binutils-gdb/opcodes/ia64-gen.c

2790 lines
70 KiB
C
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/* ia64-gen.c -- Generate a shrunk set of opcode tables
Copyright 1999, 2000, 2001 Free Software Foundation, Inc.
Written by Bob Manson, Cygnus Solutions, <manson@cygnus.com>
This file is part of GDB, GAS, and the GNU binutils.
GDB, GAS, and the GNU binutils are free software; you can redistribute
them and/or modify them 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.
GDB, GAS, and the GNU binutils are distributed in the hope that they
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 file; see the file COPYING. If not, write to the
Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA
02111-1307, USA. */
/* While the ia64-opc-* set of opcode tables are easy to maintain,
they waste a tremendous amount of space. ia64-gen rearranges the
instructions into a directed acyclic graph (DAG) of instruction opcodes and
their possible completers, as well as compacting the set of strings used.
The disassembler table consists of a state machine that does
branching based on the bits of the opcode being disassembled. The
state encodings have been chosen to minimize the amount of space
required.
The resource table is constructed based on some text dependency tables,
which are also easier to maintain than the final representation.
*/
#include <stdio.h>
#include "ansidecl.h"
#include "libiberty.h"
#include "safe-ctype.h"
#include "sysdep.h"
#include "ia64-opc.h"
#include "ia64-opc-a.c"
#include "ia64-opc-i.c"
#include "ia64-opc-m.c"
#include "ia64-opc-b.c"
#include "ia64-opc-f.c"
#include "ia64-opc-x.c"
#include "ia64-opc-d.c"
int debug = 0;
#define tmalloc(X) (X *) xmalloc (sizeof (X))
/* The main opcode table entry. Each entry is a unique combination of
name and flags (no two entries in the table compare as being equal
via opcodes_eq). */
struct main_entry
{
/* The base name of this opcode. The names of its completers are
appended to it to generate the full instruction name. */
struct string_entry *name;
/* The base opcode entry. Which one to use is a fairly arbitrary choice;
it uses the first one passed to add_opcode_entry. */
struct ia64_opcode *opcode;
/* The list of completers that can be applied to this opcode. */
struct completer_entry *completers;
/* Next entry in the chain. */
struct main_entry *next;
/* Index in the main table. */
int main_index;
} *maintable, **ordered_table;
int otlen = 0;
int ottotlen = 0;
int opcode_count = 0;
/* The set of possible completers for an opcode. */
struct completer_entry
{
/* This entry's index in the ia64_completer_table[] array. */
int num;
/* The name of the completer. */
struct string_entry *name;
/* This entry's parent. */
struct completer_entry *parent;
/* Set if this is a terminal completer (occurs at the end of an
opcode). */
int is_terminal;
/* An alternative completer. */
struct completer_entry *alternative;
/* Additional completers that can be appended to this one. */
struct completer_entry *addl_entries;
/* Before compute_completer_bits () is invoked, this contains the actual
instruction opcode for this combination of opcode and completers.
Afterwards, it contains those bits that are different from its
parent opcode. */
ia64_insn bits;
/* Bits set to 1 correspond to those bits in this completer's opcode
that are different from its parent completer's opcode (or from
the base opcode if the entry is the root of the opcode's completer
list). This field is filled in by compute_completer_bits (). */
ia64_insn mask;
/* Index into the opcode dependency list, or -1 if none. */
int dependencies;
/* Remember the order encountered in the opcode tables. */
int order;
};
/* One entry in the disassembler name table. */
struct disent
{
/* The index into the ia64_name_dis array for this entry. */
int ournum;
/* The index into the main_table[] array. */
int insn;
/* The disassmbly priority of this entry. */
int priority;
/* The completer_index value for this entry. */
int completer_index;
/* How many other entries share this decode. */
int nextcnt;
/* The next entry sharing the same decode. */
struct disent *nexte;
/* The next entry in the name list. */
struct disent *next_ent;
} *disinsntable = NULL;
/* A state machine that will eventually be used to generate the
disassembler table. */
struct bittree
{
struct disent *disent;
struct bittree *bits[3]; /* 0, 1, and X (don't care) */
int bits_to_skip;
int skip_flag;
} *bittree;
/* The string table contains all opcodes and completers sorted in
alphabetical order. */
/* One entry in the string table. */
struct string_entry
{
/* The index in the ia64_strings[] array for this entry. */
int num;
/* And the string. */
char *s;
} **string_table = NULL;
int strtablen = 0;
int strtabtotlen = 0;
/* resource dependency entries */
struct rdep
{
char *name; /* resource name */
unsigned
mode:2, /* RAW, WAW, or WAR */
semantics:3; /* dependency semantics */
char *extra; /* additional semantics info */
int nchks;
int total_chks; /* total #of terminal insns */
int *chks; /* insn classes which read (RAW), write
(WAW), or write (WAR) this rsrc */
int *chknotes; /* dependency notes for each class */
int nregs;
int total_regs; /* total #of terminal insns */
int *regs; /* insn class which write (RAW), write2
(WAW), or read (WAR) this rsrc */
int *regnotes; /* dependency notes for each class */
int waw_special; /* special WAW dependency note */
} **rdeps = NULL;
static int rdepslen = 0;
static int rdepstotlen = 0;
/* array of all instruction classes */
struct iclass
{
char *name; /* instruction class name */
int is_class; /* is a class, not a terminal */
int nsubs;
int *subs; /* other classes within this class */
int nxsubs;
int xsubs[4]; /* exclusions */
char *comment; /* optional comment */
int note; /* optional note */
int terminal_resolved; /* did we match this with anything? */
int orphan; /* detect class orphans */
} **ics = NULL;
static int iclen = 0;
static int ictotlen = 0;
/* an opcode dependency (chk/reg pair of dependency lists) */
struct opdep
{
int chk; /* index into dlists */
int reg; /* index into dlists */
} **opdeps;
static int opdeplen = 0;
static int opdeptotlen = 0;
/* a generic list of dependencies w/notes encoded. these may be shared. */
struct deplist
{
int len;
unsigned short *deps;
} **dlists;
static int dlistlen = 0;
static int dlisttotlen = 0;
/* add NAME to the resource table, where TYPE is RAW or WAW */
static struct rdep *
insert_resource (const char *name, enum ia64_dependency_mode type)
{
if (rdepslen == rdepstotlen)
{
rdepstotlen += 20;
rdeps = (struct rdep **)
xrealloc (rdeps, sizeof(struct rdep **) * rdepstotlen);
}
rdeps[rdepslen] = tmalloc(struct rdep);
memset((void *)rdeps[rdepslen], 0, sizeof(struct rdep));
rdeps[rdepslen]->name = xstrdup (name);
rdeps[rdepslen]->mode = type;
rdeps[rdepslen]->waw_special = 0;
return rdeps[rdepslen++];
}
/* are the lists of dependency indexes equivalent? */
static int
deplist_equals (struct deplist *d1, struct deplist *d2)
{
int i;
if (d1->len != d2->len)
return 0;
for (i=0;i < d1->len;i++)
{
if (d1->deps[i] != d2->deps[i])
return 0;
}
return 1;
}
/* add the list of dependencies to the list of dependency lists */
static short
insert_deplist(int count, unsigned short *deps)
{
/* sort the list, then see if an equivalent list exists already.
