darling-gdb/sim/igen/gen.c
1997-09-08 17:40:24 +00:00

1499 lines
38 KiB
C

/* This file is part of the program psim.
Copyright (C) 1994-1997, Andrew Cagney <cagney@highland.com.au>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#include "misc.h"
#include "lf.h"
#include "table.h"
#include "filter.h"
#include "igen.h"
#include "ld-insn.h"
#include "ld-decode.h"
#include "gen.h"
static insn_uint
sub_val (insn_uint val,
insn_field_entry *field,
int first_pos,
int last_pos)
{
return ((val >> (field->last - last_pos))
& (((insn_uint)1 << (last_pos - first_pos + 1)) - 1));
}
static void
update_depth (lf *file,
gen_entry *entry,
int depth,
void *data)
{
int *max_depth = (int*)data;
if (*max_depth < depth)
*max_depth = depth;
}
int
gen_entry_depth (gen_entry *table)
{
int depth = 0;
gen_entry_traverse_tree (NULL,
table,
1,
NULL, /*start*/
update_depth,
NULL, /*end*/
&depth); /* data */
return depth;
}
static void
print_gen_entry_path (line_ref *line,
gen_entry *table,
error_func *print)
{
if (table->parent == NULL)
{
if (table->top->processor != NULL)
print (line, "%s", table->top->processor);
else
print (line, "");
}
else
{
print_gen_entry_path (line, table->parent, print);
print (NULL, ".%d", table->opcode_nr);
}
}
static void
print_gen_entry_insns (gen_entry *table,
error_func *print,
char *first_message,
char *next_message)
{
insn_list *i;
char *message;
message = first_message;
for (i = table->insns; i != NULL; i = i->next)
{
insn_entry *insn = i->insn;
print_gen_entry_path (insn->line, table, print);
print (NULL, ": %s.%s %s\n",
insn->format_name,
insn->name,
message);
if (next_message != NULL)
message = next_message;
}
}
/* same as strcmp */
static int
insn_word_cmp (insn_word_entry *l, insn_word_entry *r)
{
while (1)
{
int bit_nr;
if (l == NULL && r == NULL)
return 0; /* all previous fields the same */
if (l == NULL)
return -1; /* left shorter than right */
if (r == NULL)
return +1; /* left longer than right */
for (bit_nr = 0;
bit_nr < options.insn_bit_size;
bit_nr++)
{
if (l->bit[bit_nr]->mask < r->bit[bit_nr]->mask)
return -1;
if (l->bit[bit_nr]->mask > r->bit[bit_nr]->mask)
return 1;
if (l->bit[bit_nr]->value < r->bit[bit_nr]->value)
return -1;
if (l->bit[bit_nr]->value > r->bit[bit_nr]->value)
return 1;
}
l = l->next;
r = r->next;
}
}
static int
opcode_bit_cmp (opcode_bits *l,
opcode_bits *r)
{
if (l == NULL && r == NULL)
return 0; /* all previous bits the same */
if (l == NULL)
return -1; /* left shorter than right */
if (r == NULL)
return +1; /* left longer than right */
/* most significant word */
if (l->field->word_nr < r->field->word_nr)
return +1; /* left has more significant word */
if (l->field->word_nr > r->field->word_nr)
return -1; /* right has more significant word */
/* most significant bit? */
if (l->first < r->first)
return +1; /* left as more significant bit */
if (l->first > r->first)
return -1; /* right as more significant bit */
/* nr bits? */
if (l->last < r->last)
return +1; /* left as less bits */
if (l->last > r->last)
return -1; /* right as less bits */
/* value? */
if (l->value < r->value)
return -1;
if (l->value > r->value)
return 1;
return 0;
}
static int
opcode_bits_cmp (opcode_bits *l,
opcode_bits *r)
{
while (1)
{
int cmp;
if (l == NULL && r == NULL)
return 0; /* all previous bits the same */
cmp = opcode_bit_cmp (l, r);
if (cmp != 0)
return cmp;
l = l->next;
r = r->next;
}
}
static opcode_bits *
new_opcode_bits (opcode_bits *old_bits,
int value,
int first,
int last,
insn_field_entry *field,
opcode_field *opcode)
{
opcode_bits *new_bits = ZALLOC (opcode_bits);
new_bits->field = field;
new_bits->value = value;
new_bits->first = first;
new_bits->last = last;
new_bits->opcode = opcode;
if (old_bits != NULL)
{
opcode_bits *new_list;
opcode_bits **last = &new_list;
new_list = new_opcode_bits (old_bits->next,
old_bits->value,
old_bits->first,
old_bits->last,
old_bits->field,
old_bits->opcode);
while (*last != NULL)
{
int cmp = opcode_bit_cmp (new_bits, *last);
if (cmp < 0) /* new < new_list */
{
break;
}
if (cmp == 0)
{
ERROR ("Duplicated insn bits in list");
}
last = &(*last)->next;
