#include "beilpsched.h"
typedef struct _ilpsched_options_t {
+ unsigned limit_dead;
unsigned time_limit;
char log_file[1024];
} ilpsched_options_t;
*/
typedef struct _ilp_var_types_t {
int *x; /* x_{nt}^k variables */
+ int *a; /* a_{nt}^k variables */
int *d; /* d_{nt}^k variables */
int *y; /* y_{nt}^k variables */
} ilp_var_types_t;
unsigned consumer_idx; /**< Index of the node having counted this node as consumer last */
unsigned n_consumer; /**< Number of consumers */
ir_node **block_consumer; /**< List of consumer being in the same block */
+ waitq *projkeeps; /**< A List of Projs and Keeps belonging to this node */
unsigned block_idx : 30; /**< A unique per block index */
unsigned alap_changed : 1; /**< the current ALAP has changed, revisit preds */
unsigned is_dummy_node : 1; /**< this node is assigned to DUMMY unit */
/* option variable */
static ilpsched_options_t ilp_opts = {
- 120, /* 120 sec per block time limit */
+ 70, /* if we have more than 70 nodes: use alive nodes constraint */
+ 300, /* 300 sec per block time limit */
"" /* no log file */
};
#ifdef WITH_LIBCORE
/* ILP options */
static const lc_opt_table_entry_t ilpsched_option_table[] = {
+ LC_OPT_ENT_INT("limit_dead", "Upto how many nodes the dead node constraint should be used", &ilp_opts.limit_dead),
LC_OPT_ENT_INT("time_limit", "ILP time limit per block", &ilp_opts.time_limit),
LC_OPT_ENT_STR("lpp_log", "LPP logfile (stderr and stdout are supported)", ilp_opts.log_file, sizeof(ilp_opts.log_file)),
{ NULL }
};
#endif /* WITH_LIBCORE */
+/*
+ We need this global variable as we compare nodes dependent on heights,
+ but we cannot pass any information to the qsort compare function.
+*/
+static heights_t *glob_heights;
+
/**
* Check if irn is a Proj, which has no execution units assigned.
* @return 1 if irn is a Proj having no execution units assigned, 0 otherwise
return irn;
}
-static INLINE fixed_latency(const ilp_sched_selector_t *sel, ir_node *irn, void *env) {
+static INLINE int fixed_latency(const ilp_sched_selector_t *sel, ir_node *irn, void *env) {
unsigned lat = be_ilp_sched_latency(sel, irn, env);
if (lat == 0 && ! is_Proj(irn) && ! be_is_Keep(irn))
lat = 1;
ilpsched_node_attr_t *n1_a = get_ilpsched_node_attr(n1);
ilpsched_node_attr_t *n2_a = get_ilpsched_node_attr(n2);
- return QSORT_CMP(n1_a->sched_point, n2_a->sched_point);
+ if (n1_a->sched_point == n2_a->sched_point) {
+ ir_node *irn_a = n1->irn;
+ ir_node *irn_b = n2->irn;
+
+ if (heights_reachable_in_block(glob_heights, irn_a, irn_b))
+ return 1;
+ if (heights_reachable_in_block(glob_heights, irn_b, irn_a))
+ return -1;
+ return 0;
+ }
+ else
+ return QSORT_CMP(n1_a->sched_point, n2_a->sched_point);
}
/**
be_ilpsched_irn_t *node, *block_node;
ilpsched_node_attr_t *na;
ilpsched_block_attr_t *ba;
- unsigned lat;
/* These nodes are handled separate */
if (! consider_for_sched(env->arch_env->isa, irn))
set_irn_link(irn, ba->head_ilp_nodes);
ba->head_ilp_nodes = irn;
- ba->max_steps += fixed_latency(env->sel, irn, env->block_env);
+ ba->max_steps = fixed_latency(env->sel, irn, env->block_env);
DB((env->dbg, LEVEL_2, "%u\n", na->asap));
}
* Set the ASAP/ALAP times of Projs and Keeps to their ancestor ones.