this results in a much smaller set of dependency lists
*/
struct deplist *list;
char set[0x10000];
int i;
memset ((void *)set, 0, sizeof(set));
for (i=0;i < count;i++)
set[deps[i]] = 1;
count = 0;
for (i=0;i < (int)sizeof(set);i++)
if (set[i])
++count;
list = tmalloc(struct deplist);
list->len = count;
list->deps = (unsigned short *)malloc (sizeof(unsigned short) * count);
for (i=0, count=0;i < (int)sizeof(set);i++)
{
if (set[i])
{
list->deps[count++] = i;
}
}
/* does this list exist already? */
for (i=0;i < dlistlen;i++)
{
if (deplist_equals (list, dlists[i]))
{
free (list->deps);
free (list);
return i;
}
}
if (dlistlen == dlisttotlen)
{
dlisttotlen += 20;
dlists = (struct deplist **)
xrealloc (dlists, sizeof(struct deplist **) * dlisttotlen);
}
dlists[dlistlen] = list;
return dlistlen++;
}
/* add the given pair of dependency lists to the opcode dependency list */
static short
insert_dependencies (int nchks, unsigned short *chks,
int nregs, unsigned short *regs)
{
struct opdep *pair;
int i;
int regind = -1;
int chkind = -1;
if (nregs > 0)
regind = insert_deplist (nregs, regs);
if (nchks > 0)
chkind = insert_deplist (nchks, chks);
for (i=0;i < opdeplen;i++)
{
if (opdeps[i]->chk == chkind
&& opdeps[i]->reg == regind)
return i;
}
pair = tmalloc(struct opdep);
pair->chk = chkind;
pair->reg = regind;
if (opdeplen == opdeptotlen)
{
opdeptotlen += 20;
opdeps = (struct opdep **)
xrealloc (opdeps, sizeof(struct opdep **) * opdeptotlen);
}
opdeps[opdeplen] = pair;
return opdeplen++;
}
static void
mark_used (struct iclass *ic, int clear_terminals)
{
int i;
ic->orphan = 0;
if (clear_terminals)
ic->terminal_resolved = 1;
for (i=0;i < ic->nsubs;i++)
{
mark_used (ics[ic->subs[i]], clear_terminals);
}
for (i=0;i < ic->nxsubs;i++)
{
mark_used (ics[ic->xsubs[i]], clear_terminals);
}
}
/* look up an instruction class; if CREATE make a new one if none found;
returns the index into the insn class array */
static int
fetch_insn_class(const char *full_name, int create)
{
char *name;
char *notestr;
char *xsect;
char *comment;
int i, note = 0;
int ind;
int is_class = 0;
if (strncmp (full_name, "IC:", 3) == 0)
{
name = xstrdup (full_name + 3);
is_class = 1;
}
else
name = xstrdup (full_name);
if ((xsect = strchr(name, '\\')) != NULL)
is_class = 1;
if ((comment = strchr(name, '[')) != NULL)
is_class = 1;
if ((notestr = strchr(name, '+')) != NULL)
is_class = 1;
/* If it is a composite class, then ignore comments and notes that come after
the '\\', since they don't apply to the part we are decoding now. */
if (xsect)
{
if (comment > xsect)
comment = 0;
if (notestr > xsect)
notestr = 0;
}
if (notestr)
{
char *nextnotestr;
note = atoi (notestr + 1);
if ((nextnotestr = strchr (notestr + 1, '+')) != NULL)
{
if (strcmp (notestr, "+1+13") == 0)
note = 13;
else if (!xsect || nextnotestr < xsect)
fprintf (stderr, "Warning: multiple note %s not handled\n",
notestr);
}
}
/* If it's a composite class, leave the notes and comments in place so that
we have a unique name for the composite class. Otherwise, we remove
them. */
if (!xsect)
{
if (notestr)
*notestr = 0;
if (comment)
*comment = 0;
}
for (i=0;i < iclen;i++)
if (strcmp(name, ics[i]->name) == 0
&& ((comment == NULL && ics[i]->comment == NULL)
|| (comment != NULL && ics[i]->comment != NULL
&& strncmp (ics[i]->comment, comment,
strlen (ics[i]->comment)) == 0))
&& note == ics[i]->note)
return i;
if (!create)
return -1;
/* doesn't exist, so make a new one */
if (iclen == ictotlen)
{
ictotlen += 20;
ics = (struct iclass **)
xrealloc(ics, (ictotlen)*sizeof(struct iclass *));
}
ind = iclen++;
ics[ind] = tmalloc(struct iclass);
memset((void *)ics[ind], 0, sizeof(struct iclass));
ics[ind]->name = xstrdup(name);
ics[ind]->is_class = is_class;
ics[ind]->orphan = 1;
if (comment)
{
ics[ind]->comment = xstrdup (comment + 1);
ics[ind]->comment[strlen(ics[ind]->comment)-1] = 0;
}
if (notestr)
ics[ind]->note = note;
/* if it's a composite class, there's a comment or note, look for an
existing class or terminal with the same name. */
if ((xsect || comment || notestr) && is_class)
{
/* First, populate with the class we're based on. */
char *subname = name;
if (xsect)
*xsect = 0;
else if (comment)
*comment = 0;
else if (notestr)
*notestr = 0;
ics[ind]->nsubs = 1;
ics[ind]->subs = tmalloc(int);
ics[ind]->subs[0] = fetch_insn_class (subname, 1);;
}
while (xsect)
{
char *subname = xsect + 1;
xsect = strchr (subname, '\\');
if (xsect)
*xsect = 0;
ics[ind]->xsubs[ics[ind]->nxsubs] = fetch_insn_class (subname,1);
ics[ind]->nxsubs++;
}
free (name);
return ind;
}
/* for sorting a class's sub-class list only; make sure classes appear before
terminals */
static int
sub_compare (const void *e1, const void *e2)
{
struct iclass *ic1 = ics[*(int *)e1];
struct iclass *ic2 = ics[*(int *)e2];
if (ic1->is_class)
{
if (!ic2->is_class)
return -1;
}
else if (ic2->is_class)
return 1;
return strcmp (ic1->name, ic2->name);
}
static void
load_insn_classes()
{
FILE *fp = fopen("ia64-ic.tbl", "r");
char buf[2048];
if (fp == NULL){
fprintf (stderr, "Can't find ia64-ic.tbl for reading\n");
exit(1);
}
/* discard first line */
fgets (buf, sizeof(buf), fp);
while (!feof(fp))
{
int iclass;
char *name;
char *tmp;
if (fgets (buf, sizeof(buf), fp) == NULL)
break;
while (ISSPACE (buf[strlen(buf)-1]))
buf[strlen(buf)-1] = '\0';
name = tmp = buf;
while (*tmp != ';')
{
++tmp;
if (tmp == buf + sizeof(buf))
abort ();
}
*tmp++ = '\0';
iclass = fetch_insn_class(name, 1);
ics[iclass]->is_class = 1;
if (strcmp (name, "none") == 0)
{
ics[iclass]->is_class = 0;
ics[iclass]->terminal_resolved = 1;
continue;
}
/* for this class, record all sub-classes */
while (*tmp)
{
char *subname;
int sub;
while (*tmp && ISSPACE (*tmp))
{
++tmp;
if (tmp == buf + sizeof(buf))
abort();
}
subname = tmp;
while (*tmp && *tmp != ',')
{
++tmp;
if (tmp == buf + sizeof(buf))
abort();
}
if (*tmp == ',')
*tmp++ = '\0';
ics[iclass]->subs = (int *)
xrealloc((void *)ics[iclass]->subs,
(ics[iclass]->nsubs+1)*sizeof(int));
sub = fetch_insn_class(subname, 1);
ics[iclass]->subs = (int *)
xrealloc(ics[iclass]->subs, (ics[iclass]->nsubs+1)*sizeof(int));
ics[iclass]->subs[ics[iclass]->nsubs++] = sub;
}
/* make sure classes come before terminals */
qsort ((void *)ics[iclass]->subs,
ics[iclass]->nsubs, sizeof(int), sub_compare);
}
fclose(fp);
if (debug)
{
printf ("%d classes\n", iclen);
}
}
/* extract the insn classes from the given line */
static void
parse_resource_users(ref, usersp, nusersp, notesp)
char *ref;
int **usersp;
int *nusersp;
int **notesp;
{
int c;
char *line = xstrdup (ref);
char *tmp = line;
int *users = *usersp;
int count = *nusersp;
int *notes = *notesp;
c = *tmp;
while (c != 0)
{
char *notestr;
int note;
char *xsect;
int iclass;
int create = 0;
char *name;
while (ISSPACE (*tmp))
++tmp;
name = tmp;
while (*tmp && *tmp != ',')
++tmp;
c = *tmp;
*tmp++ = '\0';
xsect = strchr(name, '\\');
if ((notestr = strstr(name, "+")) != NULL)
{
char *nextnotestr;
note = atoi (notestr + 1);
if ((nextnotestr = strchr (notestr + 1, '+')) != NULL)
{
/* note 13 always implies note 1 */
if (strcmp (notestr, "+1+13") == 0)
note = 13;
else if (!xsect || nextnotestr < xsect)
fprintf (stderr, "Warning: multiple note %s not handled\n",
notestr);
}
if (!xsect)
*notestr = '\0';
}
else
note = 0;
/* All classes are created when the insn class table is parsed;
Individual instructions might not appear until the dependency tables
are read. Only create new classes if it's *not* an insn class,
or if it's a composite class (which wouldn't necessarily be in the IC
table).
