-/** vim: set sw=4 ts=4:
- * @file bespillremat.c
- * @date 2006-04-06
- * @author Adam M. Szalkowski & Sebastian Hack
+/*
+ * Copyright (C) 1995-2007 University of Karlsruhe. All right reserved.
*
- * ILP based spilling & rematerialization
+ * This file is part of libFirm.
*
- * Copyright (C) 2006 Universitaet Karlsruhe
- * Released under the GPL
+ * 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.
+ *
+ * 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 ILP based spilling & rematerialization
+ * @author Adam M. Szalkowski
+ * @date 06.04.2006
+ * @version $Id$
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#include "irnode_t.h"
#include "ircons_t.h"
#include "irloop_t.h"
-#include "phiclass_t.h"
-#include "iredges.h"
+#include "irnodeset.h"
+#include "phiclass.h"
+#include "iredges_t.h"
#include "execfreq.h"
#include "irvrfy.h"
+#include "irbackedge_t.h"
#include <lpp/lpp.h>
#include <lpp/mps.h>
#include <lpp/lpp_net.h>
#include <lpp/lpp_cplex.h>
-//#include <lc_pset.h>
-#include <libcore/lc_bitset.h>
#include "be_t.h"
+#include "beirg_t.h"
#include "belive_t.h"
#include "besched_t.h"
-#include "beirgmod.h"
-#include "bearch.h"
+#include "bessaconstr.h"
+#include "bearch_t.h"
+#include "beintlive_t.h"
+#include "beabi.h"
#include "benode_t.h"
#include "beutil.h"
#include "bespillremat.h"
#include "bespill.h"
#include "bepressurestat.h"
-
+#include "beprofile.h"
+#include "bespilloptions.h"
#include "bechordal_t.h"
+#include "bemodule.h"
-#ifdef WITH_LIBCORE
#include <libcore/lc_opts.h>
#include <libcore/lc_opts_enum.h>
-#endif /* WITH_LIBCORE */
#define DUMP_PROBLEM 1
#define DUMP_MPS 2
#define DUMP_SOLUTION 4
+#define DUMP_STATS 8
+#define DUMP_PRESSURE 16
#define KEEPALIVE_REMATS 1
#define KEEPALIVE_SPILLS 2
#define REMATS_NOINVERSE 2
#define REMATS_ALL 3
-static int opt_dump_flags = 0;
+static unsigned opt_dump_flags = 0;
static int opt_log = 0;
-static int opt_keep_alive = 0;
+static unsigned opt_keep_alive = 0;
static int opt_goodwin = 1;
static int opt_memcopies = 1;
static int opt_memoperands = 1;
static int opt_verify = VERIFY_MEMINTERF;
-static int opt_remats = REMATS_ALL;
+static unsigned opt_remats = REMATS_ALL;
static int opt_repair_schedule = 0;
static int opt_no_enlarge_liveness = 0;
static int opt_remat_while_live = 1;
static int opt_timeout = 300;
static double opt_cost_reload = 8.0;
static double opt_cost_memoperand = 7.0;
-static double opt_cost_spill = 50.0;
+static double opt_cost_spill = 15.0;
static double opt_cost_remat = 1.0;
-#ifdef WITH_LIBCORE
static const lc_opt_enum_mask_items_t dump_items[] = {
{ "problem", DUMP_PROBLEM },
{ "mps", DUMP_MPS },
{ "solution", DUMP_SOLUTION },
+ { "stats", DUMP_STATS },
+ { "pressure", DUMP_PRESSURE },
{ NULL, 0 }
};
};
static const lc_opt_table_entry_t options[] = {
- LC_OPT_ENT_ENUM_MASK("keepalive", "keep alive remats, spills or reloads", &keep_alive_var),
+ LC_OPT_ENT_ENUM_MASK("keepalive", "keep alive inserted nodes", &keep_alive_var),
LC_OPT_ENT_BOOL ("goodwin", "activate goodwin reduction", &opt_goodwin),
LC_OPT_ENT_BOOL ("memcopies", "activate memcopy handling", &opt_memcopies),
LC_OPT_ENT_BOOL ("memoperands", "activate memoperands", &opt_memoperands),
- LC_OPT_ENT_ENUM_INT ("remats", "type of remats to insert (none, briggs, noinverse or all)",&remats_var),
+ LC_OPT_ENT_ENUM_INT ("remats", "type of remats to insert", &remats_var),
LC_OPT_ENT_BOOL ("repair_schedule", "repair the schedule by rematting once used nodes",&opt_repair_schedule),
LC_OPT_ENT_BOOL ("no_enlage_liveness", "do not enlarge liveness of operands of remats",&opt_no_enlarge_liveness),
- LC_OPT_ENT_BOOL ("remat_while_live", "remat only values that can be used by real ops", &opt_remat_while_live),
+ LC_OPT_ENT_BOOL ("remat_while_live", "only remat where rematted value was live", &opt_remat_while_live),
- LC_OPT_ENT_ENUM_MASK("dump", "dump problem, mps or solution", &dump_var),
+ LC_OPT_ENT_ENUM_MASK("dump", "dump problem, solution or statistical data", &dump_var),
LC_OPT_ENT_BOOL ("log", "activate the lpp log", &opt_log),
LC_OPT_ENT_INT ("timeout", "ILP solver timeout", &opt_timeout),
LC_OPT_ENT_DBL ("cost_memoperand", "cost of a memory operand", &opt_cost_memoperand),
LC_OPT_ENT_DBL ("cost_spill", "cost of a spill instruction", &opt_cost_spill),
LC_OPT_ENT_DBL ("cost_remat", "cost of a rematerialization", &opt_cost_remat),
- { NULL }
+ LC_OPT_LAST
};
-void be_spill_remat_register_options(lc_opt_entry_t *grp)
-{
- lc_opt_entry_t *my_grp = lc_opt_get_grp(grp, "remat");
- lc_opt_add_table(my_grp, options);
-}
-#endif
-
-
//#define EXECFREQ_LOOPDEPH /* compute execution frequency from loop depth only */
//#define SCHEDULE_PHIM /* insert phim nodes into schedule */
typedef struct _spill_ilp_t {
const arch_register_class_t *cls;
int n_regs;
- const be_chordal_env_t *chordal_env;
+ be_irg_t *birg;
be_lv_t *lv;
lpp_t *lpp;
struct obstack *obst;
set *interferences;
ir_node *m_unknown;
set *memoperands;
+ phi_classes_t *pc;
+#ifndef SCHEDULE_PHIM
+ pset *phims;
+#endif
DEBUG_ONLY(firm_dbg_module_t * dbg);
} spill_ilp_t;
static INLINE int
has_reg_class(const spill_ilp_t * si, const ir_node * irn)
{
- return chordal_has_class(si->chordal_env, irn);
+ return arch_irn_consider_in_reg_alloc(si->birg->main_env->arch_env,
+ si->cls, irn);
}
#if 0
cmp_remat(const void *a, const void *b)
{
const remat_t *r = a;
- const remat_t *s = a;
+ const remat_t *s = b;
return !(r == s || r->op == s->op);
}
{
const spill_t *p = a;
const spill_t *q = b;
+ (void) size;
// return !(p->irn == q->irn && p->bb == q->bb);
return !(p->irn == q->irn);
{
const memoperand_t *p = a;
const memoperand_t *q = b;
+ (void) size;
return !(p->irn == q->irn && p->pos == q->pos);
}
{
const remat_info_t *p = a;
const remat_info_t *q = b;
+ (void) size;
return !(p->irn == q->irn);
}
{
const defs_t *p = a;
const defs_t *q = b;
+ (void) size;
return !(p->value == q->value);
}
{
const keyval_t *p = a;
const keyval_t *q = b;
+ (void) size;
return !(p->key == q->key);
}
execution_frequency(const spill_ilp_t *si, const ir_node * irn)
{
#define FUDGE 0.001
+ if(be_profile_has_data())
+ return ((double)be_profile_get_block_execcount(get_block(irn))) + FUDGE;
+
#ifndef EXECFREQ_LOOPDEPH
- return get_block_execfreq(si->chordal_env->exec_freq, get_block(irn)) + FUDGE;
+ return get_block_execfreq(si->birg->exec_freq, get_block(irn)) + FUDGE;
#else
if(is_Block(irn))
return exp(get_loop_depth(get_irn_loop(irn)) * log(10)) + FUDGE;
} else if(be_is_Reload(irn)){
return opt_cost_reload;
} else {
- return arch_get_op_estimated_cost(si->chordal_env->birg->main_env->arch_env, irn);
+ return arch_get_op_estimated_cost(si->birg->main_env->arch_env, irn);
}
}
is_rematerializable(const spill_ilp_t * si, const ir_node * irn)
{
int n;
- const arch_env_t *arch_env = si->chordal_env->birg->main_env->arch_env;
+ const arch_env_t *arch_env = si->birg->main_env->arch_env;
int remat = (arch_irn_get_flags(arch_env, irn) & arch_irn_flags_rematerializable) != 0;
#if 0
if(!is_rematerializable(si, op))
return NULL;
- remat = obstack_alloc(si->obst, sizeof(*remat));
- remat->op = op;
- remat->cost = get_cost(si, op);
- remat->value = dest_value;
- remat->proj = proj;
+ remat = obstack_alloc(si->obst, sizeof(*remat));
+ remat->op = op;
+ remat->cost = (int)get_cost(si, op);
+ remat->value = dest_value;
+ remat->proj = proj;
remat->inverse = 0;
} else {
arch_inverse_t inverse;
DBG((si->dbg, LEVEL_5, "\t requesting inverse op for argument %d of op %+F\n", n, op));
/* else ask the backend to give an inverse op */
- if(arch_get_inverse(si->chordal_env->birg->main_env->arch_env, op, n, &inverse, si->obst)) {
+ if(arch_get_inverse(si->birg->main_env->arch_env, op, n, &inverse, si->obst)) {
int i;
DBG((si->dbg, LEVEL_4, "\t backend gave us an inverse op with %d nodes and cost %d\n", inverse.n, inverse.costs));
remat->proj = (inverse.n==2)?inverse.nodes[1]:NULL;
remat->inverse = 1;
- assert(is_Proj(remat->proj));
+ // Matze: commented this out, this doesn't seem to be true if
+ // the inverse is a simple operation with only 1 result...
