/* -*- mode: C; c-basic-offset: 3; -*- */
/*---------------------------------------------------------------*/
/*--- begin host_s390_disasm.c ---*/
/*---------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright IBM Corp. 2010-2011
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., 51 Franklin Street, Fifth Floor, Boston, MA
02110-1301, USA.
The GNU General Public License is contained in the file COPYING.
*/
/* Contributed by Florian Krohm */
#include <stdarg.h>
#include "libvex_basictypes.h"
#include "main_util.h" // vassert
#include "main_globals.h" // vex_traceflags
#include "host_s390_disasm.h"
/* The format that is used to write out a mnemonic.
These should be declared as 'const HChar' but vex_printf needs
to be changed for that first */
static HChar s390_mnm_fmt[] = "%-8s";
/* Return the name of a general purpose register for dis-assembly purposes. */
static const HChar *
gpr_operand(UInt archreg)
{
static const HChar names[16][5] = {
"%r0", "%r1", "%r2", "%r3",
"%r4", "%r5", "%r6", "%r7",
"%r8", "%r9", "%r10", "%r11",
"%r12", "%r13", "%r14", "%r15",
};
vassert(archreg < 16);
return names[archreg];
}
/* Return the name of a floating point register for dis-assembly purposes. */
static const HChar *
fpr_operand(UInt archreg)
{
static const HChar names[16][5] = {
"%f0", "%f1", "%f2", "%f3",
"%f4", "%f5", "%f6", "%f7",
"%f8", "%f9", "%f10", "%f11",
"%f12", "%f13", "%f14", "%f15",
};
vassert(archreg < 16);
return names[archreg];
}
/* Return the name of an access register for dis-assembly purposes. */
static const HChar *
ar_operand(UInt archreg)
{
static const HChar names[16][5] = {
"%a0", "%a1", "%a2", "%a3",
"%a4", "%a5", "%a6", "%a7",
"%a8", "%a9", "%a10", "%a11",
"%a12", "%a13", "%a14", "%a15",
};
vassert(archreg < 16);
return names[archreg];
}
/* Build and return the extended mnemonic for the compare and branch
opcodes as introduced by z10. See also the opcodes in file
opcodes/s390-opc.txt (from binutils) that have a '$' in their name. */
static const HChar *
cab_operand(const HChar *base, UInt mask)
{
HChar *to;
const HChar *from;
static HChar buf[10]; /* Maximum is 6 + 2 */
static HChar *suffix[] = {
"", "h", "l", "ne", "e", "nl", "nh", ""
};
/* strcpy(buf, from); */
for (from = base, to = buf; *from; ++from, ++to) {
*to = *from;
}
/* strcat(buf, suffix); */
for (from = suffix[mask >> 1]; *from; ++from, ++to) {
*to = *from;
}
*to = '\0';
return buf;
}
/* Common function used to construct a mnemonic based on a condition code
mask. */
static const HChar *
construct_mnemonic(const HChar *prefix, const HChar *suffix, UInt mask)
{
HChar *to;
const HChar *from;
static HChar buf[10];
static HChar mask_id[16][4] = {
"", /* 0 -> unused */
"o", "h", "nle", "l", "nhe", "lh", "ne",
"e", "nlh", "he", "nl", "le", "nh", "no",
"" /* 15 -> unused */
};
/* Guard against buffer overflow */
vassert(vex_strlen(prefix) + vex_strlen(suffix) + sizeof mask_id[0] <= sizeof buf);
/* strcpy(buf, prefix); */
for (from = prefix, to = buf; *from; ++from, ++to) {
*to = *from;
}