}
new_bits->next = *last;
*last = new_bits;
return new_list;
}
else
{
return new_bits;
}
}
typedef enum {
merge_duplicate_insns,
report_duplicate_insns,
} duplicate_insn_actions;
static insn_list *
insn_list_insert (insn_list **cur_insn_ptr,
int *nr_insns,
insn_entry *insn,
opcode_bits *expanded_bits,
opcode_field *opcodes,
int nr_prefetched_words,
duplicate_insn_actions duplicate_action)
{
/* insert it according to the order of the fields & bits */
while ((*cur_insn_ptr) != NULL)
{
int word_cmp = insn_word_cmp (insn->words,
(*cur_insn_ptr)->insn->words);
if (word_cmp < 0)
{
/* found insertion point - new_insn < cur_insn->next */
break;
}
else if (word_cmp == 0)
{
/* words same, try for bit fields */
int bit_cmp = opcode_bits_cmp (expanded_bits,
(*cur_insn_ptr)->expanded_bits);
if (bit_cmp < 0)
{
/* found insertion point - new_insn < cur_insn->next */
break;
}
else if (bit_cmp == 0)
{
switch (duplicate_action)
{
case report_duplicate_insns:
/* two instructions with the same constant field
values across all words and bits */
warning (insn->line,
"Location of second (duplicated?) instruction");
error ((*cur_insn_ptr)->insn->line,
"Two instructions with identical constant fields\n");
case merge_duplicate_insns:
/* Add the opcode path to the instructions list */
if (opcodes != NULL)
{
insn_opcodes **last = &(*cur_insn_ptr)->opcodes;
while (*last != NULL)
{
last = &(*last)->next;
}
(*last) = ZALLOC (insn_opcodes);
(*last)->opcode = opcodes;
}
/* Use the larger nr_prefetched_words */
if ((*cur_insn_ptr)->nr_prefetched_words < nr_prefetched_words)
(*cur_insn_ptr)->nr_prefetched_words = nr_prefetched_words;
return (*cur_insn_ptr);
}
}
}
/* keep looking - new_insn > cur_insn->next */
cur_insn_ptr = &(*cur_insn_ptr)->next;
}
/* create a new list entry and insert it */
{
insn_list *new_insn = ZALLOC (insn_list);
new_insn->insn = insn;
new_insn->expanded_bits = expanded_bits;
new_insn->next = (*cur_insn_ptr);
new_insn->nr_prefetched_words = nr_prefetched_words;
if (opcodes != NULL)
{
new_insn->opcodes = ZALLOC (insn_opcodes);
new_insn->opcodes->opcode = opcodes;
}
(*cur_insn_ptr) = new_insn;
}
*nr_insns += 1;
return (*cur_insn_ptr);
}
extern void
gen_entry_traverse_tree (lf *file,
gen_entry *table,
int depth,
gen_entry_handler *start,
gen_entry_handler *leaf,
gen_entry_handler *end,
void *data)
{
gen_entry *entry;
ASSERT (table != NULL);
ASSERT (table->opcode != NULL);
ASSERT (table->nr_entries > 0);
ASSERT (table->entries != 0);
/* prefix */
if (start != NULL && depth >= 0)
{
start (file, table, depth, data);
}
/* infix leaves */
for (entry = table->entries;
entry != NULL;
entry = entry->sibling)
{
if (entry->entries != NULL && depth != 0)
{
gen_entry_traverse_tree (file, entry, depth + 1,
start, leaf, end, data);
}
else if (depth >= 0)
{
if (leaf != NULL)
{
leaf (file, entry, depth, data);
}
}
}
/* postfix */
if (end != NULL && depth >= 0)
{
end (file, table, depth, data);
}
}
/* create a list element containing a single gen_table entry */
static gen_list *
make_table (insn_table *isa,
decode_table *rules,
char *processor)
{
insn_entry *insn;
gen_list *entry = ZALLOC (gen_list);
entry->table = ZALLOC (gen_entry);
entry->table->top = entry;
entry->processor = processor;
entry->isa = isa;
for (insn = isa->insns; insn != NULL; insn = insn->next)
{
if (processor == NULL
|| insn->processors == NULL
|| filter_is_member (insn->processors, processor))
{
insn_list_insert (&entry->table->insns,
&entry->table->nr_insns,
insn,
NULL, /* expanded_bits - none yet */
NULL, /* opcodes - none yet */
0, /* nr_prefetched_words - none yet */
report_duplicate_insns);
}
}
entry->table->opcode_rule = rules;
return entry;
}
gen_table *
make_gen_tables (insn_table *isa,
decode_table *rules)
{
gen_table *gen = ZALLOC (gen_table);
gen->isa = isa;
gen->rules = rules;
if (options.gen.multi_sim)
{
gen_list **last = &gen->tables;
char *processor;
filter *processors;
if (options.model_filter != NULL)
processors = options.model_filter;
else
processors = isa->model->processors;
for (processor = filter_next (processors, "");
processor != NULL;
