/*
- * Project: libFIRM
- * File name: ir/ir/stat_dmp.c
- * Purpose: Statistics for Firm.
- * Author: Michael Beck
- * Created:
- * 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 Statistics for Firm. Dumping.
+ * @author Michael Beck
+ * @version $Id$
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#include "stat_dmp.h"
+#include "irtools.h"
#include "irhooks.h"
/**
{ FS_OPT_ADD_SUB, "algebraic simplification: (a + x) - x = (a - x) + x = a" },
{ FS_OPT_ADD_MUL_A_X_A, "algebraic simplification: a * x + a = a * (x + 1)" },
{ FS_OPT_SUB_0_A, "algebraic simplification: 0 - a = -a" },
+ { FS_OPT_MINUS_SUB, "algebraic simplification: -(a - b) = b - a" },
+ { FS_OPT_SUB_MINUS, "algebraic simplification: a - (-b) = a + b" },
{ FS_OPT_SUB_MUL_A_X_A, "algebraic simplification: a * x - a = a * (x - 1)" },
+ { FS_OPT_SUB_SUB_X_Y_Z, "algebraic simplification: (x - y) - z = x - (y + z)" },
+ { FS_OPT_SUB_C_NOT_X, "algebraic simplification: c - ~a = a + (c+1)" },
+ { FS_OPT_SUB_TO_ADD, "algebraic simplification: (-a) - b = -(a + b), a - (b - c) = a + (c - b), a - (b * C) -> a + (b * -C)" },
+ { FS_OPT_MUL_MINUS, "algebraic simplification: (-a) * (b - c) -> a * (c - b)" },
{ FS_OPT_MUL_MINUS_1, "algebraic simplification: a * -1 = -a" },
+ { FS_OPT_MINUS_MUL_C, "algebraic simplification: (-a) * C = a * (-C)" },
+ { FS_OPT_MUL_MINUS_MINUS,"algebraic simplification: (-a) * (-b) = a * b" },
{ FS_OPT_OR, "algebraic simplification: a | a = a | 0 = 0 | a = a" },
- { FS_OPT_AND, "algebraic simplification: a & 0b1...1 = 0b1...1 & a = a & a = a" },
+ { FS_OPT_AND, "algebraic simplification: a & 0b1...1 = 0b1...1 & a = a & a = (a|X) & a = a" },
+ { FS_OPT_TO_EOR, "algebraic simplification: (a|b) & ~(a&b) = a^b" },
{ FS_OPT_EOR_A_A, "algebraic simplification: a ^ a = 0" },
{ FS_OPT_EOR_TO_NOT_BOOL,"algebraic simplification: bool ^ 1 = !bool" },
- { FS_OPT_EOR_TO_NOT, "algebraic simplification: x ^ 0b1..1 = ~x" },
+ { FS_OPT_EOR_TO_NOT, "algebraic simplification: x ^ 0b1..1 = ~x, (a ^ b) & b -> ~a & b" },
{ FS_OPT_NOT_CMP, "algebraic simplification: !(a cmp b) = a !cmp b" },
{ FS_OPT_OR_SHFT_TO_ROT, "algebraic simplification: (x << c) | (x >> (bits - c)) == Rot(x, c)" },
{ FS_OPT_REASSOC_SHIFT, "algebraic simplification: (x SHF c1) SHF c2 = x SHF (c1+c2)" },
+ { FS_OPT_SHIFT_AND, "algebraic simplification: (a SHF c) AND (b SHF c) = (a AND b) SHF c" },
+ { FS_OPT_SHIFT_OR, "algebraic simplification: (a SHF c) OR (b SHF c) = (a OR b) SHF c" },
+ { FS_OPT_SHIFT_EOR, "algebraic simplification: (a SHF c) XOR (b SHF c) = (a XOR b) SHF c" },
{ FS_OPT_CONV, "algebraic simplification: Conv could be removed" },
{ FS_OPT_CAST, "algebraic simplification: a Cast could be removed" },
{ FS_OPT_MIN_MAX_EQ, "algebraic simplification: Min(a,a) = Max(a,a) = a" },
{ FS_OPT_MUX_TO_MAX, "algebraic simplification: Mux(a > b, a, b) = Max(a,b)" },
{ FS_OPT_MUX_TO_ABS, "algebraic simplification: Mux(a > b, a, b) = Abs(a,b)" },
{ FS_OPT_MUX_TO_SHR, "algebraic simplification: Mux(a > b, a, b) = a >> b" },
+ { FS_OPT_IDEM_UNARY, "algebraic simplification: Idempotent unary operation" },
+ { FS_OPT_MINUS_NOT, "algebraic simplification: -(~x) = x + 1" },