*/
static void refine_asap_alap_times(ir_node *irn, void *walk_env) {
- be_ilpsched_env_t *env = walk_env;
+ be_ilpsched_env_t *env = walk_env;
+ ir_node *pred = irn;
be_ilpsched_irn_t *node, *pred_node;
ilpsched_node_attr_t *na, *pna;
- ir_node *pred;
if (! consider_for_sched(env->arch_env->isa, irn))
return;
/* go to the ancestor */
if (be_is_Keep(irn))
- irn = get_irn_n(irn, 0);
- pred = skip_Proj(irn);
+ pred = get_irn_n(irn, 0);
+ pred = skip_Proj(pred);
node = get_ilpsched_irn(env, irn);
pred_node = get_ilpsched_irn(env, pred);
na->asap = pna->asap;
na->alap = pna->alap;
- DBG((env->dbg, LEVEL_2, "fixing ASAP/ALAP of %+F to %u/%u\n", irn, na->asap, na->alap));
-}
-
-#if 0
-/**
- * Calculate the ASAP scheduling step for current irn.
- */
-static void calculate_irn_asap(ir_node *irn, void *walk_env) {
- be_ilpsched_irn_t *node;
- be_ilpsched_env_t *env = walk_env;
- int i;
- ir_node *block;
- ilpsched_node_attr_t *na;
-
- /* These nodes are handled separate */
- if (! consider_for_sched(env->arch_env->isa, irn))
- return;
-
- DBG((env->dbg, LEVEL_2, "Calculating ASAP of node %+F\n", irn));
-
- node = get_ilpsched_irn(env, irn);
- block = get_nodes_block(irn);
- na = get_ilpsched_node_attr(node);
-
- /* accumulate all transitive predecessors of current node */
- for (i = get_irn_ins_or_deps(irn) - 1; i >= 0; --i) {
- ir_node *pred = skip_normal_Proj(env->arch_env->isa, get_irn_in_or_dep(irn, i));
- be_ilpsched_irn_t *pred_node;
- ilpsched_node_attr_t *pna;
- unsigned idx;
-
- if (be_is_Keep(pred))
- pred = skip_normal_Proj(env->arch_env->isa, get_irn_n(pred, 0));
-
- if (is_Phi(pred) || block != get_nodes_block(pred) || is_NoMem(pred))
- continue;
-
- pred_node = get_ilpsched_irn(env, pred);
- pna = get_ilpsched_node_attr(pred_node);
- idx = get_irn_idx(irn);
-
- assert(pna->asap && "missing ASAP of predecessor");
-
- /*
- We have not already visited this predecessor
- -> accumulate it's predecessors
- */
- if (pna->visit_idx != idx) {
- pna->visit_idx = idx;
- na->transitive_block_nodes = bitset_or(na->transitive_block_nodes, pna->transitive_block_nodes);
- DBG((env->dbg, LEVEL_3, "\taccumulating preds of %+F\n", pred));
- }
- }
-
- /* every node is it's own transitive predecessor in block */
- bitset_set(na->transitive_block_nodes, na->block_idx);
-
- /* asap = number of transitive predecessors in this block */
- na->asap = bitset_popcnt(na->transitive_block_nodes);
-
- DBG((env->dbg, LEVEL_2, "\tcalculated ASAP is %u\n", na->asap));
-}
-
-/**
- * Calculate the ALAP scheduling step for current irn.
- * @note: requires ASAP being calculated.
- */
-static void calculate_irn_alap(ir_node *irn, void *walk_env) {
- be_ilpsched_env_t *env = walk_env;
- int i, is_head;
- ir_node *block;
- be_ilpsched_irn_t *node;
- ilpsched_node_attr_t *na;
-
- /* These nodes are handled separate */
- if (! consider_for_sched(env->arch_env->isa, irn))
- return;
-
- DBG((env->dbg, LEVEL_2, "Calculating ALAP of node %+F ... ", irn));
-
- block = get_nodes_block(irn);
- node = get_ilpsched_irn(env, irn);
- na = get_ilpsched_node_attr(node);
- is_head = 1;
-
- for (i = get_irn_ins_or_deps(irn) - 1; i >= i; --i) {
- ir_node *pred = skip_normal_Proj(env->arch_env->isa, get_irn_in_or_dep(irn, i));
-
- /* check, if we have a head node */
- if (! is_Phi(pred) && ! is_NoMem(pred) && get_nodes_block(pred) == block) {
- be_ilpsched_irn_t *pred_node = get_ilpsched_irn(env, pred);
- ilpsched_node_attr_t *pna = get_ilpsched_node_attr(pred_node);
- unsigned lat;
-
- lat = fixed_latency(env->sel, pred, env->block_env);
- na->alap = MAX(na->alap, pna->alap + lat);
- is_head = 0;
- }
- }
-
- /* handle head nodes (no predecessor in same block) */
- if (is_head) {
- be_ilpsched_irn_t *block_node = get_ilpsched_irn(env, block);
- ilpsched_block_attr_t *ba = get_ilpsched_block_attr(block_node);
- plist_element_t *el;
-
- DB((env->dbg, LEVEL_2, "head node ... "));
-
- /*
- We have a head node here:
- ALAP(m) = sum_over_all_m(ASAP(m))
- where m is a root node and there is no path from m to n
- */
- foreach_plist(ba->root_nodes, el) {
- ir_node *root = plist_element_get_value(el);
-
- /* check if current root is independent from irn */
- if (! heights_reachable_in_block(env->height, root, irn)) {
- be_ilpsched_irn_t *root_node = get_ilpsched_irn(env, root);
- ilpsched_node_attr_t *rna = get_ilpsched_node_attr(root_node);
-
- na->alap = rna->asap + fixed_latency(env->sel, root, env->block_env);
- }
- }
- }
-
- DB((env->dbg, LEVEL_2, "%u\n", na->alap));
-}
-
-/**
- * Accumulate the successors of all nodes from irn on upwards.
