/*
- * Project: libFIRM
- * File name: ir/ana/execution_frequency.c
- * Purpose: Compute an estimate of basic block executions.
- * Author: Goetz Lindenmaier
- * Modified by:
- * Created: 5.11.2004
- * CVS-ID: $Id$
- * Copyright: (c) 2004 Universität Karlsruhe
- * Licence: This file protected by GPL - GNU GENERAL PUBLIC LICENSE.
+ * Copyright (C) 1995-2008 University of Karlsruhe. All right reserved.
+ *
+ * This file is part of libFirm.
+ *
+ * This file may be distributed and/or modified under the terms of the
+ * GNU General Public License version 2 as published by the Free Software
+ * Foundation and appearing in the file LICENSE.GPL included in the
+ * packaging of this file.
+ *
+ * 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 Compute an estimate of basic block executions.
+ * @author Goetz Lindenmaier
+ * @date 5.11.2004
+ * @version $Id$
*/
-#ifdef HAVE_CONFIG_H
#include "config.h"
-#endif
#include "execution_frequency.h"
-#include "firm_common_t.h"
#include "set.h"
#include "pdeq.h"
#include "hashptr.h"
+#include "error.h"
#include "irprog_t.h"
#include "irgraph_t.h"
/* We use this set for all nodes in all irgraphs. */
static set *exec_freq_set = NULL;
-static int exec_freq_cmp(const void *e1, const void *e2, size_t size) {
+static int exec_freq_cmp(const void *e1, const void *e2, size_t size)
+{
reg_exec_freq *ef1 = (reg_exec_freq *)e1;
reg_exec_freq *ef2 = (reg_exec_freq *)e2;
+ (void) size;
+
return (ef1->reg != ef2->reg);
}
-static INLINE unsigned int exec_freq_hash(reg_exec_freq *e) {
+static inline unsigned int exec_freq_hash(reg_exec_freq *e)
+{
return HASH_PTR(e->reg);
}
-static INLINE void set_region_exec_freq(void *reg, double freq) {
+static inline void set_region_exec_freq(void *reg, double freq)
+{
reg_exec_freq ef;
ef.reg = reg;
ef.freq = freq;
set_insert(exec_freq_set, &ef, sizeof(ef), exec_freq_hash(&ef));
}
-double get_region_exec_freq(void *reg) {
+double get_region_exec_freq(void *reg)
+{
reg_exec_freq ef, *found;
ef.reg = reg;
assert(exec_freq_set);
- found = set_find(exec_freq_set, &ef, sizeof(ef), exec_freq_hash(&ef));
+ found = (reg_exec_freq*) set_find(exec_freq_set, &ef, sizeof(ef), exec_freq_hash(&ef));
/* Not found if information is invalid. */
if (found)
}
/* Returns the number of times the block is executed. */
-double get_Block_exec_freq(ir_node *b) {
+double get_Block_exec_freq(ir_node *b)
+{
return get_region_exec_freq((void *)b);
}
-double get_irn_exec_freq(ir_node *n) {
+double get_irn_exec_freq(ir_node *n)
+{
if (!is_Block(n)) n = get_nodes_block(n);
return get_Block_exec_freq(n);
}
static ir_node *Cond_list = NULL;
/* We do not use an extra set, as Projs are not yet in the existing one. */
-void set_ProjX_probability(ir_node *n, Cond_prob prob) {
+static void set_ProjX_probability(ir_node *n, Cond_prob prob)
+{
reg_exec_freq ef;
ef.reg = n;
ef.prob = prob;
set_insert(exec_freq_set, &ef, sizeof(ef), exec_freq_hash(&ef));
}
-Cond_prob get_ProjX_probability(ir_node *n) {
+static Cond_prob get_ProjX_probability(ir_node *n)
+{
reg_exec_freq ef, *found;
ef.reg = n;
- found = set_find(exec_freq_set, &ef, sizeof(ef), exec_freq_hash(&ef));
+ found = (reg_exec_freq*) set_find(exec_freq_set, &ef, sizeof(ef), exec_freq_hash(&ef));
if (found)
return (Cond_prob)found->prob;
/* A walker that only visits the nodes we want to see. */
-static void