processor = filter_next (processors, processor))
{
*last = make_table (isa, rules, processor);
last = &(*last)->next;
}
}
else
{
gen->tables = make_table (isa, rules, NULL);
}
return gen;
}
/****************************************************************/
#if 0
typedef enum {
field_is_not_constant = 0,
field_constant_int = 1,
field_constant_reserved = 2,
field_constant_string = 3
} constant_field_types;
static constant_field_types
insn_field_is_constant (insn_field *field,
decode_table *rule)
{
switch (field->type)
{
case insn_field_int:
/* field is an integer */
return field_constant_int;
case insn_field_reserved:
/* field is `/' and treating that as a constant */
if (rule->with_zero_reserved)
return field_constant_reserved;
else
return field_is_not_constant;
case insn_field_wild:
return field_is_not_constant; /* never constant */
case insn_field_string:
/* field, though variable, is on the list of forced constants */
if (filter_is_member (rule->constant_field_names, field->val_string))
return field_constant_string;
else
return field_is_not_constant;
}
ERROR ("Internal error");
return field_is_not_constant;
}
#endif
/****************************************************************/
/* Is the bit, according to the decode rule, identical across all the
instructions? */
static int
insns_bit_useless (insn_list *insns,
decode_table *rule,
int bit_nr)
{
insn_list *entry;
int value = -1;
int is_useless = 1; /* cleared if something actually found */
for (entry = insns; entry != NULL; entry = entry->next)
{
insn_word_entry *word = entry->insn->word[rule->word_nr];
insn_bit_entry *bit = word->bit[bit_nr];
switch (bit->field->type)
{
case insn_field_wild:
case insn_field_reserved:
/* neither useless or useful - ignore */
break;
case insn_field_int:
switch (rule->search)
{
case decode_find_strings:
/* an integer isn't a string */
return 1;
case decode_find_constants:
case decode_find_mixed:
/* an integer is useful if its value isn't the same
between all instructions? */
if (value < 0)
value = bit->value;
else if (value != bit->value)
is_useless = 0;
break;
}
break;
case insn_field_string:
switch (rule->search)
{
case decode_find_strings:
/* at least one string, keep checking */
is_useless = 0;
break;
case decode_find_constants:
case decode_find_mixed:
/* a string field forced to constant */
if (filter_is_member (rule->constant_field_names,
bit->field->val_string))
is_useless = 0;
else if (rule->search == decode_find_constants)
/* the string field isn't constant */
return 1;
break;
}
}
}
return is_useless;
}
/* go through a gen-table's list of instruction formats looking for a
range of bits that meet the decode table RULEs requirements */
static opcode_field *
gen_entry_find_opcode_field (insn_list *insns,
decode_table *rule,
int string_only)
{
opcode_field curr_opcode;
ASSERT (rule != NULL);
memset (&curr_opcode, 0, sizeof (curr_opcode));
curr_opcode.word_nr = rule->word_nr;
curr_opcode.first = rule->first;
curr_opcode.last = rule->last;
/* Try to reduce the size of first..last in accordance with the
decode rules */
while (curr_opcode.first <= rule->last)
{
if (insns_bit_useless (insns, rule, curr_opcode.first))
curr_opcode.first ++;
else
break;
}
while (curr_opcode.last >= rule->first)
{
if (insns_bit_useless (insns, rule, curr_opcode.last))
curr_opcode.last --;
else
break;
}
#if 0
for (entry = insns; entry != NULL; entry = entry->next)
{
insn_word_entry *fields = entry->insn->word[rule->word_nr];
opcode_field new_opcode;
ASSERT (fields != NULL);
/* find a start point for the opcode field */
new_opcode.first = rule->first;
while (new_opcode.first <= rule->last
&& (!string_only
|| (insn_field_is_constant(fields->bit[new_opcode.first], rule)
!= field_constant_string))
&& (string_only
|| (insn_field_is_constant(fields->bit[new_opcode.first], rule)
== field_is_not_constant)))
{
int new_first = fields->bit[new_opcode.first]->last + 1;
ASSERT (new_first > new_opcode.first);
new_opcode.first = new_first;
}
ASSERT(new_opcode.first > rule->last
|| (string_only
&& insn_field_is_constant(fields->bit[new_opcode.first],
rule) == field_constant_string)