- */
-static void accumulate_succs(be_ilpsched_env_t *env, ir_node *irn) {
- unsigned i, n;
- be_ilpsched_irn_t *node = get_ilpsched_irn(env, irn);
- ilpsched_node_attr_t *na = get_ilpsched_node_attr(node);
- ir_node *block = get_nodes_block(irn);
- waitq *wq = new_waitq();
-
- DBG((env->dbg, LEVEL_3, "\taccumulating succs of %+F\n", irn));
-
- /* enqueue node for final alap calculation */
- if (! na->enqueued) {
- be_ilpsched_irn_t *block_node = get_ilpsched_irn(env, block);
- ilpsched_block_attr_t *ba = get_ilpsched_block_attr(block_node);
-
- na->enqueued = 1;
- na->alap = ba->max_steps;
- waitq_put(env->alap_queue, node);
-
- set_irn_link(irn, ba->head_ilp_nodes);
- ba->head_ilp_nodes = irn;
- DBG((env->dbg, LEVEL_5, "\t\tlinked %+F to ilp nodes of %+F, attr %p\n", irn, block, ba));
- DBG((env->dbg, LEVEL_4, "\t\tenqueueing %+F for final ALAP calculation\n", irn));
- }
-
- for (i = 0, n = get_irn_ins_or_deps(irn); i < n; ++i) {
- ir_node *pred = skip_normal_Proj(env->arch_env->isa, get_irn_in_or_dep(irn, i));
- unsigned idx;
- be_ilpsched_irn_t *pred_node;
- ilpsched_node_attr_t *pna;
-
- if (be_is_Keep(pred))
- pred = skip_normal_Proj(env->arch_env->isa, get_irn_n(pred, 0));
-
- if (is_Phi(pred) || block != get_nodes_block(pred) || is_NoMem(pred))
- continue;
-
- pred_node = get_ilpsched_irn(env, pred);
- pna = get_ilpsched_node_attr(pred_node);
- idx = get_irn_idx(irn);
-
- /* accumulate the successors */
- if (pna->visit_idx != idx) {
- pna->visit_idx = idx;
- pna->transitive_block_nodes = bitset_or(pna->transitive_block_nodes, na->transitive_block_nodes);
-
- /* set current node as successor */
- bitset_set(pna->transitive_block_nodes, na->block_idx);
- waitq_put(wq, pred);
-
- DBG((env->dbg, LEVEL_3, "\taccumulating succs of %+F to %+F\n", irn, pred));
- }
- }
-
- /* process all predecessors */
- while (! waitq_empty(wq)) {
- accumulate_succs(env, waitq_get(wq));
- }
+ /* record all Projs and Keeps for this node */
+ if (! pna->projkeeps)
+ pna->projkeeps = new_waitq();
+ waitq_put(pna->projkeeps, irn);
- del_waitq(wq);
-}
-
-/**
- * Calculate the ALAP scheduling step of all irns in current block.
- * Depends on ASAP being calculated.