+ { FS_OPT_NOT_MINUS_1, "algebraic simplification: ~(x - 1) = -x" },
+ { FS_OPT_NOT_PLUS_1, "algebraic simplification: ~x + 1 = -x" },
+ { FS_OPT_ADD_X_NOT_X, "algebraic simplification: ~x + x = -1" },
+ { FS_OPT_FP_INV_MUL, "algebraic simplification: x / y = x * (1.0/y)" },
+ { FS_OPT_ABS_MINUS_X, "algebraic simplification: Abs(-x) = Abs(x)" },
+ { FS_OPT_CONST_PHI, "constant evaluation on Phi node" },
+ { FS_OPT_PREDICATE, "predicate optimization" },
+ { FS_OPT_DEMORGAN, "optimization using DeMorgan's law" },
+ { FS_OPT_CMP_OP_OP, "CMP optimization: Cmp(OP(x), OP(y)) = Cmp(x, y)" },
+ { FS_OPT_CMP_OP_C, "CMP optimization: Cmp(OP(x), c1) = Cmp(x, c2)" },
+ { FS_OPT_CMP_CONV_CONV, "CMP optimization: Cmp(Conv(x), Conv(y)) = Cmp(x, y)" },
+ { FS_OPT_CMP_CONV, "CMP optimization: Cmp(Conv(x), Conv(y)) = Cmp(Conv(x), y)" },
+ { FS_OPT_CMP_TO_BOOL, "CMP optimization: Cmp(x, y) = BoolOP(x, y)" },
+ { FS_OPT_CMP_CNST_MAGN, "CMP optimization: reduced magnitude of a const" },
+ { FS_OPT_CMP_SHF_TO_AND, "CMP optimization: transformed shift into And" },
+ { FS_OPT_CMP_MOD_TO_AND, "CMP optimization: transformed Mod into And" },
+ { FS_OPT_RTS_ABS, "RTS optimization: call to abs() replaced" },
+ { FS_OPT_RTS_ALLOCA, "RTS optimization: call to alloca() replaced" },
+ { FS_OPT_RTS_SQRT, "RTS optimization: call to sqrt() replaced" },
+ { FS_OPT_RTS_CBRT, "RTS optimization: call to cbrt() replaced" },
+ { FS_OPT_RTS_POW, "RTS optimization: call to pow() replaced" },
+ { FS_OPT_RTS_EXP, "RTS optimization: call to exp() replaced" },
+ { FS_OPT_RTS_LOG, "RTS optimization: call to log() replaced" },
+ { FS_OPT_RTS_SIN, "RTS optimization: call to sin() replaced" },
+ { FS_OPT_RTS_COS, "RTS optimization: call to cos() replaced" },
+ { FS_OPT_RTS_TAN, "RTS optimization: call to tan() replaced" },
+ { FS_OPT_RTS_ASIN, "RTS optimization: call to asin() replaced" },
+ { FS_OPT_RTS_ACOS, "RTS optimization: call to atan() replaced" },
+ { FS_OPT_RTS_ATAN, "RTS optimization: call to acos() replaced" },
+ { FS_OPT_RTS_SINH, "RTS optimization: call to sinh() replaced" },
+ { FS_OPT_RTS_COSH, "RTS optimization: call to cosh() replaced" },
+ { FS_OPT_RTS_TANH, "RTS optimization: call to tanh() replaced" },
+ { FS_OPT_RTS_STRCMP, "RTS optimization: call to strcmp() replaced" },
+ { FS_OPT_RTS_STRNCMP, "RTS optimization: call to strncmp() replaced" },
+ { FS_OPT_RTS_MEMCPY, "RTS optimization: call to memcpy() replaced" },
+ { FS_OPT_RTS_MEMSET, "RTS optimization: call to memset() replaced" },
+ { FS_OPT_RTS_STRLEN, "RTS optimization: call to strlen() replaced" },
{ FS_BE_IA32_LEA, "ia32 Backend transformation: Lea was created" },
{ FS_BE_IA32_LOAD_LEA, "ia32 Backend transformation: Load merged with a Lea" },
{ FS_BE_IA32_STORE_LEA, "ia32 Backend transformation: Store merged with a Lea" },
cnt_add(&f_alive, &entry->cnt_alive);
cnt_add(&f_new_node, &entry->new_node);
cnt_add(&f_Id, &entry->into_Id);
- }
+ } /* foreach_pset */
fprintf(dmp->f, "-------------------------------------------\n");
fprintf(dmp->f, "%-16s %8u %8u %8u\n", "Sum",
cnt_to_uint(&f_alive),
cnt_to_uint(&f_new_node),
cnt_to_uint(&f_Id)
);
-}
+} /* simple_dump_opcode_hash */
+
+/**
+ * Return the name of an optimization.