|| (!string_only
&& insn_field_is_constant(fields->bit[new_opcode.first],
rule)));
/* find the end point for the opcode field */
new_opcode.last = rule->last;
while (new_opcode.last >= rule->first
&& (!string_only
|| insn_field_is_constant(fields->bit[new_opcode.last],
rule) != field_constant_string)
&& (string_only
|| !insn_field_is_constant(fields->bit[new_opcode.last],
rule)))
{
int new_last = fields->bit[new_opcode.last]->first - 1;
ASSERT (new_last < new_opcode.last);
new_opcode.last = new_last;
}
ASSERT(new_opcode.last < rule->first
|| (string_only
&& insn_field_is_constant(fields->bit[new_opcode.last],
rule) == field_constant_string)
|| (!string_only
&& insn_field_is_constant(fields->bit[new_opcode.last],
rule)));
/* now see if our current opcode needs expanding to include the
interesting fields within this instruction */
if (new_opcode.first <= rule->last
&& curr_opcode.first > new_opcode.first)
curr_opcode.first = new_opcode.first;
if (new_opcode.last >= rule->first
&& curr_opcode.last < new_opcode.last)
curr_opcode.last = new_opcode.last;
}
#endif
/* did the final opcode field end up being empty? */
if (curr_opcode.first > curr_opcode.last)
{
return NULL;
}
ASSERT (curr_opcode.last >= rule->first);
ASSERT (curr_opcode.first <= rule->last);
ASSERT (curr_opcode.first <= curr_opcode.last);
/* Ensure that, for the non string only case, the opcode includes
the range forced_first .. forced_last */
if (!string_only
&& curr_opcode.first > rule->force_first)
{
curr_opcode.first = rule->force_first;
}
if (!string_only
&& curr_opcode.last < rule->force_last)
{
curr_opcode.last = rule->force_last;
}
/* For the string only case, force just the lower bound (so that the
shift can be eliminated) */
if (string_only
&& rule->force_last == options.insn_bit_size - 1)
{
curr_opcode.last = options.insn_bit_size - 1;
}
/* handle any special cases */
switch (rule->type)
{
case normal_decode_rule:
/* let the above apply */
curr_opcode.nr_opcodes =
(1 << (curr_opcode.last - curr_opcode.first + 1));
break;
case boolean_rule:
curr_opcode.is_boolean = 1;
curr_opcode.boolean_constant = rule->constant;
curr_opcode.nr_opcodes = 2;
break;
}
{
opcode_field *new_field = ZALLOC (opcode_field);
memcpy (new_field, &curr_opcode, sizeof (opcode_field));
return new_field;
}
}
static void
gen_entry_insert_insn (gen_entry *table,
insn_entry *old_insn,
int new_word_nr,
int new_nr_prefetched_words,
int new_opcode_nr,
opcode_bits *new_bits)
{
gen_entry **entry = &table->entries;
/* find the new table for this entry */
while ((*entry) != NULL && (*entry)->opcode_nr < new_opcode_nr)
{
entry = &(*entry)->sibling;
}
if ((*entry) == NULL || (*entry)->opcode_nr != new_opcode_nr)
{
/* insert the missing entry */
gen_entry *new_entry = ZALLOC (gen_entry);
new_entry->sibling = (*entry);
(*entry) = new_entry;
table->nr_entries++;
/* fill it in */
new_entry->top = table->top;
new_entry->opcode_nr = new_opcode_nr;
new_entry->word_nr = new_word_nr;
new_entry->expanded_bits = new_bits;
new_entry->opcode_rule = table->opcode_rule->next;
new_entry->parent = table;
new_entry->nr_prefetched_words = new_nr_prefetched_words;
}
/* ASSERT new_bits == cur_entry bits */
ASSERT ((*entry) != NULL && (*entry)->opcode_nr == new_opcode_nr);
insn_list_insert (&(*entry)->insns,
&(*entry)->nr_insns,
old_insn,
NULL, /* expanded_bits - only in final list */
NULL, /* opcodes - only in final list */
new_nr_prefetched_words, /* for this table */
report_duplicate_insns);
}
static void
gen_entry_expand_opcode (gen_entry *table,
insn_entry *instruction,
int bit_nr,
int opcode_nr,
opcode_bits *bits)
{
if (bit_nr > table->opcode->last)
{
/* Only include the hardwired bit information with an entry IF
that entry (and hence its functions) are being duplicated. */
if (table->opcode_rule->with_duplicates)
{
gen_entry_insert_insn (table, instruction,
table->opcode->word_nr,
table->nr_prefetched_words,
opcode_nr, bits);
}
else
{
gen_entry_insert_insn (table, instruction,
table->opcode->word_nr,
table->nr_prefetched_words,
opcode_nr, NULL);
}
}
else
{
insn_word_entry *word = instruction->word[table->opcode->word_nr];