- */
-static void calculate_block_alap(ir_node *block, void *walk_env) {
- be_ilpsched_env_t *env = walk_env;
- be_ilpsched_irn_t *block_node = get_ilpsched_irn(env, block);
- ilpsched_block_attr_t *ba = get_ilpsched_block_attr(block_node);
-
- assert(is_Block(block));
-
- DBG((env->dbg, LEVEL_2, "Calculating ALAP for nodes in %+F (%u nodes)\n", block, ba->n_interesting_nodes));
-
- /* TODO: Might be faster to use out edges and call phase_reinit_single_irn_data */
- phase_reinit_block_irn_data(&env->ph, block);
-
- /* calculate the alap of all nodes, starting at collected roots upwards */
- while (! waitq_empty(ba->root_nodes)) {
- accumulate_succs(env, waitq_get(ba->root_nodes));
- }
-
- /* we don't need it anymore */
- del_waitq(ba->root_nodes);
- ba->root_nodes = NULL;
-
- /* all interesting nodes should have their successors accumulated now */
- while (! waitq_empty(env->alap_queue)) {
- be_ilpsched_irn_t *node = waitq_get(env->alap_queue);
- ilpsched_node_attr_t *na = get_ilpsched_node_attr(node);
-
- /* control flow ops must always be scheduled last */
- if (is_cfop(node->irn) && ! is_Start(node->irn) && get_irn_opcode(node->irn) != iro_End)
- na->asap = na->alap;
- else
- na->alap -= bitset_popcnt(na->transitive_block_nodes);
- DBG((env->dbg, LEVEL_2, "\tALAP of %+F is %u (%u succs, %u consumer)\n",
- node->irn, na->alap, bitset_popcnt(na->transitive_block_nodes), na->n_consumer));
-
- /* maximum block steps is maximum alap of all nodes */
- ba->max_steps = MAX(ba->max_steps, na->alap);
- }
+ DBG((env->dbg, LEVEL_2, "fixing ASAP/ALAP of %+F to %u/%u\n", irn, na->asap, na->alap));
}
-#endif /* if 0 */
/*******************************************
* _ _ _
}
}
+ glob_heights = heights_new(env->irg);
/* sort nodes ascending by scheduling time step */
qsort(sched_nodes, ARR_LEN(sched_nodes), sizeof(sched_nodes[0]), cmp_ilpsched_irn);
+ heights_free(glob_heights);
}
/* make all Phis ready and remember the single cf op */
* - x_{nt}^k binary weigthed with: t
* node n is scheduled at time step t to unit type k
* ==>> These variables represent the schedule
- * TODO:
*
* - d_{nt}^k binary weighted with: t
* node n dies at time step t on unit type k
+ * - a_{nt}^k binary weighted with num_nodes
+ * node n is alive at time step t on unit type k
*
* - y_{nt}^k binary weighted with: num_nodes^2
* node n is scheduled at time step t to unit type k
* although all units of this type are occupied
* ==>> These variables represent the register pressure
+ *
*/
static void create_variables(be_ilpsched_env_t *env, lpp_t *lpp, be_ilpsched_irn_t *block_node, struct obstack *var_obst) {
char buf[1024];
be_ilpsched_irn_t *node;
ilpsched_node_attr_t *na;
unsigned n_unit_types, tp_idx, unit_idx, n_var, cur_unit;
- unsigned cur_var_d, cur_var_x, cur_var_y, num_die;
+ unsigned cur_var_ad, cur_var_x, cur_var_y, num_ad;
/* count number of available unit types for this node */
for (n_unit_types = 0; execunits[n_unit_types]; ++n_unit_types)
na->ilp_vars.y = NEW_ARR_D(int, var_obst, n_unit_types * VALID_SCHED_INTERVAL(na));
memset(na->ilp_vars.y, -1, ARR_LEN(na->ilp_vars.y) * sizeof(na->ilp_vars.y[0]));
