/* -*- mode: C; c-basic-offset: 3; -*- */
/*---------------------------------------------------------------*/
/*--- begin host_s390_defs.c ---*/
/*---------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright IBM Corp. 2010-2017
Copyright (C) 2012-2017 Florian Krohm (britzel@acm.org)
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 "libvex_basictypes.h"
#include "libvex.h"
#include "libvex_trc_values.h"
#include "libvex_s390x_common.h"
#include "main_util.h"
#include "main_globals.h"
#include "host_generic_regs.h"
#include "host_s390_defs.h"
#include "s390_disasm.h"
#include "guest_s390_defs.h" /* S390X_GUEST_OFFSET */
#include <stdarg.h>
/*------------------------------------------------------------*/
/*--- Forward declarations ---*/
/*------------------------------------------------------------*/
static Bool s390_insn_is_reg_reg_move(const s390_insn *, HReg *src, HReg *dst);
static void s390_insn_map_regs(HRegRemap *, s390_insn *);
static void s390_insn_get_reg_usage(HRegUsage *u, const s390_insn *);
static UInt s390_tchain_load64_len(void);
/*------------------------------------------------------------*/
/*--- Registers ---*/
/*------------------------------------------------------------*/
/* A mapping from register number to register index */
static Int gpr_index[16]; // GPR regno -> register index
static Int fpr_index[16]; // FPR regno -> register index
HReg
s390_hreg_gpr(UInt regno)
{
Int ix = gpr_index[regno];
vassert(ix >= 0);
return mkHReg(/*virtual*/False, HRcInt64, regno, ix);
}
HReg
s390_hreg_fpr(UInt regno)
{
Int ix = fpr_index[regno];
vassert(ix >= 0);
return mkHReg(/*virtual*/False, HRcFlt64, regno, ix);
}
static __inline__ UInt
hregNumber(HReg reg)
{
return hregEncoding(reg);
}
/* Decompile the given register into a static buffer and return it */
const HChar *
s390_hreg_as_string(HReg reg)
{
static HChar buf[10];
static const HChar ireg_names[16][5] = {
"%r0", "%r1", "%r2", "%r3", "%r4", "%r5", "%r6", "%r7",
"%r8", "%r9", "%r10", "%r11", "%r12", "%r13", "%r14", "%r15"
};
static const HChar freg_names[16][5] = {
"%f0", "%f1", "%f2", "%f3", "%f4", "%f5", "%f6", "%f7",
"%f8", "%f9", "%f10", "%f11", "%f12", "%f13", "%f14", "%f15"
};
UInt r; /* hregNumber() returns an UInt */
r = hregNumber(reg);
/* Be generic for all virtual regs. */
if (hregIsVirtual(reg)) {
buf[0] = '\0';
switch (hregClass(reg)) {
case HRcInt64: vex_sprintf(buf, "%%vR%u", r); break;
case HRcFlt64: vex_sprintf(buf, "%%vF%u", r); break;
default: goto fail;
}
return buf;
}
/* But specific for real regs. */
vassert(r < 16);
switch (hregClass(reg)) {
case HRcInt64: return ireg_names[r];
case HRcFlt64: return freg_names[r];
default: goto fail;
}
fail: vpanic("s390_hreg_as_string");
}
/* Return the real register that holds the guest state pointer */
HReg
s390_hreg_guest_state_pointer(void)
{
return s390_hreg_gpr(S390_REGNO_GUEST_STATE_POINTER);
}
/* Is VALUE within the domain of a 20-bit signed integer. */
static __inline__ Bool
fits_signed_20bit(Int value)
{
UInt uval = value;
return ((Int)(uval << 12) >> 12) == value;
}
/* Is VALUE within the domain of a 12-bit unsigned integer. */
static __inline__ Bool
fits_unsigned_12bit(Int value)
{
return (value & 0xFFF) == value;
}
/*------------------------------------------------------------*/
/*--- Addressing modes (amodes) ---*/
/*------------------------------------------------------------*/
/* Construct a b12 amode. */
s390_amode *
s390_amode_b12(Int d, HReg b)
{
s390_amode *am = LibVEX_Alloc_inline(sizeof(s390_amode));
vassert(fits_unsigned_12bit(d));
am->tag = S390_AMODE_B12;
am->d = d;
am->b = b;
am->x = s390_hreg_gpr(0); /* hregNumber(am->x) == 0 */
return am;
}
/* Construct a b20 amode. */
s390_amode *
s390_amode_b20(Int d, HReg b)
{
s390_amode *am = LibVEX_Alloc_inline(sizeof(s390_amode));
vassert(fits_signed_20bit(d));
am->tag = S390_AMODE_B20;
am->d = d;
am->b = b;
am->x = s390_hreg_gpr(0); /* hregNumber(am->x) == 0 */
return am;
}
/* Construct a bx12 amode. */
s390_amode *
s390_amode_bx12(Int d, HReg b, HReg x)
{
s390_amode *am = LibVEX_Alloc_inline(sizeof(s390_amode));
vassert(fits_unsigned_12bit(d));
vassert(hregNumber(b) != 0);
vassert(hregNumber(x) != 0);
am->tag = S390_AMODE_BX12;
am->d = d;
am->b = b;
am->x = x;
return am;
}
/* Construct a bx20 amode. */
s390_amode *
s390_amode_bx20(Int d, HReg b, HReg x)
{
s390_amode *am = LibVEX_Alloc_inline(sizeof(s390_amode));
vassert(fits_signed_20bit(d));
vassert(hregNumber(b) != 0);
vassert(hregNumber(x) != 0);
am->tag = S390_AMODE_BX20;
am->d = d;
am->b = b;
am->x = x;
return am;
}
/* Construct an AMODE for accessing the guest state at OFFSET.
OFFSET can be at most 3 * sizeof(VexGuestS390XState) + LibVEX_N_SPILL_BYTES
which may be too large for a B12 addressing mode.
