irn));
+ return 0;
}
/**
* @return 1 if there are interferences between nodes of c1 and c2, 0 otherwise.
*/
static INLINE int aff_chunks_interfere(co_mst_env_t *env, aff_chunk_t *c1, aff_chunk_t *c2) {
- void *nodes_it = be_ifg_nodes_iter_alloca(env->ifg);
- int idx;
+ int idx;
+
+ if (c1 == c2)
+ return 0;
- /* check if there is a node in c1 having an interfering neighbour in c2 */
- bitset_foreach(c1->nodes, idx) {
+ /* check if there is a node in c2 having an interfering neighbor in c1 */
+ bitset_foreach(c2->nodes, idx) {
ir_node *n = get_idx_irn(env->co->irg, idx);
- ir_node *neigh;
- be_ifg_foreach_neighbour(env->ifg, nodes_it, n, neigh) {
- if (bitset_is_set(c2->nodes, get_irn_idx(neigh)))
- return 1;
- }
+ if (aff_chunk_interferes(env, c1, n))
+ return 1;
}
return 0;
* are no interference edges from c1 to c2).
* @return 1 if successful, 0 if not possible
*/
-static INLINE int aff_chunk_absorb(co_mst_env_t *env, aff_chunk_t *c1, aff_chunk_t *c2) {
- if (! aff_chunks_interfere(env, c1, c2)) {
+static int aff_chunk_absorb(co_mst_env_t *env, aff_chunk_t *c1, aff_chunk_t *c2) {
+ DB((env->dbg, LEVEL_4, "Attempt to let c1 (id %d): ", c1->id));
+ DBG_AFF_CHUNK(env, LEVEL_4, c1);
+ DB((env->dbg, LEVEL_4, "\n\tabsorb c2 (id %d): ", c2->id));
+ DBG_AFF_CHUNK(env, LEVEL_4, c2);
+ DB((env->dbg, LEVEL_4, "\n"));
+
+ if (c1 != c2 && ! aff_chunks_interfere(env, c1, c2)) {
int idx;
bitset_or(c1->nodes, c2->nodes);
mn->chunk = c1;
}
+ DB((env->dbg, LEVEL_4, " ... absorbed, c2 deleted\n"));
delete_aff_chunk(env, c2);
return 1;
}
+ DB((env->dbg, LEVEL_4, " ... c1 interferes with c2, skipped\n"));
return 0;
}
* Returns the affinity chunk of @p irn or creates a new
* one with @p irn as element if there is none assigned.
*/
-static INLINE aff_chunk_t *get_or_set_aff_chunk(co_mst_env_t *env, ir_node *irn) {
+static INLINE aff_chunk_t *get_aff_chunk(co_mst_env_t *env, ir_node *irn) {
co_mst_irn_t *node = get_co_mst_irn(env, irn);
-
- if (node->chunk == NULL) {
- node->chunk = new_aff_chunk(env);
- aff_chunk_add_node(node->chunk, node);
- }
-
+ assert(node->chunk && "Node should have a chunk.");
return node->chunk;
}
*/
static void aff_chunk_assure_weight(co_mst_env_t *env, aff_chunk_t *c) {
if (! c->weight_consistent) {
- double w = 0.0;
- int idx;
+ int w = 0;
+ int idx;
bitset_foreach(c->nodes, idx) {
ir_node *n = get_idx_irn(env->co->irg, idx);
affinity_node_t *an = get_affinity_info(env->co, n);
- co_mst_irn_t *n1 = get_co_mst_irn(env, n);
if (an != NULL) {
neighb_t *neigh;
co_gs_foreach_neighb(an, neigh) {
ir_node *m = neigh->irn;
int m_idx = get_irn_idx(m);
- co_mst_irn_t *n2;
/* skip ignore nodes */
if (arch_irn_is(env->aenv, m, ignore))
continue;
- n2 = get_co_mst_irn(env, m);
-
- /* record the edge in only one direction */
- if (idx < m_idx)
- w += (double)neigh->costs / (double)(1 + n1->int_neigh + n2->int_neigh);
+ w += bitset_is_set(c->nodes, m_idx) ? neigh->costs : 0;
}
}
}
}
}
+/**
+ * Count the number of interfering affinity neighbours
+ */
+static int count_interfering_aff_neighs(co_mst_env_t *env, affinity_node_t *an) {
+ neighb_t *neigh;
+ ir_node *irn = an->irn;
+ co_mst_irn_t *node = get_co_mst_irn(env, irn);
+ int res = 0;
+
+ co_gs_foreach_neighb(an, neigh) {
+ ir_node *n = neigh->irn;
+ int i;
+
+ /* skip ignore nodes */
+ if (arch_irn_is(env->aenv, n, ignore))
+ continue;
+
+ /* check if the affinity neighbour interfere */
+ for (i = 0; i < ARR_LEN(node->int_neighs); ++i) {
+ if (node->int_neighs[i] == n) {
+ ++res;
+ break;
+ }
+ }
+ }
+ return res;
+}
+
+
/**
* Build chunks of nodes connected by affinity edges.