+ //assert(is_Proj(remat->proj));
} else {
assert(0 && "I can not handle remats with more than 2 nodes");
}
int n;
int ret = 0;
-// if(is_Proj(irn))
-// irn = get_Proj_pred(irn);
+ if(is_Proj(irn))
+ irn = get_Proj_pred(irn);
for(n=get_irn_arity(irn)-1; n>=0; --n) {
const ir_node *arg = get_irn_n(irn, n);
ir_node *block;
ir_node *def_block = get_nodes_block(val);
int ret;
+ (void) si;
if(val == pos)
return 0;
static INLINE ir_node *
sched_block_last_noncf(const spill_ilp_t * si, const ir_node * bb)
{
- return sched_skip((ir_node*)bb, 0, sched_skip_cf_predicator, (void *) si->chordal_env->birg->main_env->arch_env);
+ return sched_skip((ir_node*)bb, 0, sched_skip_cf_predicator, (void *) si->birg->main_env->arch_env);
}
/**
static int
sched_skip_proj_predicator(const ir_node * irn, void * data)
{
+ (void) data;
return (is_Proj(irn));
}
} else {
insert = sched_next_op(insert);
}
+ sched_reset(irn);
sched_add_before(insert, irn);
}
insert = sched_next_nonproj(insert, 0);
insert = sched_prev(insert);
}
+ sched_reset(irn);
sched_add_after(insert, irn);
}
+static ir_node *
+next_post_remat(const ir_node * irn)
+{
+ op_t *op;
+ ir_node *next;
+
+ if(is_Block(irn)) {
+ next = sched_block_first_nonphi(irn);
+ } else {
+ next = sched_next_op(irn);
+ }
+
+ if(sched_is_end(next))
+ return NULL;
+
+ op = get_irn_link(next);
+ if(op->is_remat && !op->attr.remat.pre) {
+ return next;
+ }
+
+ return NULL;
+}
+
+
+static ir_node *
+next_pre_remat(const spill_ilp_t * si, const ir_node * irn)
+{
+ op_t *op;
+ ir_node *ret;
+
+ if(is_Block(irn)) {
+ ret = sched_block_last_noncf(si, irn);
+ ret = sched_next(ret);
+ ret = sched_prev_op(ret);
+ } else {
+ ret = sched_prev_op(irn);
+ }
+
+ if(sched_is_end(ret) || is_Phi(ret))
+ return NULL;
+
+ op = (op_t*)get_irn_link(ret);
+ if(op->is_remat && op->attr.remat.pre) {
+ return ret;
+ }
+
+ return NULL;
+}
+
/**
* Tells you whether a @p remat can be placed before the irn @p pos
*/
bb = is_Block(pos)?pos:get_nodes_block(pos);
copy = exact_copy(irn);
- _set_phi_class(copy, NULL);
+ set_phi_class(si->pc, copy, NULL);
set_nodes_block(copy, bb);
sched_put_before(si, pos, copy);
bb = is_Block(pos)?pos:get_nodes_block(pos);
copy = exact_copy(irn);
- _set_phi_class(copy, NULL);
+ set_phi_class(si->pc, copy, NULL);
set_nodes_block(copy, bb);
sched_put_after(pos, copy);
return get_irg_start_block(get_irn_irg(bb)) == bb;
}
-static int
-is_before_frame(const ir_node * bb, const ir_node * irn)
-{
- const ir_node *frame = get_irg_frame(get_irn_irg(bb));
-
- if(is_start_block(bb) && sched_get_time_step(frame) >= sched_get_time_step(irn))
- return 1;
- else
- return 0;
-}
-
static int
is_merge_edge(const ir_node * bb)
{
return 1;
}
+static void
+get_live_end(spill_ilp_t * si, ir_node * bb, pset * live)
+{
+ ir_node *irn;
+ int i;
+
+ be_lv_foreach(si->lv, bb, be_lv_state_end, i) {
+ irn = be_lv_get_irn(si->lv, bb, i);
+
+ if (has_reg_class(si, irn) && !pset_find_ptr(si->all_possible_remats, irn)) {
+ pset_insert_ptr(live, irn);
+ }
+ }
+
+ irn = sched_last(bb);
+
+ /* all values eaten by control flow operations are also live until the end of the block */
+ sched_foreach_reverse(bb, irn) {
+ int i;
+
+ if(!sched_skip_cf_predicator(irn, si->birg->main_env->arch_env)) break;
+
+ for(i=get_irn_arity(irn)-1; i>=0; --i) {
+ ir_node *arg = get_irn_n(irn,i);
+
+ if(has_reg_class(si, arg)) {
+ pset_insert_ptr(live, arg);
+ }
+ }
+ }
+ /*
+ * find values that are used by remats at end of block
+ * and insert them into live set
+ */
+ foreach_pre_remat(si, bb, irn) {
+ int n;
+
+ for (n=get_irn_arity(irn)-1; n>=0; --n) {
+ ir_node *remat_arg = get_irn_n(irn, n);
+
+ if(!has_reg_class(si, remat_arg)) continue;
+
+ /* if value is becoming live through use by remat */
+ if(!pset_find_ptr(live, remat_arg)) {
+ DBG((si->dbg, LEVEL_4, " value %+F becoming live through use by remat at end of block %+F\n", remat_arg, irn));
+
+ pset_insert_ptr(live, remat_arg);
+ }
+ }
+ }
+}
+
static void
walker_regclass_copy_insertor(ir_node * irn, void * data)
{
ir_node *bb = get_Block_cfgpred_block(get_nodes_block(irn), n);
if(!has_reg_class(si, phi_arg)) {
- ir_node *copy = be_new_Copy(si->cls, si->chordal_env->irg, bb, phi_arg);
+ ir_node *copy = be_new_Copy(si->cls, si->birg->irg, bb, phi_arg);
ir_node *pos = sched_block_last_noncf(si, bb);
op_t *op = obstack_alloc(si->obst, sizeof(*op));
}
}
-
/**
* Insert (so far unused) remats into the irg to
* recompute the potential liveness of all values
walker_remat_insertor(ir_node * bb, void * data)
{
spill_ilp_t *si = data;
- spill_bb_t *spill_bb;
ir_node *irn;
int n, i;
- pset *live = pset_new_ptr_default();
+ pset *live;
+ pset *post_remats;
+ remat_t *remat;
+
+ /* skip start block, no remats to do there */
+ if(is_start_block(bb)) return;
DBG((si->dbg, LEVEL_3, "\t Entering %+F\n\n", bb));
+ live = pset_new_ptr_default();
be_lv_foreach(si->lv, bb, be_lv_state_end, i) {
ir_node *value = be_lv_get_irn(si->lv, bb, i);
}
}
- spill_bb = obstack_alloc(si->obst, sizeof(*spill_bb));
- set_irn_link(bb, spill_bb);
-
irn = sched_last(bb);
while(!sched_is_end(irn)) {
ir_node *next;
- op_t *op;
pset *args;
ir_node *arg;
- pset *remat_args;
+ pset *used;
next = sched_prev(irn);
- DBG((si->dbg, LEVEL_5, "\t at %+F (next: %+F)\n", irn, next));
+ /* delete defined value from live set */
+ if(has_reg_class(si, irn)) {
+ pset_remove_ptr(live, irn);
+ }
if(is_Phi(irn) || is_Proj(irn)) {
- op_t *op;
-
- if(has_reg_class(si, irn)) {
- pset_remove_ptr(live, irn);
- }
-
- op = obstack_alloc(si->obst, sizeof(*op));
- op->is_remat = 0;
- op->attr.live_range.args.reloads = NULL;
- op->attr.live_range.ilp = ILP_UNDEF;
- set_irn_link(irn, op);
-
irn = next;
continue;
}
- op = obstack_alloc(si->obst, sizeof(*op));
- op->is_remat = 0;
- op->attr.live_range.ilp = ILP_UNDEF;
- op->attr.live_range.args.reloads = obstack_alloc(si->obst, sizeof(*op->attr.live_range.args.reloads) * get_irn_arity(irn));
- memset(op->attr.live_range.args.reloads, 0xFF, sizeof(*op->attr.live_range.args.reloads) * get_irn_arity(irn));
- set_irn_link(irn, op);
-
args = pset_new_ptr_default();
+ used = pset_new_ptr_default();
- /* collect arguments of op */
+ /* collect arguments of op and set args of op already live in epilog */
for (n = get_irn_arity(irn)-1; n>=0; --n) {
ir_node *arg = get_irn_n(irn, n);
pset_insert_ptr(args, arg);
- }
-
- /* set args of op already live in epilog */
- pset_foreach(args, arg) {
if(has_reg_class(si, arg)) {
pset_insert_ptr(live, arg);
+ pset_insert_ptr(used, arg);
}
}
- /* delete defined value from live set */
- if(has_reg_class(si, irn)) {
- pset_remove_ptr(live, irn);
- }
-
-
- remat_args = pset_new_ptr_default();
/* insert all possible remats before irn */
pset_foreach(args, arg) {
remat_info_t *remat_info,
query;
- remat_t *remat;
- /* continue if the operand has the wrong reg class
- */
+ /* continue if the operand has the wrong reg class */
if(!has_reg_class(si, arg))
continue;
ir_node *remat_irn = NULL;
DBG((si->dbg, LEVEL_4, "\t considering remat %+F for arg %+F\n", remat->op, arg));
- if(opt_remat_while_live) {
- if(pset_find_ptr(live, remat->value)) {
- remat_irn = insert_remat_before(si, remat, irn, live);
- }
- } else {
- remat_irn = insert_remat_before(si, remat, irn, live);
- }
+ remat_irn = insert_remat_before(si, remat, irn, live);
+
if(remat_irn) {
for(n=get_irn_arity(remat_irn)-1; n>=0; --n) {
ir_node *remat_arg = get_irn_n(remat_irn, n);
- if(!has_reg_class(si, remat_arg)) continue;
-
- pset_insert_ptr(remat_args, remat_arg);
+ /* collect args of remats which are not args of op */
+ if(has_reg_class(si, remat_arg) && !pset_find_ptr(args, remat_arg)) {
+ pset_insert_ptr(used, remat_arg);
+ }
}
}
}
}
}
- /* now we add remat args to op's args because they could also die at this op */
- pset_foreach(args,arg) {
- if(pset_find_ptr(remat_args, arg)) {
- pset_remove_ptr(remat_args, arg);
- }
- }
- pset_foreach(remat_args,arg) {
- pset_insert_ptr(args, arg);
+ /* do not place post remats after jumps */
+ if(sched_skip_cf_predicator(irn, si->birg->main_env->arch_env)) {
+ del_pset(used);
+ del_pset(args);
+ break;
}
/* insert all possible remats after irn */
- pset_foreach(args, arg) {
+ post_remats = pset_new_ptr_default();
+ pset_foreach(used, arg) {
remat_info_t *remat_info,
query;
- remat_t *remat;
/* continue if the operand has the wrong reg class */
if(!has_reg_class(si, arg))
continue;
}
- /* do not place post remats after jumps */
- if(sched_skip_cf_predicator(irn, si->chordal_env->birg->main_env->arch_env)) continue;
-
if(remat_info->remats_by_operand) {
pset_foreach(remat_info->remats_by_operand, remat) {