*/
if (strncmp(name, "IC:", 3) != 0 || xsect != NULL)
create = 1;
iclass = fetch_insn_class(name, create);
if (iclass != -1)
{
users = (int *)
xrealloc ((void *)users,(count+1)*sizeof(int));
notes = (int *)
xrealloc ((void *)notes,(count+1)*sizeof(int));
notes[count] = note;
users[count++] = iclass;
mark_used (ics[iclass], 0);
}
else
{
if (debug)
printf("Class %s not found\n", name);
}
}
/* update the return values */
*usersp = users;
*nusersp = count;
*notesp = notes;
free (line);
}
static int
parse_semantics (char *sem)
{
if (strcmp (sem, "none") == 0)
return IA64_DVS_NONE;
else if (strcmp (sem, "implied") == 0)
return IA64_DVS_IMPLIED;
else if (strcmp (sem, "impliedF") == 0)
return IA64_DVS_IMPLIEDF;
else if (strcmp (sem, "data") == 0)
return IA64_DVS_DATA;
else if (strcmp (sem, "instr") == 0)
return IA64_DVS_INSTR;
else if (strcmp (sem, "specific") == 0)
return IA64_DVS_SPECIFIC;
else if (strcmp (sem, "stop") == 0)
return IA64_DVS_STOP;
else
return IA64_DVS_OTHER;
}
static void
add_dep (const char *name, const char *chk, const char *reg,
int semantics, int mode, char *extra, int flag)
{
struct rdep *rs;
rs = insert_resource (name, mode);
parse_resource_users (chk, &rs->chks, &rs->nchks,
&rs->chknotes);
parse_resource_users (reg, &rs->regs, &rs->nregs,
&rs->regnotes);
rs->semantics = semantics;
rs->extra = extra;
rs->waw_special = flag;
}
static void
load_depfile (const char *filename, enum ia64_dependency_mode mode)
{
FILE *fp = fopen(filename, "r");
char buf[1024];
if (fp == NULL){
fprintf (stderr, "Can't find %s for reading\n", filename);
exit(1);
}
fgets(buf, sizeof(buf), fp);
while (!feof(fp))
{
char *name, *tmp;
int semantics;
char *extra;
char *regp, *chkp;
if (fgets (buf, sizeof(buf), fp) == NULL)
break;
while (ISSPACE (buf[strlen(buf)-1]))
buf[strlen(buf)-1] = '\0';
name = tmp = buf;
while (*tmp != ';')
++tmp;
*tmp++ = '\0';
while (ISSPACE (*tmp))
++tmp;
regp = tmp;
tmp = strchr (tmp, ';');
if (!tmp)
abort ();
*tmp++ = 0;
while (ISSPACE (*tmp))
++tmp;
chkp = tmp;
tmp = strchr (tmp, ';');
if (!tmp)
abort ();
*tmp++ = 0;
while (ISSPACE (*tmp))
++tmp;
semantics = parse_semantics (tmp);
extra = semantics == IA64_DVS_OTHER ? xstrdup (tmp) : NULL;
/* For WAW entries, if the chks and regs differ, we need to enter the
entries in both positions so that the tables will be parsed properly,
without a lot of extra work */
if (mode == IA64_DV_WAW && strcmp (regp, chkp) != 0)
{
add_dep (name, chkp, regp, semantics, mode, extra, 0);
add_dep (name, regp, chkp, semantics, mode, extra, 1);
}
else
{
add_dep (name, chkp, regp, semantics, mode, extra, 0);
}
}
fclose(fp);
}
static void
load_dependencies()
{
load_depfile ("ia64-raw.tbl", IA64_DV_RAW);
load_depfile ("ia64-waw.tbl", IA64_DV_WAW);
load_depfile ("ia64-war.tbl", IA64_DV_WAR);
if (debug)
printf ("%d RAW/WAW/WAR dependencies\n", rdepslen);
}
/* is the given operand an indirect register file operand? */
static int
irf_operand (int op, const char *field)
{
if (!field)
{
return op == IA64_OPND_RR_R3 || op == IA64_OPND_DBR_R3
|| op == IA64_OPND_IBR_R3 || op == IA64_OPND_PKR_R3
|| op == IA64_OPND_PMC_R3 || op == IA64_OPND_PMD_R3
|| op == IA64_OPND_MSR_R3 || op == IA64_OPND_CPUID_R3;
}
else
{
return ((op == IA64_OPND_RR_R3 && strstr (field, "rr"))
|| (op == IA64_OPND_DBR_R3 && strstr (field, "dbr"))
|| (op == IA64_OPND_IBR_R3 && strstr (field, "ibr"))
|| (op == IA64_OPND_PKR_R3 && strstr (field, "pkr"))
|| (op == IA64_OPND_PMC_R3 && strstr (field, "pmc"))
|| (op == IA64_OPND_PMD_R3 && strstr (field, "pmd"))
|| (op == IA64_OPND_MSR_R3 && strstr (field, "msr"))
|| (op == IA64_OPND_CPUID_R3 && strstr (field, "cpuid")));
}
}
/* handle mov_ar, mov_br, mov_cr, mov_indirect, mov_ip, mov_pr, mov_psr, and
mov_um insn classes */
static int
in_iclass_mov_x (struct ia64_opcode *idesc, struct iclass *ic,
const char *format, const char *field)
{
int plain_mov = strcmp (idesc->name, "mov") == 0;
if (!format)
return 0;
switch (ic->name[4])
{
default:
abort ();
case 'a':
{
int i = strcmp (idesc->name, "mov.i") == 0;
int m = strcmp (idesc->name, "mov.m") == 0;
int i2627 = i && idesc->operands[0] == IA64_OPND_AR3;
int i28 = i && idesc->operands[1] == IA64_OPND_AR3;
int m2930 = m && idesc->operands[0] == IA64_OPND_AR3;
int m31 = m && idesc->operands[1] == IA64_OPND_AR3;
int pseudo0 = plain_mov && idesc->operands[1] == IA64_OPND_AR3;
int pseudo1 = plain_mov && idesc->operands[0] == IA64_OPND_AR3;
/* IC:mov ar */
if (i2627)
return strstr (format, "I26") || strstr (format, "I27");
if (i28)
return strstr (format, "I28") != NULL;
if (m2930)
return strstr (format, "M29") || strstr (format, "M30");
if (m31)
return strstr (format, "M31") != NULL;
if (pseudo0 || pseudo1)
return 1;
}
break;
case 'b':
{
int i21 = idesc->operands[0] == IA64_OPND_B1;
int i22 = plain_mov && idesc->operands[1] == IA64_OPND_B2;
if (i22)
return strstr (format, "I22") != NULL;
if (i21)
return strstr (format, "I21") != NULL;
}
break;
case 'c':
{
int m32 = plain_mov && idesc->operands[0] == IA64_OPND_CR3;
int m33 = plain_mov && idesc->operands[1] == IA64_OPND_CR3;
if (m32)
return strstr (format, "M32") != NULL;
if (m33)
return strstr (format, "M33") != NULL;
}
break;
case 'i':
if (ic->name[5] == 'n')
{
int m42 = plain_mov && irf_operand (idesc->operands[0], field);
int m43 = plain_mov && irf_operand (idesc->operands[1], field);
if (m42)
return strstr (format, "M42") != NULL;
if (m43)
return strstr (format, "M43") != NULL;
}
else if (ic->name[5] == 'p')
{
return idesc->operands[1] == IA64_OPND_IP;
}
else
abort ();
break;
case 'p':
if (ic->name[5] == 'r')
{
int i25 = plain_mov && idesc->operands[1] == IA64_OPND_PR;
int i23 = plain_mov && idesc->operands[0] == IA64_OPND_PR;
int i24 = plain_mov && idesc->operands[0] == IA64_OPND_PR_ROT;
if (i23)
return strstr (format, "I23") != NULL;
if (i24)
return strstr (format, "I24") != NULL;
if (i25)
return strstr (format, "I25") != NULL;
}
else if (ic->name[5] == 's')
{
int m35 = plain_mov && idesc->operands[0] == IA64_OPND_PSR_L;
int m36 = plain_mov && idesc->operands[1] == IA64_OPND_PSR;
if (m35)
return strstr (format, "M35") != NULL;
if (m36)
return strstr (format, "M36") != NULL;
}
else
abort ();
break;
case 'u':
{
int m35 = plain_mov && idesc->operands[0] == IA64_OPND_PSR_UM;
int m36 = plain_mov && idesc->operands[1] == IA64_OPND_PSR_UM;
if (m35)
return strstr (format, "M35") != NULL;
if (m36)
return strstr (format, "M36") != NULL;
}
break;
}
return 0;
}
/* is the given opcode in the given insn class? */
static int
in_iclass(struct ia64_opcode *idesc, struct iclass *ic,
const char *format, const char *field, int *notep)
{
int i;
int resolved = 0;
if (ic->comment)
{
if (!strncmp (ic->comment, "Format", 6))
{
/* assume that the first format seen is the most restrictive, and
only keep a later one if it looks like it's more restrictive. */
if (format)
{
if (strlen (ic->comment) < strlen (format))
{
fprintf (stderr, "Warning: most recent format '%s'\n"