insn_field_entry *field = word->bit[bit_nr]->field;
int last_pos = ((field->last < table->opcode->last)
? field->last : table->opcode->last);
int first_pos = ((field->first > table->opcode->first)
? field->first : table->opcode->first);
int width = last_pos - first_pos + 1;
switch (field->type)
{
case insn_field_int:
{
int val;
val = sub_val (field->val_int, field, first_pos, last_pos);
gen_entry_expand_opcode (table, instruction,
last_pos + 1,
((opcode_nr << width) | val),
bits);
break;
}
default:
{
if (field->type == insn_field_reserved)
gen_entry_expand_opcode (table, instruction,
last_pos + 1,
((opcode_nr << width)),
bits);
else
{
int val;
int last_val = (table->opcode->is_boolean
? 2 : (1 << width));
for (val = 0; val < last_val; val++)
{
/* check to see if the value has been limited */
insn_field_exclusion *exclusion;
for (exclusion = field->exclusions;
exclusion != NULL;
exclusion = exclusion->next)
{
int value = sub_val (exclusion->value, field,
first_pos, last_pos);
if (value == val)
break;
}
if (exclusion == NULL)
{
/* Only add additional hardwired bit
information if the entry is not going to
later be combined */
if (table->opcode_rule->with_combine)
{
gen_entry_expand_opcode (table, instruction,
last_pos + 1,
((opcode_nr << width) | val),
bits);
}
else
{
opcode_bits *new_bits = new_opcode_bits (bits, val,
first_pos, last_pos,
field,
table->opcode);
gen_entry_expand_opcode (table, instruction,
last_pos + 1,
((opcode_nr << width) | val),
new_bits);
}
}
}
}
}
}
}
}
static void
gen_entry_insert_expanding (gen_entry *table,
insn_entry *instruction)
{
gen_entry_expand_opcode (table,
instruction,
table->opcode->first,
0,
table->expanded_bits);
}
static int
insns_match_format_names (insn_list *insns,
filter *format_names)
{
if (format_names != NULL)
{
insn_list *i;
for (i = insns; i != NULL; i = i->next)
{
if ( i->insn->format_name != NULL
&& !filter_is_member (format_names, i->insn->format_name))
return 0;
}
}
return 1;
}
static int
table_matches_path (gen_entry *table,
decode_path_list *paths)
{
if (paths == NULL)
return 1;
while (paths != NULL)
{
gen_entry *entry = table;
decode_path *path = paths->path;
while (1)
{
if (entry == NULL && path == NULL)
return 1;
if (entry == NULL || path == NULL)
break;
if (entry->opcode_nr != path->opcode_nr)
break;
entry = entry->parent;
path = path->parent;
}
paths = paths->next;
}
return 0;
}
static int
insns_match_conditions (insn_list *insns,
decode_cond *conditions)
{
if (conditions != NULL)
{
insn_list *i;
for (i = insns; i != NULL; i = i->next)
{
decode_cond *cond;
for (cond = conditions; cond != NULL; cond = cond->next)
{
int bit_nr;
if (i->insn->nr_words <= cond->word_nr)
return 0;
for (bit_nr = 0; bit_nr < options.insn_bit_size; bit_nr++)
{
if (!cond->mask[bit_nr])
continue;
if (!i->insn->word[cond->word_nr]->bit[bit_nr]->mask)
return 0;
if ((i->insn->word[cond->word_nr]->bit[bit_nr]->value
== cond->value[bit_nr])
== !cond->is_equal)
return 0;
}
}
}
}
return 1;
}
static int
insns_match_nr_words (insn_list *insns,
int nr_words)
{
insn_list *i;
for (i = insns; i != NULL; i = i->next)
{
if (i->insn->nr_words < nr_words)
return 0;
}
return 1;
}
static int
insn_list_cmp (insn_list *l,
insn_list *r)
{
while (1)
{
insn_entry *insn;
if (l == NULL && r == NULL)
return 0;
if (l == NULL)
return -1;
if (r == NULL)
return 1;
if (l->insn != r->insn)
return -1; /* somewhat arbitrary at present */
/* skip this insn */
insn = l->insn;
while (l != NULL && l->insn == insn)
l = l->next;
while (r != NULL && r->insn == insn)
r = r->next;
}
}
static void
gen_entry_expand_insns (gen_entry *table)
{
decode_table *opcode_rule;
ASSERT(table->nr_insns >= 1);
/* determine a valid opcode */
for (opcode_rule = table->opcode_rule;
opcode_rule != NULL;
opcode_rule = opcode_rule->next)
{
char *discard_reason;
if (table->top->processor != NULL
&& opcode_rule->model_names != NULL
&& !filter_is_member (opcode_rule->model_names,
table->top->processor))
{
/* the rule isn't applicable to this processor */
discard_reason = "wrong model";
}
else if (table->nr_insns == 1 && opcode_rule->conditions == NULL)