Use a B20 amode as a fallback which will be safe for any offset.
*/
s390_amode *
s390_amode_for_guest_state(Int offset)
{
if (fits_unsigned_12bit(offset))
return s390_amode_b12(offset, s390_hreg_guest_state_pointer());
if (fits_signed_20bit(offset))
return s390_amode_b20(offset, s390_hreg_guest_state_pointer());
vpanic("invalid guest state offset");
}
/* Decompile the given amode into a static buffer and return it. */
const HChar *
s390_amode_as_string(const s390_amode *am)
{
static HChar buf[30];
HChar *p;
buf[0] = '\0';
p = buf;
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_B20:
vex_sprintf(p, "%d(%s)", am->d, s390_hreg_as_string(am->b));
break;
case S390_AMODE_BX12:
case S390_AMODE_BX20:
/* s390_hreg_as_string returns pointer to local buffer. Need to
split this into two printfs */
p += vex_sprintf(p, "%d(%s,", am->d, s390_hreg_as_string(am->x));
vex_sprintf(p, "%s)", s390_hreg_as_string(am->b));
break;
default:
vpanic("s390_amode_as_string");
}
return buf;
}
/* Helper function for s390_amode_is_sane */
static __inline__ Bool
is_virtual_gpr(HReg reg)
{
return hregIsVirtual(reg) && hregClass(reg) == HRcInt64;
}
/* Sanity check for an amode */
Bool
s390_amode_is_sane(const s390_amode *am)
{
switch (am->tag) {
case S390_AMODE_B12:
return is_virtual_gpr(am->b) && fits_unsigned_12bit(am->d);
case S390_AMODE_B20:
return is_virtual_gpr(am->b) && fits_signed_20bit(am->d);
case S390_AMODE_BX12:
return is_virtual_gpr(am->b) && is_virtual_gpr(am->x) &&
fits_unsigned_12bit(am->d);
case S390_AMODE_BX20:
return is_virtual_gpr(am->b) && is_virtual_gpr(am->x) &&
fits_signed_20bit(am->d);
default:
vpanic("s390_amode_is_sane");
}
}
/* Record the register use of an amode */
static void
s390_amode_get_reg_usage(HRegUsage *u, const s390_amode *am)
{
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_B20:
addHRegUse(u, HRmRead, am->b);
return;
case S390_AMODE_BX12:
case S390_AMODE_BX20:
addHRegUse(u, HRmRead, am->b);
addHRegUse(u, HRmRead, am->x);
return;
default:
vpanic("s390_amode_get_reg_usage");
}
}
static void
s390_amode_map_regs(HRegRemap *m, s390_amode *am)
{
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_B20:
am->b = lookupHRegRemap(m, am->b);
return;
case S390_AMODE_BX12:
case S390_AMODE_BX20:
am->b = lookupHRegRemap(m, am->b);
am->x = lookupHRegRemap(m, am->x);
return;
default:
vpanic("s390_amode_map_regs");
}
}
void
ppS390AMode(const s390_amode *am)
{
vex_printf("%s", s390_amode_as_string(am));
}
void
ppS390Instr(const s390_insn *insn, Bool mode64)
{
vex_printf("%s", s390_insn_as_string(insn));
}
void
ppHRegS390(HReg reg)
{
vex_printf("%s", s390_hreg_as_string(reg));
}
/*------------------------------------------------------------*/
/*--- Helpers for register allocation ---*/
/*------------------------------------------------------------*/
/* Initialise and return the "register universe", i.e. a list of
all hardware registers. Called once. */
const RRegUniverse *
getRRegUniverse_S390(void)
{
static RRegUniverse all_regs;
static Bool initialised = False;
RRegUniverse *ru = &all_regs;
if (LIKELY(initialised))
return ru;
RRegUniverse__init(ru);
/* Assign invalid values to the gpr/fpr_index */
for (UInt i = 0; i < sizeof gpr_index / sizeof gpr_index[0]; ++i)
gpr_index[i] = -1;
for (UInt i = 0; i < sizeof fpr_index / sizeof fpr_index[0]; ++i)
fpr_index[i] = -1;
/* Add the registers that are available to the register allocator.
GPRs: registers 1..11 are available
FPRs: registers 0..15 are available
FPR12 - FPR15 are also used as register pairs for 128-bit
floating point operations
*/
UInt regno;
for (regno = 1; regno <= 11; ++regno) {
gpr_index[regno] = ru->size;
ru->regs[ru->size++] = s390_hreg_gpr(regno);
}
for (regno = 0; regno <= 15; ++regno) {
fpr_index[regno] = ru->size;
ru->regs[ru->size++] = s390_hreg_fpr(regno);
}
ru->allocable = ru->size;
/* Add the registers that are not available for allocation.
r0 -- cannot be used as a base or index register
r12 -- scratch register for translation chaining support
r13 -- guest state pointer
r14 -- link register
r15 -- stack pointer
*/
UInt other[] = { 0, 12, 13, 14, 15 };
for (UInt i = 0; i < sizeof other / sizeof other[0]; ++i) {
gpr_index[other[i]] = ru->size;
ru->regs[ru->size++] = s390_hreg_gpr(other[i]);
}
/* Sanity checking */
for (UInt i = 0; i < sizeof gpr_index / sizeof gpr_index[0]; ++i)
vassert(gpr_index[i] >= 0);
for (UInt i = 0; i < sizeof fpr_index / sizeof fpr_index[0]; ++i)
vassert(fpr_index[i] >= 0);
initialised = True;
return ru;
}
/* Tell the register allocator how the given instruction uses the registers
it refers to. */
void
getRegUsage_S390Instr(HRegUsage *u, const s390_insn *insn, Bool mode64)
{
s390_insn_get_reg_usage(u, insn);
}
/* Map the registers of the given instruction */
void
mapRegs_S390Instr(HRegRemap *m, s390_insn *insn, Bool mode64)
{
s390_insn_map_regs(m, insn);
}
/* Figure out if the given insn represents a reg-reg move, and if so
assign the source and destination to *src and *dst. If in doubt say No.
