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|
/* Generate code from to output assembler insns as recognized from rtl.
Copyright (C) 1987, 88, 92, 94-95, 97-98, 1999
Free Software Foundation, Inc.
This file is part of GNU CC.
GNU CC 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, or (at your option)
any later version.
GNU CC 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 GNU CC; see the file COPYING. If not, write to
the Free Software Foundation, 59 Temple Place - Suite 330,
Boston, MA 02111-1307, USA. */
/* This program reads the machine description for the compiler target machine
and produces a file containing these things:
1. An array of `struct insn_data', which is indexed by insn code number,
which contains:
a. `name' is the name for that pattern. Nameless patterns are
given a name.
b. `output' hold either the output template, an array of output
templates, or an output function.
c. `genfun' is the function to generate a body for that pattern,
given operands as arguments.
d. `n_operands' is the number of distinct operands in the pattern
for that insn,
e. `n_dups' is the number of match_dup's that appear in the insn's
pattern. This says how many elements of `recog_data.dup_loc' are
significant after an insn has been recognized.
f. `n_alternatives' is the number of alternatives in the constraints
of each pattern.
g. `output_format' tells what type of thing `output' is.
h. `operand' is the base of an array of operand data for the insn.
2. An array of `struct insn_operand data', used by `operand' above.
a. `predicate', an int-valued function, is the match_operand predicate
for this operand.
b. `constraint' is the constraint for this operand. This exists
only if register constraints appear in match_operand rtx's.
c. `address_p' indicates that the operand appears within ADDRESS
rtx's. This exists only if there are *no* register constraints
in the match_operand rtx's.
d. `mode' is the machine mode that that operand is supposed to have.
e. `strict_low', is nonzero for operands contained in a STRICT_LOW_PART.
The code number of an insn is simply its position in the machine
description; code numbers are assigned sequentially to entries in
the description, starting with code number 0.
Thus, the following entry in the machine description
(define_insn "clrdf"
[(set (match_operand:DF 0 "general_operand" "")
(const_int 0))]
""
"clrd %0")
assuming it is the 25th entry present, would cause
insn_data[24].template to be "clrd %0", and
insn_data[24].n_operands to be 1. */
#include "hconfig.h"
#include "system.h"
#include "rtl.h"
#include "obstack.h"
#include "errors.h"
/* No instruction can have more operands than this. Sorry for this
arbitrary limit, but what machine will have an instruction with
this many operands? */
#define MAX_MAX_OPERANDS 40
static struct obstack obstack;
struct obstack *rtl_obstack = &obstack;
#define obstack_chunk_alloc xmalloc
#define obstack_chunk_free free
static int n_occurrences PROTO((int, char *));
/* insns in the machine description are assigned sequential code numbers
that are used by insn-recog.c (produced by genrecog) to communicate
to insn-output.c (produced by this program). */
static int next_code_number;
/* This counts all definitions in the md file,
for the sake of error messages. */
static int next_index_number;
/* This counts all operands used in the md file. The first is null. */
static int next_operand_number = 1;
/* Record in this chain all information about the operands we will output. */
struct operand_data
{
struct operand_data *next;
int index;
const char *predicate;
const char *constraint;
enum machine_mode mode;
unsigned char n_alternatives;
char address_p;
char strict_low;
char seen;
};
/* Begin with a null operand at index 0. */