* We start at the heaviest affinity edge.
void *nodes_it = be_ifg_nodes_iter_alloca(env->ifg);
aff_edge_t *edges = NEW_ARR_F(aff_edge_t, 0);
ir_node *n;
- int i;
+ int i, len;
aff_chunk_t *curr_chunk;
pset_new_iterator_t iter;
if (an != NULL) {
neighb_t *neigh;
- co_gs_foreach_neighb(an, neigh) {
- ir_node *m = neigh->irn;
- int m_idx = get_irn_idx(m);
- co_mst_irn_t *n2;
-
- /* skip ignore nodes */
- if (arch_irn_is(env->aenv, m, ignore))
- continue;
- n2 = get_co_mst_irn(env, m);
+ if (n1->int_aff_neigh < 0)
+ n1->int_aff_neigh = count_interfering_aff_neighs(env, an);
+ co_gs_foreach_neighb(an, neigh) {
+ ir_node *m = neigh->irn;
+ int m_idx = get_irn_idx(m);
/* record the edge in only one direction */
if (n_idx < m_idx) {
- aff_edge_t edge;
+ co_mst_irn_t *n2;
+ aff_edge_t edge;
+
+ /* skip ignore nodes */
+ if (arch_irn_is(env->aenv, m, ignore))
+ continue;
- edge.src = n;
- edge.tgt = m;
- edge.weight = (double)neigh->costs / (double)(1 + n1->int_neigh + n2->int_neigh);
+ edge.src = n;
+ edge.tgt = m;
+
+ n2 = get_co_mst_irn(env, m);
+ if (n2->int_aff_neigh < 0) {
+ affinity_node_t *am = get_affinity_info(env->co, m);
+ n2->int_aff_neigh = count_interfering_aff_neighs(env, am);
+ }
+ edge.weight = (double)neigh->costs / (double)(1 + n1->int_aff_neigh + n2->int_aff_neigh);
ARR_APP1(aff_edge_t, edges, edge);
}
}
}
/* now: sort edges and build the affinity chunks */
- qsort(edges, ARR_LEN(edges), sizeof(edges[0]), cmp_aff_edge);
- for (i = 0; i < ARR_LEN(edges); ++i) {
- aff_chunk_t *c1 = get_or_set_aff_chunk(env, edges[i].src);
- aff_chunk_t *c2 = get_or_set_aff_chunk(env, edges[i].tgt);
+ len = ARR_LEN(edges);
+ qsort(edges, len, sizeof(edges[0]), cmp_aff_edge);
+ for (i = 0; i < len; ++i) {
+ aff_chunk_t *c1 = get_aff_chunk(env, edges[i].src);
+ aff_chunk_t *c2 = get_aff_chunk(env, edges[i].tgt);
+
+ DBG((env->dbg, LEVEL_1, "edge (%u,%u) %f\n", edges[i].src->node_idx, edges[i].tgt->node_idx, edges[i].weight));
(void)aff_chunk_absorb(env, c1, c2);
}
/* now insert all chunks into a priority queue */
foreach_pset_new(&env->chunkset, curr_chunk, iter) {
aff_chunk_assure_weight(env, curr_chunk);
+
+ DBG((env->dbg, LEVEL_1, "entry #%d", curr_chunk->id));
+ DBG_AFF_CHUNK(env, LEVEL_1, curr_chunk);
+ DBG((env->dbg, LEVEL_1, "\n"));
+
+
pqueue_put(env->chunks, curr_chunk, curr_chunk->weight);
}
{
waitq *nodes = new_waitq();
+ DBG((env->dbg, LEVEL_1, "\nExpanding new chunk (id %d) from %+F:", chunk->id, node->irn));