"appears more restrictive than '%s'\n",
ic->comment, format);
format = ic->comment;
}
}
else
format = ic->comment;
}
else if (!strncmp (ic->comment, "Field", 5))
{
if (field)
fprintf (stderr, "Overlapping field %s->%s\n",
ic->comment, field);
field = ic->comment;
}
}
/* an insn class matches anything that is the same followed by completers,
except when the absence and presence of completers constitutes different
instructions */
if (ic->nsubs == 0 && ic->nxsubs == 0)
{
int is_mov = strncmp (idesc->name, "mov", 3) == 0;
int plain_mov = strcmp (idesc->name, "mov") == 0;
int len = strlen(ic->name);
resolved = ((strncmp (ic->name, idesc->name, len) == 0)
&& (idesc->name[len] == '\0'
|| idesc->name[len] == '.'));
/* all break and nop variations must match exactly */
if (resolved &&
(strcmp (ic->name, "break") == 0
|| strcmp (ic->name, "nop") == 0))
resolved = strcmp (ic->name, idesc->name) == 0;
/* assume restrictions in the FORMAT/FIELD negate resolution,
unless specifically allowed by clauses in this block */
if (resolved && field)
{
/* check Field(sf)==sN against opcode sN */
if (strstr(field, "(sf)==") != NULL)
{
char *sf;
if ((sf = strstr (idesc->name, ".s")) != 0)
{
resolved = strcmp (sf + 1, strstr (field, "==") + 2) == 0;
}
}
/* check Field(lftype)==XXX */
else if (strstr (field, "(lftype)") != NULL)
{
if (strstr (idesc->name, "fault") != NULL)
resolved = strstr (field, "fault") != NULL;
else
resolved = strstr (field, "fault") == NULL;
}
/* handle Field(ctype)==XXX */
else if (strstr (field, "(ctype)") != NULL)
{
if (strstr (idesc->name, "or.andcm"))
resolved = strstr (field, "or.andcm") != NULL;
else if (strstr (idesc->name, "and.orcm"))
resolved = strstr (field, "and.orcm") != NULL;
else if (strstr (idesc->name, "orcm"))
resolved = strstr (field, "or orcm") != NULL;
else if (strstr (idesc->name, "or"))
resolved = strstr (field, "or orcm") != NULL;
else if (strstr (idesc->name, "andcm"))
resolved = strstr (field, "and andcm") != NULL;
else if (strstr (idesc->name, "and"))
resolved = strstr (field, "and andcm") != NULL;
else if (strstr (idesc->name, "unc"))
resolved = strstr (field, "unc") != NULL;
else
resolved = strcmp (field, "Field(ctype)==") == 0;
}
}
if (resolved && format)
{
if (strncmp (idesc->name, "dep", 3) == 0
&& strstr (format, "I13") != NULL)
resolved = idesc->operands[1] == IA64_OPND_IMM8;
else if (strncmp (idesc->name, "chk", 3) == 0
&& strstr (format, "M21") != NULL)
resolved = idesc->operands[0] == IA64_OPND_F2;
else if (strncmp (idesc->name, "lfetch", 6) == 0)
resolved = (strstr (format, "M14 M15") != NULL
&& (idesc->operands[1] == IA64_OPND_R2
|| idesc->operands[1] == IA64_OPND_IMM9b));
else if (strncmp (idesc->name, "br.call", 7) == 0
&& strstr (format, "B5") != NULL)
resolved = idesc->operands[1] == IA64_OPND_B2;
else if (strncmp (idesc->name, "br.call", 7) == 0
&& strstr (format, "B3") != NULL)
resolved = idesc->operands[1] == IA64_OPND_TGT25c;
else if (strncmp (idesc->name, "brp", 3) == 0
&& strstr (format, "B7") != NULL)
resolved = idesc->operands[0] == IA64_OPND_B2;
else if (strcmp (ic->name, "invala") == 0)
resolved = strcmp (idesc->name, ic->name) == 0;
else if (strncmp (idesc->name, "st", 2) == 0
&& strstr (format, "M5") != NULL)
resolved = idesc->flags & IA64_OPCODE_POSTINC;
else
resolved = 0;
}
/* misc brl variations ('.cond' is optional);
plain brl matches brl.cond */
if (!resolved
&& (strcmp (idesc->name, "brl") == 0
|| strncmp (idesc->name, "brl.", 4) == 0)
&& strcmp (ic->name, "brl.cond") == 0)
{
resolved = 1;
}
/* misc br variations ('.cond' is optional) */
if (!resolved
&& (strcmp (idesc->name, "br") == 0
|| strncmp (idesc->name, "br.", 3) == 0)
&& strcmp (ic->name, "br.cond") == 0)
{
if (format)
resolved = (strstr (format, "B4") != NULL
&& idesc->operands[0] == IA64_OPND_B2)
|| (strstr (format, "B1") != NULL
&& idesc->operands[0] == IA64_OPND_TGT25c);
else
resolved = 1;
}
/* probe variations */
if (!resolved && strncmp (idesc->name, "probe", 5) == 0)
{
resolved = strcmp (ic->name, "probe") == 0
&& !((strstr (idesc->name, "fault") != NULL)
^ (format && strstr (format, "M40") != NULL));
}
/* mov variations */
if (!resolved && is_mov)
{
if (plain_mov)
{
/* mov alias for fmerge */
if (strcmp (ic->name, "fmerge") == 0)
{
resolved = idesc->operands[0] == IA64_OPND_F1
&& idesc->operands[1] == IA64_OPND_F3;
}
/* mov alias for adds (r3 or imm14) */
else if (strcmp (ic->name, "adds") == 0)
{
resolved = (idesc->operands[0] == IA64_OPND_R1
&& (idesc->operands[1] == IA64_OPND_R3
|| (idesc->operands[1] == IA64_OPND_IMM14)));
}
/* mov alias for addl */
else if (strcmp (ic->name, "addl") == 0)
{
resolved = idesc->operands[0] == IA64_OPND_R1
&& idesc->operands[1] == IA64_OPND_IMM22;
}
}
/* some variants of mov and mov.[im] */
if (!resolved && strncmp (ic->name, "mov_", 4) == 0)
{
resolved = in_iclass_mov_x (idesc, ic, format, field);
}
}
/* keep track of this so we can flag any insn classes which aren't
mapped onto at least one real insn */
if (resolved)
{
ic->terminal_resolved = 1;
}
}
else for (i=0;i < ic->nsubs;i++)
{
if (in_iclass(idesc, ics[ic->subs[i]], format, field, notep))
{
int j;
for (j=0;j < ic->nxsubs;j++)
{
if (in_iclass(idesc, ics[ic->xsubs[j]], NULL, NULL, NULL))
return 0;
}
if (debug > 1)
printf ("%s is in IC %s\n",
idesc->name, ic->name);
resolved = 1;
break;
}
}
/* If it's in this IC, add the IC note (if any) to the insn */
if (resolved)
{
if (ic->note && notep)
{
if (*notep && *notep != ic->note)
{
fprintf (stderr, "Warning: overwriting note %d with note %d"
"(IC:%s)\n",
*notep, ic->note, ic->name);
}
*notep = ic->note;
}
}
return resolved;
}
static int
lookup_regindex (const char *name, int specifier)
{
switch (specifier)
{
case IA64_RS_ARX:
if (strstr (name, "[RSC]"))
return 16;
if (strstr (name, "[BSP]"))
return 17;
else if (strstr (name, "[BSPSTORE]"))
return 18;
else if (strstr (name, "[RNAT]"))
return 19;
else if (strstr (name, "[CCV]"))
return 32;
else if (strstr (name, "[ITC]"))
return 44;
else if (strstr (name, "[PFS]"))
return 64;
else if (strstr (name, "[LC]"))
return 65;
else if (strstr (name, "[EC]"))
return 66;
abort ();
case IA64_RS_CRX:
if (strstr (name, "[DCR]"))
return 0;
else if (strstr (name, "[ITM]"))
return 1;
else if (strstr (name, "[IVA]"))
return 2;
else if (strstr (name, "[PTA]"))
return 8;
else if (strstr (name, "[GPTA]"))
return 9;
else if (strstr (name, "[IPSR]"))
return 16;
else if (strstr (name, "[ISR]"))
return 17;
else if (strstr (name, "[IIP]"))
return 19;
else if (strstr (name, "[IFA]"))
return 20;
else if (strstr (name, "[ITIR]"))
return 21;
else if (strstr (name, "[IIPA]"))
return 22;
else if (strstr (name, "[IFS]"))
return 23;
else if (strstr (name, "[IIM]"))
return 24;
else if (strstr (name, "[IHA]"))
return 25;
else if (strstr (name, "[LID]"))
return 64;
else if (strstr (name, "[IVR]"))
return 65;
else if (strstr (name, "[TPR]"))
return 66;
else if (strstr (name, "[EOI]"))