static struct operand_data null_operand =
{
0, 0, "", "", VOIDmode, 0, 0, 0, 0
};
static struct operand_data *odata = &null_operand;
static struct operand_data **odata_end = &null_operand.next;
/* Must match the constants in recog.h. */
#define INSN_OUTPUT_FORMAT_NONE 0 /* abort */
#define INSN_OUTPUT_FORMAT_SINGLE 1 /* const char * */
#define INSN_OUTPUT_FORMAT_MULTI 2 /* const char * const * */
#define INSN_OUTPUT_FORMAT_FUNCTION 3 /* const char * (*)(...) */
/* Record in this chain all information that we will output,
associated with the code number of the insn. */
struct data
{
struct data *next;
const char *name;
const char *template;
int code_number;
int index_number;
int n_operands; /* Number of operands this insn recognizes */
int n_dups; /* Number times match_dup appears in pattern */
int n_alternatives; /* Number of alternatives in each constraint */
int operand_number; /* Operand index in the big array. */
int output_format; /* INSN_OUTPUT_FORMAT_*. */
struct operand_data operand[MAX_MAX_OPERANDS];
};
/* This variable points to the first link in the insn chain. */
static struct data *idata, **idata_end = &idata;
/* Nonzero if any match_operand has a constraint string; implies that
REGISTER_CONSTRAINTS will be defined for this machine description. */
static int have_constraints;
static void output_prologue PROTO((void));
static void output_predicate_decls PROTO((void));
static void output_operand_data PROTO((void));
static void output_insn_data PROTO((void));
static void output_get_insn_name PROTO((void));
static void scan_operands PROTO((struct data *, rtx, int, int));
static int compare_operands PROTO((struct operand_data *,
struct operand_data *));
static void place_operands PROTO((struct data *));
static void process_template PROTO((struct data *, char *));
static void validate_insn_alternatives PROTO((struct data *));
static void gen_insn PROTO((rtx));
static void gen_peephole PROTO((rtx));
static void gen_expand PROTO((rtx));
static void gen_split PROTO((rtx));
static int n_occurrences PROTO((int, char *));
const char *
get_insn_name (index)
int index;
{
static char buf[100];
struct data *i, *last_named = NULL;
for (i = idata; i ; i = i->next)
{
if (i->index_number == index)
return i->name;
if (i->name)
last_named = i;
}
if (last_named)
sprintf(buf, "%s+%d", last_named->name, index - last_named->index_number);
else
sprintf(buf, "insn %d", index);
return buf;
}
static void
output_prologue ()
{
printf ("/* Generated automatically by the program `genoutput'\n\
from the machine description file `md'. */\n\n");
printf ("#define NO_MD_PROTOTYPES\n");
printf ("#include \"config.h\"\n");
printf ("#include \"system.h\"\n");
printf ("#include \"flags.h\"\n");
printf ("#include \"rtl.h\"\n");
printf ("#include \"function.h\"\n");
printf ("#include \"regs.h\"\n");
printf ("#include \"hard-reg-set.h\"\n");
printf ("#include \"real.h\"\n");
printf ("#include \"insn-config.h\"\n\n");
printf ("#include \"conditions.h\"\n");
printf ("#include \"insn-flags.h\"\n");
printf ("#include \"insn-attr.h\"\n\n");
printf ("#include \"insn-codes.h\"\n\n");
printf ("#include \"recog.h\"\n\n");
printf ("#include \"output.h\"\n");
}
/* We need to define all predicates used. Keep a list of those we
have defined so far. There normally aren't very many predicates
used, so a linked list should be fast enough. */
static void
output_predicate_decls ()
{
struct predicate { const char *name; struct predicate *next; } *predicates = 0;
register struct operand_data *d;
struct predicate *p;
for (d = odata; d; d = d->next)
if (d->predicate && d->predicate[0])
{
for (p = predicates; p; p = p->next)
if (strcmp (p->name, d->predicate) == 0)
break;
if (p == 0)
{