+
/* init queue and chunk */
waitq_put(nodes, node);
bitset_set(visited, get_irn_idx(node->irn));
aff_chunk_add_node(chunk, node);
+ DB((env->dbg, LEVEL_1, " %+F", node->irn));
/* as long as there are nodes in the queue */
while (! waitq_empty(nodes)) {
- co_mst_irn_t *n = waitq_get(nodes);
- affinity_node_t *an = get_affinity_info(env->co, n->irn);
- int n_idx = get_irn_idx(n->irn);
+ co_mst_irn_t *n = waitq_get(nodes);
+ affinity_node_t *an = get_affinity_info(env->co, n->irn);
/* check all affinity neighbors */
if (an != NULL) {
n2 = get_co_mst_irn(env, m);
- if (n_idx < m_idx &&
- ! bitset_is_set(visited, m_idx) &&
- decider(n2, col) &&
- ! n2->fixed &&
- ! aff_chunks_interfere(env, chunk, n2->chunk) &&
+ if (! bitset_is_set(visited, m_idx) &&
+ decider(n2, col) &&
+ ! n2->fixed &&
+ ! aff_chunk_interferes(env, chunk, m) &&
bitset_is_set(orig_chunk->nodes, m_idx))
{
/*
- neighbour is not visited
- neighbour likes the color
- neighbour has not yet a fixed color
- - the new chunk doesn't interfere with the chunk of the neighbour
+ - the new chunk doesn't interfere with the neighbour
- neighbour belongs or belonged once to the original chunk
*/
bitset_set(visited, m_idx);
aff_chunk_add_node(chunk, n2);
+ DB((env->dbg, LEVEL_1, " %+F", n2->irn));
/* enqueue for further search */
waitq_put(nodes, n2);
}
}
}
+ DB((env->dbg, LEVEL_1, "\n"));
+
del_waitq(nodes);
}
co_mst_irn_t *node;
aff_chunk_t *tmp_chunk;
decide_func_t *decider;
+ int check_for_best;
if (bitset_is_set(visited, idx))
continue;
irn = get_idx_irn(env->co->irg, idx);
node = get_co_mst_irn(env, irn);
+ if (get_mst_irn_col(node) == col) {
+ decider = decider_has_color;
+ check_for_best = 1;
+ }
+ else {
+ decider = decider_hasnot_color;
+ check_for_best = 0;
+ }
+
/* create a new chunk starting at current node */
tmp_chunk = new_aff_chunk(env);
waitq_put(tmp, tmp_chunk);
- decider = get_mst_irn_col(node) == col ? decider_has_color : decider_hasnot_color;
expand_chunk_from(env, node, visited, tmp_chunk, c, decider, col);
assert(bitset_popcnt(tmp_chunk->nodes) > 0 && "No nodes added to chunk");
/* remember the local best */
aff_chunk_assure_weight(env, tmp_chunk);
- if (! best || best->weight < tmp_chunk->weight)
+ if (check_for_best && (! best || best->weight < tmp_chunk->weight))
best = tmp_chunk;
}
* Determines the costs for each color if it would be assigned to node @p node.