/* do not insert remats producing the same value as one of the operands */
if(!pset_find_ptr(args, remat->value)) {
DBG((si->dbg, LEVEL_4, "\t considering remat %+F with arg %+F\n", remat->op, arg));
- if(opt_remat_while_live) {
- if(pset_find_ptr(live, remat->value)) {
- insert_remat_after(si, remat, irn, live);
- }
- } else {
- insert_remat_after(si, remat, irn, live);
+
+ /* only remat values that can be used by real ops */
+ if(!opt_remat_while_live || pset_find_ptr(live, remat->value)) {
+ pset_insert_ptr(post_remats, remat);
}
}
}
}
}
+ pset_foreach(post_remats, remat) {
+ insert_remat_after(si, remat, irn, live);
+ }
+ del_pset(post_remats);
- del_pset(remat_args);
+ del_pset(used);
del_pset(args);
irn = next;
}
pset *live_out = pset_new_ptr_default();
ir_node *value;
- be_lv_foreach(si->lv, bb, be_lv_state_end, i) {
- value = be_lv_get_irn(si->lv, bb, i);
-
- if (be_is_live_end(si->lv, bb, value) && has_reg_class(si, value)) {
- pset_insert_ptr(live_out, value);
- }
- }
+ get_live_end(si, bb, live_out);
/* add remats at end of block */
pset_foreach(live_out, value) {
remat_info_t *remat_info,
query;
- remat_t *remat;
query.irn = value;
query.remats = NULL;
be_lv_foreach(si->lv, bb, be_lv_state_in, i) {
value = be_lv_get_irn(si->lv, bb, i);
- if (has_reg_class(si, value)) {
+ if(has_reg_class(si, value)) {
+ pset_insert_ptr(live_in, value);
+ }
+ }
+ /* add phis to live_in */
+ sched_foreach(bb, value) {
+ if(!is_Phi(value)) break;
+
+ if(has_reg_class(si, value)) {
pset_insert_ptr(live_in, value);
}
}
/* add remat2s at beginning of block */
+ post_remats = pset_new_ptr_default();
pset_foreach(live_in, value) {
- if ((be_is_live_in(si->lv, bb, value) || (is_Phi(value) && get_nodes_block(value)==bb)) && has_reg_class(si, value)) {
- remat_info_t *remat_info,
- query;
- remat_t *remat;
-
- query.irn = value;
- query.remats = NULL;
- query.remats_by_operand = NULL;
- remat_info = set_find(si->remat_info, &query, sizeof(query), HASH_PTR(value));
+ remat_info_t *remat_info,
+ query;
- if(remat_info && remat_info->remats_by_operand) {
- pset_foreach(remat_info->remats_by_operand, remat) {
- DBG((si->dbg, LEVEL_4, "\t considering remat2 %+F at beginning of block %+F\n", remat->op, bb));
+ query.irn = value;
+ query.remats = NULL;
+ query.remats_by_operand = NULL;
+ remat_info = set_find(si->remat_info, &query, sizeof(query), HASH_PTR(value));
- /* put the remat here if all its args are available */
- insert_remat_after(si, remat, bb, live_in);
+ if(remat_info && remat_info->remats_by_operand) {
+ pset_foreach(remat_info->remats_by_operand, remat) {
+ DBG((si->dbg, LEVEL_4, "\t considering remat2 %+F at beginning of block %+F\n", remat->op, bb));
+ /* put the remat here if all its args are available and result is still live */
+ if(!opt_remat_while_live || pset_find_ptr(live_in, remat->value)) {
+ pset_insert_ptr(post_remats, remat);
}
}
}
}
+ pset_foreach(post_remats, remat) {
+ insert_remat_after(si, remat, bb, live_in);
+ }
+ del_pset(post_remats);
del_pset(live_in);
}
}
+static int
+can_be_copied(const ir_node * bb, const ir_node * irn)
+{
+ const ir_edge_t *edge = get_block_succ_first(bb);
+ const ir_node *next_bb = edge->src;
+ int pos = edge->pos;
+ const ir_node *phi;
+
+ assert(is_merge_edge(bb));
+
+ sched_foreach(next_bb, phi) {
+ const ir_node *phi_arg;
+
+ if(!is_Phi(phi)) break;
+
+ phi_arg = get_irn_n(phi, pos);
+
+ if(phi_arg == irn) {
+ return 1;
+ }
+ }
+ return 0;
+}
+
+/**
+ * Initialize additional node info
+ */
+static void
+luke_initializer(ir_node * bb, void * data)
+{
+ spill_ilp_t *si = (spill_ilp_t*)data;
+ spill_bb_t *spill_bb;
+ ir_node *irn;
+
+ spill_bb = obstack_alloc(si->obst, sizeof(*spill_bb));
+ set_irn_link(bb, spill_bb);
+
+ sched_foreach(bb, irn) {
+ op_t *op;
+
+ op = obstack_alloc(si->obst, sizeof(*op));
+ op->is_remat = 0;
+ op->attr.live_range.ilp = ILP_UNDEF;
+ if(is_Phi(irn)) {
+ if(opt_memcopies) {
+ op->attr.live_range.args.copies = obstack_alloc(si->obst, sizeof(*op->attr.live_range.args.copies) * get_irn_arity(irn));
+ memset(op->attr.live_range.args.copies, 0xFF, sizeof(*op->attr.live_range.args.copies) * get_irn_arity(irn));
+ }
+ } else if(!is_Proj(irn)) {
+ op->attr.live_range.args.reloads = obstack_alloc(si->obst, sizeof(*op->attr.live_range.args.reloads) * get_irn_arity(irn));
+ memset(op->attr.live_range.args.reloads, 0xFF, sizeof(*op->attr.live_range.args.reloads) * get_irn_arity(irn));
+ } else {
+ op->attr.live_range.args.reloads = NULL;
+ }
+ set_irn_link(irn, op);
+ }
+}
+
+
/**
* Preparation of blocks' ends for Luke Blockwalker(tm)(R)
*/
spill_bb_t *spill_bb = get_irn_link(bb);
int i;
-
live = pset_new_ptr_default();
use_end = pset_new_ptr_default();
be_lv_foreach(si->lv, bb, be_lv_state_end, i) {
irn = be_lv_get_irn(si->lv, bb, i);
if (has_reg_class(si, irn) && !pset_find_ptr(si->all_possible_remats, irn)) {
- op_t *op;
-
pset_insert_ptr(live, irn);
- op = get_irn_link(irn);
- assert(!op->is_remat);
+ }
+ }
+ /*
+ * find values that are used by remats at end of block
+ * and insert them into live set
+ */
+ foreach_pre_remat(si, bb, irn) {
+ int n;
+
+ for (n=get_irn_arity(irn)-1; n>=0; --n) {
+ ir_node *remat_arg = get_irn_n(irn, n);
+
+ if(has_reg_class(si, remat_arg)) {
+ pset_insert_ptr(live, remat_arg);
+ }
}
}
sched_foreach_reverse(bb, irn) {
int n;
- if(!sched_skip_cf_predicator(irn, si->chordal_env->birg->main_env->arch_env)) break;
+ if(!sched_skip_cf_predicator(irn, si->birg->main_env->arch_env)) break;
for (n=get_irn_arity(irn)-1; n>=0; --n) {
ir_node *irn_arg = get_irn_n(irn, n);
ilp_cst_t rel_cst;
ir_snprintf(buf, sizeof(buf), "reload_%N_%N", bb, irn);
- reload = lpp_add_var_default(si->lpp, buf, lpp_binary, opt_cost_reload*execution_frequency(si, bb), 1.0);
+ reload = lpp_add_var_default(si->lpp, buf, lpp_binary, opt_cost_reload*execution_frequency(si, bb), can_be_copied(bb, irn));
set_insert_keyval(spill_bb->reloads, irn, INT_TO_PTR(reload));
/* reload <= mem_out */
ir_snprintf(buf, sizeof(buf), "reg_out_%N_%N", irn, bb);
spill->reg_out = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, 1.0);
- /* if irn is used at the end of the block, then it is live anyway */
- //lpp_set_factor_fast(si->lpp, cst, spill->reg_out, 1.0);
ir_snprintf(buf, sizeof(buf), "mem_out_%N_%N", irn, bb);
spill->mem_out = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, 1.0);
ir_snprintf(buf, sizeof(buf), "req_cf_end_%N_%N", irn, bb);
end_use_req = lpp_add_cst_uniq(si->lpp, buf, lpp_equal, 1);
- lpp_set_factor_fast(si->lpp, end_use_req, spill->reg_out, 1.0);
- }
-
- del_pset(live);
- del_pset(use_end);
-}
-
-static ir_node *
-next_post_remat(const ir_node * irn)
-{
- op_t *op;
- ir_node *next;
-
- if(is_Block(irn)) {
- next = sched_block_first_nonphi(irn);
- } else {
- next = sched_next_op(irn);
- }
-
- if(sched_is_end(next))
- return NULL;
-
- op = get_irn_link(next);
- if(op->is_remat && !op->attr.remat.pre) {
- return next;
- }
-
- return NULL;
-}
-
-
-static ir_node *
-next_pre_remat(const spill_ilp_t * si, const ir_node * irn)
-{
- op_t *op;
- ir_node *ret;
-
- if(is_Block(irn)) {
- ret = sched_block_last_noncf(si, irn);
- ret = sched_next(ret);
- ret = sched_prev_op(ret);
- } else {
- ret = sched_prev_op(irn);
- }
-
- if(sched_is_end(ret) || is_Phi(ret))
- return NULL;
-
- op = (op_t*)get_irn_link(ret);
- if(op->is_remat && op->attr.remat.pre) {
- return ret;
+ lpp_set_factor_fast(si->lpp, end_use_req, spill->reg_out, 1.0);
}
- return NULL;
+ del_pset(live);
+ del_pset(use_end);
}
+#ifndef NDEBUG
/**
* Find a remat of value @p value in the epilog of @p pos
*/
return NULL;
}
+#endif
static spill_t *
add_to_spill_bb(spill_ilp_t * si, ir_node * bb, ir_node * irn)
return spill;
}
-static void
-get_live_end(spill_ilp_t * si, ir_node * bb, pset * live)
-{
- ir_node *irn;
- int i;
-
- be_lv_foreach(si->lv, bb, be_lv_state_end, i) {
- irn = be_lv_get_irn(si->lv, bb, i);
-
- if (has_reg_class(si, irn) && !pset_find_ptr(si->all_possible_remats, irn)) {
- pset_insert_ptr(live, irn);
- }
- }
-
- irn = sched_last(bb);
-
- /* all values eaten by control flow operations are also live until the end of the block */
- sched_foreach_reverse(bb, irn) {
- int i;
-
- if(!sched_skip_cf_predicator(irn, si->chordal_env->birg->main_env->arch_env)) break;
-
- for(i=get_irn_arity(irn)-1; i>=0; --i) {
- ir_node *arg = get_irn_n(irn,i);
-
- if(has_reg_class(si, arg)) {
- pset_insert_ptr(live, arg);
- }
- }
- }
-}
-
/**
* Inserts ILP-constraints and variables for memory copying before the given position
*/
if(!has_reg_class(si, phi)) continue;
to_copy = get_irn_n(phi, pos);
-
to_copy_op = get_irn_link(to_copy);