printf ("extern int %s PROTO ((rtx, enum machine_mode));\n",
d->predicate);
p = (struct predicate *) alloca (sizeof (struct predicate));
p->name = d->predicate;
p->next = predicates;
predicates = p;
}
}
printf ("\n\n");
}
static void
output_operand_data ()
{
register struct operand_data *d;
printf ("\nstatic const struct insn_operand_data operand_data[] = \n{\n");
for (d = odata; d; d = d->next)
{
printf (" {\n");
printf (" %s,\n",
d->predicate && d->predicate[0] ? d->predicate : "0");
if (have_constraints)
{
printf (" \"%s\",\n",
d->constraint ? d->constraint : "");
}
printf (" %smode,\n", GET_MODE_NAME (d->mode));
if (! have_constraints)
printf (" %d,\n", d->address_p);
printf (" %d\n", d->strict_low);
printf(" },\n");
}
printf("};\n\n\n");
}
static void
output_insn_data ()
{
register struct data *d;
int name_offset = 0;
int next_name_offset;
const char * last_name = 0;
const char * next_name = 0;
register struct data *n;
for (n = idata, next_name_offset = 1; n; n = n->next, next_name_offset++)
if (n->name)
{
next_name = n->name;
break;
}
printf ("\nconst struct insn_data insn_data[] = \n{\n");
for (d = idata; d; d = d->next)
{
printf (" {\n");
if (d->name)
{
printf (" \"%s\",\n", d->name);
name_offset = 0;
last_name = d->name;
next_name = 0;
for (n = d->next, next_name_offset = 1; n;
n = n->next, next_name_offset++)
{
if (n->name)
{
next_name = n->name;
break;
}
}
}
else
{
name_offset++;
if (next_name && (last_name == 0
|| name_offset > next_name_offset / 2))
printf (" \"%s-%d\",\n", next_name,
next_name_offset - name_offset);
else
printf (" \"%s+%d\",\n", last_name, name_offset);
}
switch (d->output_format)
{
case INSN_OUTPUT_FORMAT_NONE:
printf (" 0,\n");
break;
case INSN_OUTPUT_FORMAT_SINGLE:
printf (" \"%s\",\n", d->template);
break;
case INSN_OUTPUT_FORMAT_MULTI:
case INSN_OUTPUT_FORMAT_FUNCTION:
printf (" output_%d,\n", d->code_number);
break;
default:
abort ();
}
if (d->name && d->name[0] != '*')
printf (" gen_%s,\n", d->name);
else
printf (" 0,\n");
printf (" &operand_data[%d],\n", d->operand_number);
printf (" %d,\n", d->n_operands);
printf (" %d,\n", d->n_dups);
printf (" %d,\n", d->n_alternatives);
printf (" %d\n", d->output_format);
printf(" },\n");
}
printf ("};\n\n\n");
}
static void
output_get_insn_name ()
{
printf ("const char *\n");
printf ("get_insn_name (code)\n");
printf (" int code;\n");
printf ("{\n");
printf (" return insn_data[code].name;\n");
printf ("}\n");
}
/* Stores in max_opno the largest operand number present in `part', if
that is larger than the previous value of max_opno, and the rest of
the operand data into `d->operand[i]'.
THIS_ADDRESS_P is nonzero if the containing rtx was an ADDRESS.
THIS_STRICT_LOW is nonzero if the containing rtx was a STRICT_LOW_PART. */
static int max_opno;
static int num_dups;
static void
scan_operands (d, part, this_address_p, this_strict_low)
struct data *d;
rtx part;
int this_address_p;
int this_strict_low;
{
register int i, j;
register const char *format_ptr;
int opno;
if (part == 0)
return;
switch (GET_CODE (part))
{
case MATCH_OPERAND:
opno = XINT (part, 0);
if (opno > max_opno)
max_opno = opno;
if (max_opno >= MAX_MAX_OPERANDS)
{
error ("Too many operands (%d) in definition %s.\n",
max_opno + 1, get_insn_name (next_index_number));
return;
}
if (d->operand[opno].seen)
error ("Definition %s specified operand number %d more than once.\n",
get_insn_name (next_index_number), opno);
d->operand[opno].seen = 1;
d->operand[opno].mode = GET_MODE (part);
d->operand[opno].strict_low = this_strict_low;
d->operand[opno].predicate = XSTR (part, 1);
d->operand[opno].constraint = XSTR (part, 2);
if (XSTR (part, 2) != 0 && *XSTR (part, 2) != 0)
{
d->operand[opno].n_alternatives
= n_occurrences (',', XSTR (part, 2)) + 1;
have_constraints = 1;