Used by the register allocator to do move coalescing. */
Bool
isMove_S390Instr(const s390_insn *insn, HReg *src, HReg *dst)
{
return s390_insn_is_reg_reg_move(insn, src, dst);
}
/* Generate s390 spill/reload instructions under the direction of the
register allocator. Note it's critical these don't write the
condition codes. This is like an Ist_Put */
void
genSpill_S390(HInstr **i1, HInstr **i2, HReg rreg, Int offsetB, Bool mode64)
{
s390_amode *am;
vassert(offsetB >= 0);
vassert(!hregIsVirtual(rreg));
*i1 = *i2 = NULL;
am = s390_amode_for_guest_state(offsetB);
switch (hregClass(rreg)) {
case HRcInt64:
case HRcFlt64:
*i1 = s390_insn_store(8, am, rreg);
return;
default:
ppHRegClass(hregClass(rreg));
vpanic("genSpill_S390: unimplemented regclass");
}
}
/* This is like an Iex_Get */
void
genReload_S390(HInstr **i1, HInstr **i2, HReg rreg, Int offsetB, Bool mode64)
{
s390_amode *am;
vassert(offsetB >= 0);
vassert(!hregIsVirtual(rreg));
*i1 = *i2 = NULL;
am = s390_amode_for_guest_state(offsetB);
switch (hregClass(rreg)) {
case HRcInt64:
case HRcFlt64:
*i1 = s390_insn_load(8, rreg, am);
return;
default:
ppHRegClass(hregClass(rreg));
vpanic("genReload_S390: unimplemented regclass");
}
}
/* Helper function for s390_insn_get_reg_usage */
static void
s390_opnd_RMI_get_reg_usage(HRegUsage *u, s390_opnd_RMI op)
{
switch (op.tag) {
case S390_OPND_REG:
addHRegUse(u, HRmRead, op.variant.reg);
break;
case S390_OPND_AMODE:
s390_amode_get_reg_usage(u, op.variant.am);
break;
case S390_OPND_IMMEDIATE:
break;
default:
vpanic("s390_opnd_RMI_get_reg_usage");
}
}
/* Tell the register allocator how the given insn uses the registers */
static void
s390_insn_get_reg_usage(HRegUsage *u, const s390_insn *insn)
{
initHRegUsage(u);
switch (insn->tag) {
case S390_INSN_LOAD:
addHRegUse(u, HRmWrite, insn->variant.load.dst);
s390_amode_get_reg_usage(u, insn->variant.load.src);
break;
case S390_INSN_LOAD_IMMEDIATE:
addHRegUse(u, HRmWrite, insn->variant.load_immediate.dst);
break;
case S390_INSN_STORE:
addHRegUse(u, HRmRead, insn->variant.store.src);
s390_amode_get_reg_usage(u, insn->variant.store.dst);
break;
case S390_INSN_MOVE:
addHRegUse(u, HRmRead, insn->variant.move.src);
addHRegUse(u, HRmWrite, insn->variant.move.dst);
break;
case S390_INSN_MEMCPY:
s390_amode_get_reg_usage(u, insn->variant.memcpy.src);
s390_amode_get_reg_usage(u, insn->variant.memcpy.dst);
break;
case S390_INSN_COND_MOVE:
s390_opnd_RMI_get_reg_usage(u, insn->variant.cond_move.src);
addHRegUse(u, HRmWrite, insn->variant.cond_move.dst);
break;
case S390_INSN_ALU:
addHRegUse(u, HRmWrite, insn->variant.alu.dst);
addHRegUse(u, HRmRead, insn->variant.alu.dst); /* op1 */
s390_opnd_RMI_get_reg_usage(u, insn->variant.alu.op2);
break;
case S390_INSN_SMUL:
case S390_INSN_UMUL:
addHRegUse(u, HRmRead, insn->variant.mul.dst_lo); /* op1 */
addHRegUse(u, HRmWrite, insn->variant.mul.dst_lo);
addHRegUse(u, HRmWrite, insn->variant.mul.dst_hi);
s390_opnd_RMI_get_reg_usage(u, insn->variant.mul.op2);
break;
case S390_INSN_SDIV:
case S390_INSN_UDIV:
addHRegUse(u, HRmRead, insn->variant.div.op1_lo);
addHRegUse(u, HRmRead, insn->variant.div.op1_hi);
addHRegUse(u, HRmWrite, insn->variant.div.op1_lo);
addHRegUse(u, HRmWrite, insn->variant.div.op1_hi);
s390_opnd_RMI_get_reg_usage(u, insn->variant.div.op2);
break;
case S390_INSN_DIVS:
addHRegUse(u, HRmRead, insn->variant.divs.op1);
addHRegUse(u, HRmWrite, insn->variant.divs.op1); /* quotient */
addHRegUse(u, HRmWrite, insn->variant.divs.rem); /* remainder */
s390_opnd_RMI_get_reg_usage(u, insn->variant.divs.op2);
break;
case S390_INSN_CLZ:
addHRegUse(u, HRmWrite, insn->variant.clz.num_bits);
addHRegUse(u, HRmWrite, insn->variant.clz.clobber);
s390_opnd_RMI_get_reg_usage(u, insn->variant.clz.src);
break;
case S390_INSN_UNOP:
addHRegUse(u, HRmWrite, insn->variant.unop.dst);
s390_opnd_RMI_get_reg_usage(u, insn->variant.unop.src);
break;
case S390_INSN_TEST:
s390_opnd_RMI_get_reg_usage(u, insn->variant.test.src);
break;
case S390_INSN_CC2BOOL:
addHRegUse(u, HRmWrite, insn->variant.cc2bool.dst);
break;
case S390_INSN_CAS:
addHRegUse(u, HRmRead, insn->variant.cas.op1);
s390_amode_get_reg_usage(u, insn->variant.cas.op2);
addHRegUse(u, HRmRead, insn->variant.cas.op3);
addHRegUse(u, HRmWrite, insn->variant.cas.old_mem);
break;