{
/* for safety, require a pre-codition when attempting to
apply a rule to a single instruction */
discard_reason = "need pre-condition when nr-insn == 1";
}
else if (table->nr_insns == 1 && !opcode_rule->with_duplicates)
{
/* Little point in expanding a single instruction when we're
not duplicating the semantic functions that this table
calls */
discard_reason = "need duplication with nr-insns == 1";
}
else if (!insns_match_format_names (table->insns, opcode_rule->format_names))
{
discard_reason = "wrong format name";
}
else if (!insns_match_nr_words (table->insns, opcode_rule->word_nr + 1))
{
discard_reason = "wrong nr words";
}
else if (!table_matches_path (table, opcode_rule->paths))
{
discard_reason = "path failed";
}
else if (!insns_match_conditions (table->insns, opcode_rule->conditions))
{
discard_reason = "condition failed";
}
else
{
discard_reason = "no opcode field";
table->opcode =
gen_entry_find_opcode_field (table->insns,
opcode_rule,
table->nr_insns == 1/*string-only*/
);
if (table->opcode != NULL)
{
table->opcode_rule = opcode_rule;
break;
}
}
if (options.trace.rule_rejection)
{
print_gen_entry_path (opcode_rule->line, table, notify);
notify (NULL, ": rule discarded - %s\n", discard_reason);
}
}
/* did we find anything */
if (opcode_rule == NULL)
{
/* the decode table failed, this set of instructions haven't
been uniquely identified */
if (table->nr_insns > 1)
{
print_gen_entry_insns (table, warning,
"was not uniquely decoded",
"decodes to the same entry");
error (NULL, "");
}
return;
}
/* Determine the number of words that must have been prefetched for
this table to function */
if (table->parent == NULL)
table->nr_prefetched_words = table->opcode_rule->word_nr + 1;
else if (table->opcode_rule->word_nr + 1 > table->parent->nr_prefetched_words)
table->nr_prefetched_words = table->opcode_rule->word_nr + 1;
else
table->nr_prefetched_words = table->parent->nr_prefetched_words;
/* back link what we found to its parent */
if (table->parent != NULL)
{
ASSERT(table->parent->opcode != NULL);
table->opcode->parent = table->parent->opcode;
}
/* expand the raw instructions according to the opcode */
{
insn_list *entry;
for (entry = table->insns; entry != NULL; entry = entry->next)
{
gen_entry_insert_expanding (table, entry->insn);
}
}
if (options.trace.rule_selection)
{
print_gen_entry_path (table->opcode_rule->line, table, notify);
notify (NULL,
": decode - word %d, bits [%d..%d] in [%d..%d], opcodes %d, entries %d\n",
table->opcode->word_nr,
i2target (options.hi_bit_nr, table->opcode->first),
i2target (options.hi_bit_nr, table->opcode->last),
i2target (options.hi_bit_nr, table->opcode_rule->first),
i2target (options.hi_bit_nr, table->opcode_rule->last),
table->opcode->nr_opcodes,
table->nr_entries);
}
/* dump the results */
if (options.trace.entries)
{
gen_entry *entry;
for (entry = table->entries; entry != NULL; entry = entry->sibling)
{
insn_list *l;
print_gen_entry_path (table->opcode_rule->line, entry, notify);
notify (NULL, ": %d - entries %d -",
entry->opcode_nr,
entry->nr_insns);
for (l = entry->insns; l != NULL; l = l->next)
notify (NULL, " %s.%s", l->insn->format_name, l->insn->name);
notify (NULL, "\n");
}
}
/* perform a combine pass if needed */
if (table->opcode_rule->with_combine)
{
gen_entry *entry;
for (entry = table->entries; entry != NULL; entry = entry->sibling)
{
if (entry->combined_parent == NULL)
{
gen_entry **last = &entry->combined_next;
gen_entry *alt;
for (alt = entry->sibling; alt != NULL; alt = alt->sibling)
{
if (alt->combined_parent == NULL
&& insn_list_cmp (entry->insns, alt->insns) == 0)
{
alt->combined_parent = entry;
*last = alt;
last = &alt->combined_next;
}
}
}
}
if (options.trace.combine)
{
int nr_unique = 0;
gen_entry *entry;
for (entry = table->entries; entry != NULL; entry = entry->sibling)
{
if (entry->combined_parent == NULL)
{
insn_list *l;
gen_entry *duplicate;
nr_unique++;
print_gen_entry_path (table->opcode_rule->line, entry, notify);
for (duplicate = entry->combined_next;
duplicate != NULL;
duplicate = duplicate->combined_next)
{