}
d->operand[opno].address_p = this_address_p;
return;
case MATCH_SCRATCH:
opno = XINT (part, 0);
if (opno > max_opno)
max_opno = opno;
if (max_opno >= MAX_MAX_OPERANDS)
{
error ("Too many operands (%d) in definition %s.\n",
max_opno + 1, get_insn_name (next_index_number));
return;
}
if (d->operand[opno].seen)
error ("Definition %s specified operand number %d more than once.\n",
get_insn_name (next_index_number), opno);
d->operand[opno].seen = 1;
d->operand[opno].mode = GET_MODE (part);
d->operand[opno].strict_low = 0;
d->operand[opno].predicate = "scratch_operand";
d->operand[opno].constraint = XSTR (part, 1);
if (XSTR (part, 1) != 0 && *XSTR (part, 1) != 0)
{
d->operand[opno].n_alternatives
= n_occurrences (',', XSTR (part, 1)) + 1;
have_constraints = 1;
}
d->operand[opno].address_p = 0;
return;
case MATCH_OPERATOR:
case MATCH_PARALLEL:
opno = XINT (part, 0);
if (opno > max_opno)
max_opno = opno;
if (max_opno >= MAX_MAX_OPERANDS)
{
error ("Too many operands (%d) in definition %s.\n",
max_opno + 1, get_insn_name (next_index_number));
return;
}
if (d->operand[opno].seen)
error ("Definition %s specified operand number %d more than once.\n",
get_insn_name (next_index_number), opno);
d->operand[opno].seen = 1;
d->operand[opno].mode = GET_MODE (part);
d->operand[opno].strict_low = 0;
d->operand[opno].predicate = XSTR (part, 1);
d->operand[opno].constraint = 0;
d->operand[opno].address_p = 0;
for (i = 0; i < XVECLEN (part, 2); i++)
scan_operands (d, XVECEXP (part, 2, i), 0, 0);
return;
case MATCH_DUP:
case MATCH_OP_DUP:
case MATCH_PAR_DUP:
++num_dups;
return;
case ADDRESS:
scan_operands (d, XEXP (part, 0), 1, 0);
return;
case STRICT_LOW_PART:
scan_operands (d, XEXP (part, 0), 0, 1);
return;
default:
break;
}
format_ptr = GET_RTX_FORMAT (GET_CODE (part));
for (i = 0; i < GET_RTX_LENGTH (GET_CODE (part)); i++)
switch (*format_ptr++)
{
case 'e':
case 'u':
scan_operands (d, XEXP (part, i), 0, 0);
break;
case 'E':
if (XVEC (part, i) != NULL)
for (j = 0; j < XVECLEN (part, i); j++)
scan_operands (d, XVECEXP (part, i, j), 0, 0);
break;
}
}
/* Compare two operands for content equality. */
static int
compare_operands (d0, d1)
struct operand_data *d0, *d1;
{
const char *p0, *p1;
p0 = d0->predicate;
if (!p0)
p0 = "";
p1 = d1->predicate;
if (!p1)
p1 = "";
if (strcmp (p0, p1) != 0)
return 0;
if (have_constraints)
{
p0 = d0->constraint;
if (!p0)
p0 = "";
p1 = d1->constraint;
if (!p1)
p1 = "";
if (strcmp (p0, p1) != 0)
return 0;
}
if (d0->mode != d1->mode)
return 0;
if (!have_constraints)
if (d0->address_p != d1->address_p)
return 0;
if (d0->strict_low != d1->strict_low)
return 0;
return 1;
}
/* Scan the list of operands we've already committed to output and either
find a subsequence that is the same, or allocate a new one at the end. */
static void
place_operands (d)
struct data *d;
{
struct operand_data *od, *od2;
int i;
if (d->n_operands == 0)
{
d->operand_number = 0;
return;
}
/* Brute force substring search. */
for (od = odata, i = 0; od; od = od->next, i = 0)
if (compare_operands (od, &d->operand[0]))
{
od2 = od->next;
i = 1;
while (1)
{
if (i == d->n_operands)
goto full_match;
if (od2 == NULL)
goto partial_match;
if (! compare_operands (od2, &d->operand[i]))
break;
++i, od2 = od2->next;
}
}
/* Either partial match at the end of the list, or no match. In either
case, we tack on what operands are remaining to the end of the list. */
partial_match:
d->operand_number = next_operand_number - i;
for (; i < d->n_operands; ++i)
{
od2 = &d->operand[i];
*odata_end = od2;
odata_end = &od2->next;
od2->index = next_operand_number++;
}
*odata_end = NULL;
return;
full_match:
d->operand_number = od->index;
return;
}
/* Process an assembler template from a define_insn or a define_peephole.