to_copy_spill = set_find_spill(spill_bb->ilp, to_copy);
ir_node *tmp;
spill_t *spill;
pset *defs = pset_new_ptr_default();
- const arch_env_t *arch_env = si->chordal_env->birg->main_env->arch_env;
-
+ const arch_env_t *arch_env = si->birg->main_env->arch_env;
live = pset_new_ptr_default();
lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, -1.0);
}
}
- /* maybe we should also assure that reg_out >= live_range etc. */
+ ir_snprintf(buf, sizeof(buf), "reg_out2_%N_%N", bb, irn);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_greater, 0.0);
+
+ /* value may only die at bb end if it is used for a mem copy */
+ /* reg_out + \sum copy - reload - remat - live_range >= 0 */
+ lpp_set_factor_fast(si->lpp, cst, spill->reg_out, 1.0);
+ if(reload != ILP_UNDEF) lpp_set_factor_fast(si->lpp, cst, reload, -1.0);
+ lpp_set_factor_fast(si->lpp, cst, op->attr.live_range.ilp, -1.0);
+ foreach_pre_remat(si, bb, tmp) {
+ op_t *remat_op = get_irn_link(tmp);
+ if(remat_op->attr.remat.remat->value == irn) {
+ lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, -1.0);
+ }
+ }
+ if(is_merge_edge(bb)) {
+ const ir_edge_t *edge = get_block_succ_first(bb);
+ const ir_node *next_bb = edge->src;
+ int pos = edge->pos;
+ const ir_node *phi;
+
+ sched_foreach(next_bb, phi) {
+ const ir_node *phi_arg;
+
+ if(!is_Phi(phi)) break;
+
+ phi_arg = get_irn_n(phi, pos);
+
+ if(phi_arg == irn) {
+ op_t *phi_op = get_irn_link(phi);
+ ilp_var_t copy = phi_op->attr.live_range.args.copies[pos];
+
+ lpp_set_factor_fast(si->lpp, cst, copy, 1.0);
+ }
+ }
+ }
}
if(opt_memcopies)
insert_mem_copy_position(si, live, bb);
/*
- * start new live ranges for values used by remats at end of block
- * and assure the remat args are available
+ * assure the remat args are available
*/
foreach_pre_remat(si, bb, tmp) {
op_t *remat_op = get_irn_link(tmp);
for (n=get_irn_arity(tmp)-1; n>=0; --n) {
ir_node *remat_arg = get_irn_n(tmp, n);
op_t *arg_op = get_irn_link(remat_arg);
- ilp_var_t prev_lr;
if(!has_reg_class(si, remat_arg)) continue;
- /* if value is becoming live through use by remat */
- if(!pset_find_ptr(live, remat_arg)) {
- ir_snprintf(buf, sizeof(buf), "lr_%N_end%N", remat_arg, bb);
- prev_lr = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, 0.0);
-
- arg_op->attr.live_range.ilp = prev_lr;
- arg_op->attr.live_range.op = bb;
-
- DBG((si->dbg, LEVEL_4, " value %+F becoming live through use by remat at end of block %+F\n", remat_arg, tmp));
+ spill = set_find_spill(spill_bb->ilp, remat_arg);
+ assert(spill);
- pset_insert_ptr(live, remat_arg);
- add_to_spill_bb(si, bb, remat_arg);
- }
+ /* arguments of remats have to be live until the very end of the block
+ * remat = reg_out(remat_arg) and (reload(remat_arg) or live_range(remat_arg)),
+ * no remats, they could be in wrong order
+ */
- /* remat <= live_rang(remat_arg) [ + reload(remat_arg) ] */
ir_snprintf(buf, sizeof(buf), "req_remat_%N_arg_%N", tmp, remat_arg);
cst = lpp_add_cst(si->lpp, buf, lpp_less, 0.0);
- lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, 3.0);
+ lpp_set_factor_fast(si->lpp, cst, spill->reg_out, -2.0);
lpp_set_factor_fast(si->lpp, cst, arg_op->attr.live_range.ilp, -1.0);
/* use reload placed for this argument */
pset *used;
pset *remat_defs;
keyval_t *keyval;
- ilp_cst_t one_memoperand;
+ ilp_cst_t one_memoperand = -1;
/* iterate only until first phi */
if(is_Phi(irn))
op = get_irn_link(irn);
/* skip remats */
if(op->is_remat) continue;
+
DBG((si->dbg, LEVEL_4, "\t at node %+F\n", irn));
/* collect defined values */
used = pset_new_ptr(pset_count(live) + get_irn_arity(irn));
remat_defs = pset_new_ptr(pset_count(live));
- for (n=get_irn_arity(irn)-1; n>=0; --n) {
- ir_node *irn_arg = get_irn_n(irn, n);
- if(has_reg_class(si, irn_arg)) {
- set_insert_keyval(args, irn_arg, (void*)n);
- pset_insert_ptr(used, irn_arg);
+ if(!is_start_block(bb) || !be_is_Barrier(irn)) {
+ for (n=get_irn_arity(irn)-1; n>=0; --n) {
+ ir_node *irn_arg = get_irn_n(irn, n);
+ if(has_reg_class(si, irn_arg)) {
+ set_insert_keyval(args, irn_arg, (void*)n);
+ pset_insert_ptr(used, irn_arg);
+ }
}
- }
- foreach_post_remat(irn, tmp) {
- op_t *remat_op = get_irn_link(tmp);
+ foreach_post_remat(irn, tmp) {
+ op_t *remat_op = get_irn_link(tmp);
- pset_insert_ptr(remat_defs, remat_op->attr.remat.remat->value);
+ pset_insert_ptr(remat_defs, remat_op->attr.remat.remat->value);
- for (n=get_irn_arity(tmp)-1; n>=0; --n) {
- ir_node *remat_arg = get_irn_n(tmp, n);
- if(has_reg_class(si, remat_arg)) {
- pset_insert_ptr(used, remat_arg);
+ for (n=get_irn_arity(tmp)-1; n>=0; --n) {
+ ir_node *remat_arg = get_irn_n(tmp, n);
+ if(has_reg_class(si, remat_arg)) {
+ pset_insert_ptr(used, remat_arg);
+ }
}
}
- }
- foreach_pre_remat(si, irn, tmp) {
- for (n=get_irn_arity(tmp)-1; n>=0; --n) {
- ir_node *remat_arg = get_irn_n(tmp, n);
- if(has_reg_class(si, remat_arg)) {
- pset_insert_ptr(used, remat_arg);
+ foreach_pre_remat(si, irn, tmp) {
+ for (n=get_irn_arity(tmp)-1; n>=0; --n) {
+ ir_node *remat_arg = get_irn_n(tmp, n);
+ if(has_reg_class(si, remat_arg)) {
+ pset_insert_ptr(used, remat_arg);
+ }
}
}
}
}
}
- // value_op->attr.live_range.ilp != ILP_UNDEF
if(pset_find_ptr(live, value) && cst != ILP_UNDEF) {
lpp_set_factor_fast(si->lpp, cst, value_op->attr.live_range.ilp, -n_remats);
}
/* new live range for each used value */
ir_snprintf(buf, sizeof(buf), "lr_%N_%N", arg, irn);
- prev_lr = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, is_before_frame(bb, irn)?1.0:0.0);
+ prev_lr = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, 0.0);
/* the epilog stuff - including post_use, check_post, check_post_remat */
ir_snprintf(buf, sizeof(buf), "post_use_%N_%N", arg, irn);
cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 0.0);
lpp_set_factor_fast(si->lpp, cst, post_use, -1.0);
lpp_set_factor_fast(si->lpp, cst, arg_op->attr.live_range.ilp, 1.0);
+ }
+
+ /* forall post remat which use arg add a similar cst */
+ foreach_post_remat(irn, remat) {
+ int n;
+
+ for (n=get_irn_arity(remat)-1; n>=0; --n) {
+ ir_node *remat_arg = get_irn_n(remat, n);
+ op_t *remat_op = get_irn_link(remat);
+
+ if(remat_arg == arg) {
+ DBG((si->dbg, LEVEL_3, "\t found remat with arg %+F in epilog of %+F\n", arg, irn));
+ /* post_use >= remat */
+ ir_snprintf(buf, sizeof(buf), "post_use_%N_%N-%d", arg, irn, p++);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 0.0);
+ lpp_set_factor_fast(si->lpp, cst, post_use, -1.0);
+ lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, 1.0);
+ }
+ }
}
/* if value is not an arg of op and not possibly defined by post remat
}
}
-
- /* forall post remat which use arg add a similar cst */
- foreach_post_remat(irn, remat) {
- int n;
-
- for (n=get_irn_arity(remat)-1; n>=0; --n) {
- ir_node *remat_arg = get_irn_n(remat, n);
- op_t *remat_op = get_irn_link(remat);
-
- if(remat_arg == arg) {
- DBG((si->dbg, LEVEL_3, "\t found remat with arg %+F in epilog of %+F\n", arg, irn));
-
- ir_snprintf(buf, sizeof(buf), "post_use_%N_%N-%d", arg, irn, p++);
- cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 0.0);
- lpp_set_factor_fast(si->lpp, cst, post_use, -1.0);
- lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, 1.0);
- }
- }
- }
-
- if(opt_memoperands) {
+ if(opt_memoperands && (!is_start_block(bb) || be_is_Barrier(irn))) {
for(n = get_irn_arity(irn)-1; n>=0; --n) {
if(get_irn_n(irn, n) == arg && arch_possible_memory_operand(arch_env, irn, n)) {
ilp_var_t memoperand;
lpp_set_factor_fast(si->lpp, cst, memoperand, 1.0);
lpp_set_factor_fast(si->lpp, cst, post_use, 1.0);
-// if(arg_op->attr.live_range.ilp != ILP_UNDEF)
-// lpp_set_factor_fast(si->lpp, cst, arg_op->attr.live_range.ilp, 1.0);
}
}
}
arg_op->attr.live_range.ilp = prev_lr;
arg_op->attr.live_range.op = irn;
- /*if(!pset_find_ptr(live, arg)) {
- pset_insert_ptr(live, arg);
- add_to_spill_bb(si, bb, arg);
- }*/
pset_insert_ptr(live, arg);
-
}
/* just to be sure */
check_post = ILP_UNDEF;
-
+ /* allow original defintions to be removed */
+ if(opt_repair_schedule) {
+ pset_foreach(defs, tmp) {
+ op_t *tmp_op = get_irn_link(tmp);
+ spill_t *spill = set_find_spill(spill_bb->ilp, tmp);
+#if 1
+ ilp_var_t delete;
+ assert(spill);
+
+ ir_snprintf(buf, sizeof(buf), "delete_%N", tmp);
+ delete = lpp_add_var_default(si->lpp, buf, lpp_binary, -1.0*get_cost(si, irn)*execution_frequency(si, bb), 0.0);
+
+ /* op may not be killed if its first live_range is 1 */
+ ir_snprintf(buf, sizeof(buf), "killorig-lr_%N", tmp);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, delete, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, tmp_op->attr.live_range.ilp, 1.0);
+