+ */
+static const char *get_opt_name(int index) {
+ assert(index < (int) ARR_SIZE(opt_names) && "index out of range");
+ assert((int) opt_names[index].kind == index && "opt_names broken");
+ return opt_names[index].name;
+} /* get_opt_name */
/**
* dumps an optimization hash into human readable form
*/
static void simple_dump_opt_hash(dumper_t *dmp, pset *set, int index)
{
- assert(index < ARR_SIZE(opt_names) && "index out of range");
- assert(opt_names[index].kind == index && "opt_names broken");
-
if (pset_count(set) > 0) {
opt_entry_t *entry;
+ const char *name = get_opt_name(index);
- fprintf(dmp->f, "\n%s:\n", opt_names[index].name);
+ fprintf(dmp->f, "\n%s:\n", name);
fprintf(dmp->f, "%-16s %-8s\n", "Opcode", "deref");
foreach_pset(set, entry) {
fprintf(dmp->f, "%-16s %8u\n",
get_id_str(entry->op->name), cnt_to_uint(&entry->count));
- }
- }
-}
+ } /* foreach_pset */
+ } /* if */
+} /* simple_dump_opt_hash */
/**
* dumps the register pressure for each block and for each register class
foreach_pset(b_entry->reg_pressure, rp_entry)
fprintf(dmp->f, "%15d", rp_entry->pressure);
fprintf(dmp->f, "\n");
- }
-}
+ } /* for */
+} /* simple_dump_be_block_reg_pressure */
/** prints a distribution entry */
-static void simple_dump_distrib_entry(const distrib_entry_t *entry, void *env)
-{
- FILE *dmp_f = env;
- fprintf(dmp_f, "%12d", cnt_to_uint(&entry->cnt));
-}
+static void simple_dump_distrib_entry(const distrib_entry_t *entry, void *env) {
+ dumper_t *dmp = env;
+ fprintf(dmp->f, "%12d", cnt_to_uint(&entry->cnt));
+} /* simple_dump_distrib_entry */
/**
* dumps the distribution of the amount of ready nodes for each block
stat_insert_int_distrib_tbl(b_entry->sched_ready, i);
fprintf(dmp->f, "BLK %6ld", b_entry->block_nr);
- stat_iterate_distrib_tbl(b_entry->sched_ready, simple_dump_distrib_entry, dmp->f);
+ stat_iterate_distrib_tbl(b_entry->sched_ready, simple_dump_distrib_entry, dmp);
fprintf(dmp->f, "%12.2lf", stat_calc_avg_distrib_tbl(b_entry->sched_ready));
fprintf(dmp->f, "\n");
- }
- }
-}
+ } /* foreach_pset */
+ } /* if */
+} /* simple_dump_be_block_sched_ready */
/**
* Adds the counter for given entry to another distribution table.