return 67;
else if (strstr (name, "[ITV]"))
return 72;
else if (strstr (name, "[PMV]"))
return 73;
else if (strstr (name, "[CMCV]"))
return 74;
abort ();
case IA64_RS_PSR:
if (strstr (name, ".be"))
return 1;
else if (strstr (name, ".up"))
return 2;
else if (strstr (name, ".ac"))
return 3;
else if (strstr (name, ".mfl"))
return 4;
else if (strstr (name, ".mfh"))
return 5;
else if (strstr (name, ".ic"))
return 13;
else if (strstr (name, ".i"))
return 14;
else if (strstr (name, ".pk"))
return 15;
else if (strstr (name, ".dt"))
return 17;
else if (strstr (name, ".dfl"))
return 18;
else if (strstr (name, ".dfh"))
return 19;
else if (strstr (name, ".sp"))
return 20;
else if (strstr (name, ".pp"))
return 21;
else if (strstr (name, ".di"))
return 22;
else if (strstr (name, ".si"))
return 23;
else if (strstr (name, ".db"))
return 24;
else if (strstr (name, ".lp"))
return 25;
else if (strstr (name, ".tb"))
return 26;
else if (strstr (name, ".rt"))
return 27;
else if (strstr (name, ".cpl"))
return 32;
else if (strstr (name, ".rs"))
return 34;
else if (strstr (name, ".mc"))
return 35;
else if (strstr (name, ".it"))
return 36;
else if (strstr (name, ".id"))
return 37;
else if (strstr (name, ".da"))
return 38;
else if (strstr (name, ".dd"))
return 39;
else if (strstr (name, ".ss"))
return 40;
else if (strstr (name, ".ri"))
return 41;
else if (strstr (name, ".ed"))
return 43;
else if (strstr (name, ".bn"))
return 44;
else if (strstr (name, ".ia"))
return 45;
else
abort ();
default:
break;
}
return REG_NONE;
}
static int
lookup_specifier (const char *name)
{
if (strchr (name, '%'))
{
if (strstr (name, "AR[K%]") != NULL)
return IA64_RS_AR_K;
if (strstr (name, "AR[UNAT]") != NULL)
return IA64_RS_AR_UNAT;
if (strstr (name, "AR%, % in 8") != NULL)
return IA64_RS_AR;
if (strstr (name, "AR%, % in 48") != NULL)
return IA64_RS_ARb;
if (strstr (name, "BR%") != NULL)
return IA64_RS_BR;
if (strstr (name, "CR[IRR%]") != NULL)
return IA64_RS_CR_IRR;
if (strstr (name, "CR[LRR%]") != NULL)
return IA64_RS_CR_LRR;
if (strstr (name, "CR%") != NULL)
return IA64_RS_CR;
if (strstr (name, "FR%, % in 0") != NULL)
return IA64_RS_FR;
if (strstr (name, "FR%, % in 2") != NULL)
return IA64_RS_FRb;
if (strstr (name, "GR%") != NULL)
return IA64_RS_GR;
if (strstr (name, "PR%, % in 1 ") != NULL)
return IA64_RS_PR;
if (strstr (name, "PR%, % in 16 ") != NULL)
return IA64_RS_PRr;
fprintf (stderr, "Warning! Don't know how to specify %% dependency %s\n",
name);
}
else if (strchr (name, '#'))
{
if (strstr (name, "CPUID#") != NULL)
return IA64_RS_CPUID;
if (strstr (name, "DBR#") != NULL)
return IA64_RS_DBR;
if (strstr (name, "IBR#") != NULL)
return IA64_RS_IBR;
if (strstr (name, "MSR#") != NULL)
return IA64_RS_MSR;
if (strstr (name, "PKR#") != NULL)
return IA64_RS_PKR;
if (strstr (name, "PMC#") != NULL)
return IA64_RS_PMC;
if (strstr (name, "PMD#") != NULL)
return IA64_RS_PMD;
if (strstr (name, "RR#") != NULL)
return IA64_RS_RR;
fprintf (stderr, "Warning! Don't know how to specify # dependency %s\n",
name);
}
else if (strncmp (name, "AR[FPSR]", 8) == 0)
return IA64_RS_AR_FPSR;
else if (strncmp (name, "AR[", 3) == 0)
return IA64_RS_ARX;
else if (strncmp (name, "CR[", 3) == 0)
return IA64_RS_CRX;
else if (strncmp (name, "PSR.", 4) == 0)
return IA64_RS_PSR;
else if (strcmp (name, "InService*") == 0)
return IA64_RS_INSERVICE;
else if (strcmp (name, "GR0") == 0)
return IA64_RS_GR0;
else if (strcmp (name, "CFM") == 0)
return IA64_RS_CFM;
else if (strcmp (name, "PR63") == 0)
return IA64_RS_PR63;
else if (strcmp (name, "RSE") == 0)
return IA64_RS_RSE;
return IA64_RS_ANY;
}
void
print_dependency_table ()
{
int i, j;
if (debug)
{
for (i=0;i < iclen;i++)
{
if (ics[i]->is_class)
{
if (!ics[i]->nsubs)
{
fprintf (stderr, "Warning: IC:%s", ics[i]->name);
if (ics[i]->comment)
fprintf (stderr, "[%s]", ics[i]->comment);
fprintf (stderr, " has no terminals or sub-classes\n");
}
}
else
{
if (!ics[i]->terminal_resolved && !ics[i]->orphan)
{
fprintf(stderr, "Warning: no insns mapped directly to "
"terminal IC %s", ics[i]->name);
if (ics[i]->comment)
fprintf(stderr, "[%s] ", ics[i]->comment);
fprintf(stderr, "\n");
}
}
}
for (i=0;i < iclen;i++)
{
if (ics[i]->orphan)
{
mark_used (ics[i], 1);
fprintf (stderr, "Warning: class %s is defined but not used\n",
ics[i]->name);
}
}
if (debug > 1) for (i=0;i < rdepslen;i++)
{
static const char *mode_str[] = { "RAW", "WAW", "WAR" };
if (rdeps[i]->total_chks == 0)
{
fprintf (stderr, "Warning: rsrc %s (%s) has no chks%s\n",
rdeps[i]->name, mode_str[rdeps[i]->mode],
rdeps[i]->total_regs ? "" : " or regs");
}
else if (rdeps[i]->total_regs == 0)
{
fprintf (stderr, "Warning: rsrc %s (%s) has no regs\n",
rdeps[i]->name, mode_str[rdeps[i]->mode]);
}
}
}
/* the dependencies themselves */
printf ("static const struct ia64_dependency\ndependencies[] = {\n");
for (i=0;i < rdepslen;i++)
{
/* '%', '#', AR[], CR[], or PSR. indicates we need to specify the actual
resource used */
int specifier = lookup_specifier (rdeps[i]->name);
int regindex = lookup_regindex (rdeps[i]->name, specifier);
printf (" { \"%s\", %d, %d, %d, %d, ",
rdeps[i]->name, specifier,
(int)rdeps[i]->mode, (int)rdeps[i]->semantics, regindex);
if (rdeps[i]->semantics == IA64_DVS_OTHER)
printf ("\"%s\", ", rdeps[i]->extra);
else
printf ("NULL, ");
printf("},\n");
}
printf ("};\n\n");
/* and dependency lists */
for (i=0;i < dlistlen;i++)
{
int len = 2;
printf ("static const short dep%d[] = {\n ", i);
for (j=0;j < dlists[i]->len; j++)
{
len += printf ("%d, ", dlists[i]->deps[j]);
if (len > 75)
{
printf("\n ");
len = 2;
}
}
printf ("\n};\n\n");
}
/* and opcode dependency list */
printf ("#define NELS(X) (sizeof(X)/sizeof(X[0]))\n");
printf ("static const struct ia64_opcode_dependency\n");
printf ("op_dependencies[] = {\n");
for (i=0;i < opdeplen;i++)
{
printf (" { ");
if (opdeps[i]->chk == -1)
printf ("0, NULL, ");
else
printf ("NELS(dep%d), dep%d, ", opdeps[i]->chk, opdeps[i]->chk);
if (opdeps[i]->reg == -1)
printf ("0, NULL, ");
else
printf ("NELS(dep%d), dep%d, ", opdeps[i]->reg, opdeps[i]->reg);
printf ("},\n");
}
printf ("};\n\n");
}
/* Add STR to the string table. */
static struct string_entry *
insert_string (str)
char *str;
{
int start = 0, end = strtablen;
int i, x;
if (strtablen == strtabtotlen)
{
strtabtotlen += 20;
string_table = (struct string_entry **)
xrealloc (string_table,
sizeof (struct string_entry **) * strtabtotlen);
}
if (strtablen == 0)
{
strtablen = 1;
string_table[0] = tmalloc (struct string_entry);
string_table[0]->s = xstrdup (str);
string_table[0]->num = 0;
return string_table[0];
}
if (strcmp (str, string_table[strtablen - 1]->s) > 0)
{
i = end;
}
else if (strcmp (str, string_table[0]->s) < 0)
{
i = 0;
}
else
{
while (1)
{
int c;
i = (start + end) / 2;
c = strcmp (str, string_table[i]->s);
if (c < 0)
{
end = i - 1;
}
else if (c == 0)
{
return string_table[i];
}
else
{
start = i + 1;
}
if (start > end)
{
break;
}
}