- num_die = ba->max_steps - na->asap + 1;
- na->ilp_vars.d = NEW_ARR_D(int, var_obst, n_unit_types * num_die);
- memset(na->ilp_vars.d, -1, ARR_LEN(na->ilp_vars.d) * sizeof(na->ilp_vars.d[0]));
+ num_ad = ba->max_steps - na->asap + 1;
+
+ if (ba->n_interesting_nodes > env->opts->limit_dead) {
+ na->ilp_vars.a = NEW_ARR_D(int, var_obst, n_unit_types * num_ad);
+ memset(na->ilp_vars.a, -1, ARR_LEN(na->ilp_vars.a) * sizeof(na->ilp_vars.a[0]));
+ }
+ else {
+ na->ilp_vars.d = NEW_ARR_D(int, var_obst, n_unit_types * num_ad);
+ memset(na->ilp_vars.d, -1, ARR_LEN(na->ilp_vars.d) * sizeof(na->ilp_vars.d[0]));
+ }
}
DBG((env->dbg, LEVEL_3, "\thandling %+F (asap %u, alap %u, unit types %u):\n",
irn, na->asap, na->alap, na->n_unit_types));
- cur_var_x = cur_var_d = cur_var_y = cur_unit = n_var = 0;
+ cur_var_x = cur_var_ad = cur_var_y = cur_unit = n_var = 0;
/* create variables */
for (tp_idx = 0; tp_idx < n_unit_types; ++tp_idx) {
unsigned t;
/* a node can die at any step t: asap(n) <= t <= U */
if (! na->is_dummy_node) {
for (t = na->asap - 1; t <= ba->max_steps; ++t) {
- /* d_{nt}^k variables */
- snprintf(buf, sizeof(buf), "d_n%u_%s_%u",
- get_irn_idx(irn), na->type_info[tp_idx].tp->name, t);
- na->ilp_vars.d[cur_var_d++] = lpp_add_var(lpp, buf, lpp_binary, (double)(t + 1));
+
+ if (ba->n_interesting_nodes > env->opts->limit_dead) {
+ /* a_{nt}^k variables */
+ snprintf(buf, sizeof(buf), "a_n%u_%s_%u",
+ get_irn_idx(irn), na->type_info[tp_idx].tp->name, t);
+ na->ilp_vars.a[cur_var_ad++] = lpp_add_var(lpp, buf, lpp_binary, (double)(ba->n_interesting_nodes));
+ }
+ else {
+ /* d_{nt}^k variables */
+ snprintf(buf, sizeof(buf), "d_n%u_%s_%u",
+ get_irn_idx(irn), na->type_info[tp_idx].tp->name, t);
+ na->ilp_vars.d[cur_var_ad++] = lpp_add_var(lpp, buf, lpp_binary, (double)(t + 1));
+ }
DBG((env->dbg, LEVEL_4, "\t\tcreated ILP variable %s\n", buf));
/* variable counter */
ilp_timer_pop();
/* the dead node assignment constraint */
- if (! na->is_dummy_node) {
+ if (! na->is_dummy_node && ba->n_interesting_nodes <= env->opts->limit_dead) {
ilp_timer_push(t_cst_dead);
snprintf(buf, sizeof(buf), "dead_node_assign_cst_n%u", get_irn_idx(irn));
cst = lpp_add_cst_uniq(lpp, buf, lpp_less, 1.0);
ilp_timer_pop();
}
+ /* We have separate constraints for Projs and Keeps */
+ // ILP becomes infeasible ?!?
+// if (is_Proj(irn) || be_is_Keep(irn))
+// continue;
+
/* the precedence constraints */
ilp_timer_push(t_cst_prec);
bs_block_irns = bitset_clear_all(bs_block_irns);
}
/**
-* Create ILP pressure constraints:
-* - add additional costs to objective function if a node is scheduled
-* on a unit although all units of this type are currently occupied
+* Create ILP alive nodes constraints:
+* - set variable a_{nt}^k to 1 if nodes n is alive at step t on unit k
*/
-static void create_pressure_constraint(be_ilpsched_env_t *env, lpp_t *lpp, be_ilpsched_irn_t *block_node) {
+static void create_alive_nodes_constraint(be_ilpsched_env_t *env, lpp_t *lpp, be_ilpsched_irn_t *block_node) {
+ char buf[1024];
+ ir_node *irn;
+ unsigned num_cst = 0;