/* strcat(buf, mask_id); */
for (from = mask_id[mask]; *from; ++from, ++to) {
*to = *from;
}
/* strcat(buf, suffix); */
for (from = suffix; *from; ++from, ++to) {
*to = *from;
}
*to = '\0';
return buf;
}
/* Return the special mnemonic for the BCR opcode */
static const HChar *
bcr_operand(UInt m1)
{
if (m1 == 0) return "nopr";
if (m1 == 15) return "br";
return construct_mnemonic("b", "r", m1);
}
/* Return the special mnemonic for the BC opcode */
static const HChar *
bc_operand(UInt m1)
{
if (m1 == 0) return "nop";
if (m1 == 15) return "b";
return construct_mnemonic("b", "", m1);
}
/* Return the special mnemonic for the BRC opcode */
static const HChar *
brc_operand(UInt m1)
{
if (m1 == 0) return "brc";
if (m1 == 15) return "j";
return construct_mnemonic("j", "", m1);
}
/* Return the special mnemonic for the BRCL opcode */
static const HChar *
brcl_operand(UInt m1)
{
if (m1 == 0) return "brcl";
if (m1 == 15) return "jg";
return construct_mnemonic("jg", "", m1);
}
/* Return the special mnemonic for a conditional load/store opcode */
static const HChar *
cls_operand(Int kind, UInt mask)
{
HChar *prefix;
switch (kind) {
case S390_XMNM_LOCR: prefix = "locr"; break;
case S390_XMNM_LOCGR: prefix = "locgr"; break;
case S390_XMNM_LOC: prefix = "loc"; break;
case S390_XMNM_LOCG: prefix = "locg"; break;
case S390_XMNM_STOC: prefix = "stoc"; break;
case S390_XMNM_STOCG: prefix = "stocg"; break;
default:
vpanic("cls_operand");
}
return construct_mnemonic(prefix, "", mask);
}
/* An operand with a base register, an index register, and a displacement.
If the displacement is signed, the rightmost 20 bit of D need to be
sign extended */
static HChar *
dxb_operand(HChar *p, UInt d, UInt x, UInt b, Bool displacement_is_signed)
{
if (displacement_is_signed) {
Int displ = ((Int)d << 12) >> 12; /* sign extend */
p += vex_sprintf(p, "%d", displ);
} else {
p += vex_sprintf(p, "%u", d);
}
if (x != 0) {
p += vex_sprintf(p, "(%s", gpr_operand(x));
if (b != 0) {
p += vex_sprintf(p, ",%s", gpr_operand(b));
}
p += vex_sprintf(p, ")");
} else {
if (b != 0) {
p += vex_sprintf(p, "(%s)", gpr_operand(b));
}
}
return p;
}
/* An operand with base register, unsigned length, and a 12-bit
unsigned displacement */
static HChar *
udlb_operand(HChar *p, UInt d, UInt length, UInt b)
{
p += vex_sprintf(p, "%u", d);
p += vex_sprintf(p, "(%u", length + 1); // actual length is +1
if (b != 0) {
p += vex_sprintf(p, ",%s", gpr_operand(b));
}
p += vex_sprintf(p, ")");
return p;
}
/* The first argument is the command that says how to write the disassembled
insn. It is understood that the mnemonic comes first and that arguments
are separated by a ','. The command holds the arguments. Each argument is
encoded using a 4-bit S390_ARG_xyz value. The first argument is placed
in the least significant bits of the command and so on. There are at most
5 arguments in an insn and a sentinel (S390_ARG_DONE) is needed to identify
the end of the argument list. 6 * 4 = 24 bits are required for the
command. */
void
s390_disasm(UInt command, ...)