+ /* op may not be killed if it is spilled after the definition */
+ ir_snprintf(buf, sizeof(buf), "killorig-spill_%N", tmp);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, delete, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, spill->spill, 1.0);
+#else
+ ilp_var_t keep;
+ assert(spill);
+
+ ir_snprintf(buf, sizeof(buf), "keep_%N", tmp);
+ keep = lpp_add_var_default(si->lpp, buf, lpp_binary, get_cost(si, irn)*execution_frequency(si, bb), 1.0);
+
+ /* op may not be killed if its first live_range is 1 */
+ ir_snprintf(buf, sizeof(buf), "killorig-lr_%N", tmp);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_greater, 0.0);
+ lpp_set_factor_fast(si->lpp, cst, keep, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, tmp_op->attr.live_range.ilp, -1.0);
+
+ /* op may not be killed if it is spilled after the definition */
+ ir_snprintf(buf, sizeof(buf), "killorig-spill_%N", tmp);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_greater, 0.0);
+ lpp_set_factor_fast(si->lpp, cst, keep, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, spill->spill, -1.0);
+#endif
+ }
+ } else {
+#if 0
+ pset_foreach(defs, tmp) {
+ op_t *tmp_op = get_irn_link(tmp);
+ spill_t *spill = set_find_spill(spill_bb->ilp, tmp);
+ assert(spill);
+
+ /* live_range or spill should be 1
+ TODO: lr should be live until first use */
+ ir_snprintf(buf, sizeof(buf), "nokillorig_%N", tmp);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_greater, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, tmp_op->attr.live_range.ilp, 1.0);
+ lpp_set_factor_fast(si->lpp, cst, spill->spill, 1.0);
+ }
+#endif
+ }
/******************
pset_remove_ptr(live, tmp);
}
- if(opt_memoperands) {
+ if(opt_memoperands && (!is_start_block(bb) || be_is_Barrier(irn))) {
ir_snprintf(buf, sizeof(buf), "one_memoperand_%N", irn);
one_memoperand = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 1.0);
}
assert(spill);
ir_snprintf(buf, sizeof(buf), "reload_%N_%N", arg, irn);
- op->attr.live_range.args.reloads[i] = lpp_add_var_default(si->lpp, buf, lpp_binary, opt_cost_reload*execution_frequency(si, bb), is_before_frame(bb, irn)?0.0:1.0);
+ op->attr.live_range.args.reloads[i] = lpp_add_var_default(si->lpp, buf, lpp_binary, opt_cost_reload*execution_frequency(si, bb), 1.0);
/* reload <= mem_out */
ir_snprintf(buf, sizeof(buf), "req_reload_%N_%N", arg, irn);
}
}
- if(opt_memoperands) {
+ if(opt_memoperands && (!is_start_block(bb) || be_is_Barrier(irn))) {
n_memoperands = 0;
for(n = get_irn_arity(irn)-1; n>=0; --n) {
if(get_irn_n(irn, n) == arg) {
}
}
-
/* requirements for remats */
- /* start new live ranges for values used by remats */
foreach_pre_remat(si, irn, tmp) {
op_t *remat_op = get_irn_link(tmp);
int n;
assert(has_reg_class(si, tmp));
}
+#ifndef NDEBUG
for (n=get_irn_arity(irn)-1; n>=0; --n) {
ir_node *arg = get_irn_n(irn, n);
assert(!find_post_remat(arg, irn) && "there should be no post remat for an argument of an op");
}
+#endif
del_pset(remat_defs);
del_pset(used);
del_set(args);
del_pset(defs);
defs = pset_new_ptr_default();
+
+ /* skip everything above barrier in start block */
+ if(is_start_block(bb) && be_is_Barrier(irn)) {
+ assert(pset_count(live) == 0);
+ break;
+ }
+
}
+ del_pset(defs);
}
/* construct mem_outs for all values */
-
set_foreach(spill_bb->ilp, spill) {
ir_snprintf(buf, sizeof(buf), "mem_out_%N_%N", spill->irn, bb);
cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 0.0);
int n;
op_t *op = get_irn_link(spill->irn);
- /* do we have to copy a phi argument? */
- op->attr.live_range.args.copies = obstack_alloc(si->obst, sizeof(*op->attr.live_range.args.copies) * get_irn_arity(spill->irn));
- memset(op->attr.live_range.args.copies, 0xFF, sizeof(*op->attr.live_range.args.copies) * get_irn_arity(spill->irn));
-
for(n=get_irn_arity(spill->irn)-1; n>=0; --n) {
const ir_node *arg = get_irn_n(spill->irn, n);
double freq=0.0;
foreach_post_remat(bb, tmp) {
int n;
+ op_t *remat_op = get_irn_link(tmp);
+ pset *remat_args = pset_new_ptr(get_irn_arity(tmp));
+ ir_node *remat_arg;
for (n=get_irn_arity(tmp)-1; n>=0; --n) {
- ir_node *remat_arg = get_irn_n(tmp, n);
+ remat_arg = get_irn_n(tmp, n);
- if(!has_reg_class(si, remat_arg)) continue;
+ if(has_reg_class(si, remat_arg)) {
+ pset_insert_ptr(remat_args, remat_arg);
+ }
+ }
+
+ /* remat + \sum live_range(remat_arg) <= |args| */
+ ir_snprintf(buf, sizeof(buf), "one_must_die_%N", tmp);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, pset_count(remat_args));
+ lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, 1.0);
+
+ pset_foreach(remat_args, remat_arg) {
+ if(pset_find_ptr(live, remat_arg)) {
+ op_t *remat_arg_op = get_irn_link(remat_arg);
+ lpp_set_factor_fast(si->lpp, cst, remat_arg_op->attr.live_range.ilp, 1.0);
+ }
+ }
+ del_pset(remat_args);
+ }
+
+ foreach_post_remat(bb, tmp) {
+ int n;
+
+ for(n=get_irn_arity(tmp)-1; n>=0; --n) {
+ ir_node *remat_arg = get_irn_n(tmp, n);
/* if value is becoming live through use by remat2 */
- if(!pset_find_ptr(live, remat_arg)) {
+ if(has_reg_class(si, remat_arg) && !pset_find_ptr(live, remat_arg)) {
op_t *remat_arg_op = get_irn_link(remat_arg);
ilp_cst_t nomem;
/* optimization: all memory stuff should be 0, for we do not want to insert reloads for remats */
ir_snprintf(buf, sizeof(buf), "nomem_%N_%N", remat_arg, bb);
nomem = lpp_add_cst_uniq(si->lpp, buf, lpp_equal, 0.0);
-
lpp_set_factor_fast(si->lpp, nomem, spill->spill, 1.0);
- if(spill_bb->reloads) {
- keyval_t *keyval = set_find_keyval(spill_bb->reloads, remat_arg);
-
- if(keyval) {
- ilp_var_t reload = PTR_TO_INT(keyval->val);
- lpp_set_factor_fast(si->lpp, nomem, reload, 1.0);
- }
- }
}
}
}
spill = set_find_spill(spill_bb->ilp, remat_arg);
assert(spill);
- /* remat <= reg_in_argument */
ir_snprintf(buf, sizeof(buf), "req_remat2_%N_%N_arg_%N", tmp, bb, remat_arg);
cst = lpp_add_cst(si->lpp, buf, lpp_less, 0.0);
lpp_set_factor_fast(si->lpp, cst, spill->reg_in, -1.0);
const ir_node *remat;
int n_remats = 0;
- if(op->attr.live_range.ilp == ILP_UNDEF) continue;
-
cst = ILP_UNDEF;
foreach_post_remat(bb, remat) {
const op_t *remat_op = get_irn_link(remat);
if(cst == ILP_UNDEF) {
- /* \sum post_remat <= 1 + #post_remats * next(lr) */
- ir_snprintf(buf, sizeof(buf), "remat2_%N_%N_arg_%N", remat, bb, irn);
- cst = lpp_add_cst(si->lpp, buf, lpp_less, 1.0);
+ /* sum remat2s <= 1 + n_remats*live_range */
+ ir_snprintf(buf, sizeof(buf), "dying_lr_%N_%N", irn, bb);
+ cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 1.0);
}
lpp_set_factor_fast(si->lpp, cst, remat_op->attr.remat.ilp, 1.0);
++n_remats;
}
}
}
- if(n_remats) {
- lpp_set_factor_fast(si->lpp, cst, op->attr.live_range.ilp, n_remats);
+ if(cst != ILP_UNDEF && op->attr.live_range.ilp != ILP_UNDEF) {
+ lpp_set_factor_fast(si->lpp, cst, op->attr.live_range.ilp, -n_remats);
}
}
/* walk forward now and compute constraints for placing spills */
/* this must only be done for values that are not defined in this block */
- /* TODO are these values at start of block? if yes, just check whether this is a diverge edge and skip the loop */
pset_foreach(live, irn) {
/*
* if value is defined in this block we can anways place the spill directly after the def
* -> no constraint necessary
*/
- if(!is_Phi(irn) && get_nodes_block(irn) == bb) continue;
+ if(!is_Phi(irn) && get_nodes_block(irn) == bb) {
+ assert(0);
+ }
spill = set_find_spill(spill_bb->ilp, irn);
{
const interference_t *p = a;
const interference_t *q = b;
+ (void) size;
return !(p->a == q->a && p->b == q->b);
}
return result;
}
-static int
-values_interfere_in_block(const spill_ilp_t * si, const ir_node * bb, const ir_node * a, const ir_node * b)
+static
+int values_interfere_in_block(const spill_ilp_t *si, const ir_node *bb, const ir_node *a, const ir_node *b)
{
const ir_edge_t *edge;
- if(get_nodes_block(a) != bb && get_nodes_block(b) != bb) {
+ if (get_nodes_block(a) != bb && get_nodes_block(b) != bb) {
/* both values are live in, so they interfere */
return 1;
}
/* ensure a dominates b */
- if(value_dominates(b,a)) {
- const ir_node * t;
+ if (value_dominates(b, a)) {
+ const ir_node *t;
t = b;
b = a;
a = t;
/* the following code is stolen from bera.c */
- if(be_is_live_end(si->lv, bb, a))
+ if (be_is_live_end(si->lv, bb, a))
return 1;
foreach_out_edge(a, edge) {
const ir_node *user = edge->src;
- if(get_nodes_block(user) == bb
- && !is_Phi(user)
+ if (get_nodes_block(user) == bb
+ && ! is_Phi(user)
&& b != user
- && !pset_find_ptr(si->inverse_ops, user)
+ && ! pset_find_ptr(si->inverse_ops, user)
&& value_dominates(b, user))
return 1;
}
/* a is only interesting if it is in my register class and if it is inside a phi class */