case S390_INSN_CDAS: {
s390_cdas *cdas = insn->variant.cdas.details;
addHRegUse(u, HRmRead, cdas->op1_high);
addHRegUse(u, HRmRead, cdas->op1_low);
s390_amode_get_reg_usage(u, cdas->op2);
addHRegUse(u, HRmRead, cdas->op3_high);
addHRegUse(u, HRmRead, cdas->op3_low);
addHRegUse(u, HRmWrite, cdas->old_mem_high);
addHRegUse(u, HRmWrite, cdas->old_mem_low);
addHRegUse(u, HRmWrite, cdas->scratch);
break;
}
case S390_INSN_COMPARE:
addHRegUse(u, HRmRead, insn->variant.compare.src1);
s390_opnd_RMI_get_reg_usage(u, insn->variant.compare.src2);
break;
case S390_INSN_HELPER_CALL: {
UInt i;
/* Assume that all volatile registers are clobbered. ABI says,
volatile registers are: r0 - r5. Valgrind's register allocator
does not know about r0, so we can leave that out */
for (i = 1; i <= 5; ++i) {
addHRegUse(u, HRmWrite, s390_hreg_gpr(i));
}
/* Ditto for floating point registers. f0 - f7 are volatile */
for (i = 0; i <= 7; ++i) {
addHRegUse(u, HRmWrite, s390_hreg_fpr(i));
}
/* The registers that are used for passing arguments will be read.
Not all of them may, but in general we need to assume that. */
for (i = 0; i < insn->variant.helper_call.details->num_args; ++i) {
addHRegUse(u, HRmRead, s390_hreg_gpr(s390_gprno_from_arg_index(i)));
}
/* s390_insn_helper_call_emit also reads / writes the link register
and stack pointer. But those registers are not visible to the
register allocator. So we don't need to do anything for them. */
break;
}
case S390_INSN_BFP_TRIOP:
addHRegUse(u, HRmWrite, insn->variant.bfp_triop.dst);
addHRegUse(u, HRmRead, insn->variant.bfp_triop.dst); /* first */
addHRegUse(u, HRmRead, insn->variant.bfp_triop.op2); /* second */
addHRegUse(u, HRmRead, insn->variant.bfp_triop.op3); /* third */
break;
case S390_INSN_BFP_BINOP:
addHRegUse(u, HRmWrite, insn->variant.bfp_binop.dst_hi);
addHRegUse(u, HRmRead, insn->variant.bfp_binop.dst_hi); /* left */
addHRegUse(u, HRmRead, insn->variant.bfp_binop.op2_hi); /* right */
if (insn->size == 16) {
addHRegUse(u, HRmWrite, insn->variant.bfp_binop.dst_lo);
addHRegUse(u, HRmRead, insn->variant.bfp_binop.dst_lo); /* left */
addHRegUse(u, HRmRead, insn->variant.bfp_binop.op2_lo); /* right */
}
break;
case S390_INSN_BFP_UNOP:
addHRegUse(u, HRmWrite, insn->variant.bfp_unop.dst_hi);
addHRegUse(u, HRmRead, insn->variant.bfp_unop.op_hi); /* operand */
if (insn->size == 16) {
addHRegUse(u, HRmWrite, insn->variant.bfp_unop.dst_lo);
addHRegUse(u, HRmRead, insn->variant.bfp_unop.op_lo); /* operand */
}
break;
case S390_INSN_BFP_COMPARE:
addHRegUse(u, HRmWrite, insn->variant.bfp_compare.dst);
addHRegUse(u, HRmRead, insn->variant.bfp_compare.op1_hi); /* left */
addHRegUse(u, HRmRead, insn->variant.bfp_compare.op2_hi); /* right */
if (insn->size == 16) {
addHRegUse(u, HRmRead, insn->variant.bfp_compare.op1_lo); /* left */
addHRegUse(u, HRmRead, insn->variant.bfp_compare.op2_lo); /* right */
}
break;
case S390_INSN_BFP_CONVERT:
addHRegUse(u, HRmWrite, insn->variant.bfp_convert.dst_hi);
if (! hregIsInvalid(insn->variant.bfp_convert.dst_lo))
addHRegUse(u, HRmWrite, insn->variant.bfp_convert.dst_lo);
addHRegUse(u, HRmRead, insn->variant.bfp_convert.op_hi);
if (! hregIsInvalid(insn->variant.bfp_convert.op_lo))
addHRegUse(u, HRmRead, insn->variant.bfp_convert.op_lo);
break;
case S390_INSN_DFP_BINOP: {
s390_dfp_binop *dfp_binop = insn->variant.dfp_binop.details;
addHRegUse(u, HRmWrite, dfp_binop->dst_hi);
addHRegUse(u, HRmRead, dfp_binop->op2_hi); /* left */
addHRegUse(u, HRmRead, dfp_binop->op3_hi); /* right */
if (insn->size == 16) {
addHRegUse(u, HRmWrite, dfp_binop->dst_lo);
addHRegUse(u, HRmRead, dfp_binop->op2_lo); /* left */
addHRegUse(u, HRmRead, dfp_binop->op3_lo); /* right */
}
break;
}
case S390_INSN_DFP_UNOP:
addHRegUse(u, HRmWrite, insn->variant.dfp_unop.dst_hi);
addHRegUse(u, HRmRead, insn->variant.dfp_unop.op_hi); /* operand */
if (insn->size == 16) {
addHRegUse(u, HRmWrite, insn->variant.dfp_unop.dst_lo);
addHRegUse(u, HRmRead, insn->variant.dfp_unop.op_lo); /* operand */
}
break;
case S390_INSN_DFP_INTOP:
addHRegUse(u, HRmWrite, insn->variant.dfp_intop.dst_hi);
addHRegUse(u, HRmRead, insn->variant.dfp_intop.op2);
addHRegUse(u, HRmRead, insn->variant.dfp_intop.op3_hi);
if (insn->size == 16) {
addHRegUse(u, HRmWrite, insn->variant.dfp_intop.dst_lo);