+ ilpsched_block_attr_t *ba = get_ilpsched_block_attr(block_node);
+#ifdef WITH_LIBCORE
+ lc_timer_t *t_cst = lc_timer_register("beilpsched_cst_alive_nodes", "create alive nodes constraints");
+#endif /* WITH_LIBCORE */
+
+ ilp_timer_push(t_cst);
+ /* for each node */
+ foreach_linked_irns(ba->head_ilp_nodes, irn) {
+ be_ilpsched_irn_t *node = get_ilpsched_irn(env, irn);
+ ilpsched_node_attr_t *na = get_ilpsched_node_attr(node);
+ unsigned t;
+
+ /* we ignore nodes assigned to dummy unit here */
+ if (na->is_dummy_node)
+ continue;
+
+ /* check check all time steps: asap(n) <= t <= U */
+ for (t = na->asap - 1; t < ba->max_steps; ++t) {
+ int node_tp_idx;
+
+ /* for all unit types available for this node */
+ for (node_tp_idx = na->n_unit_types - 1; node_tp_idx >= 0; --node_tp_idx) {
+ unsigned tn, tn_max, idx;
+ int cst, i;
+ int *tmp_var_idx_n = NEW_ARR_F(int, 0);
+ int *tmp_var_idx_m = NEW_ARR_F(int, 0);
+
+ snprintf(buf, sizeof(buf), "alive_node_cst_%u_n%u_%s",
+ t, get_irn_idx(irn), na->type_info[node_tp_idx].tp->name);
+ cst = lpp_add_cst_uniq(lpp, buf, lpp_less, 0.0);
+ DBG((env->dbg, LEVEL_2, "added constraint %s\n", buf));
+ num_cst++;
+
+ tn_max = MIN(na->alap - 1, t);
+ /* check if the node has been scheduled so far */
+ for (tn = na->asap - 1; tn <= tn_max; ++tn) {
+ int idx = ILPVAR_IDX(na, node_tp_idx, tn);
+ ARR_APP1(int, tmp_var_idx_n, na->ilp_vars.x[idx]);
+ }
+
+ if (ARR_LEN(tmp_var_idx_n) > 0)
+ lpp_set_factor_fast_bulk(lpp, cst, tmp_var_idx_n, ARR_LEN(tmp_var_idx_n), (double)(na->n_consumer));
+ DEL_ARR_F(tmp_var_idx_n);
+
+ /* subtract the number of consumer scheduled so far */
+ for (i = ARR_LEN(na->block_consumer) - 1; i >= 0; --i) {
+ be_ilpsched_irn_t *cons = get_ilpsched_irn(env, na->block_consumer[i]);
+ ilpsched_node_attr_t *ca = get_ilpsched_node_attr(cons);
+ int tp_idx;
+ unsigned tm, tm_max;
+
+ tm_max = MIN(ca->alap - 1, t);
+ for (tp_idx = ca->n_unit_types - 1; tp_idx >= 0; --tp_idx) {
+ for (tm = ca->asap - 1; tm <= tm_max; ++tm) {
+ int idx = ILPVAR_IDX(ca, tp_idx, tm);
+ ARR_APP1(int, tmp_var_idx_m, ca->ilp_vars.x[idx]);
+ }
+ }
+ }
+
+ if (ARR_LEN(tmp_var_idx_m) > 0)
+ lpp_set_factor_fast_bulk(lpp, cst, tmp_var_idx_m, ARR_LEN(tmp_var_idx_m), -1.0);
+ DEL_ARR_F(tmp_var_idx_m);
+
+ /* -c * a_{nt}^k */
+ idx = ILPVAR_IDX_DEAD(ba, na, node_tp_idx, t);
+ lpp_set_factor_fast(lpp, cst, na->ilp_vars.a[idx], 0.0 - (double)(na->n_consumer));
+
+ }
+ }
+ }
+ ilp_timer_pop();
+ DBG((env->dbg, LEVEL_1, "\t%u alive nodes constraints (%g sec)\n",
+ num_cst, ilp_timer_elapsed_usec(t_cst) / 1000000.0));
+}
+
+/**
+ * Create ILP pressure constraints, based on dead nodes:
+ * - add additional costs to objective function if a node is scheduled
+ * on a unit although all units of this type are currently occupied
+ */
+static void create_pressure_dead_constraint(be_ilpsched_env_t *env, lpp_t *lpp, be_ilpsched_irn_t *block_node) {
char buf[1024];
ir_node *cur_irn;
unsigned num_cst = 0;
num_cst, ilp_timer_elapsed_usec(t_cst) / 1000000.0));
}
+/**
+ * Create ILP pressure constraints, based on alive nodes:
+ * - add additional costs to objective function if a node is scheduled