- if (has_reg_class(si, a) && get_phi_class(a)) {
- if(a_op->is_remat || pset_find_ptr(si->inverse_ops, a))
+ if (has_reg_class(si, a) && get_phi_class(si->pc, a)) {
+ if (a_op->is_remat || pset_find_ptr(si->inverse_ops, a))
continue;
- for(l2=_be_lv_next_irn(si->lv, bb, 0xff, l1+1); l2>=0; l2=_be_lv_next_irn(si->lv, bb, 0xff, l2+1)) {
- ir_node *b = be_lv_get_irn(si->lv, bb, l2);
- op_t *b_op = get_irn_link(b);
-
+ for (l2 = _be_lv_next_irn(si->lv, bb, 0xff, l1 + 1); l2 >= 0; l2 = _be_lv_next_irn(si->lv, bb, 0xff, l2 + 1)) {
+ ir_node *b = be_lv_get_irn(si->lv, bb, l2);
+ op_t *b_op = get_irn_link(b);
/* a and b are only interesting if they are in the same phi class */
- if(has_reg_class(si, b) && get_phi_class(a) == get_phi_class(b)) {
- if(b_op->is_remat || pset_find_ptr(si->inverse_ops, b))
+ if (has_reg_class(si, b) && get_phi_class(si->pc, a) == get_phi_class(si->pc, b)) {
+ if (b_op->is_remat || pset_find_ptr(si->inverse_ops, b))
continue;
- if(values_interfere_in_block(si, bb, a, b)) {
+ if (values_interfere_in_block(si, bb, a, b)) {
DBG((si->dbg, LEVEL_4, "\tvalues interfere in %+F: %+F, %+F\n", bb, a, b));
set_insert_interference(si, si->interferences, a, b, bb);
}
char buf[256];
/* teste Speicherwerte auf Interferenz */
- /* analyze phi classes */
- phi_class_compute(si->chordal_env->irg);
-
DBG((si->dbg, LEVEL_2, "\t calling interferencewalker\n"));
- irg_block_walk_graph(si->chordal_env->irg, luke_interferencewalker, NULL, si);
+ irg_block_walk_graph(si->birg->irg, luke_interferencewalker, NULL, si);
/* now lets emit the ILP unequations for the crap */
set_foreach(si->interferences, interference) {
irnlist_t *irnlist;
- ilp_var_t interfere,
- any_interfere;
- ilp_cst_t any_interfere_cst,
- cst;
+ ilp_var_t interfere, any_interfere;
+ ilp_cst_t any_interfere_cst, cst;
const ir_node *a = interference->a;
const ir_node *b = interference->b;
/* any_interf <= \sum interf */
ir_snprintf(buf, sizeof(buf), "interfere_%N_%N", a, b);
any_interfere_cst = lpp_add_cst_uniq(si->lpp, buf, lpp_less, 0);
- any_interfere = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, 1.0);
+ any_interfere = lpp_add_var_default(si->lpp, buf, lpp_binary, 0.0, 1.0);
lpp_set_factor_fast(si->lpp, any_interfere_cst, any_interfere, 1.0);
static int mark_remat_nodes_hook(FILE *F, ir_node *n, ir_node *l)
{
spill_ilp_t *si = get_irg_link(current_ir_graph);
+ (void) l;
if(pset_find_ptr(si->all_possible_remats, n)) {
op_t *op = (op_t*)get_irn_link(n);
static void
dump_pressure_graph(spill_ilp_t * si, const char *suffix)
{
- be_dump(si->chordal_env->irg, suffix, dump_ir_block_graph_sched_pressure);
+ be_dump(si->birg->irg, suffix, dump_ir_block_graph_sched_pressure);
}
static void
++pos;
}
- si->keep = be_new_Keep(si->chordal_env->cls, si->chordal_env->irg, get_irg_end_block(si->chordal_env->irg), n_remats, ins);
+ si->keep = be_new_Keep(si->cls, si->birg->irg, get_irg_end_block(si->birg->irg), n_remats, ins);
obstack_free(si->obst, ins);
}
++pos;
}
- keep = be_new_Keep(si->chordal_env->cls, si->chordal_env->irg, get_irg_end_block(si->chordal_env->irg), n_spills, ins);
+ keep = be_new_Keep(si->cls, si->birg->irg, get_irg_end_block(si->birg->irg), n_spills, ins);
obstack_free(si->obst, ins);
}
/** insert a spill at an arbitrary position */
ir_node *be_spill2(const arch_env_t *arch_env, ir_node *irn, ir_node *insert)
{
- ir_node *bl = is_Block(insert)?insert:get_nodes_block(insert);
+ ir_node *bl = is_Block(insert) ? insert : get_nodes_block(insert);
ir_graph *irg = get_irn_irg(bl);
- ir_node *frame = get_irg_frame(irg);
- ir_node *spill;
- ir_node *next;
-
+ ir_node *frame = get_irg_frame(irg);
+ ir_node *spill;
+ ir_node *next;
const arch_register_class_t *cls = arch_get_irn_reg_class(arch_env, irn, -1);
const arch_register_class_t *cls_frame = arch_get_irn_reg_class(arch_env, frame, -1);
* which is its default initialization (see above).
*/
- if(bl == get_irg_start_block(irg) && sched_get_time_step(frame) >= sched_get_time_step(insert))
+ if (bl == get_irg_start_block(irg) && sched_get_time_step(frame) >= sched_get_time_step(insert))
insert = frame;
for (next = sched_next(insert); is_Phi(next) || is_Proj(next); next = sched_next(insert))
static void
delete_remat(spill_ilp_t * si, ir_node * remat) {
int n;
- ir_node *bad = get_irg_bad(si->chordal_env->irg);
+ ir_node *bad = get_irg_bad(si->birg->irg);
sched_remove(remat);
int n;
remat_t *remat;
remat_info_t *remat_info;
- ir_node *bad = get_irg_bad(si->chordal_env->irg);
+ ir_node *bad = get_irg_bad(si->birg->irg);
set_foreach(si->remat_info, remat_info) {
if(!remat_info->remats) continue;
pset_foreach(remat_info->remats, remat)
{
if(remat->proj && get_irn_n_edges(remat->proj) == 0) {
+ if(sched_is_scheduled(remat->proj)) {
+ sched_remove((ir_node*)remat->proj);
+ }
set_irn_n((ir_node*)remat->proj, -1, bad);
set_irn_n((ir_node*)remat->proj, 0, bad);
}
if(get_irn_n_edges(remat->op) == 0) {
+ if(sched_is_scheduled(remat->op)) {
+ sched_remove((ir_node*)remat->op);
+ }
for (n=get_irn_arity(remat->op)-1; n>=-1; --n) {
set_irn_n((ir_node*)remat->op, n, bad);
}
{
if(opt_keep_alive & KEEPALIVE_REMATS) {
int n;
- ir_node *bad = get_irg_bad(si->chordal_env->irg);
+ ir_node *bad = get_irg_bad(si->birg->irg);
if(si->keep) {
-// ir_node *end = get_irg_end(si->chordal_env->irg);
-// ir_node **keeps;
-
for (n=get_irn_arity(si->keep)-1; n>=0; --n) {
ir_node *keep_arg = get_irn_n(si->keep, n);
op_t *arg_op = get_irn_link(keep_arg);
set_irn_n(si->keep, n, bad);
}
-#if 0
- for (i = 0, n = get_End_n_keepalives(end); i < n; ++i) {
- ir_node *end_arg = get_End_keepalive(end, i);
-
- if(end_arg != si->keep) {
- obstack_grow(si->obst, &end_arg, sizeof(end_arg));
- }
- }
- keeps = obstack_finish(si->obst);
- set_End_keepalives(end, n-1, keeps);
- obstack_free(si->obst, keeps);
-#endif
} else {
DBG((si->dbg, LEVEL_2, "\t no remats to delete (none have been inserted)\n"));
}
return spills;
}
+static ir_node *
+new_r_PhiM_nokeep(ir_graph * irg, ir_node *block, int arity, ir_node **in)
+{
+ ir_node *res;
+
+ assert( get_irn_arity(block) == arity );
+
+ res = new_ir_node(NULL, irg, block, op_Phi, mode_M, arity, in);
+ res->attr.phi_backedge = new_backedge_arr(irg->obst, arity);
+
+ return res;
+}
+
/**
* @param before The node after which the spill will be placed in the schedule
*/
{
defs_t *defs;
ir_node *spill;
- const arch_env_t *arch_env = si->chordal_env->birg->main_env->arch_env;
+ const arch_env_t *arch_env = si->birg->main_env->arch_env;
DBG((si->dbg, LEVEL_3, "\t inserting spill for value %+F after %+F\n", irn, before));
ins[n] = si->m_unknown;
}
- mem_phi = new_r_Phi(si->chordal_env->irg, get_nodes_block(phi), get_irn_arity(phi), ins, mode_M);
+ mem_phi = new_r_PhiM_nokeep(si->birg->irg, get_nodes_block(phi), get_irn_arity(phi), ins);
defs = set_insert_def(si->values, phi);
assert(defs);
#ifdef SCHEDULE_PHIM
sched_add_after(phi, mem_phi);
+#else
+ pset_insert_ptr(si->phims, mem_phi);
#endif
if(opt_keep_alive & KEEPALIVE_SPILLS)
defs_t *defs;
ir_node *reload,
*spill;
- const arch_env_t *arch_env = si->chordal_env->birg->main_env->arch_env;
+ const arch_env_t *arch_env = si->birg->main_env->arch_env;
DBG((si->dbg, LEVEL_3, "\t inserting reload for value %+F before %+F\n", value, after));
void perform_memory_operand(spill_ilp_t * si, memoperand_t * memoperand)
{
defs_t *defs;
- ir_node *reload;
ir_node *value = get_irn_n(memoperand->irn, memoperand->pos);
ir_node *spill;
- const arch_env_t *arch_env = si->chordal_env->birg->main_env->arch_env;
+ const arch_env_t *arch_env = si->birg->main_env->arch_env;
DBG((si->dbg, LEVEL_2, "\t inserting memory operand for value %+F at %+F\n", value, memoperand->irn));
spill = defs->spills;
assert(spill && "no spill placed before reload");
- reload = be_reload(arch_env, si->cls, memoperand->irn, get_irn_mode(value), spill);
-
- arch_perform_memory_operand(arch_env, memoperand->irn, reload, memoperand->pos);
- sched_remove(reload);
+ arch_perform_memory_operand(arch_env, memoperand->irn, spill, memoperand->pos);
}
void insert_memoperands(spill_ilp_t * si)
{
ir_node *insert_pos = bb;
ir_node *spill;
- const arch_env_t *arch_env = si->chordal_env->birg->main_env->arch_env;
+ const arch_env_t *arch_env = si->birg->main_env->arch_env;
/* find last definition of arg value in block */
ir_node *next;
reload = insert_reload(si, arg, insert_pos);
+ assert(reload && "no reload returned");
set_irn_n(irn, n, reload);
if(opt_keep_alive & KEEPALIVE_RELOADS)
static void
walker_collect_used(ir_node * irn, void * data)
{
- lc_bitset_t *used = data;
+ bitset_t *used = data;