addHRegUse(u, HRmRead, insn->variant.dfp_intop.op3_lo);
}
break;
case S390_INSN_DFP_COMPARE:
addHRegUse(u, HRmWrite, insn->variant.dfp_compare.dst);
addHRegUse(u, HRmRead, insn->variant.dfp_compare.op1_hi); /* left */
addHRegUse(u, HRmRead, insn->variant.dfp_compare.op2_hi); /* right */
if (insn->size == 16) {
addHRegUse(u, HRmRead, insn->variant.dfp_compare.op1_lo); /* left */
addHRegUse(u, HRmRead, insn->variant.dfp_compare.op2_lo); /* right */
}
break;
case S390_INSN_DFP_CONVERT:
addHRegUse(u, HRmWrite, insn->variant.dfp_convert.dst_hi);
if (! hregIsInvalid(insn->variant.dfp_convert.dst_lo))
addHRegUse(u, HRmWrite, insn->variant.dfp_convert.dst_lo);
addHRegUse(u, HRmRead, insn->variant.dfp_convert.op_hi); /* operand */
if (! hregIsInvalid(insn->variant.dfp_convert.op_lo))
addHRegUse(u, HRmRead, insn->variant.dfp_convert.op_lo); /* operand */
break;
case S390_INSN_DFP_REROUND:
addHRegUse(u, HRmWrite, insn->variant.dfp_reround.dst_hi);
addHRegUse(u, HRmRead, insn->variant.dfp_reround.op2); /* left */
addHRegUse(u, HRmRead, insn->variant.dfp_reround.op3_hi); /* right */
if (insn->size == 16) {
addHRegUse(u, HRmWrite, insn->variant.dfp_reround.dst_lo);
addHRegUse(u, HRmRead, insn->variant.dfp_reround.op3_lo); /* right */
}
break;
case S390_INSN_FP_CONVERT: {
s390_fp_convert *fp_convert = insn->variant.fp_convert.details;
addHRegUse(u, HRmWrite, fp_convert->dst_hi);
if (! hregIsInvalid(fp_convert->dst_lo))
addHRegUse(u, HRmWrite, fp_convert->dst_lo);
addHRegUse(u, HRmRead, fp_convert->op_hi);
if (! hregIsInvalid(fp_convert->op_lo))
addHRegUse(u, HRmRead, fp_convert->op_lo);
addHRegUse(u, HRmWrite, fp_convert->r1);
break;
}
case S390_INSN_MIMM:
s390_amode_get_reg_usage(u, insn->variant.mimm.dst);
break;
case S390_INSN_MADD:
s390_amode_get_reg_usage(u, insn->variant.madd.dst);
break;
case S390_INSN_MFENCE:
break;
case S390_INSN_SET_FPC_BFPRM:
addHRegUse(u, HRmRead, insn->variant.set_fpc_bfprm.mode);
break;
case S390_INSN_SET_FPC_DFPRM:
addHRegUse(u, HRmRead, insn->variant.set_fpc_dfprm.mode);
break;
case S390_INSN_EVCHECK:
s390_amode_get_reg_usage(u, insn->variant.evcheck.counter);
s390_amode_get_reg_usage(u, insn->variant.evcheck.fail_addr);
break;
case S390_INSN_PROFINC:
/* Does not use any register visible to the register allocator */
break;
case S390_INSN_XDIRECT:
s390_amode_get_reg_usage(u, insn->variant.xdirect.guest_IA);
break;
case S390_INSN_XINDIR:
addHRegUse(u, HRmRead, insn->variant.xindir.dst);
s390_amode_get_reg_usage(u, insn->variant.xindir.guest_IA);
break;
case S390_INSN_XASSISTED:
addHRegUse(u, HRmRead, insn->variant.xassisted.dst);
s390_amode_get_reg_usage(u, insn->variant.xassisted.guest_IA);
break;
default:
vpanic("s390_insn_get_reg_usage");
}
}
/* Helper function for s390_insn_map_regs */
static void
s390_opnd_RMI_map_regs(HRegRemap *m, s390_opnd_RMI *op)
{
switch (op->tag) {
case S390_OPND_REG:
op->variant.reg = lookupHRegRemap(m, op->variant.reg);
break;
case S390_OPND_IMMEDIATE:
break;
case S390_OPND_AMODE:
s390_amode_map_regs(m, op->variant.am);
break;
default:
vpanic("s390_opnd_RMI_map_regs");
}
}
static void
s390_insn_map_regs(HRegRemap *m, s390_insn *insn)
{
switch (insn->tag) {
case S390_INSN_LOAD:
insn->variant.load.dst = lookupHRegRemap(m, insn->variant.load.dst);
s390_amode_map_regs(m, insn->variant.load.src);
break;
case S390_INSN_STORE:
s390_amode_map_regs(m, insn->variant.store.dst);
insn->variant.store.src = lookupHRegRemap(m, insn->variant.store.src);
break;
case S390_INSN_MOVE:
insn->variant.move.dst = lookupHRegRemap(m, insn->variant.move.dst);
insn->variant.move.src = lookupHRegRemap(m, insn->variant.move.src);
break;
case S390_INSN_MEMCPY:
s390_amode_map_regs(m, insn->variant.memcpy.dst);
s390_amode_map_regs(m, insn->variant.memcpy.src);
break;
case S390_INSN_COND_MOVE:
insn->variant.cond_move.dst = lookupHRegRemap(m, insn->variant.cond_move.dst);
s390_opnd_RMI_map_regs(m, &insn->variant.cond_move.src);
break;
case S390_INSN_LOAD_IMMEDIATE:
insn->variant.load_immediate.dst =
lookupHRegRemap(m, insn->variant.load_immediate.dst);
break;
case S390_INSN_ALU:
insn->variant.alu.dst = lookupHRegRemap(m, insn->variant.alu.dst);
s390_opnd_RMI_map_regs(m, &insn->variant.alu.op2);
break;
case S390_INSN_SMUL:
case S390_INSN_UMUL:
insn->variant.mul.dst_hi = lookupHRegRemap(m, insn->variant.mul.dst_hi);
insn->variant.mul.dst_lo = lookupHRegRemap(m, insn->variant.mul.dst_lo);
s390_opnd_RMI_map_regs(m, &insn->variant.mul.op2);
break;
case S390_INSN_SDIV:
case S390_INSN_UDIV:
insn->variant.div.op1_hi = lookupHRegRemap(m, insn->variant.div.op1_hi);
insn->variant.div.op1_lo = lookupHRegRemap(m, insn->variant.div.op1_lo);
s390_opnd_RMI_map_regs(m, &insn->variant.div.op2);
break;
case S390_INSN_DIVS:
insn->variant.divs.op1 = lookupHRegRemap(m, insn->variant.divs.op1);
insn->variant.divs.rem = lookupHRegRemap(m, insn->variant.divs.rem);
s390_opnd_RMI_map_regs(m, &insn->variant.divs.op2);
break;
case S390_INSN_CLZ:
insn->variant.clz.num_bits = lookupHRegRemap(m, insn->variant.clz.num_bits);
insn->variant.clz.clobber = lookupHRegRemap(m, insn->variant.clz.clobber);
s390_opnd_RMI_map_regs(m, &insn->variant.clz.src);
break;
case S390_INSN_UNOP:
insn->variant.unop.dst = lookupHRegRemap(m, insn->variant.unop.dst);
s390_opnd_RMI_map_regs(m, &insn->variant.unop.src);
break;
case S390_INSN_TEST:
s390_opnd_RMI_map_regs(m, &insn->variant.test.src);
break;
case S390_INSN_CC2BOOL:
insn->variant.cc2bool.dst = lookupHRegRemap(m, insn->variant.cc2bool.dst);
break;
case S390_INSN_CAS:
insn->variant.cas.op1 = lookupHRegRemap(m, insn->variant.cas.op1);
s390_amode_map_regs(m, insn->variant.cas.op2);
insn->variant.cas.op3 = lookupHRegRemap(m, insn->variant.cas.op3);
insn->variant.cas.old_mem = lookupHRegRemap(m, insn->variant.cas.old_mem);
break;
case S390_INSN_CDAS: {
s390_cdas *cdas = insn->variant.cdas.details;
cdas->op1_high = lookupHRegRemap(m, cdas->op1_high);
cdas->op1_low = lookupHRegRemap(m, cdas->op1_low);
s390_amode_map_regs(m, cdas->op2);
cdas->op3_high = lookupHRegRemap(m, cdas->op3_high);
cdas->op3_low = lookupHRegRemap(m, cdas->op3_low);
cdas->old_mem_high = lookupHRegRemap(m, cdas->old_mem_high);
cdas->old_mem_low = lookupHRegRemap(m, cdas->old_mem_low);
cdas->scratch = lookupHRegRemap(m, cdas->scratch);
break;
}
case S390_INSN_COMPARE:
insn->variant.compare.src1 = lookupHRegRemap(m, insn->variant.compare.src1);
s390_opnd_RMI_map_regs(m, &insn->variant.compare.src2);
break;
case S390_INSN_HELPER_CALL:
/* s390_insn_helper_call_emit also reads / writes the link register
and stack pointer. But those registers are not visible to the
register allocator. So we don't need to do anything for them.
As for the arguments of the helper call -- they will be loaded into
non-virtual registers. Again, we don't need to do anything for those
here. */
break;
case S390_INSN_BFP_TRIOP:
insn->variant.bfp_triop.dst =
lookupHRegRemap(m, insn->variant.bfp_triop.dst);
insn->variant.bfp_triop.op2 =
lookupHRegRemap(m, insn->variant.bfp_triop.op2);
insn->variant.bfp_triop.op3 =
lookupHRegRemap(m, insn->variant.bfp_triop.op3);
break;
case S390_INSN_BFP_BINOP:
insn->variant.bfp_binop.dst_hi =
lookupHRegRemap(m, insn->variant.bfp_binop.dst_hi);
insn->variant.bfp_binop.op2_hi =
lookupHRegRemap(m, insn->variant.bfp_binop.op2_hi);
if (insn->size == 16) {
insn->variant.bfp_binop.dst_lo =
lookupHRegRemap(m, insn->variant.bfp_binop.dst_lo);
insn->variant.bfp_binop.op2_lo =
lookupHRegRemap(m, insn->variant.bfp_binop.op2_lo);
}
break;
case S390_INSN_BFP_UNOP:
insn->variant.bfp_unop.dst_hi =
lookupHRegRemap(m, insn->variant.bfp_unop.dst_hi);
insn->variant.bfp_unop.op_hi =
lookupHRegRemap(m, insn->variant.bfp_unop.op_hi);
if (insn->size == 16) {
insn->variant.bfp_unop.dst_lo =
lookupHRegRemap(m, insn->variant.bfp_unop.dst_lo);
insn->variant.bfp_unop.op_lo =
lookupHRegRemap(m, insn->variant.bfp_unop.op_lo);
}
break;
case S390_INSN_BFP_COMPARE:
insn->variant.bfp_compare.dst =
lookupHRegRemap(m, insn->variant.bfp_compare.dst);
insn->variant.bfp_compare.op1_hi =
lookupHRegRemap(m, insn->variant.bfp_compare.op1_hi);
insn->variant.bfp_compare.op2_hi =
lookupHRegRemap(m, insn->variant.bfp_compare.op2_hi);
if (insn->size == 16) {
insn->variant.bfp_compare.op1_lo =
lookupHRegRemap(m, insn->variant.bfp_compare.op1_lo);
insn->variant.bfp_compare.op2_lo =
lookupHRegRemap(m, insn->variant.bfp_compare.op2_lo);
}
break;
case S390_INSN_BFP_CONVERT:
insn->variant.bfp_convert.dst_hi =
lookupHRegRemap(m, insn->variant.bfp_convert.dst_hi);
if (! hregIsInvalid(insn->variant.bfp_convert.dst_lo))