notify (NULL, "+%d", duplicate->opcode_nr);
}
notify (NULL, ": entries %d -", entry->nr_insns);
for (l = entry->insns; l != NULL; l = l->next)
{
notify (NULL, " %s.%s",
l->insn->format_name,
l->insn->name);
}
notify (NULL, "\n");
}
}
print_gen_entry_path (table->opcode_rule->line, table, notify);
notify (NULL, ": combine - word %d, bits [%d..%d] in [%d..%d], opcodes %d, entries %d, unique %d\n",
table->opcode->word_nr,
i2target (options.hi_bit_nr, table->opcode->first),
i2target (options.hi_bit_nr, table->opcode->last),
i2target (options.hi_bit_nr, table->opcode_rule->first),
i2target (options.hi_bit_nr, table->opcode_rule->last),
table->opcode->nr_opcodes,
table->nr_entries,
nr_unique);
}
}
/* Check that the rule did more than re-arange the order of the
instructions */
{
gen_entry *entry;
for (entry = table->entries; entry != NULL; entry = entry->sibling)
{
if (entry->combined_parent == NULL)
{
if (insn_list_cmp (table->insns, entry->insns) == 0)
{
print_gen_entry_path (table->opcode_rule->line, table, warning);
warning (NULL, ": Applying rule just copied all instructions\n");
print_gen_entry_insns (entry, warning, "Copied", NULL);
error (NULL, "");
}
}
}
}
/* if some form of expanded table, fill in the missing dots */
switch (table->opcode_rule->gen)
{
case padded_switch_gen:
case array_gen:
case goto_switch_gen:
if (!table->opcode->is_boolean)
{
gen_entry **entry = &table->entries;
gen_entry *illegals = NULL;
gen_entry **last_illegal = &illegals;
int opcode_nr = 0;
while (opcode_nr < table->opcode->nr_opcodes)
{
if ((*entry) == NULL || (*entry)->opcode_nr != opcode_nr)
{
/* missing - insert it under our feet at *entry */
gen_entry_insert_insn (table,
table->top->isa->illegal_insn,
table->opcode->word_nr,
0, /* nr_prefetched_words == 0 for invalid */
opcode_nr, NULL);
ASSERT ((*entry) != NULL);
ASSERT ((*entry)->opcode_nr == opcode_nr);
(*last_illegal) = *entry;
(*last_illegal)->combined_parent = illegals;
last_illegal = &(*last_illegal)->combined_next;
}
entry = &(*entry)->sibling;
opcode_nr++;
}
/* oops, will have pointed the first illegal insn back to
its self. Fix this */
if (illegals != NULL)
illegals->combined_parent = NULL;
}
break;
case switch_gen:
case invalid_gen:
/* ignore */
break;
}
/* and do the same for the newly created sub entries but *only*
expand entries that haven't been combined. */
{
gen_entry *entry;
for (entry = table->entries; entry != NULL; entry = entry->sibling)
{
if (entry->combined_parent == NULL)
{
gen_entry_expand_insns (entry);
}
}
}
}
void
gen_tables_expand_insns (gen_table *gen)
{
gen_list *entry;
for (entry = gen->tables; entry != NULL; entry = entry->next)
{
gen_entry_expand_insns (entry->table);
}
}
/* create a list of all the semantic functions that need to be
generated. Eliminate any duplicates. Verify that the decode stage
worked. */
static void
make_gen_semantics_list (lf *file,
gen_entry *entry,
int depth,
void *data)
{
gen_table *gen = (gen_table*) data;
insn_list *insn;
/* Not interested in an entrie that have been combined into some
other entry at the same level */
if (entry->combined_parent != NULL)
return;
/* a leaf should contain exactly one instruction. If not the decode
stage failed. */
ASSERT (entry->nr_insns == 1);
/* Enter this instruction into the list of semantic functions. */
insn = insn_list_insert (&gen->semantics, &gen->nr_semantics,
entry->insns->insn,
entry->expanded_bits,
entry->parent->opcode,
entry->insns->nr_prefetched_words,
merge_duplicate_insns);
/* point the table entry at the real semantic function */
ASSERT (insn != NULL);
entry->insns->semantic = insn;
}
void
gen_tables_expand_semantics (gen_table *gen)
{
gen_list *entry;
for (entry = gen->tables; entry != NULL; entry = entry->next)
{
gen_entry_traverse_tree (NULL,
entry->table,
1, /* depth */
NULL, /* start-handler */
make_gen_semantics_list, /* leaf-handler */
NULL, /* end-handler */
gen); /* data */
}
}
#ifdef MAIN
static void
dump_opcode_field (lf *file,
char *prefix,
opcode_field *field,
char *suffix,
int levels)
{
lf_printf (file, "%s(opcode_field *) 0x%lx", prefix, (long) field);
if (levels && field != NULL) {