- lc_bitset_set(used, get_irn_idx(irn));
+ bitset_set(used, get_irn_idx(irn));
}
struct kill_helper {
- lc_bitset_t *used;
+ bitset_t *used;
spill_ilp_t *si;
};
ir_node *next = sched_next(irn);
int n;
- if(!lc_bitset_is_set(kh->used, get_irn_idx(irn))) {
+ if(!bitset_is_set(kh->used, get_irn_idx(irn))) {
if(be_is_Spill(irn) || be_is_Reload(irn)) {
DBG((kh->si->dbg, LEVEL_1, "\t SUBOPTIMAL! %+F IS UNUSED (cost: %g)\n", irn, get_cost(kh->si, irn)*execution_frequency(kh->si, bb)));
#if 0
}
}
+#ifndef SCHEDULE_PHIM
+static void
+kill_unused_phims(spill_ilp_t * si, struct kill_helper * kh)
+{
+ ir_node *phi;
+ ir_node *bad = get_irg_bad(si->birg->irg);
+ int n;
+
+ pset_foreach(si->phims, phi) {
+ if(!bitset_is_set(kh->used, get_irn_idx(phi))) {
+
+ set_nodes_block(phi, bad);
+ for (n=get_irn_arity(phi)-1; n>=0; --n) {
+ set_irn_n(phi, n, bad);
+ }
+ }
+ }
+}
+#endif
+
static void
kill_all_unused_values_in_schedule(spill_ilp_t * si)
{
- struct kill_helper kh;
+ struct kill_helper kh;
- kh.used = lc_bitset_malloc(get_irg_last_idx(si->chordal_env->irg));
+ kh.used = bitset_malloc(get_irg_last_idx(si->birg->irg));
kh.si = si;
- irg_walk_graph(si->chordal_env->irg, walker_collect_used, NULL, kh.used);
- irg_block_walk_graph(si->chordal_env->irg, walker_kill_unused, NULL, &kh);
+ irg_walk_graph(si->birg->irg, walker_collect_used, NULL, kh.used);
+#ifndef SCHEDULE_PHIM
+ kill_unused_phims(si, &kh);
+#endif
+ irg_block_walk_graph(si->birg->irg, walker_kill_unused, NULL, &kh);
- lc_bitset_free(kh.used);
+ bitset_free(kh.used);
}
void
}
void
-dump_phi_class(spill_ilp_t * si, pset * phiclass, const char * file)
+dump_phi_class(spill_ilp_t *si, ir_node **phiclass, const char * file)
{
FILE *f = fopen(file, "w");
ir_node *irn;
interference_t *interference;
+ int i;
- pset_break(phiclass);
set_break(si->interferences);
ir_fprintf(f, "digraph phiclass {\n");
- pset_foreach(phiclass, irn) {
- if(is_Phi(irn))
- ir_fprintf(f, " %F%N [shape=box]\n",irn,irn);
+ for (i = ARR_LEN(phiclass) - 1; i >= 0; --i) {
+ irn = phiclass[i];
+ if (is_Phi(irn))
+ ir_fprintf(f, " %F%N [shape=box]\n", irn, irn);
}
- pset_foreach(phiclass, irn) {
+ for (i = ARR_LEN(phiclass) - 1; i >= 0; --i) {
int n;
- if(!is_Phi(irn)) continue;
+ irn = phiclass[i];
+ if (! is_Phi(irn))
+ continue;
- for(n=get_irn_arity(irn)-1; n>=0; --n) {
+ for (n = get_irn_arity(irn) - 1; n >= 0; --n) {
ir_node *arg = get_irn_n(irn, n);
- ir_fprintf(f, " %F%N -> %F%N\n",irn,irn,arg,arg);
+ ir_fprintf(f, " %F%N -> %F%N\n", irn, irn, arg, arg);
}
}
set_foreach(si->interferences, interference) {
- const ir_node *a = interference->a;
- const ir_node *b = interference->b;
- if(get_phi_class(a) == phiclass) {
- ir_fprintf(f, " %F%N -> %F%N [color=red,dir=none,style=bold]\n",a,a,b,b);
+ const ir_node *a = interference->a;
+ const ir_node *b = interference->b;
+ if (get_phi_class(si->pc, (ir_node *)a) == phiclass) {
+ ir_fprintf(f, " %F%N -> %F%N [color=red,dir=none,style=bold]\n", a, a, b, b);
}
}
static void
rewire_uses(spill_ilp_t * si)
{
- dom_front_info_t *dfi = be_compute_dominance_frontiers(si->chordal_env->irg);
defs_t *defs;
- pset *ignore = pset_new_ptr(1);
+ ir_nodeset_t ignore;
- pset_insert_ptr(ignore, get_irg_end(si->chordal_env->irg));
+ ir_nodeset_init(&ignore);
+ ir_nodeset_insert(&ignore, get_irg_end(si->birg->irg));
/* then fix uses of spills */
set_foreach(si->values, defs) {
spills = get_spills_for_value(si, defs->value);
DBG((si->dbg, LEVEL_2, "\t %d remats, %d reloads, and %d spills for value %+F\n", remats, pset_count(reloads), pset_count(spills), defs->value));
if(pset_count(spills) > 1) {
+ be_ssa_construction_env_t senv;
+ ir_node *node;
//assert(pset_count(reloads) > 0);
// print_irn_pset(spills);
// print_irn_pset(reloads);
- be_ssa_constr_set_ignore(dfi, si->lv, spills, ignore);
+ be_ssa_construction_init(&senv, si->birg);
+ be_ssa_construction_set_ignore_uses(&senv, &ignore);
+ pset_foreach(spills, node) {
+ be_ssa_construction_add_copy(&senv, node);
+ }
+ pset_foreach(spills, node) {
+ be_ssa_construction_fix_users(&senv, node);
+ }
+ be_ssa_construction_update_liveness_phis(&senv, si->lv);
+ pset_foreach(spills, node) {
+ be_liveness_update(si->lv, node);
+ }
+ be_ssa_construction_destroy(&senv);
}
del_pset(reloads);
/* first fix uses of remats and reloads */
set_foreach(si->values, defs) {
- pset *nodes;
const ir_node *next = defs->remats;
+ int orig_kept = 0;
if(next) {
- nodes = pset_new_ptr_default();
- pset_insert_ptr(nodes, defs->value);
+ be_ssa_construction_env_t senv;
+
+ be_ssa_construction_init(&senv, si->birg);
+
+ if(sched_is_scheduled(defs->value)) {
+ be_ssa_construction_add_copy(&senv, (ir_node*) defs->value);
+ orig_kept = 1;
+ }
+
+ next = defs->remats;
+ while(next) {
+ be_ssa_construction_add_copy(&senv, (ir_node*) next);
+ next = get_irn_link(next);
+ }
+
+ if(sched_is_scheduled(defs->value)) {
+ be_ssa_construction_fix_users(&senv, (ir_node*) defs->value);
+ }
+ next = defs->remats;
while(next) {
- pset_insert_ptr(nodes, next);
+ be_ssa_construction_fix_users(&senv, (ir_node*) next);
next = get_irn_link(next);
}
- if(pset_count(nodes) > 1) {
- DBG((si->dbg, LEVEL_4, "\t %d new definitions for value %+F\n", pset_count(nodes)-1, defs->value));
- be_ssa_constr_set(dfi, si->lv, nodes);
+ be_ssa_construction_update_liveness_phis(&senv, si->lv);
+ if(sched_is_scheduled(defs->value)) {
+ be_liveness_update(si->lv, (ir_node*) defs->value);
+ }
+
+ next = defs->remats;
+ while(next) {
+ be_liveness_update(si->lv, (ir_node*) next);
+ next = get_irn_link(next);
}
- del_pset(nodes);
+ be_ssa_construction_destroy(&senv);
}
}
+ ir_nodeset_destroy(&ignore);
// remove_unused_defs(si);
-
- be_free_dominance_frontiers(dfi);
}
DBG((si->dbg, LEVEL_1, "Applying results\n"));
delete_unnecessary_remats(si);
- si->m_unknown = new_r_Unknown(si->chordal_env->irg, mode_M);
- irg_block_walk_graph(si->chordal_env->irg, walker_spill_placer, NULL, si);
- irg_block_walk_graph(si->chordal_env->irg, walker_reload_placer, NULL, si);
+ si->m_unknown = new_r_Unknown(si->birg->irg, mode_M);
+ irg_block_walk_graph(si->birg->irg, walker_spill_placer, NULL, si);
+ irg_block_walk_graph(si->birg->irg, walker_reload_placer, NULL, si);
if(opt_memoperands)
insert_memoperands(si);
phim_fixer(si);
static int
get_n_regs(spill_ilp_t * si)
{
- int arch_n_regs = arch_register_class_n_regs(si->cls);
- int free = 0;
- int i;
+ int arch_n_regs = arch_register_class_n_regs(si->cls);
- for(i=0; i<arch_n_regs; i++) {
- if(!arch_register_type_is(&si->cls->regs[i], ignore)) {
- free++;
- }
- }
+ bitset_t *arch_regs = bitset_malloc(arch_n_regs);
+ bitset_t *abi_regs = bitset_malloc(arch_n_regs);
- DBG((si->dbg, LEVEL_1, "\tArchitecture has %d free registers in class %s\n", free, si->cls->name));
- return free;
+ arch_put_non_ignore_regs(si->birg->main_env->arch_env, si->cls, arch_regs);
+ be_abi_put_ignore_regs(si->birg->abi, si->cls, abi_regs);
+
+ bitset_andnot(arch_regs, abi_regs);
+ arch_n_regs = bitset_popcnt(arch_regs);
+
+ bitset_free(arch_regs);
+ bitset_free(abi_regs);
+
+ DBG((si->dbg, LEVEL_1, "\tArchitecture has %d free registers in class %s\n", arch_n_regs, si->cls->name));
+ return arch_n_regs;
}
static void
static void
move_reloads_upward(spill_ilp_t * si)
{
- irg_block_walk_graph(si->chordal_env->irg, walker_reload_mover, NULL, si);
+ irg_block_walk_graph(si->birg->irg, walker_reload_mover, NULL, si);
}
static void
luke_meminterferencechecker(ir_node * bb, void * data)
{
- spill_ilp_t *si = (spill_ilp_t*)data;
- int l1, l2;
+ spill_ilp_t *si = (spill_ilp_t*)data;
+ int l1, l2;
be_lv_foreach(si->lv, bb, be_lv_state_end | be_lv_state_out | be_lv_state_in, l1) {
ir_node *a = be_lv_get_irn(si->lv, bb, l1);
- if(!be_is_Spill(a) && (!is_Phi(a) || get_irn_mode(a) != mode_T)) continue;
+ if (! be_is_Spill(a) && (!is_Phi(a) || get_irn_mode(a) != mode_T))
+ continue;
/* a is only interesting if it is in my register class and if it is inside a phi class */
- if (has_reg_class(si, a) && get_phi_class(a)) {
- for(l2=_be_lv_next_irn(si->lv, bb, 0xff, l1+1); l2>=0; l2=_be_lv_next_irn(si->lv, bb, 0xff, l2+1)) {
- ir_node *b = be_lv_get_irn(si->lv, bb, l2);
+ if (has_reg_class(si, a) && get_phi_class(si->pc, a)) {
+ for (l2 = _be_lv_next_irn(si->lv, bb, 0xff, l1 + 1); l2 >= 0; l2 = _be_lv_next_irn(si->lv, bb, 0xff, l2 + 1)) {
+ ir_node *b = be_lv_get_irn(si->lv, bb, l2);
- if(!be_is_Spill(b) && (!is_Phi(b) || get_irn_mode(b) != mode_T)) continue;
+ if (! be_is_Spill(b) && (! is_Phi(b) || get_irn_mode(b) != mode_T))
+ continue;
/* a and b are only interesting if they are in the same phi class */