+ * on a unit although all units of this type are currently occupied
+ */
+static void create_pressure_alive_constraint(be_ilpsched_env_t *env, lpp_t *lpp, be_ilpsched_irn_t *block_node) {
+ char buf[1024];
+ ir_node *cur_irn;
+ unsigned num_cst = 0;
+ ilpsched_block_attr_t *ba = get_ilpsched_block_attr(block_node);
+#ifdef WITH_LIBCORE
+ lc_timer_t *t_cst = lc_timer_register("beilpsched_cst_pressure", "create pressure constraints");
+#endif /* WITH_LIBCORE */
+
+ ilp_timer_push(t_cst);
+ /* y_{nt}^k is set for each node and timestep and unit type */
+ foreach_linked_irns(ba->head_ilp_nodes, cur_irn) {
+ unsigned cur_idx = get_irn_idx(cur_irn);
+ be_ilpsched_irn_t *cur_node = get_ilpsched_irn(env, cur_irn);
+ ilpsched_node_attr_t *cur_na = get_ilpsched_node_attr(cur_node);
+ int glob_type_idx;
+
+ /* we ignore nodes assigned to DUMMY unit here */
+ if (cur_na->is_dummy_node)
+ continue;
+
+ /* for all types */
+ for (glob_type_idx = env->cpu->n_unit_types - 1; glob_type_idx >= 0; --glob_type_idx) {
+ be_execution_unit_type_t *cur_tp = &env->cpu->unit_types[glob_type_idx];
+ int cur_tp_idx;
+ unsigned t;
+
+ /* BEWARE: the DUMMY unit types is not in CPU, so it's skipped automatically */
+
+ /* check if node can be executed on this unit type */
+ cur_tp_idx = is_valid_unit_type_for_node(cur_tp, cur_node);
+ if (cur_tp_idx < 0)
+ continue;
+
+ /* check all time_steps at which the current node can be scheduled */
+ for (t = cur_na->asap - 1; t <= cur_na->alap - 1; ++t) {
+ int cst, y_idx;
+ ir_node *irn;
+ int *tmp_var_idx = NEW_ARR_F(int, 0);
+
+ snprintf(buf, sizeof(buf), "pressure_cst_n%u_%u_%s", cur_idx, t, cur_tp->name);
+ cst = lpp_add_cst_uniq(lpp, buf, lpp_less, (double)(cur_tp->n_units - 1));
+ DBG((env->dbg, LEVEL_2, "added constraint %s\n", buf));
+ num_cst++;
+
+ /* - accumulate all nodes alive at point t on unit type k */
+ foreach_linked_irns(ba->head_ilp_nodes, irn) {
+ be_ilpsched_irn_t *node = get_ilpsched_irn(env, irn);
+ ilpsched_node_attr_t *na = get_ilpsched_node_attr(node);
+ int a_idx, tp_idx;
+
+ /* check if node can be alive here */
+ if (t < na->asap - 1)
+ continue;
+
+ tp_idx = is_valid_unit_type_for_node(cur_tp, node);
+
+ /* current type is not suitable */
+ if (tp_idx < 0)
+ continue;
+
+ a_idx = ILPVAR_IDX_DEAD(ba, na, tp_idx, t);
+ ARR_APP1(int, tmp_var_idx, na->ilp_vars.a[a_idx]);
+ }
+
+ if (ARR_LEN(tmp_var_idx) > 0)
+ lpp_set_factor_fast_bulk(lpp, cst, tmp_var_idx, ARR_LEN(tmp_var_idx), 1.0);
+ DEL_ARR_F(tmp_var_idx);
+
+ /* - num_nodes * y_{nt}^k */
+ y_idx = ILPVAR_IDX(cur_na, cur_tp_idx, t);
+ lpp_set_factor_fast(lpp, cst, cur_na->ilp_vars.y[y_idx], 0.0 - (double)(ba->n_interesting_nodes));
+ }
+ }
+ }
+ ilp_timer_pop();
+ DBG((env->dbg, LEVEL_1, "\t%u pressure constraints (%g sec)\n",
+ num_cst, ilp_timer_elapsed_usec(t_cst) / 1000000.0));
+}
+
+static void create_proj_keep_constraints(be_ilpsched_env_t *env, lpp_t *lpp, be_ilpsched_irn_t *block_node) {
+ char buf[1024];
+ ir_node *irn;
+ unsigned num_cst = 0;
+ ilpsched_block_attr_t *ba = get_ilpsched_block_attr(block_node);
+#ifdef WITH_LIBCORE