*/
static void determine_color_costs(co_mst_env_t *env, co_mst_irn_t *node, col_cost_t *costs) {
- affinity_node_t *an = get_affinity_info(env->co, node->irn);
- void *nodes_it = be_ifg_nodes_iter_alloca(env->ifg);
+ affinity_node_t *an = get_affinity_info(env->co, node->irn);
neighb_t *aff_neigh;
- ir_node *int_neigh;
- int idx;
+ int idx, i;
col_cost_init(env, costs, 0.0);
/* calculate (negative) costs for affinity neighbours */
- co_gs_foreach_neighb(an, aff_neigh) {
- ir_node *m = aff_neigh->irn;
- co_mst_irn_t *neigh = get_co_mst_irn(env, m);
- double c = (double)aff_neigh->costs;
-
- /* calculate costs for fixed affinity neighbours */
- if (neigh->tmp_fixed || neigh->fixed) {
- int col = get_mst_irn_col(neigh);
- costs[col].cost -= c * AFF_NEIGHBOUR_FIX_BENEFIT;
+ if (an != NULL) {
+ co_gs_foreach_neighb(an, aff_neigh) {
+ ir_node *m = aff_neigh->irn;
+ co_mst_irn_t *neigh;
+ double c;
+
+ /* skip ignore nodes */
+ if (arch_irn_is(env->aenv, m, ignore))
+ continue;
+
+ neigh = get_co_mst_irn(env, m);
+ c = (double)aff_neigh->costs;
+
+ /* calculate costs for fixed affinity neighbours */
+ if (neigh->tmp_fixed || neigh->fixed) {
+ int col = get_mst_irn_col(neigh);
+ costs[col].cost -= c * AFF_NEIGHBOUR_FIX_BENEFIT;
+ }
}
}
/* calculate (positive) costs for interfering neighbours */
- be_ifg_foreach_neighbour(env->ifg, nodes_it, node->irn, int_neigh) {
- co_mst_irn_t *neigh = get_co_mst_irn(env, int_neigh);
- int col = get_mst_irn_col(neigh);
- int col_cnt = bitset_popcnt(neigh->adm_colors);
+ for (i = 0; i < ARR_LEN(node->int_neighs); ++i) {
+ co_mst_irn_t *neigh;
+ int col, col_cnt;
+ ir_node *int_neigh;
+
+ int_neigh = node->int_neighs[i];
+
+ /* skip ignore nodes */
+ if (arch_irn_is(env->aenv, int_neigh, ignore))
+ continue;
+
+ neigh = get_co_mst_irn(env, int_neigh);
+ col = get_mst_irn_col(neigh);
+ col_cnt = bitset_popcnt(neigh->adm_colors);
if (neigh->tmp_fixed || neigh->fixed) {
/* colors of fixed interfering neighbours are infeasible */
static int recolor_nodes(co_mst_env_t *env, co_mst_irn_t *node, col_cost_t *costs, waitq *changed_ones) {
int i;
waitq *local_changed = new_waitq();
+ waitq *tmp = new_waitq();
+
+ DBG((env->dbg, LEVEL_1, "\tRecoloring %+F with color-costs", node->irn));
+ DBG_COL_COST(env, LEVEL_1, costs);
+ DB((env->dbg, LEVEL_1, "\n"));
for (i = 0; i < env->n_regs; ++i) {
- void *nodes_it = be_ifg_nodes_iter_alloca(env->ifg);
- int tgt_col = costs[i].col;
- int neigh_ok = 1;
- ir_node *neigh;
+ int tgt_col = costs[i].col;
+ int neigh_ok = 1;
+ int j;
/* If the costs for that color (and all successive) are infinite, bail out we won't make it anyway. */
if (costs[i].cost == COL_COST_INFEASIBLE) {
node->tmp_fixed = 0;
del_waitq(local_changed);
+ del_waitq(tmp);
return 0;
}
waitq_put(local_changed, node);
/* try to color all interfering neighbours with current color forbidden */
- be_ifg_foreach_neighbour(env->ifg, nodes_it, node->irn, neigh) {
- co_mst_irn_t *nn = get_co_mst_irn(env, neigh);
+ for (j = 0; j < ARR_LEN(node->int_neighs); ++j) {
+ co_mst_irn_t *nn;
+ ir_node *neigh;
+
+ neigh = node->int_neighs[j];
+
+ /* skip ignore nodes */
+ if (arch_irn_is(env->aenv, neigh, ignore))
+ continue;
+
+ nn = get_co_mst_irn(env, neigh);
+
/*
Try to change the color of the neighbor and record all nodes which
get changed in the tmp list. Add this list to the "changed" list for
we bail out and try the next color.