- if(has_reg_class(si, b) && get_phi_class(a) == get_phi_class(b)) {
- if(values_interfere_in_block(si, bb, a, b)) {
+ if (has_reg_class(si, b) && get_phi_class(si->pc, a) == get_phi_class(si->pc, b)) {
+ if (values_interfere_in_block(si, bb, a, b)) {
ir_fprintf(stderr, "$$ Spills interfere in %+F: %+F, %+F \t$$\n", bb, a, b);
}
}
verify_phiclasses(spill_ilp_t * si)
{
/* analyze phi classes */
- phi_class_compute(si->chordal_env->irg);
+ phi_class_free(si->pc);
+ si->pc = phi_class_new_from_irg(si->birg->irg, 0);
DBG((si->dbg, LEVEL_2, "\t calling memory interference checker\n"));
- irg_block_walk_graph(si->chordal_env->irg, luke_meminterferencechecker, NULL, si);
-}
-
-static void
-walker_spillslotassigner(ir_node * irn, void * data)
-{
- void *cls;
-
- if(!be_is_Spill(irn)) return;
-
- /* set spill context to phi class if it has one ;) */
- (void) cls;
-#if 0
- // Matze: not needed anymore
- cls = get_phi_class(irn);
- if(cls)
- be_set_Spill_context(irn, cls);
- else
- be_set_Spill_context(irn, irn);
-#endif
-}
-
-
-static void
-assign_spillslots(spill_ilp_t * si)
-{
- DBG((si->dbg, LEVEL_2, "\t calling spill slot assigner\n"));
- irg_walk_graph(si->chordal_env->irg, walker_spillslotassigner, NULL, si);
+ irg_block_walk_graph(si->birg->irg, luke_meminterferencechecker, NULL, si);
}
void
-be_spill_remat(const be_chordal_env_t * chordal_env)
+be_spill_remat(be_irg_t *birg, const arch_register_class_t *cls)
{
char buf[256];
char problem_name[256];
char dump_suffix2[256];
struct obstack obst;
spill_ilp_t si;
+ ir_graph *irg = be_get_birg_irg(birg);
- ir_snprintf(problem_name, sizeof(problem_name), "%F_%s", chordal_env->irg, chordal_env->cls->name);
- ir_snprintf(dump_suffix, sizeof(dump_suffix), "-%s-remats", chordal_env->cls->name);
- ir_snprintf(dump_suffix2, sizeof(dump_suffix2), "-%s-pressure", chordal_env->cls->name);
+ ir_snprintf(problem_name, sizeof(problem_name), "%F_%s", irg, cls->name);
+ ir_snprintf(dump_suffix, sizeof(dump_suffix), "-%s-remats", cls->name);
+ ir_snprintf(dump_suffix2, sizeof(dump_suffix2), "-%s-pressure", cls->name);
FIRM_DBG_REGISTER(si.dbg, "firm.be.ra.spillremat");
DBG((si.dbg, LEVEL_1, "\n\n\t\t===== Processing %s =====\n\n", problem_name));
if(opt_verify & VERIFY_DOMINANCE)
- be_check_dominance(chordal_env->irg);
+ be_check_dominance(irg);
+
+ be_assure_dom_front(birg);
+ be_assure_liveness(birg);
obstack_init(&obst);
- si.chordal_env = chordal_env;
- si.obst = &obst;
- si.cls = chordal_env->cls;
- si.lpp = new_lpp(problem_name, lpp_minimize);
- si.remat_info = new_set(cmp_remat_info, 4096);
- si.interferences = new_set(cmp_interference, 32);
- si.memoperands = new_set(cmp_memoperands, 128);
+ si.obst = &obst;
+ si.birg = birg;
+ si.cls = cls;
+ si.lpp = new_lpp(problem_name, lpp_minimize);
+ si.remat_info = new_set(cmp_remat_info, 4096);
+ si.interferences = new_set(cmp_interference, 32);
+ si.memoperands = new_set(cmp_memoperands, 128);
si.all_possible_remats = pset_new_ptr_default();
- si.spills = pset_new_ptr_default();
- si.inverse_ops = pset_new_ptr_default();
- si.lv = chordal_env->lv;
- si.keep = NULL;
- si.n_regs = get_n_regs(&si);
+ si.spills = pset_new_ptr_default();
+ si.inverse_ops = pset_new_ptr_default();
+ si.lv = birg->lv;
+ si.keep = NULL;
+ si.n_regs = get_n_regs(&si);
- set_irg_link(chordal_env->irg, &si);
- compute_doms(chordal_env->irg);
+ set_irg_link(irg, &si);
+ compute_doms(irg);
/* compute phi classes */
-// phi_class_compute(chordal_env->irg);
+ // phi_class_compute(irg);
- be_analyze_regpressure(chordal_env, "-pre");
+ if(opt_dump_flags & DUMP_STATS)
+ be_analyze_regpressure(birg, cls, "-pre");
+
+ DBG((si.dbg, LEVEL_2, "\t initializing\n"));
+ irg_block_walk_graph(irg, luke_initializer, NULL, &si);
if(opt_remats) {
/* collect remats */
DBG((si.dbg, LEVEL_1, "Collecting remats\n"));
- irg_walk_graph(chordal_env->irg, walker_remat_collector, NULL, &si);
+ irg_walk_graph(irg, walker_remat_collector, NULL, &si);
}
/* insert possible remats */
DBG((si.dbg, LEVEL_1, "Inserting possible remats\n"));
- irg_block_walk_graph(chordal_env->irg, walker_remat_insertor, NULL, &si);
+ irg_block_walk_graph(irg, walker_remat_insertor, NULL, &si);
DBG((si.dbg, LEVEL_2, " -> inserted %d possible remats\n", pset_count(si.all_possible_remats)));
if(opt_keep_alive & KEEPALIVE_REMATS) {
DBG((si.dbg, LEVEL_1, "Connecting remats with keep and dumping\n"));
connect_all_remats_with_keep(&si);
/* dump graph with inserted remats */
- dump_graph_with_remats(chordal_env->irg, dump_suffix);
+ dump_graph_with_remats(irg, dump_suffix);
}
/* insert copies for phi arguments not in my regclass */
- irg_walk_graph(chordal_env->irg, walker_regclass_copy_insertor, NULL, &si);
+ irg_walk_graph(irg, walker_regclass_copy_insertor, NULL, &si);
/* recompute liveness */
DBG((si.dbg, LEVEL_1, "Recomputing liveness\n"));
be_liveness_recompute(si.lv);
/* build the ILP */
-
DBG((si.dbg, LEVEL_1, "\tBuilding ILP\n"));
DBG((si.dbg, LEVEL_2, "\t endwalker\n"));
- irg_block_walk_graph(chordal_env->irg, luke_endwalker, NULL, &si);
+ irg_block_walk_graph(irg, luke_endwalker, NULL, &si);
DBG((si.dbg, LEVEL_2, "\t blockwalker\n"));
- irg_block_walk_graph(chordal_env->irg, luke_blockwalker, NULL, &si);
+ irg_block_walk_graph(irg, luke_blockwalker, NULL, &si);
- if(opt_memcopies) {
+ si.pc = phi_class_new_from_irg(birg->irg, 0);
+ if (opt_memcopies) {
DBG((si.dbg, LEVEL_2, "\t memcopyhandler\n"));
memcopyhandler(&si);
}
- if(opt_dump_flags & DUMP_PROBLEM) {
+ if (opt_dump_flags & DUMP_PROBLEM) {
FILE *f;
ir_snprintf(buf, sizeof(buf), "%s-spillremat.ilp", problem_name);
if ((f = fopen(buf, "wt")) != NULL) {
}
}
- if(opt_dump_flags & DUMP_MPS) {
+ if (opt_dump_flags & DUMP_MPS) {
FILE *f;
ir_snprintf(buf, sizeof(buf), "%s-spillremat.mps", problem_name);
- if((f = fopen(buf, "wt")) != NULL) {
+ if ((f = fopen(buf, "wt")) != NULL) {
mps_write_mps(si.lpp, s_mps_fixed, f);
fclose(f);
}
ir_snprintf(buf, sizeof(buf), "%s-spillremat.mst", problem_name);
- if((f = fopen(buf, "wt")) != NULL) {
+ if ((f = fopen(buf, "wt")) != NULL) {
mps_write_mst(si.lpp, s_mps_fixed, f);
fclose(f);
}
assert(lpp_is_sol_valid(si.lpp)
&& "solution of ILP must be valid");
- DBG((si.dbg, LEVEL_1, "\t%s: iterations: %d, solution time: %g, objective function: %g\n", problem_name, si.lpp->iterations, si.lpp->sol_time, is_zero(si.lpp->objval)?0.0:si.lpp->objval));
+ DBG((si.dbg, LEVEL_1, "\t%s: iterations: %d, solution time: %g, objective function: %g, best bound: %g\n", problem_name, si.lpp->iterations, si.lpp->sol_time, is_zero(si.lpp->objval)?0.0:si.lpp->objval, is_zero(si.lpp->best_bound)?0.0:si.lpp->best_bound));
if(opt_dump_flags & DUMP_SOLUTION) {
FILE *f;
}
}
+#ifndef SCHEDULE_PHIM
+ si.phims = pset_new_ptr_default();
+#endif
writeback_results(&si);
+
#endif /* SOLVE */
kill_all_unused_values_in_schedule(&si);
+#if !defined(SCHEDULE_PHIM) && defined(SOLVE)
+ del_pset(si.phims);
+#endif
+
if(opt_keep_alive & (KEEPALIVE_SPILLS | KEEPALIVE_RELOADS))
- be_dump(chordal_env->irg, "-spills-placed", dump_ir_block_graph);
+ be_dump(irg, "-spills-placed", dump_ir_block_graph);
// move reloads upwards
be_liveness_recompute(si.lv);
- irg_block_walk_graph(chordal_env->irg, walker_pressure_annotator, NULL, &si);
+ irg_block_walk_graph(irg, walker_pressure_annotator, NULL, &si);
move_reloads_upward(&si);
if(opt_memcopies) {
verify_phiclasses(&si);
- assign_spillslots(&si);
}
- irg_block_walk_graph(chordal_env->irg, walker_pressure_annotator, NULL, &si);
+ irg_block_walk_graph(irg, walker_pressure_annotator, NULL, &si);
- dump_pressure_graph(&si, dump_suffix2);
+ if(opt_dump_flags & DUMP_PRESSURE)
+ dump_pressure_graph(&si, dump_suffix2);
- be_analyze_regpressure(chordal_env, "-post");
+ if(opt_dump_flags & DUMP_STATS)
+ be_analyze_regpressure(birg, cls, "-post");
if(opt_verify & VERIFY_DOMINANCE)
- be_check_dominance(chordal_env->irg);
+ be_check_dominance(irg);
- free_dom(chordal_env->irg);
+ free_dom(irg);
del_set(si.interferences);
del_pset(si.inverse_ops);
del_pset(si.all_possible_remats);
del_set(si.memoperands);
del_pset(si.spills);
free_lpp(si.lpp);
+ phi_class_free(si.pc);
obstack_free(&obst, NULL);
DBG((si.dbg, LEVEL_1, "\tdone.\n"));
}
+void be_init_spillremat(void)
+{
+ static be_spiller_t remat_spiller = {
+ be_spill_remat
+ };
+ 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 *remat_grp = lc_opt_get_grp(chordal_grp, "remat");
+
+ be_register_spiller("remat", &remat_spiller);
+ lc_opt_add_table(remat_grp, options);
+}
+
+BE_REGISTER_MODULE_CONSTRUCTOR(be_init_spillremat);
+
#else /* WITH_ILP */
-static void
+static void INLINE
only_that_you_can_compile_without_WITH_ILP_defined(void)
{
}