static void add_distrib_entry(const distrib_entry_t *entry, void *env) {
distrib_tbl_t *sum_tbl = env;
- stat_add_int_distrib_tbl(sum_tbl, (int)(entry->object), &entry->cnt);
-}
+ stat_add_int_distrib_tbl(sum_tbl, PTR_TO_INT(entry->object), &entry->cnt);
+} /* add_distrib_entry */
/**
* dumps permutation statistics for one and block and one class
/* sum up distribution table for cycles */
stat_iterate_distrib_tbl(ps_ent->cycles, add_distrib_entry, sum_cycles);
- }
+ } /* foreach_pset */
/* print chain distribution for all perms of this class in this block */
fprintf(dmp->f, "chain distribution:\n");
snprintf(buf, sizeof(buf), "length %d", i);
fprintf(dmp->f, "%12s", buf);
stat_insert_int_distrib_tbl(sum_chains, i);
- }
+ } /* for */
fprintf(dmp->f, "\n");
- stat_iterate_distrib_tbl(sum_chains, simple_dump_distrib_entry, dmp->f);
+ stat_iterate_distrib_tbl(sum_chains, simple_dump_distrib_entry, dmp);
fprintf(dmp->f, "\n");
/* print cycle distribution for all perms of this class in this block */
snprintf(buf, sizeof(buf), "length %d", i);
fprintf(dmp->f, "%12s", buf);
stat_insert_int_distrib_tbl(sum_cycles, i);
- }
+ } /* for */
fprintf(dmp->f, "\n");
- stat_iterate_distrib_tbl(sum_cycles, simple_dump_distrib_entry, dmp->f);
+ stat_iterate_distrib_tbl(sum_cycles, simple_dump_distrib_entry, dmp);
fprintf(dmp->f, "\n");
/* delete temporary sum distribution tables */
stat_delete_distrib_tbl(sum_chains);
stat_delete_distrib_tbl(sum_cycles);
-}
+} /* simple_dump_be_block_permstat_class */
/**
* dumps statistics about perms
fprintf(dmp->f, "BLOCK %ld:\n", b_entry->block_nr);
- if (b_entry->perm_class_stat)
+ if (b_entry->perm_class_stat) {
foreach_pset(b_entry->perm_class_stat, pc_ent) {
fprintf(dmp->f, "register class %s:\n", pc_ent->class_name);
simple_dump_be_block_permstat_class(dmp, pc_ent);
- }
- }
+ } /* foreach_pset */
+ } /* if */
+ } /* foreach_pset */
fprintf(dmp->f, "PERMUTATION STATISTICS END\n");
- }
-}
+ } /* if */
+} /* simple_dump_be_block_permstat */
/**
* dumps the number of real_function_call optimization
if (! cnt_eq(cnt, 0)) {
fprintf(dmp->f, "\nReal Function Calls optimized:\n");
fprintf(dmp->f, "%-16s %8u\n", "Call", cnt_to_uint(cnt));
- }
-}
+ } /* if */
+} /* simple_dump_real_func_calls */
/**
* dumps the number of tail_recursion optimization
if (num_tail_recursion > 0) {
fprintf(dmp->f, "\nTail recursion optimized:\n");
fprintf(dmp->f, "%-16s %8u\n", "Call", num_tail_recursion);
- }
-}
+ } /* if */
+} /* simple_dump_tail_recursion */
/**
* dumps the edges count
return;
fprintf(dmp->f, "%-16s %8d\n", "Edges", cnt_to_uint(cnt));
-}
+} /* simple_dump_edges */
/**
* dumps the IRG
fprintf(dmp->f, "\nEntity %s, Irg %p", get_entity_ld_name(entry->ent), (void *)entry->irg);
else
fprintf(dmp->f, "\nIrg %p", (void *)entry->irg);
- }
+ } /* if */
fprintf(dmp->f, " %swalked %u over blocks %u:\n"
" was inlined : %u\n"
" calls : %u\n"
" indirect calls : %u\n",
entry->is_deleted ? "DELETED " : "",
- cnt_to_uint(&entry->cnt_walked), cnt_to_uint(&entry->cnt_walked_blocks),
- cnt_to_uint(&entry->cnt_was_inlined),
- cnt_to_uint(&entry->cnt_got_inlined),