*/
if (get_mst_irn_col(nn) == tgt_col) {
- waitq *tmp = new_waitq();
-
/* try to color neighbour with tgt_col forbidden */
neigh_ok = change_node_color_excluded(env, nn, tgt_col, tmp);
/* join lists of changed nodes */
while (! waitq_empty(tmp))
waitq_put(local_changed, waitq_get(tmp));
- del_waitq(tmp);
if (! neigh_ok)
break;
while (! waitq_empty(local_changed))
waitq_put(changed_ones, waitq_get(local_changed));
del_waitq(local_changed);
+ del_waitq(tmp);
return 1;
}
else {
}
del_waitq(local_changed);
+ del_waitq(tmp);
return 0;
}
/* if node already has the target color -> good, temporary fix it */
if (col == tgt_col) {
+ DBG((env->dbg, LEVEL_4, "\t\tCNC: %+F has already color %d, fix temporary\n", node->irn, tgt_col));
if (! node->tmp_fixed) {
node->tmp_fixed = 1;
node->tmp_col = tgt_col;
*/
if (! (node->fixed || node->tmp_fixed) && bitset_is_set(node->adm_colors, tgt_col)) {
col_cost_t *costs = alloca(env->n_regs * sizeof(costs[0]));
+ int res;
+
col_cost_init_single(env, costs, tgt_col);
- return recolor_nodes(env, node, costs, changed_ones);
+
+ DBG((env->dbg, LEVEL_4, "\t\tCNC: Attempt to recolor %+F ===>>\n", node->irn));
+ res = recolor_nodes(env, node, costs, changed_ones);
+ DBG((env->dbg, LEVEL_4, "\t\tCNC: <<=== Recoloring of %+F %s\n", node->irn, res ? "succeeded" : "failed"));
+
+ return res;
}
+ DEBUG_ONLY(
+ if (firm_dbg_get_mask(env->dbg) & LEVEL_4) {
+ if (node->fixed || node->tmp_fixed)
+ DB((env->dbg, LEVEL_4, "\t\tCNC: %+F has already fixed color %d\n", node->irn, col));
+ else {
+ DB((env->dbg, LEVEL_4, "\t\tCNC: color %d not admissible for %+F (", tgt_col, node->irn));
+ dbg_admissible_colors(env, node);
+ DB((env->dbg, LEVEL_4, ")\n"));
+ }
+ }
+ )
+
return 0;
}
bitset_t *visited;
int col, idx;
+ DB((env->dbg, LEVEL_2, "fragmentizing chunk #%d", c->id));
+ DBG_AFF_CHUNK(env, LEVEL_2, c);
+ DB((env->dbg, LEVEL_2, "\n"));
+
+
/* check which color is the "best" for the given chunk */
for (col = 0; col < env->k; ++col) {
int one_good = 0;
aff_chunk_t *local_best;
+ DB((env->dbg, LEVEL_3, "\ttrying color %d\n", col));
+
/* try to bring all nodes of given chunk to the current color. */
bitset_foreach(c->nodes, idx) {
ir_node *irn = get_idx_irn(env->co->irg, idx);
assert(! node->fixed && "Node must not have a fixed color.");
- one_good = change_node_color(env, node, col, changed_ones);
-
- if (one_good)
- break;
+ DB((env->dbg, LEVEL_4, "\t\tBringing %+F from color %d to color %d ...\n", irn, node->col, col));
+ one_good |= change_node_color(env, node, col, changed_ones);
+ DB((env->dbg, LEVEL_4, "\t\t... %+F attempt from %d to %d %s\n", irn, node->col, col, one_good ? "succeeded" : "failed"));
}
/* try next color when failed */
/* fragment the chunk according to the coloring */
local_best = fragment_chunk(env, col, c, tmp_chunks);
- /* check if the local best is global best */
+ /* search the best of the good list
+ and make it the new best if it is better than the current */
if (local_best) {
aff_chunk_assure_weight(env, local_best);
+ DB((env->dbg, LEVEL_4, "\t\tlocal best chunk (id %d) for color %d: ", local_best->id, col));
+ DBG_AFF_CHUNK(env, LEVEL_4, local_best);
+
if (! best_chunk || best_chunk->weight < local_best->weight) {
- /* kill the old best */
- if (best_chunk)
- delete_aff_chunk(env, best_chunk);
best_chunk = local_best;
best_color = col;