}
for (; i > 0 && i < strtablen; i--)
{
if (strcmp (str, string_table[i - 1]->s) > 0)
{
break;
}
}
for (; i < strtablen; i++)
{
if (strcmp (str, string_table[i]->s) < 0)
{
break;
}
}
for (x = strtablen - 1; x >= i; x--)
{
string_table[x + 1] = string_table[x];
string_table[x + 1]->num = x + 1;
}
string_table[i] = tmalloc (struct string_entry);
string_table[i]->s = xstrdup (str);
string_table[i]->num = i;
strtablen++;
return string_table[i];
}
struct bittree *
make_bittree_entry ()
{
struct bittree *res = tmalloc (struct bittree);
res->disent = NULL;
res->bits[0] = NULL;
res->bits[1] = NULL;
res->bits[2] = NULL;
res->skip_flag = 0;
res->bits_to_skip = 0;
return res;
}
struct disent *
add_dis_table_ent (which, insn, order, completer_index)
struct disent *which;
int insn;
int order;
int completer_index;
{
int ci = 0;
struct disent *ent;
if (which != NULL)
{
ent = which;
ent->nextcnt++;
while (ent->nexte != NULL)
{
ent = ent->nexte;
}
ent = (ent->nexte = tmalloc (struct disent));
}
else
{
ent = tmalloc (struct disent);
ent->next_ent = disinsntable;
disinsntable = ent;
which = ent;
}
ent->nextcnt = 0;
ent->nexte = NULL;
ent->insn = insn;
ent->priority = order;
while (completer_index != 1)
{
ci = (ci << 1) | (completer_index & 1);
completer_index >>= 1;
}
ent->completer_index = ci;
return which;
}
void
finish_distable ()
{
struct disent *ent = disinsntable;
struct disent *prev = ent;
ent->ournum = 32768;
while ((ent = ent->next_ent) != NULL)
{
ent->ournum = prev->ournum + prev->nextcnt + 1;
prev = ent;
}
}
void
insert_bit_table_ent (curr_ent, bit, opcode, mask,
opcodenum, order, completer_index)
struct bittree *curr_ent;
int bit;
ia64_insn opcode;
ia64_insn mask;
int opcodenum;
int order;
int completer_index;
{
ia64_insn m;
int b;
struct bittree *next;
if (bit == -1)
{
struct disent *nent = add_dis_table_ent (curr_ent->disent,
opcodenum, order,
completer_index);
curr_ent->disent = nent;
return;
}
m = ((ia64_insn) 1) << bit;
if (mask & m)
{
b = (opcode & m) ? 1 : 0;
}
else
{
b = 2;
}
next = curr_ent->bits[b];
if (next == NULL)
{
next = make_bittree_entry ();
curr_ent->bits[b] = next;
}
insert_bit_table_ent (next, bit - 1, opcode, mask, opcodenum, order,
completer_index);
}
void
add_dis_entry (first, opcode, mask, opcodenum, ent, completer_index)
struct bittree *first;
ia64_insn opcode;
ia64_insn mask;
int opcodenum;
struct completer_entry *ent;
int completer_index;
{
if (completer_index & (1 << 20))
{
abort ();
}
while (ent != NULL)
{
ia64_insn newopcode = (opcode & (~ ent->mask)) | ent->bits;
add_dis_entry (first, newopcode, mask, opcodenum, ent->addl_entries,
(completer_index << 1) | 1);
if (ent->is_terminal)
{
insert_bit_table_ent (bittree, 40, newopcode, mask,
opcodenum, opcode_count - ent->order - 1,
(completer_index << 1) | 1);
}
completer_index <<= 1;
ent = ent->alternative;
}
}
/* This optimization pass combines multiple "don't care" nodes. */
void
compact_distree (ent)
struct bittree *ent;
{
#define IS_SKIP(ent) \
((ent->bits[2] !=NULL) \
&& (ent->bits[0] == NULL && ent->bits[1] == NULL && ent->skip_flag == 0))
int bitcnt = 0;
struct bittree *nent = ent;
int x;
while (IS_SKIP (nent))
{
bitcnt++;
nent = nent->bits[2];
}
if (bitcnt)
{
struct bittree *next = ent->bits[2];
ent->bits[0] = nent->bits[0];
ent->bits[1] = nent->bits[1];
ent->bits[2] = nent->bits[2];
ent->disent = nent->disent;
ent->skip_flag = 1;
ent->bits_to_skip = bitcnt;
while (next != nent)
{
struct bittree *b = next;
next = next->bits[2];
free (b);
}
free (nent);
}
for (x = 0; x < 3; x++)
{
struct bittree *i = ent->bits[x];
if (i != NULL)
{
compact_distree (i);
}
}
}
static unsigned char *insn_list;
static int insn_list_len = 0;
static int tot_insn_list_len = 0;
/* Generate the disassembler state machine corresponding to the tree
in ENT. */
void
gen_dis_table (ent)
struct bittree *ent;
{
int x;
int our_offset = insn_list_len;
int bitsused = 5;
int totbits = bitsused;
int needed_bytes;
int zero_count = 0;
int zero_dest = 0; /* initialize this with 0 to keep gcc quiet... */
/* If this is a terminal entry, there's no point in skipping any
bits. */
if (ent->skip_flag && ent->bits[0] == NULL && ent->bits[1] == NULL &&
ent->bits[2] == NULL)
{
if (ent->disent == NULL)
{
abort ();
}
else
{
ent->skip_flag = 0;
}
}
/* Calculate the amount of space needed for this entry, or at least
a conservatively large approximation. */
if (ent->skip_flag)
{
totbits += 5;
}
for (x = 1; x < 3; x++)
{
if (ent->bits[x] != NULL)
{
totbits += 16;
}
}
if (ent->disent != NULL)
{
if (ent->bits[2] != NULL)
{
abort ();
}
totbits += 16;
}
/* Now allocate the space. */
needed_bytes = (totbits + 7) / 8;
if ((needed_bytes + insn_list_len) > tot_insn_list_len)
{
tot_insn_list_len += 256;
insn_list = (char *) xrealloc (insn_list, tot_insn_list_len);
}
our_offset = insn_list_len;
insn_list_len += needed_bytes;
memset (insn_list + our_offset, 0, needed_bytes);
/* Encode the skip entry by setting bit 6 set in the state op field,
and store the # of bits to skip immediately after. */
if (ent->skip_flag)
{
bitsused += 5;
insn_list[our_offset + 0] |= 0x40 | ((ent->bits_to_skip >> 2) & 0xf);
insn_list[our_offset + 1] |= ((ent->bits_to_skip & 3) << 6);
}
#define IS_ONLY_IFZERO(ENT) \
((ENT)->bits[0] != NULL && (ENT)->bits[1] == NULL && (ENT)->bits[2] == NULL \
&& (ENT)->disent == NULL && (ENT)->skip_flag == 0)
/* Store an "if (bit is zero)" instruction by setting bit 7 in the
state op field. */
if (ent->bits[0] != NULL)
{
struct bittree *nent = ent->bits[0];
zero_count = 0;
insn_list[our_offset] |= 0x80;
/* We can encode sequences of multiple "if (bit is zero)" tests
by storing the # of zero bits to check in the lower 3 bits of
the instruction. However, this only applies if the state
solely tests for a zero bit. */
if (IS_ONLY_IFZERO (ent))
{
while (IS_ONLY_IFZERO (nent) && zero_count < 7)
{
nent = nent->bits[0];
zero_count++;
}
insn_list[our_offset + 0] |= zero_count;
}
zero_dest = insn_list_len;
gen_dis_table (nent);
}
/* Now store the remaining tests. We also handle a sole "termination
entry" by storing it as an "any bit" test. */
for (x = 1; x < 3; x++)
{
if (ent->bits[x] != NULL || (x == 2 && ent->disent != NULL))
{
struct bittree *i = ent->bits[x];
int idest;
int currbits = 15;
if (i != NULL)
{
/* If the instruction being branched to only consists of
a termination entry, use the termination entry as the
place to branch to instead. */
if (i->bits[0] == NULL && i->bits[1] == NULL
&& i->bits[2] == NULL && i->disent != NULL)
{
idest = i->disent->ournum;
i = NULL;
}
else
{
idest = insn_list_len - our_offset;
}
}
else
{
idest = ent->disent->ournum;
}
/* If the destination offset for the if (bit is 1) test is less
than 256 bytes away, we can store it as 8-bits instead of 16;
the instruction has bit 5 set for the 16-bit address, and bit
4 for the 8-bit address. Since we've already allocated 16
bits for the address we need to deallocate the space.