{
va_list args;
unsigned argkind;
HChar buf[128]; /* holds the disassembled insn */
HChar *p;
HChar separator;
Int mask_suffix = -1;
va_start(args, command);
p = buf;
separator = 0;
while (42) {
argkind = command & 0xF;
command >>= 4;
if (argkind == S390_ARG_DONE) goto done;
if (argkind == S390_ARG_CABM) separator = 0; /* optional */
/* Write out the separator */
if (separator) *p++ = separator;
/* argument */
switch (argkind) {
case S390_ARG_MNM:
p += vex_sprintf(p, s390_mnm_fmt, va_arg(args, HChar *));
separator = ' ';
continue;
case S390_ARG_XMNM: {
UInt mask, kind;
const HChar *mnm;
kind = va_arg(args, UInt);
separator = ' ';
switch (kind) {
case S390_XMNM_BC:
case S390_XMNM_BCR:
mask = va_arg(args, UInt);
mnm = kind == S390_XMNM_BCR ? bcr_operand(mask) : bc_operand(mask);
p += vex_sprintf(p, s390_mnm_fmt, mnm);
/* mask == 0 is a NOP and has no argument */
if (mask == 0) goto done;
break;
case S390_XMNM_BRC:
case S390_XMNM_BRCL:
mask = va_arg(args, UInt);
mnm = kind == S390_XMNM_BRC ? brc_operand(mask) : brcl_operand(mask);
p += vex_sprintf(p, s390_mnm_fmt, mnm);
/* mask == 0 has no special mnemonic */
if (mask == 0) {
p += vex_sprintf(p, " 0");
separator = ',';
}
break;
case S390_XMNM_CAB:
mnm = va_arg(args, HChar *);
mask = va_arg(args, UInt);
p += vex_sprintf(p, s390_mnm_fmt, cab_operand(mnm, mask));
break;
case S390_XMNM_LOCR:
case S390_XMNM_LOCGR:
case S390_XMNM_LOC:
case S390_XMNM_LOCG:
case S390_XMNM_STOC:
case S390_XMNM_STOCG:
mask = va_arg(args, UInt);
mnm = cls_operand(kind, mask);
p += vex_sprintf(p, s390_mnm_fmt, mnm);
/* There are no special opcodes when mask == 0 or 15. In that case
the integer mask is appended as the final operand */
if (mask == 0 || mask == 15) mask_suffix = mask;
break;
}
}
continue;
case S390_ARG_GPR:
p += vex_sprintf(p, "%s", gpr_operand(va_arg(args, UInt)));
break;
case S390_ARG_FPR:
p += vex_sprintf(p, "%s", fpr_operand(va_arg(args, UInt)));
break;
case S390_ARG_AR:
p += vex_sprintf(p, "%s", ar_operand(va_arg(args, UInt)));
break;
case S390_ARG_UINT:
p += vex_sprintf(p, "%u", va_arg(args, UInt));
break;
case S390_ARG_INT:
p += vex_sprintf(p, "%d", (Int)(va_arg(args, UInt)));
break;
case S390_ARG_PCREL: {
Int offset = (Int)(va_arg(args, UInt));
/* Convert # halfwords to # bytes */
offset <<= 1;
if (offset < 0) {
p += vex_sprintf(p, ".%d", offset);
} else {
p += vex_sprintf(p, ".+%u", offset);
}
break;
}
case S390_ARG_SDXB: {
UInt dh, dl, x, b;
dh = va_arg(args, UInt);
dl = va_arg(args, UInt);
x = va_arg(args, UInt);
b = va_arg(args, UInt);
p = dxb_operand(p, (dh << 12) | dl, x, b, 1 /* signed_displacement */);
break;
}
case S390_ARG_UDXB: {
UInt d, x, b;
d = va_arg(args, UInt);
x = va_arg(args, UInt);
b = va_arg(args, UInt);
p = dxb_operand(p, d, x, b, 0 /* signed_displacement */);
break;
}
case S390_ARG_UDLB: {
UInt d, l, b;
d = va_arg(args, UInt);
l = va_arg(args, UInt);
b = va_arg(args, UInt);
p = udlb_operand(p, d, l, b);
break;
}
case S390_ARG_CABM: {
UInt mask;
mask = va_arg(args, UInt) & 0xE;
if (mask == 0 || mask == 14) {
p += vex_sprintf(p, ",%u", mask);
}
break;
}
}
separator = ',';
}
done:
va_end(args);
if (mask_suffix != -1)
p += vex_sprintf(p, ",%d", mask_suffix);
*p = '\0';
vassert(p < buf + sizeof buf); /* detect buffer overwrite */
/* Finally, write out the disassembled insn */
vex_printf("%s\n", buf);
}
/*---------------------------------------------------------------*/
/*--- end host_s390_disasm.c ---*/
/*---------------------------------------------------------------*/