It is either the assembler code template, a list of assembler code
templates, or C code to generate the assembler code template. */
static void
process_template (d, template)
struct data *d;
char *template;
{
register char *cp;
register int i;
/* Templates starting with * contain straight code to be run. */
if (template[0] == '*')
{
d->template = 0;
d->output_format = INSN_OUTPUT_FORMAT_FUNCTION;
printf ("\nstatic const char *output_%d PROTO ((rtx *, rtx));\n",
d->code_number);
puts ("\nstatic const char *");
printf ("output_%d (operands, insn)\n", d->code_number);
puts (" rtx *operands ATTRIBUTE_UNUSED;");
puts (" rtx insn ATTRIBUTE_UNUSED;");
puts ("{");
puts (template + 1);
puts ("}");
}
/* If the assembler code template starts with a @ it is a newline-separated
list of assembler code templates, one for each alternative. */
else if (template[0] == '@')
{
d->template = 0;
d->output_format = INSN_OUTPUT_FORMAT_MULTI;
printf ("\nstatic const char * const output_%d[] = {\n", d->code_number);
for (i = 0, cp = &template[1]; *cp; )
{
while (*cp == '\n' || *cp == ' ' || *cp== '\t')
cp++;
printf (" \"");
while (*cp != '\n' && *cp != '\0')
{
putchar (*cp);
cp++;
}
printf ("\",\n");
i++;
}
printf ("};\n");
}
else
{
d->template = template;
d->output_format = INSN_OUTPUT_FORMAT_SINGLE;
}
}
/* Check insn D for consistency in number of constraint alternatives. */
static void
validate_insn_alternatives (d)
struct data *d;
{
register int n = 0, start;
/* Make sure all the operands have the same number of alternatives
in their constraints. Let N be that number. */
for (start = 0; start < d->n_operands; start++)
if (d->operand[start].n_alternatives > 0)
{
if (n == 0)
n = d->operand[start].n_alternatives;
else if (n != d->operand[start].n_alternatives)
error ("wrong number of alternatives in operand %d of insn %s",
start, get_insn_name (d->index_number));
}
/* Record the insn's overall number of alternatives. */
d->n_alternatives = n;
}
/* Look at a define_insn just read. Assign its code number. Record
on idata the template and the number of arguments. If the insn has
a hairy output action, output a function for now. */
static void
gen_insn (insn)
rtx insn;
{
register struct data *d = (struct data *) xmalloc (sizeof (struct data));
register int i;
d->code_number = next_code_number++;
d->index_number = next_index_number;
if (XSTR (insn, 0)[0])
d->name = XSTR (insn, 0);
else
d->name = 0;
/* Build up the list in the same order as the insns are seen
in the machine description. */
d->next = 0;
*idata_end = d;
idata_end = &d->next;
max_opno = -1;
num_dups = 0;
memset (d->operand, 0, sizeof (d->operand));
for (i = 0; i < XVECLEN (insn, 1); i++)
scan_operands (d, XVECEXP (insn, 1, i), 0, 0);
d->n_operands = max_opno + 1;
d->n_dups = num_dups;
validate_insn_alternatives (d);
place_operands (d);
process_template (d, XSTR (insn, 3));
}
/* Look at a define_peephole just read. Assign its code number.
Record on idata the template and the number of arguments.