Note that branchings within the table are relative, and
there are no branches that branch past our instruction yet
so we do not need to adjust any other offsets. */
if (x == 1)
{
if (idest <= 256)
{
int start = our_offset + bitsused / 8 + 1;
memmove (insn_list + start,
insn_list + start + 1,
insn_list_len - (start + 1));
currbits = 7;
totbits -= 8;
needed_bytes--;
insn_list_len--;
insn_list[our_offset] |= 0x10;
idest--;
}
else
{
insn_list[our_offset] |= 0x20;
}
}
else
{
/* An instruction which solely consists of a termination
marker and whose disassembly name index is < 4096
can be stored in 16 bits. The encoding is slightly
odd; the upper 4 bits of the instruction are 0x3, and
bit 3 loses its normal meaning. */
if (ent->bits[0] == NULL && ent->bits[1] == NULL
&& ent->bits[2] == NULL && ent->skip_flag == 0
&& ent->disent != NULL
&& ent->disent->ournum < (32768 + 4096))
{
int start = our_offset + bitsused / 8 + 1;
memmove (insn_list + start,
insn_list + start + 1,
insn_list_len - (start + 1));
currbits = 11;
totbits -= 5;
bitsused--;
needed_bytes--;
insn_list_len--;
insn_list[our_offset] |= 0x30;
idest &= ~32768;
}
else
{
insn_list[our_offset] |= 0x08;
}
}
if (debug)
{
int id = idest;
if (i == NULL)
{
id |= 32768;
}
else if (! (id & 32768))
{
id += our_offset;
}
if (x == 1)
{
printf ("%d: if (1) goto %d\n", our_offset, id);
}
else
{
printf ("%d: try %d\n", our_offset, id);
}
}
/* Store the address of the entry being branched to. */
while (currbits >= 0)
{
char *byte = insn_list + our_offset + bitsused / 8;
if (idest & (1 << currbits))
{
*byte |= (1 << (7 - (bitsused % 8)));
}
bitsused++;
currbits--;
}
/* Now generate the states for the entry being branched to. */
if (i != NULL)
{
gen_dis_table (i);
}
}
}
if (debug)
{
if (ent->skip_flag)
{
printf ("%d: skipping %d\n", our_offset, ent->bits_to_skip);
}
if (ent->bits[0] != NULL)
{
printf ("%d: if (0:%d) goto %d\n", our_offset, zero_count + 1,
zero_dest);
}
}
if (bitsused != totbits)
{
abort ();
}
}
void
print_dis_table ()
{
int x;
struct disent *cent = disinsntable;
printf ("static const char dis_table[] = {\n");
for (x = 0; x < insn_list_len; x++)
{
if ((x > 0) && ((x % 12) == 0))
{
printf ("\n");
}
printf ("0x%02x, ", insn_list[x]);
}
printf ("\n};\n\n");
printf ("static const struct ia64_dis_names ia64_dis_names[] = {\n");
while (cent != NULL)
{
struct disent *ent = cent;
while (ent != NULL)
{
printf ("{ 0x%x, %d, %d, %d },\n", ent->completer_index,
ent->insn, (ent->nexte != NULL ? 1 : 0),
ent->priority);
ent = ent->nexte;
}
cent = cent->next_ent;
}
printf ("};\n\n");
}
void
generate_disassembler ()
{
int i;
bittree = make_bittree_entry ();
for (i=0; i < otlen;i++)
{
struct main_entry *ptr = ordered_table[i];
if (ptr->opcode->type != IA64_TYPE_DYN)
{
add_dis_entry (bittree,
ptr->opcode->opcode, ptr->opcode->mask,
ptr->main_index,
ptr->completers, 1);
}
}
compact_distree (bittree);
finish_distable ();
gen_dis_table (bittree);
print_dis_table ();
}
void
print_string_table ()
{
int x;
char lbuf[80], buf[80];
int blen = 0;
printf ("static const char *ia64_strings[] = {\n");
lbuf[0] = '\0';
for (x = 0; x < strtablen; x++)
{
int len;
if (strlen (string_table[x]->s) > 75)
{
abort ();
}
sprintf (buf, " \"%s\",", string_table[x]->s);
len = strlen (buf);
if ((blen + len) > 75)
{
printf (" %s\n", lbuf);
lbuf[0] = '\0';
blen = 0;
}
strcat (lbuf, buf);
blen += len;
}
if (blen > 0)
{
printf (" %s\n", lbuf);
}
printf ("};\n\n");
}
static struct completer_entry **glist;
static int glistlen = 0;
static int glisttotlen = 0;
/* If the completer trees ENT1 and ENT2 are equal, return 1. */
int
completer_entries_eq (ent1, ent2)
struct completer_entry *ent1, *ent2;
{
while (ent1 != NULL && ent2 != NULL)
{
if (ent1->name->num != ent2->name->num
|| ent1->bits != ent2->bits
|| ent1->mask != ent2->mask
|| ent1->is_terminal != ent2->is_terminal
|| ent1->dependencies != ent2->dependencies
|| ent1->order != ent2->order)
{
return 0;
}
if (! completer_entries_eq (ent1->addl_entries, ent2->addl_entries))
{
return 0;
}
ent1 = ent1->alternative;
ent2 = ent2->alternative;
}
return ent1 == ent2;
}
/* Insert ENT into the global list of completers and return it. If an
equivalent entry (according to completer_entries_eq) already exists,
it is returned instead. */
struct completer_entry *
insert_gclist (ent)
struct completer_entry *ent;
{
if (ent != NULL)
{
int i;
int x;
int start = 0, end;
ent->addl_entries = insert_gclist (ent->addl_entries);
ent->alternative = insert_gclist (ent->alternative);
i = glistlen / 2;
end = glistlen;
if (glisttotlen == glistlen)
{
glisttotlen += 20;
glist = (struct completer_entry **)
xrealloc (glist, sizeof (struct completer_entry *) * glisttotlen);
}
if (glistlen == 0)
{
glist[0] = ent;
glistlen = 1;
return ent;
}
if (ent->name->num < glist[0]->name->num)
{
i = 0;
}
else if (ent->name->num > glist[end - 1]->name->num)
{
i = end;
}
else
{
int c;
while (1)
{
i = (start + end) / 2;
c = ent->name->num - glist[i]->name->num;
if (c < 0)
{
end = i - 1;
}
else if (c == 0)
{
while (i > 0
&& ent->name->num == glist[i - 1]->name->num)
{
i--;
}
break;
}
else
{
start = i + 1;
}
if (start > end)
{
break;
}
}
if (c == 0)
{
while (i < glistlen)
{
if (ent->name->num != glist[i]->name->num)
{
break;
}
if (completer_entries_eq (ent, glist[i]))
{
return glist[i];
}
i++;
}
}
}
for (; i > 0 && i < glistlen; i--)
{
if (ent->name->num >= glist[i - 1]->name->num)
{
break;
}
}
for (; i < glistlen; i++)
{
if (ent->name->num < glist[i]->name->num)
{
break;
}
}
for (x = glistlen - 1; x >= i; x--)
{
glist[x + 1] = glist[x];
}
glist[i] = ent;
glistlen++;
}
return ent;
}
static int
get_prefix_len (name)
const char *name;
{
char *c;
if (name[0] == '\0')
{
return 0;
}
c = strchr (name, '.');
if (c != NULL)
{
return c - name;
}
else
{
return strlen (name);
}
}
static void
compute_completer_bits (ment, ent)
struct main_entry *ment;
struct completer_entry *ent;
{
while (ent != NULL)
{
compute_completer_bits (ment, ent->addl_entries);
if (ent->is_terminal)
{
ia64_insn mask = 0;
ia64_insn our_bits = ent->bits;
struct completer_entry *p = ent->parent;
ia64_insn p_bits;
int x;
while (p != NULL && ! p->is_terminal)
{
p = p->parent;
}
if (p != NULL)
{
p_bits = p->bits;
}
else
{
p_bits = ment->opcode->opcode;
}
for (x = 0; x < 64; x++)
{
ia64_insn m = ((ia64_insn) 1) << x;
if ((p_bits & m) != (our_bits & m))
{
mask |= m;
}
else
{
our_bits &= ~m;
}
}
ent->bits = our_bits;
ent->mask = mask;
}
else
{
ent->bits = 0;
ent->mask = 0;
}
ent = ent->alternative;
}
}
/* Find identical completer trees that are used in different
instructions and collapse their entries. */
void
collapse_redundant_completers ()
{
struct main_entry *ptr;
int x;
for (ptr = maintable; ptr != NULL; ptr = ptr->next)
{
if (ptr->completers == NULL)
{
abort ();
}
compute_completer_bits (ptr, ptr->completers);
ptr->completers = insert_gclist (ptr->completers);
}
/* The table has been finalized, now number the indexes. */
for (x = 0; x < glistlen; x++)
{
glist[x]->num = x;
}
}
/* attach two lists of dependencies to each opcode.