-my_irg_walk_2_both(ir_node *node, irg_walk_func *pre, irg_walk_func *post, void * env) {
+static void my_irg_walk_2_both(ir_node *node, irg_walk_func *pre, irg_walk_func *post, void * env)
+{
int i;
set_irn_visited(node, current_ir_graph->visited);
pre(node, env);
- if (node->op != op_Block) {
+ if (!is_Block(node)) {
ir_node *pred;
- if (node->op == op_Proj)
+ if (is_Proj(node))
pred = get_irn_n(node, 0);
else
pred = get_irn_n(node, -1);
}
}
- if (node->op == op_End) {
+ if (is_End(node)) {
for (i = get_irn_arity(node) - 1; i >= 0; --i) {
ir_node *pred = get_irn_n(node, i);
if ((pred->op == op_Block) && (pred->visited < current_ir_graph->visited))
post(node, env);
}
-static void my_irg_walk_current_graph(irg_walk_func *pre, irg_walk_func *post, void *env) {
+static void my_irg_walk_current_graph(irg_walk_func *pre, irg_walk_func *post, void *env)
+{
inc_irg_visited(current_ir_graph);
my_irg_walk_2_both(get_irg_end(current_ir_graph), pre, post, env);
}
-static void walk_pre(ir_node *n, void *env) {
-
- if (get_irn_op(n) == op_Raise)
+static void walk_pre(ir_node *n, void *env)
+{
+ (void) env;
+ if (is_Raise(n))
just_passed_a_Raise = 1;
- if ( (get_irn_op(n) == op_Proj)
- && (get_irn_op(get_Proj_pred(n)) == op_Cond)
- && (just_passed_a_Raise)) {
+ if (get_irn_op(n) == op_Proj &&
+ is_Cond(get_Proj_pred(n)) &&
+ just_passed_a_Raise) {
ir_node *other_proj;
ir_node *c = get_Proj_pred(n);
}
}
- if (get_irn_op(n) == op_Cond) {
+ if (is_Cond(n)) {
set_irn_link(n, Cond_list);
Cond_list = n;
}
}
-static void walk_post(ir_node *n, void *env) {
-
- if (get_irn_op(n) == op_Raise)
+static void walk_post(ir_node *n, void *env)
+{
+ (void) env;
+ if (is_Raise(n))
just_passed_a_Raise = 0;
- if ( (get_irn_op(n) == op_Proj)
- && (get_irn_op(get_Proj_pred(n)) == op_Cond)
- && ((get_ProjX_probability(n) == Cond_prob_exception_taken) ||
- (get_ProjX_probability(n) == Cond_prob_was_exception_taken) )) {
+ if (get_irn_op(n) == op_Proj &&
+ is_Cond(get_Proj_pred(n)) && (
+ get_ProjX_probability(n) == Cond_prob_exception_taken ||
+ get_ProjX_probability(n) == Cond_prob_was_exception_taken
+ )) {
just_passed_a_Raise = 1;
}
}
/** Precompute which Conds test for an exception.
*
* Operates on current_ir_graph. */
-void precompute_cond_evaluation(void) {
+static void precompute_cond_evaluation(void)
+{
ir_node *c;
compute_irg_outs(current_ir_graph);
Cond_list = NULL;
my_irg_walk_current_graph(walk_pre, walk_post, NULL);
- for (c = Cond_list; c; c = get_irn_link(c)) {
+ for (c = Cond_list; c; c = (ir_node*)get_irn_link(c)) {
ir_node *p0, *p1;
assert(get_irn_n_outs(c) == 2 && "encountered a switch cond");
/* both are exceptions */
if ((get_ProjX_probability(p0) == Cond_prob_exception_taken) &&
(get_ProjX_probability(p1) == Cond_prob_exception_taken) ) {
- assert(0 && "I tried to avoid these!");
+ panic("I tried to avoid these!");
+#if 0
/* It's a */
set_ProjX_probability(p0, Cond_prob_normal);
set_ProjX_probability(p1, Cond_prob_normal);
+#endif
}
/* p0 is exception */
}
}
-int is_fragile_Proj(ir_node *n) {
+int is_fragile_Proj(ir_node *n)
+{
return is_Proj(n) && (get_ProjX_probability(n) == Cond_prob_exception_taken);
}
static double exception_prob = 0.001;
-static INLINE int is_loop_head(ir_node *cond) {
- return false;
+static inline int is_loop_head(ir_node *cond)
+{
+ (void) cond;
+ return 0;
}
/** Weight a single region in edge.