If the insn has a hairy output action, output it now. */
static void
gen_peephole (peep)
rtx peep;
{
register struct data *d = (struct data *) xmalloc (sizeof (struct data));
register int i;
d->code_number = next_code_number++;
d->index_number = next_index_number;
d->name = 0;
/* Build up the list in the same order as the insns are seen
in the machine description. */
d->next = 0;
*idata_end = d;
idata_end = &d->next;
max_opno = -1;
num_dups = 0;
memset (d->operand, 0, sizeof (d->operand));
/* Get the number of operands by scanning all the patterns of the
peephole optimizer. But ignore all the rest of the information
thus obtained. */
for (i = 0; i < XVECLEN (peep, 0); i++)
scan_operands (d, XVECEXP (peep, 0, i), 0, 0);
d->n_operands = max_opno + 1;
d->n_dups = 0;
validate_insn_alternatives (d);
place_operands (d);
process_template (d, XSTR (peep, 2));
}
/* Process a define_expand just read. Assign its code number,
only for the purposes of `insn_gen_function'. */
static void
gen_expand (insn)
rtx insn;
{
register struct data *d = (struct data *) xmalloc (sizeof (struct data));
register int i;
d->code_number = next_code_number++;
d->index_number = next_index_number;
if (XSTR (insn, 0)[0])
d->name = XSTR (insn, 0);
else
d->name = 0;
/* Build up the list in the same order as the insns are seen
in the machine description. */
d->next = 0;
*idata_end = d;
idata_end = &d->next;
max_opno = -1;
num_dups = 0;
memset (d->operand, 0, sizeof (d->operand));
/* Scan the operands to get the specified predicates and modes,
since expand_binop needs to know them. */
if (XVEC (insn, 1))
for (i = 0; i < XVECLEN (insn, 1); i++)
scan_operands (d, XVECEXP (insn, 1, i), 0, 0);
d->n_operands = max_opno + 1;
d->n_dups = num_dups;
d->template = 0;
d->output_format = INSN_OUTPUT_FORMAT_NONE;
validate_insn_alternatives (d);
place_operands (d);
}
/* Process a define_split just read. Assign its code number,
only for reasons of consistency and to simplify genrecog. */
static void
gen_split (split)
rtx split;
{
register struct data *d = (struct data *) xmalloc (sizeof (struct data));
register int i;
d->code_number = next_code_number++;
d->index_number = next_index_number;
d->name = 0;
/* Build up the list in the same order as the insns are seen
in the machine description. */
d->next = 0;
*idata_end = d;
idata_end = &d->next;
max_opno = -1;
num_dups = 0;
memset (d->operand, 0, sizeof (d->operand));
/* Get the number of operands by scanning all the patterns of the
split patterns. But ignore all the rest of the information thus
obtained. */
for (i = 0; i < XVECLEN (split, 0); i++)
scan_operands (d, XVECEXP (split, 0, i), 0, 0);
d->n_operands = max_opno + 1;
d->n_dups = 0;
d->n_alternatives = 0;
d->template = 0;
d->output_format = INSN_OUTPUT_FORMAT_NONE;
place_operands (d);
}
PTR
xmalloc (size)
size_t size;
{
register PTR val = (PTR) malloc (size);
if (val == 0)
fatal ("virtual memory exhausted");
return val;
}
PTR
xrealloc (old, size)
PTR old;
size_t size;
{
register PTR ptr;
if (old)
ptr = (PTR) realloc (old, size);
else
ptr = (PTR) malloc (size);
if (!ptr)
fatal ("virtual memory exhausted");
return ptr;
}
extern int main PROTO ((int, char **));
int
main (argc, argv)
int argc;
char **argv;
{
rtx desc;
FILE *infile;
register int c;
progname = "genoutput";
obstack_init (rtl_obstack);
if (argc <= 1)
fatal ("No input file name.");
infile = fopen (argv[1], "r");
if (infile == 0)
{
perror (argv[1]);
return (FATAL_EXIT_CODE);
}
output_prologue ();
next_code_number = 0;
next_index_number = 0;
have_constraints = 0;
/* Read the machine description. */
while (1)
{
c = read_skip_spaces (infile);
if (c == EOF)
break;
ungetc (c, infile);
desc = read_rtx (infile);
if (GET_CODE (desc) == DEFINE_INSN)
gen_insn (desc);
if (GET_CODE (desc) == DEFINE_PEEPHOLE)
gen_peephole (desc);
if (GET_CODE (desc) == DEFINE_EXPAND)
gen_expand (desc);
if (GET_CODE (desc) == DEFINE_SPLIT
|| GET_CODE (desc) == DEFINE_PEEPHOLE2)
gen_split (desc);
next_index_number++;
}
printf("\n\n");
output_predicate_decls ();
output_operand_data ();
output_insn_data ();
output_get_insn_name ();
fflush (stdout);
return (ferror (stdout) != 0 || have_error
? FATAL_EXIT_CODE : SUCCESS_EXIT_CODE);
}
static int
n_occurrences (c, s)
int c;
char *s;
{
int n = 0;
while (*s)
n += (*s++ == c);
return n;
}
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