1) all resources which, when already marked in use, conflict with this
opcode (chks)
2) all resources which must be marked in use when this opcode is used
(regs)
*/
int
insert_opcode_dependencies (opc, cmp)
struct ia64_opcode *opc;
struct completer_entry *cmp ATTRIBUTE_UNUSED;
{
/* note all resources which point to this opcode. rfi has the most chks
(79) and cmpxchng has the most regs (54) so 100 here should be enough */
int i;
int nregs = 0;
unsigned short regs[256];
int nchks = 0;
unsigned short chks[256];
/* flag insns for which no class matched; there should be none */
int no_class_found = 1;
for (i=0;i < rdepslen;i++)
{
struct rdep *rs = rdeps[i];
int j;
if (strcmp (opc->name, "cmp.eq.and") == 0
&& strncmp (rs->name, "PR%", 3) == 0
&& rs->mode == 1)
no_class_found = 99;
for (j=0; j < rs->nregs;j++)
{
int ic_note = 0;
if (in_iclass (opc, ics[rs->regs[j]], NULL, NULL, &ic_note))
{
/* We can ignore ic_note 11 for non PR resources */
if (ic_note == 11 && strncmp (rs->name, "PR", 2) != 0)
ic_note = 0;
if (ic_note != 0 && rs->regnotes[j] != 0
&& ic_note != rs->regnotes[j]
&& !(ic_note == 11 && rs->regnotes[j] == 1))
fprintf (stderr, "Warning: IC note %d in opcode %s (IC:%s)"
" conflicts with resource %s note %d\n",
ic_note, opc->name, ics[rs->regs[j]]->name,
rs->name, rs->regnotes[j]);
/* Instruction class notes override resource notes.
So far, only note 11 applies to an IC instead of a resource,
and note 11 implies note 1.
*/
if (ic_note)
regs[nregs++] = RDEP(ic_note, i);
else
regs[nregs++] = RDEP(rs->regnotes[j], i);
no_class_found = 0;
++rs->total_regs;
}
}
for (j=0;j < rs->nchks;j++)
{
int ic_note = 0;
if (in_iclass (opc, ics[rs->chks[j]], NULL, NULL, &ic_note))
{
/* We can ignore ic_note 11 for non PR resources */
if (ic_note == 11 && strncmp (rs->name, "PR", 2) != 0)
ic_note = 0;
if (ic_note != 0 && rs->chknotes[j] != 0
&& ic_note != rs->chknotes[j]
&& !(ic_note == 11 && rs->chknotes[j] == 1))
fprintf (stderr, "Warning: IC note %d for opcode %s (IC:%s)"
" conflicts with resource %s note %d\n",
ic_note, opc->name, ics[rs->chks[j]]->name,
rs->name, rs->chknotes[j]);
if (ic_note)
chks[nchks++] = RDEP(ic_note, i);
else
chks[nchks++] = RDEP(rs->chknotes[j], i);
no_class_found = 0;
++rs->total_chks;
}
}
}
if (no_class_found)
fprintf (stderr, "Warning: opcode %s has no class (ops %d %d %d)\n",
opc->name,
opc->operands[0], opc->operands[1], opc->operands[2]);
return insert_dependencies (nchks, chks, nregs, regs);
}
void
insert_completer_entry (opc, tabent, order)
struct ia64_opcode *opc;
struct main_entry *tabent;
int order;
{
struct completer_entry **ptr = &tabent->completers;
struct completer_entry *parent = NULL;
char pcopy[129], *prefix;
int at_end = 0;
if (strlen (opc->name) > 128)
{
abort ();
}
strcpy (pcopy, opc->name);
prefix = pcopy + get_prefix_len (pcopy);
if (prefix[0] != '\0')
{
prefix++;
}
while (! at_end)
{
int need_new_ent = 1;
int plen = get_prefix_len (prefix);
struct string_entry *sent;
at_end = (prefix[plen] == '\0');
prefix[plen] = '\0';
sent = insert_string (prefix);
while (*ptr != NULL)
{
int cmpres = sent->num - (*ptr)->name->num;
if (cmpres == 0)
{
need_new_ent = 0;
break;
}
else
{
ptr = &((*ptr)->alternative);
}
}
if (need_new_ent)
{
struct completer_entry *nent = tmalloc (struct completer_entry);
nent->name = sent;
nent->parent = parent;
nent->addl_entries = NULL;
nent->alternative = *ptr;
*ptr = nent;
nent->is_terminal = 0;
nent->dependencies = -1;
}
if (! at_end)
{
parent = *ptr;
ptr = &((*ptr)->addl_entries);
prefix += plen + 1;
}
}
if ((*ptr)->is_terminal)
{
abort ();
}
(*ptr)->is_terminal = 1;
(*ptr)->mask = (ia64_insn)-1;
(*ptr)->bits = opc->opcode;
(*ptr)->dependencies = insert_opcode_dependencies (opc, *ptr);
(*ptr)->order = order;
}
void
print_completer_entry (ent)
struct completer_entry *ent;
{
int moffset = 0;
ia64_insn mask = ent->mask, bits = ent->bits;
if (mask != 0)
{
while (! (mask & 1))
{
moffset++;
mask = mask >> 1;
bits = bits >> 1;
}
if (bits & 0xffffffff00000000LL)
{
abort ();
}
}
printf (" { 0x%x, 0x%x, %d, %d, %d, %d, %d, %d },\n",
(int)bits,
(int)mask,
ent->name->num,
ent->alternative != NULL ? ent->alternative->num : -1,
ent->addl_entries != NULL ? ent->addl_entries->num : -1,
moffset,
ent->is_terminal ? 1 : 0,
ent->dependencies);
}
void
print_completer_table ()
{
int x;
printf ("static const struct ia64_completer_table\ncompleter_table[] = {\n");
for (x = 0; x < glistlen; x++)
{
print_completer_entry (glist[x]);
}
printf ("};\n\n");
}
int
opcodes_eq (opc1, opc2)
struct ia64_opcode *opc1;
struct ia64_opcode *opc2;
{
int x;
int plen1, plen2;
if ((opc1->mask != opc2->mask) || (opc1->type != opc2->type)
|| (opc1->num_outputs != opc2->num_outputs)
|| (opc1->flags != opc2->flags))
{
return 0;
}
for (x = 0; x < 5; x++)
{
if (opc1->operands[x] != opc2->operands[x])
{
return 0;
}
}
plen1 = get_prefix_len (opc1->name);
plen2 = get_prefix_len (opc2->name);
if (plen1 == plen2 && (memcmp (opc1->name, opc2->name, plen1) == 0))
{
return 1;
}
return 0;
}
void
add_opcode_entry (opc)
struct ia64_opcode *opc;
{
struct main_entry **place;
struct string_entry *name;
char prefix[129];
int found_it = 0;
if (strlen (opc->name) > 128)
{
abort ();
}
place = &maintable;
strcpy (prefix, opc->name);
prefix[get_prefix_len (prefix)] = '\0';
name = insert_string (prefix);
/* Walk the list of opcode table entries. If it's a new
instruction, allocate and fill in a new entry. Note
the main table is alphabetical by opcode name. */
while (*place != NULL)
{
if ((*place)->name->num == name->num
&& opcodes_eq ((*place)->opcode, opc))
{
found_it = 1;
break;
}
if ((*place)->name->num > name->num)
{
break;
}
place = &((*place)->next);
}
if (! found_it)
{
struct main_entry *nent = tmalloc (struct main_entry);
nent->name = name;
nent->opcode = opc;
nent->next = *place;
nent->completers = 0;
*place = nent;
if (otlen == ottotlen)
{
ottotlen += 20;
ordered_table = (struct main_entry **)
xrealloc (ordered_table, sizeof (struct main_entry *) * ottotlen);
}
ordered_table[otlen++] = nent;
}
insert_completer_entry (opc, *place, opcode_count++);
}
void
print_main_table ()
{
struct main_entry *ptr = maintable;
int index = 0;
printf ("static const struct ia64_main_table\nmain_table[] = {\n");
while (ptr != NULL)
{
printf (" { %d, %d, %d, 0x",
ptr->name->num,
ptr->opcode->type,
ptr->opcode->num_outputs);
fprintf_vma (stdout, ptr->opcode->opcode);
printf ("ull, 0x");
fprintf_vma (stdout, ptr->opcode->mask);
printf ("ull, { %d, %d, %d, %d, %d }, 0x%x, %d, },\n",
ptr->opcode->operands[0],
ptr->opcode->operands[1],
ptr->opcode->operands[2],
ptr->opcode->operands[3],
ptr->opcode->operands[4],
ptr->opcode->flags,
ptr->completers->num);
ptr->main_index = index++;
ptr = ptr->next;
}
printf ("};\n\n");
}
void
shrink (table)
struct ia64_opcode *table;
{
int curr_opcode;
for (curr_opcode = 0; table[curr_opcode].name != NULL; curr_opcode++)
{
add_opcode_entry (table + curr_opcode);
}
}
int
main (argc, argv)
int argc;
char **argv ATTRIBUTE_UNUSED;
{
if (argc > 1)
{
debug = 1;
}
load_insn_classes();
load_dependencies();
shrink (ia64_opcodes_a);
shrink (ia64_opcodes_b);
shrink (ia64_opcodes_f);
shrink (ia64_opcodes_i);
shrink (ia64_opcodes_m);
shrink (ia64_opcodes_x);
shrink (ia64_opcodes_d);
collapse_redundant_completers ();
printf ("/* This file is automatically generated by ia64-gen. Do not edit! */\n");
print_string_table ();
print_dependency_table ();
print_completer_table ();
print_main_table ();
generate_disassembler ();
exit (0);
}