- cnt_to_uint(&entry->cnt_strength_red),
+ cnt_to_uint(&entry->cnt[gcnt_acc_walked]), cnt_to_uint(&entry->cnt[gcnt_acc_walked_blocks]),
+ cnt_to_uint(&entry->cnt[gcnt_acc_was_inlined]),
+ cnt_to_uint(&entry->cnt[gcnt_acc_got_inlined]),
+ cnt_to_uint(&entry->cnt[gcnt_acc_strength_red]),
entry->is_leaf ? "YES" : "NO",
entry->is_leaf_call == LCS_NON_LEAF_CALL ? "NO" : (entry->is_leaf_call == LCS_LEAF_CALL ? "Yes" : "Maybe"),
entry->is_recursive ? "YES" : "NO",
entry->is_chain_call ? "YES" : "NO",
- cnt_to_uint(&entry->cnt_all_calls),
- cnt_to_uint(&entry->cnt_indirect_calls)
+ cnt_to_uint(&entry->cnt[gcnt_all_calls]),
+ cnt_to_uint(&entry->cnt[gcnt_indirect_calls])
);
- for (i = 0; i < sizeof(entry->cnt_if_conv)/sizeof(entry->cnt_if_conv[0]); ++i) {
- fprintf(dmp->f, " %s : %u\n", if_conv_names[i], cnt_to_uint(&entry->cnt_if_conv[i]));
- }
- }
- else {
+ for (i = 0; i < IF_RESULT_LAST; ++i) {
+ fprintf(dmp->f, " %s : %u\n", if_conv_names[i], cnt_to_uint(&entry->cnt[gcnt_if_conv + i]));
+ } /* for */
+ } else {
fprintf(dmp->f, "\nGlobals counts:\n");
fprintf(dmp->f, "--------------\n");
dump_opts = 0;
- }
+ } /* if */
+
+ /* address ops */
+ fprintf(dmp->f,
+ " pure address calc ops : %u\n"
+ " all address calc ops : %u\n",
+ cnt_to_uint(&entry->cnt[gcnt_pure_adr_ops]),
+ cnt_to_uint(&entry->cnt[gcnt_all_adr_ops])
+ );
+
+ /* Load/Store address classification */
+ fprintf(dmp->f,
+ " global Ld/St address : %u\n"
+ " local Ld/St address : %u\n"
+ " this Ld/St address : %u\n"
+ " param Ld/St address : %u\n"
+ " other Ld/St address : %u\n",
+ cnt_to_uint(&entry->cnt[gcnt_global_adr]),
+ cnt_to_uint(&entry->cnt[gcnt_local_adr]),
+ cnt_to_uint(&entry->cnt[gcnt_this_adr]),
+ cnt_to_uint(&entry->cnt[gcnt_param_adr]),
+ cnt_to_uint(&entry->cnt[gcnt_other_adr])
+ );
simple_dump_opcode_hash(dmp, entry->opcode_hash);
- simple_dump_edges(dmp, &entry->cnt_edges);
+ simple_dump_edges(dmp, &entry->cnt[gcnt_edges]);
/* effects of optimizations */
if (dump_opts) {
- int i;
+ size_t i;
- simple_dump_real_func_calls(dmp, &entry->cnt_real_func_call);
+ simple_dump_real_func_calls(dmp, &entry->cnt[gcnt_acc_real_func_call]);
simple_dump_tail_recursion(dmp, entry->num_tail_recursion);
for (i = 0; i < sizeof(entry->opt_hash)/sizeof(entry->opt_hash[0]); ++i) {
simple_dump_opt_hash(dmp, entry->opt_hash[i], i);
- }
+ } /* for */
/* dump block info */
fprintf(dmp->f, "\n%12s %12s %12s %12s %12s %12s %12s\n", "Block Nr", "Nodes", "intern E", "incoming E", "outgoing E", "Phi", "quot");
foreach_pset(entry->block_hash, b_entry) {
fprintf(dmp->f, "BLK %6ld %12u %12u %12u %12u %12u %4.8f\n",
b_entry->block_nr,
- cnt_to_uint(&b_entry->cnt_nodes),
- cnt_to_uint(&b_entry->cnt_edges),
- cnt_to_uint(&b_entry->cnt_in_edges),
- cnt_to_uint(&b_entry->cnt_out_edges),
- cnt_to_uint(&b_entry->cnt_phi_data),
- cnt_to_dbl(&b_entry->cnt_edges) / cnt_to_dbl(&b_entry->cnt_nodes)
+ cnt_to_uint(&b_entry->cnt[bcnt_nodes]),
+ cnt_to_uint(&b_entry->cnt[bcnt_edges]),
+ cnt_to_uint(&b_entry->cnt[bcnt_in_edges]),
+ cnt_to_uint(&b_entry->cnt[bcnt_out_edges]),
+ cnt_to_uint(&b_entry->cnt[bcnt_phi_data]),
+ cnt_to_dbl(&b_entry->cnt[bcnt_edges]) / cnt_to_dbl(&b_entry->cnt[bcnt_nodes])