*
* Given all outs of the predecessor region, we can compute the weight of
* this single edge. */
-static INLINE double get_weighted_region_exec_freq(void *reg, int pos) {
+static inline double get_weighted_region_exec_freq(void *reg, int pos)
+{
void *pred_reg = get_region_in(reg, pos);
double res, full_freq = get_region_exec_freq (pred_reg);
int n_outs = get_region_n_outs (pred_reg);
ir_node *cfop;
if (is_ir_node(reg)) {
cfop = get_Block_cfgpred((ir_node *)reg, pos);
- if (is_Proj(cfop) && (get_irn_op(get_Proj_pred(cfop)) != op_Cond))
+ if (is_Proj(cfop) && !is_Cond(get_Proj_pred(cfop)))
cfop = skip_Proj(cfop);
} else {
assert(is_ir_loop(reg));
- cfop = get_loop_cfop(reg, pos);
+ cfop = (ir_node*)get_loop_cfop(reg, pos);
}
if (is_fragile_op(cfop) || is_fragile_Proj(cfop)) {
return res;
}
-static INLINE void compute_region_freqency(void *reg, double head_weight) {
+static inline void compute_region_freqency(void *reg, double head_weight)
+{
int i, n_ins = get_region_n_ins(reg);
double my_freq = 0;
- //printf("head weight %lf: ", head_weight); DDMR(reg);
-
for (i = 0; i < n_ins; ++i) {
void *pred_reg = get_region_in(reg, i);
if (pred_reg) {
set_region_exec_freq(reg, my_freq);
}
-static void check_proper_head(ir_loop *l, void *reg) {
+static void check_proper_head(ir_loop *l, void *reg)
+{
int i, n_ins = get_region_n_ins(reg);
+ (void) l;
for (i = 0; i < n_ins; ++i) {
assert(!get_region_in(reg, i));
}
}
/* Compute the ex freq for current_ir_graph */
-static void compute_frequency(int default_loop_weight) {
+static void compute_frequency(int default_loop_weight)
+{
ir_loop *outermost_l = get_irg_loop(current_ir_graph);
pdeq *block_worklist = new_pdeq1(outermost_l);
while (!pdeq_empty(block_worklist)) {
ir_loop *l = (ir_loop *)pdeq_getl(block_worklist);
- int i, n_elems = get_loop_n_elements(l);
+ size_t i, n_elems = get_loop_n_elements(l);
/* The header is initialized with the frequency of the full loop times the iteration weight. */
check_proper_head(l, get_loop_element(l, 0).son);
* irg: The graph to be analyzed.
* default_loop_weight: The number of executions of a loop.
*/
-void compute_execution_frequency(ir_graph *irg, int default_loop_weight, double exception_probability) {
+void compute_execution_frequency(ir_graph *irg, int default_loop_weight, double exception_probability)
+{
ir_graph *rem = current_ir_graph;
current_ir_graph = irg;
exception_prob = exception_probability;
}
-void compute_execution_frequencies(int default_loop_weight, double exception_probability) {
- int i, n_irgs = get_irp_n_irgs();
+void compute_execution_frequencies(int default_loop_weight, double exception_probability)
+{
+ size_t i, n_irgs = get_irp_n_irgs();
free_intervals();
for (i = 0; i < n_irgs; ++i) {
compute_execution_frequency(get_irp_irg(i), default_loop_weight, exception_probability);
}
/** free occupied memory, reset */
-void free_execution_frequency(void) {
- int i, n_irgs = get_irp_n_irgs();
+void free_execution_frequency(void)
+{
+ size_t i, n_irgs = get_irp_n_irgs();
free_intervals();
del_set(exec_freq_set);
set_irp_exec_freq_state(exec_freq_none);
}
-exec_freq_state get_irg_exec_freq_state(ir_graph *irg) {
+exec_freq_state get_irg_exec_freq_state(ir_graph *irg)
+{
return irg->execfreq_state;
}
-void set_irg_exec_freq_state(ir_graph *irg, exec_freq_state s) {
+void set_irg_exec_freq_state(ir_graph *irg, exec_freq_state s)
+{
if ((get_irp_exec_freq_state() == exec_freq_consistent && s != exec_freq_consistent) ||
(get_irp_exec_freq_state() == exec_freq_none && s != exec_freq_none))
irp->execfreq_state = exec_freq_inconsistent;
}
/* Sets irg and irp exec freq state to inconsistent if it is set to consistent. */
-void set_irg_exec_freq_state_inconsistent(ir_graph *irg) {
+void set_irg_exec_freq_state_inconsistent(ir_graph *irg)
+{
if (get_irg_exec_freq_state(irg) == exec_freq_consistent)
set_irg_exec_freq_state(irg, exec_freq_inconsistent);
}
-void set_irp_exec_freq_state(exec_freq_state s) {
+void set_irp_exec_freq_state(exec_freq_state s)
+{
irp->execfreq_state = s;
}
-exec_freq_state get_irp_exec_freq_state(void) {
+exec_freq_state get_irp_exec_freq_state(void)
+{
return irp->execfreq_state;
}
/* Sets irp and all irg exec freq states to inconsistent if it is set to consistent. */
-void set_irp_exec_freq_state_inconsistent(void) {
- if (get_irp_exec_freq_state() != exec_freq_none) {
- int i, n_irgs = get_irp_n_irgs();
- set_irp_exec_freq_state(exec_freq_inconsistent);
- for (i = 0; i < n_irgs; ++i) {
- ir_graph *irg = get_irp_irg(i);
- if (get_irg_exec_freq_state(irg) != exec_freq_none)
- irg->execfreq_state = exec_freq_inconsistent;
- }
- }
+void set_irp_exec_freq_state_inconsistent(void)
+{
+ if (get_irp_exec_freq_state() != exec_freq_none) {
+ size_t i, n_irgs = get_irp_n_irgs();
+ set_irp_exec_freq_state(exec_freq_inconsistent);
+ for (i = 0; i < n_irgs; ++i) {
+ ir_graph *irg = get_irp_irg(i);
+ if (get_irg_exec_freq_state(irg) != exec_freq_none)
+ irg->execfreq_state = exec_freq_inconsistent;
+ }
+ }
}