lf_indent (file, +1);
lf_printf (file, "\n(first %d)", field->first);
lf_printf (file, "\n(last %d)", field->last);
lf_printf (file, "\n(nr_opcodes %d)", field->nr_opcodes);
lf_printf (file, "\n(is_boolean %d)", field->is_boolean);
lf_printf (file, "\n(boolean_constant %d)", field->boolean_constant);
dump_opcode_field(file, "\n(parent ", field->parent, ")", levels - 1);
lf_indent (file, -1);
}
lf_printf (file, "%s", suffix);
}
static void
dump_opcode_bits (lf *file,
char *prefix,
opcode_bits *bits,
char *suffix,
int levels)
{
lf_printf (file, "%s(opcode_bits *) 0x%lx", prefix, (long) bits);
if (levels && bits != NULL)
{
lf_indent (file, +1);
lf_printf (file, "\n(value %d)", bits->value);
dump_opcode_field (file, "\n(opcode ", bits->opcode, ")", 0);
dump_insn_field (file, "\n(field ", bits->field, ")");
dump_opcode_bits (file, "\n(next ", bits->next, ")", levels - 1);
lf_indent (file, -1);
}
lf_printf (file, "%s", suffix);
}
static void
dump_insn_list (lf *file,
char *prefix,
insn_list *entry,
char *suffix)
{
lf_printf (file, "%s(insn_list *) 0x%lx", prefix, (long) entry);
if (entry != NULL) {
lf_indent (file, +1);
dump_insn_entry (file, "\n(insn ", entry->insn, ")");
lf_printf (file, "\n(next 0x%lx)", (long) entry->next);
lf_indent (file, -1);
}
lf_printf (file, "%s", suffix);
}
static void
dump_insn_word_entry_list_entries (lf *file,
char *prefix,
insn_list *entry,
char *suffix)
{
lf_printf (file, "%s", prefix);
while (entry != NULL)
{
dump_insn_list (file, "\n(", entry, ")");
entry = entry->next;
}
lf_printf (file, "%s", suffix);
}
static void
dump_gen_entry (lf *file,
char *prefix,
gen_entry *table,
char *suffix,
int levels)
{
lf_printf (file, "%s(gen_entry *) 0x%lx", prefix, (long) table);
if (levels && table != NULL) {
lf_indent (file, +1);
lf_printf (file, "\n(opcode_nr %d)", table->opcode_nr);
lf_printf (file, "\n(word_nr %d)", table->word_nr);
dump_opcode_bits (file, "\n(expanded_bits ", table->expanded_bits, ")", -1);
lf_printf (file, "\n(nr_insns %d)", table->nr_insns);
dump_insn_word_entry_list_entries (file, "\n(insns ", table->insns, ")");
dump_decode_rule (file, "\n(opcode_rule ", table->opcode_rule, ")");
dump_opcode_field (file, "\n(opcode ", table->opcode, ")", 0);
lf_printf (file, "\n(nr_entries %d)", table->nr_entries);
dump_gen_entry (file, "\n(entries ", table->entries, ")", table->nr_entries);
dump_gen_entry (file, "\n(sibling ", table->sibling, ")", levels - 1);
dump_gen_entry (file, "\n(parent ", table->parent, ")", 0);
lf_indent (file, -1);
}
lf_printf (file, "%s", suffix);
}
static void
dump_gen_list (lf *file,
char *prefix,
gen_list *entry,
char *suffix,
int levels)
{
while (entry != NULL)
{
lf_printf (file, "%s(gen_list *) 0x%lx", prefix, (long) entry);
dump_gen_entry (file, "\n(", entry->table, ")", levels);
lf_printf (file, "\n(next (gen_list *) 0x%lx)", (long) entry->next);
lf_printf (file, "%s", suffix);
}
}
static void
dump_gen_table (lf *file,
char *prefix,
gen_table *gen,
char *suffix,
int levels)
{
lf_printf (file, "%s(gen_table *) 0x%lx", prefix, (long) gen);
lf_printf (file, "\n(isa (insn_table *) 0x%lx)", (long) gen->isa);
lf_printf (file, "\n(rules (decode_table *) 0x%lx)", (long) gen->rules);
dump_gen_list (file, "\n(", gen->tables, ")", levels);
lf_printf (file, "%s", suffix);
}
igen_options options;
int
main (int argc,
char **argv)
{
decode_table *decode_rules;
insn_table *instructions;
gen_table *gen;
lf *l;
if (argc != 7)
error (NULL, "Usage: insn <filter-in> <hi-bit-nr> <insn-bit-size> <widths> <decode-table> <insn-table>\n");
INIT_OPTIONS (options);
filter_parse (&options.flags_filter, argv[1]);
options.hi_bit_nr = a2i(argv[2]);
options.insn_bit_size = a2i(argv[3]);
options.insn_specifying_widths = a2i(argv[4]);
ASSERT(options.hi_bit_nr < options.insn_bit_size);
instructions = load_insn_table (argv[6], NULL);
decode_rules = load_decode_table (argv[5]);
gen = make_gen_tables (instructions, decode_rules);
gen_tables_expand_insns (gen);
l = lf_open ("-", "stdout", lf_omit_references, lf_is_text, "tmp-ld-insn");
dump_gen_table (l, "(", gen, ")\n", -1);
return 0;
}
#endif