);
- }
+ } /* foreach_pset */
/* dump block reg pressure */
simple_dump_be_block_reg_pressure(dmp, entry);
foreach_pset(entry->extbb_hash, eb_entry) {
fprintf(dmp->f, "ExtBB %6ld %12u %12u %12u %12u %12u %4.8f\n",
eb_entry->block_nr,
- cnt_to_uint(&eb_entry->cnt_nodes),
- cnt_to_uint(&eb_entry->cnt_edges),
- cnt_to_uint(&eb_entry->cnt_in_edges),
- cnt_to_uint(&eb_entry->cnt_out_edges),
- cnt_to_uint(&eb_entry->cnt_phi_data),
- cnt_to_dbl(&eb_entry->cnt_edges) / cnt_to_dbl(&eb_entry->cnt_nodes)
+ cnt_to_uint(&eb_entry->cnt[bcnt_nodes]),
+ cnt_to_uint(&eb_entry->cnt[bcnt_edges]),
+ cnt_to_uint(&eb_entry->cnt[bcnt_in_edges]),
+ cnt_to_uint(&eb_entry->cnt[bcnt_out_edges]),
+ cnt_to_uint(&eb_entry->cnt[bcnt_phi_data]),
+ cnt_to_dbl(&eb_entry->cnt[bcnt_edges]) / cnt_to_dbl(&eb_entry->cnt[bcnt_nodes])
);
- }
- }
+ } /* foreach_pset */
+ } /* if */
}
-}
+} /* simple_dump_graph */
/**
- * dumps the IRG
+ * dumps the constant table
*/
static void simple_dump_const_tbl(dumper_t *dmp, const constant_info_t *tbl)
{
- int i;
+ size_t i;
counter_t sum;
if (! dmp->f)
fprintf(dmp->f, "-------------------------------\n");
for (i = 0; i < ARR_SIZE(tbl->int_bits_count); ++i) {
- fprintf(dmp->f, "%5d %12u\n", i + 1, cnt_to_uint(&tbl->int_bits_count[i]));
+ fprintf(dmp->f, "%5u %12u\n", (unsigned) (i + 1), cnt_to_uint(&tbl->int_bits_count[i]));
cnt_add(&sum, &tbl->int_bits_count[i]);
- }
+ } /* for */
fprintf(dmp->f, "-------------------------------\n");
fprintf(dmp->f, "\nFloating point constants classification\n");
for (i = 0; i < ARR_SIZE(tbl->floats); ++i) {
fprintf(dmp->f, "%-10s %12u\n", stat_fc_name(i), cnt_to_uint(&tbl->floats[i]));
cnt_add(&sum, &tbl->floats[i]);
- }
+ } /* for */
fprintf(dmp->f, "--------------------------------------\n");
fprintf(dmp->f, "other %12u\n", cnt_to_uint(&tbl->others));
fprintf(dmp->f, "-------------------------------\n");
fprintf(dmp->f, "sum %12u\n", cnt_to_uint(&sum));
-}
+} /* simple_dump_const_tbl */
+
+/**
+ * Dumps a line of the parameter table
+ */
+static void dump_tbl_line(const distrib_entry_t *entry, void *env) {
+ dumper_t *dmp = env;
+
+ fprintf(dmp->f, "%d : %u\n", PTR_TO_INT(entry->object), cnt_to_uint(&entry->cnt));
+} /* dump_tbl_line */
+
+/**
+ * dumps the parameter distribution table
+ */
+static void simple_dump_param_tbl(dumper_t *dmp, const distrib_tbl_t *tbl, graph_entry_t *global) {
+ fprintf(dmp->f, "\nCall parameter Information:\n");
+ fprintf(dmp->f, "---------------------\n");
+
+ stat_iterate_distrib_tbl(tbl, dump_tbl_line, dmp);
+ fprintf(dmp->f, "-------------------------------\n");
+
+ fprintf(dmp->f, "Number of Calls %12u\n", cnt_to_uint(&global->cnt[gcnt_all_calls]));
+ fprintf(dmp->f, "with const params %12u\n", cnt_to_uint(&global->cnt[gcnt_call_with_cnst_arg]));
+ fprintf(dmp->f, "with all const params %12u\n", cnt_to_uint(&global->cnt[gcnt_call_with_all_cnst_arg]));
+ fprintf(dmp->f, "with local var adr params %12u\n", cnt_to_uint(&global->cnt[gcnt_call_with_local_adr]));
+} /* simple_dump_param_tbl */
+
+/**
+ * dumps the optimization counter table
+ */