+ DB((env->dbg, LEVEL_4, "\n\t\t... setting global best chunk (id %d), color %d\n", best_chunk->id, best_color));
+ } else {
+ DB((env->dbg, LEVEL_4, "\n\t\t... omitting, global best is better\n"));
}
}
return;
}
+ DB((env->dbg, LEVEL_2, "\tbest chunk #%d ", best_chunk->id));
+ DBG_AFF_CHUNK(env, LEVEL_2, best_chunk);
+ DB((env->dbg, LEVEL_2, "using color %d\n", best_color));
+
/* get the best fragment from the best list and color it */
bitset_foreach(best_chunk->nodes, idx) {
ir_node *irn = get_idx_irn(env->co->irg, idx);
int res;
res = change_node_color(env, node, best_color, changed_ones);
- assert(res && "Coloring failed");
+ assert(res && "color manifesting failed");
node->fixed = 1;
- node->col = node->tmp_col;
node->chunk = best_chunk;
}
- /* fix colors */
+ /* materialize colors on changed nodes */
while (! waitq_empty(changed_ones)) {
co_mst_irn_t *n = waitq_get(changed_ones);
- n->fixed = 1;
- n->col = n->tmp_col;
+ n->tmp_fixed = 0;
+ n->col = n->tmp_col;
}
/* remove the nodes in best chunk from original chunk */
bitset_andnot(c->nodes, best_chunk->nodes);
+ /* we have to get the nodes back into the original chunk because they are scattered over temporary chunks */
+ bitset_foreach(c->nodes, idx) {
+ ir_node *n = get_idx_irn(env->co->irg, idx);
+ co_mst_irn_t *nn = get_co_mst_irn(env, n);
+ nn->chunk = c;
+ }
+
/* fragment the remaining chunk */
visited = bitset_irg_malloc(env->co->irg);
bitset_or(visited, best_chunk->nodes);
}
/* clear obsolete chunks and free some memory */
- delete_aff_chunk(env, c);
delete_aff_chunk(env, best_chunk);
bitset_free(visited);
del_waitq(changed_ones);
*/
int co_solve_heuristic_mst(copy_opt_t *co)
{
- unsigned n_regs = co->cenv->cls->n_regs;
+ unsigned n_regs = co->cls->n_regs;
bitset_t *ignore_regs = bitset_alloca(n_regs);
unsigned k;
+ ir_node *irn;
co_mst_env_t mst_env;
- memset(&mst_env, 0, sizeof(mst_env));
-
/* init phase */
phase_init(&mst_env.ph, "co_mst", co->irg, PHASE_DEFAULT_GROWTH, co_mst_irn_init, &mst_env);
- k = be_put_ignore_regs(co->cenv->birg, co->cenv->cls, ignore_regs);
+ k = be_put_ignore_regs(co->cenv->birg, co->cls, ignore_regs);
k = n_regs - k;
+ FIRM_DBG_REGISTER(mst_env.dbg, "firm.be.co.heur4");
mst_env.n_regs = n_regs;
mst_env.k = k;
mst_env.chunks = new_pqueue();
mst_env.aenv = co->aenv;
pset_new_init(&mst_env.chunkset);
+ DBG((mst_env.dbg, LEVEL_1, "==== Coloring %+F, class %s ====\n", co->irg, co->cls->name));
+
/* build affinity chunks */
build_affinity_chunks(&mst_env);
/* color chunks as long as there are some */
while (! pqueue_empty(mst_env.chunks)) {
aff_chunk_t *chunk = pqueue_get(mst_env.chunks);
+
color_aff_chunk(&mst_env, chunk);
+ DB((mst_env.dbg, LEVEL_4, "<<<====== Coloring chunk (%d) done\n", chunk->id));
+ delete_aff_chunk(&mst_env, chunk);
+ }
+
+ /* apply coloring */
+ foreach_phase_irn(&mst_env.ph, irn) {
+ co_mst_irn_t *mirn = get_co_mst_irn(&mst_env, irn);
+ const arch_register_t *reg;
+
+ if (arch_irn_is(mst_env.aenv, irn, ignore))
+ continue;
+
+ assert(mirn->fixed && "Node should have fixed color");
+
+ /* skip nodes where color hasn't changed */
+ if (mirn->init_col == mirn->col)
+ continue;
+
+ reg = arch_register_for_index(co->cls, mirn->col);
+ arch_set_irn_register(co->aenv, irn, reg);
+ DB((mst_env.dbg, LEVEL_1, "%+F set color from %d to %d\n", irn, mirn->init_col, mirn->col));
}
/* free allocated memory */