+ lc_timer_t *t_cst = lc_timer_register("beilpsched_cst_projkeep", "create proj and keep constraints");
+#endif /* WITH_LIBCORE */
+
+ ilp_timer_push(t_cst);
+ /* check all nodes */
+ foreach_linked_irns(ba->head_ilp_nodes, irn) {
+ be_ilpsched_irn_t *node;
+ ilpsched_node_attr_t *na;
+ unsigned t;
+ ir_node **pk;
+
+ /* only mode_T nodes can have Projs and Keeps assigned */
+ if (get_irn_mode(irn) != mode_T)
+ continue;
+
+ node = get_ilpsched_irn(env, irn);
+ na = get_ilpsched_node_attr(node);
+
+ /* check if has some Projs and Keeps assigned */
+ if (! na->projkeeps)
+ continue;
+
+ /* we can run only once over the queue, so preserve the nodes */
+ pk = NEW_ARR_F(ir_node *, 0);
+ while (! waitq_empty(na->projkeeps))
+ ARR_APP1(ir_node *, pk, waitq_get(na->projkeeps));
+ del_waitq(na->projkeeps);
+ na->projkeeps = NULL;
+
+ /* for all time steps at which this node can be scheduled */
+ for (t = na->asap - 1; t <= na->alap - 1; ++t) {
+ int cst, tp_idx, i;
+ int *tmp_var_idx_n = NEW_ARR_F(int, 0);
+
+ /* add the constraint, assure, that a node is always scheduled along with it's Projs and Keeps */
+ snprintf(buf, sizeof(buf), "projkeep_cst_n%u_%u", get_irn_idx(irn), t);
+ cst = lpp_add_cst_uniq(lpp, buf, lpp_equal, 0.0);
+ DBG((env->dbg, LEVEL_2, "added constraint %s\n", buf));
+ num_cst++;
+
+ /* sum up scheduling variables for this time step */
+ for (tp_idx = na->n_unit_types - 1; tp_idx >= 0; --tp_idx) {
+ int idx = ILPVAR_IDX(na, tp_idx, t);
+ ARR_APP1(int, tmp_var_idx_n, na->ilp_vars.x[idx]);
+ }
+
+ if (ARR_LEN(tmp_var_idx_n) > 0)
+ lpp_set_factor_fast_bulk(lpp, cst, tmp_var_idx_n, ARR_LEN(tmp_var_idx_n), (double)(ARR_LEN(pk)));
+ DEL_ARR_F(tmp_var_idx_n);
+
+ /* subtract all Proj and Keep variables for this step */
+ for (i = ARR_LEN(pk) - 1; i >= 0; --i) {
+ be_ilpsched_irn_t *pk_node = get_ilpsched_irn(env, pk[i]);
+ ilpsched_node_attr_t *pk_na = get_ilpsched_node_attr(pk_node);
+ int pk_tp_idx;
+
+ for (pk_tp_idx = pk_na->n_unit_types - 1; pk_tp_idx >= 0; --pk_tp_idx) {
+ int idx = ILPVAR_IDX(pk_na, pk_tp_idx, t);
+ lpp_set_factor_fast(lpp, cst, pk_na->ilp_vars.x[idx], -1.0);
+ }
+ }
+ }
+ }
+ ilp_timer_pop();
+ DBG((env->dbg, LEVEL_1, "\t%u Proj and Keep constraints (%g sec)\n",
+ num_cst, ilp_timer_elapsed_usec(t_cst) / 1000000.0));
+}
+
/***************************************************
* _____ _ _____ _
* |_ _| | | __ \ (_)
create_assignment_and_precedence_constraints(env, lpp, block_node);
create_ressource_constraints(env, lpp, block_node);
create_bundle_constraints(env, lpp, block_node);
- create_dying_nodes_constraint(env, lpp, block_node);
- create_pressure_constraint(env, lpp, block_node);
+ //create_proj_keep_constraints(env, lpp, block_node);
+ if (ba->n_interesting_nodes > env->opts->limit_dead) {
+ create_alive_nodes_constraint(env, lpp, block_node);
+ create_pressure_alive_constraint(env, lpp, block_node);
+ } else {
+ create_dying_nodes_constraint(env, lpp, block_node);
+ create_pressure_dead_constraint(env, lpp, block_node);
+ }
DBG((env->dbg, LEVEL_1, "ILP to solve: %u variables, %u constraints\n", lpp->var_next, lpp->cst_next));