+static void simple_dump_opt_cnt(dumper_t *dmp, const counter_t *tbl, unsigned len) {
+ unsigned i;
+
+ fprintf(dmp->f, "\nOptimization counts:\n");
+ fprintf(dmp->f, "---------------------\n");
+
+ for (i = 0; i < len; ++i) {
+ unsigned cnt = cnt_to_uint(&tbl[i]);
+
+ if (cnt > 0) {
+ fprintf(dmp->f, "%8u %s\n", cnt, get_opt_name(i));
+ }
+ }
+} /* simple_dump_opt_cnt */
/**
* initialize the simple dumper
*/
-static void simple_init(dumper_t *dmp, const char *name)
-{
+static void simple_init(dumper_t *dmp, const char *name) {
char fname[2048];
snprintf(fname, sizeof(fname), "%s.txt", name);
dmp->f = fopen(fname, "w");
if (! dmp->f) {
perror(fname);
- }
-}
+ } /* if */
+} /* simple_init */
/**
* finishes the simple dumper
*/
-static void simple_finish(dumper_t *dmp)
-{
+static void simple_finish(dumper_t *dmp) {
if (dmp->f)
fclose(dmp->f);
dmp->f = NULL;
-}
+} /* simple_finish */
/**
* the simple human readable dumper
const dumper_t simple_dumper = {
simple_dump_graph,
simple_dump_const_tbl,
+ simple_dump_param_tbl,
+ simple_dump_opt_cnt,
simple_init,
simple_finish,
NULL,
NULL,
NULL,
+ NULL,
+ FOURCC('S', 'M', 'P', 'L'),
};
/* ---------------------------------------------------------------------- */
if (entry->op == op_Phi) {
/* normal Phi */
cnt_add(&cnt[1], &entry->cnt_alive);
- }
- else if (entry->op == dmp->status->op_PhiM) {
+ } else if (entry->op == dmp->status->op_PhiM) {
/* memory Phi */
cnt_add(&cnt[2], &entry->cnt_alive);
- }
- else if (entry->op == op_Proj) {
+ } else if (entry->op == op_Proj) {
/* Proj */
cnt_add(&cnt[3], &entry->cnt_alive);
- }
- else {
+ } else {
/* all other nodes */
cnt_add(&cnt[0], &entry->cnt_alive);
- }
- }
-}
+ } /* if */
+ } /* foreach_pset */
+} /* csv_count_nodes */
/**
* dumps the IRG
if (entry->irg == const_irg) {
name = "<Const code Irg>";
return;
- }
- else {
+ } else {
if (entry->ent)
name = get_entity_name(entry->ent);
else
name = "<UNKNOWN IRG>";
- }
+ } /* if */
csv_count_nodes(dmp, entry, cnt);
cnt_to_uint(&cnt[2]),
cnt_to_uint(&cnt[3])
);
- }
-}
+ } /* if */
+} /* csv_dump_graph */
/**
* dumps the IRG
*/
static void csv_dump_const_tbl(dumper_t *dmp, const constant_info_t *tbl)
{
+ (void) dmp;
+ (void) tbl;
+ /* FIXME: NYI */
+} /* csv_dump_const_tbl */
+
+/**
+ * dumps the parameter distribution table
+ */
+static void csv_dump_param_tbl(dumper_t *dmp, const distrib_tbl_t *tbl, graph_entry_t *global) {
+ (void) dmp;
+ (void) tbl;
+ (void) global;
/* FIXME: NYI */
-}
+} /* csv_dump_param_tbl */
+
+/**
+ * dumps the optimization counter
+ */
+static void csv_dump_opt_cnt(dumper_t *dmp, const counter_t *tbl, unsigned len) {
+ (void) dmp;
+ (void) tbl;
+ (void) len;
+ /* FIXME: NYI */
+} /* csv_dump_opt_cnt */
/**
* initialize the simple dumper
dmp->f = fopen(fname, "a");
if (! dmp->f)
perror(fname);
-}
+} /* csv_init */
/**
* finishes the simple dumper
if (dmp->f)
fclose(dmp->f);
dmp->f = NULL;
-}
+} /* csv_finish */
/**
* the simple human readable dumper
const dumper_t csv_dumper = {
csv_dump_graph,
csv_dump_const_tbl,
+ csv_dump_param_tbl,
+ csv_dump_opt_cnt,
csv_init,
csv_finish,
NULL,
NULL,
NULL,
+ NULL,
+ FOURCC('C', 'S', 'V', '\0')
};