insn->variant.bfp_convert.dst_lo =
lookupHRegRemap(m, insn->variant.bfp_convert.dst_lo);
insn->variant.bfp_convert.op_hi =
lookupHRegRemap(m, insn->variant.bfp_convert.op_hi);
if (! hregIsInvalid(insn->variant.bfp_convert.op_lo))
insn->variant.bfp_convert.op_lo =
lookupHRegRemap(m, insn->variant.bfp_convert.op_lo);
break;
case S390_INSN_DFP_BINOP: {
s390_dfp_binop *dfp_binop = insn->variant.dfp_binop.details;
dfp_binop->dst_hi = lookupHRegRemap(m, dfp_binop->dst_hi);
dfp_binop->op2_hi = lookupHRegRemap(m, dfp_binop->op2_hi);
dfp_binop->op3_hi = lookupHRegRemap(m, dfp_binop->op3_hi);
if (insn->size == 16) {
dfp_binop->dst_lo = lookupHRegRemap(m, dfp_binop->dst_lo);
dfp_binop->op2_lo = lookupHRegRemap(m, dfp_binop->op2_lo);
dfp_binop->op3_lo = lookupHRegRemap(m, dfp_binop->op3_lo);
}
break;
}
case S390_INSN_DFP_UNOP:
insn->variant.dfp_unop.dst_hi =
lookupHRegRemap(m, insn->variant.dfp_unop.dst_hi);
insn->variant.dfp_unop.op_hi =
lookupHRegRemap(m, insn->variant.dfp_unop.op_hi);
if (insn->size == 16) {
insn->variant.dfp_unop.dst_lo =
lookupHRegRemap(m, insn->variant.dfp_unop.dst_lo);
insn->variant.dfp_unop.op_lo =
lookupHRegRemap(m, insn->variant.dfp_unop.op_lo);
}
break;
case S390_INSN_DFP_INTOP:
insn->variant.dfp_intop.dst_hi =
lookupHRegRemap(m, insn->variant.dfp_intop.dst_hi);
insn->variant.dfp_intop.op2 =
lookupHRegRemap(m, insn->variant.dfp_intop.op2);
insn->variant.dfp_intop.op3_hi =
lookupHRegRemap(m, insn->variant.dfp_intop.op3_hi);
if (insn->size == 16) {
insn->variant.dfp_intop.dst_lo =
lookupHRegRemap(m, insn->variant.dfp_intop.dst_lo);
insn->variant.dfp_intop.op3_lo =
lookupHRegRemap(m, insn->variant.dfp_intop.op3_lo);
}
break;
case S390_INSN_DFP_COMPARE:
insn->variant.dfp_compare.dst =
lookupHRegRemap(m, insn->variant.dfp_compare.dst);
insn->variant.dfp_compare.op1_hi =
lookupHRegRemap(m, insn->variant.dfp_compare.op1_hi);
insn->variant.dfp_compare.op2_hi =
lookupHRegRemap(m, insn->variant.dfp_compare.op2_hi);
if (insn->size == 16) {
insn->variant.dfp_compare.op1_lo =
lookupHRegRemap(m, insn->variant.dfp_compare.op1_lo);
insn->variant.dfp_compare.op2_lo =
lookupHRegRemap(m, insn->variant.dfp_compare.op2_lo);
}
break;
case S390_INSN_DFP_CONVERT:
insn->variant.dfp_convert.dst_hi =
lookupHRegRemap(m, insn->variant.dfp_convert.dst_hi);
if (! hregIsInvalid(insn->variant.dfp_convert.dst_lo))
insn->variant.dfp_convert.dst_lo =
lookupHRegRemap(m, insn->variant.dfp_convert.dst_lo);
insn->variant.dfp_convert.op_hi =
lookupHRegRemap(m, insn->variant.dfp_convert.op_hi);
if (! hregIsInvalid(insn->variant.dfp_convert.op_lo))
insn->variant.dfp_convert.op_lo =
lookupHRegRemap(m, insn->variant.dfp_convert.op_lo);
break;
case S390_INSN_DFP_REROUND:
insn->variant.dfp_reround.dst_hi =
lookupHRegRemap(m, insn->variant.dfp_reround.dst_hi);
insn->variant.dfp_reround.op2 =
lookupHRegRemap(m, insn->variant.dfp_reround.op2);
insn->variant.dfp_reround.op3_hi =
lookupHRegRemap(m, insn->variant.dfp_reround.op3_hi);
if (insn->size == 16) {
insn->variant.dfp_reround.dst_lo =
lookupHRegRemap(m, insn->variant.dfp_reround.dst_lo);
insn->variant.dfp_reround.op3_lo =
lookupHRegRemap(m, insn->variant.dfp_reround.op3_lo);
}
break;
case S390_INSN_FP_CONVERT: {
s390_fp_convert *fp_convert = insn->variant.fp_convert.details;
fp_convert->dst_hi = lookupHRegRemap(m, fp_convert->dst_hi);
if (! hregIsInvalid(fp_convert->dst_lo))
fp_convert->dst_lo = lookupHRegRemap(m, fp_convert->dst_lo);
fp_convert->op_hi = lookupHRegRemap(m, fp_convert->op_hi);
if (! hregIsInvalid(fp_convert->op_lo))
fp_convert->op_lo = lookupHRegRemap(m, fp_convert->op_lo);
fp_convert->r1 = lookupHRegRemap(m, fp_convert->r1);
break;
}
case S390_INSN_MIMM:
s390_amode_map_regs(m, insn->variant.mimm.dst);
break;
case S390_INSN_MADD:
s390_amode_map_regs(m, insn->variant.madd.dst);
break;
case S390_INSN_MFENCE:
break;
case S390_INSN_SET_FPC_BFPRM:
insn->variant.set_fpc_bfprm.mode =
lookupHRegRemap(m, insn->variant.set_fpc_bfprm.mode);
break;
case S390_INSN_SET_FPC_DFPRM:
insn->variant.set_fpc_dfprm.mode =
lookupHRegRemap(m, insn->variant.set_fpc_dfprm.mode);
break;
case S390_INSN_EVCHECK:
s390_amode_map_regs(m, insn->variant.evcheck.counter);
s390_amode_map_regs(m, insn->variant.evcheck.fail_addr);
break;
case S390_INSN_PROFINC:
/* Does not use any register visible to the register allocator */
break;
case S390_INSN_XDIRECT:
s390_amode_map_regs(m, insn->variant.xdirect.guest_IA);
break;
case S390_INSN_XINDIR:
s390_amode_map_regs(m, insn->variant.xindir.guest_IA);
insn->variant.xindir.dst =
lookupHRegRemap(m, insn->variant.xindir.dst);
break;
case S390_INSN_XASSISTED:
s390_amode_map_regs(m, insn->variant.xassisted.guest_IA);
insn->variant.xassisted.dst =
lookupHRegRemap(m, insn->variant.xassisted.dst);
break;
default:
vpanic("s390_insn_map_regs");
}
}
/* Return True, if INSN is a move between two registers of the same class.
In that case assign the source and destination registers to SRC and DST,
respectively. */
static Bool
s390_insn_is_reg_reg_move(const s390_insn *insn, HReg *src, HReg *dst)
{
if (insn->tag == S390_INSN_MOVE &&
hregClass(insn->variant.move.src) == hregClass(insn->variant.move.dst)) {
*src = insn->variant.move.src;
*dst = insn->variant.move.dst;
return True;
}
return False;
}
/*------------------------------------------------------------*/
/*--- Functions to emit a sequence of bytes ---*/
/*------------------------------------------------------------*/
static __inline__ UChar *
emit_2bytes(UChar *p, ULong val)
{
return (UChar *)__builtin_memcpy(p, ((UChar *)&val) + 6, 2) + 2;
}
static __inline__ UChar *
emit_4bytes(UChar *p, ULong val)
{
return (UChar *)__builtin_memcpy(p, ((UChar *)&val) + 4, 4) + 4;
}
static __inline__ UChar *
emit_6bytes(UChar *p, ULong val)
{
return (UChar *)__builtin_memcpy(p, ((UChar *)&val) + 2, 6) + 6;
}
/*------------------------------------------------------------*/
/*--- Functions to emit various instruction formats ---*/
/*------------------------------------------------------------*/
static UChar *
emit_RI(UChar *p, UInt op, UChar r1, UShort i2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 20;
the_insn |= ((ULong)i2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RIL(UChar *p, ULong op, UChar r1, UInt i2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 36;
the_insn |= ((ULong)i2) << 0;
return emit_6bytes(p, the_insn);
}
static UChar *
emit_RR(UChar *p, UInt op, UChar r1, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_2bytes(p, the_insn);
}
static UChar *
emit_RRE(UChar *p, UInt op, UChar r1, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RRF(UChar *p, UInt op, UChar r1, UChar r3, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 12;
the_insn |= ((ULong)r3) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RRF2(UChar *p, UInt op, UChar m3, UChar m4, UChar r1, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)m3) << 12;
the_insn |= ((ULong)m4) << 8;
the_insn |= ((ULong)r1) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RRF3(UChar *p, UInt op, UChar r3, UChar r1, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)r3) << 12;
the_insn |= ((ULong)r1) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RRF4(UChar *p, UInt op, UChar r3, UChar m4, UChar r1, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)r3) << 12;
the_insn |= ((ULong)m4) << 8;
the_insn |= ((ULong)r1) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RRF5(UChar *p, UInt op, UChar m4, UChar r1, UChar r2)
{
ULong the_insn = op;
the_insn |= ((ULong)m4) << 8;
the_insn |= ((ULong)r1) << 4;
the_insn |= ((ULong)r2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RS(UChar *p, UInt op, UChar r1, UChar r3, UChar b2, UShort d2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 20;
the_insn |= ((ULong)r3) << 16;
the_insn |= ((ULong)b2) << 12;
the_insn |= ((ULong)d2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RSY(UChar *p, ULong op, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 36;
the_insn |= ((ULong)r3) << 32;
the_insn |= ((ULong)b2) << 28;
the_insn |= ((ULong)dl2) << 16;
the_insn |= ((ULong)dh2) << 8;
return emit_6bytes(p, the_insn);
}
static UChar *
emit_RX(UChar *p, UInt op, UChar r1, UChar x2, UChar b2, UShort d2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 20;
the_insn |= ((ULong)x2) << 16;
the_insn |= ((ULong)b2) << 12;
the_insn |= ((ULong)d2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_RXF(UChar *p, ULong op, UChar r3, UChar x2, UChar b2, UShort d2, UChar r1)
{
ULong the_insn = op;
the_insn |= ((ULong)r3) << 36;
the_insn |= ((ULong)x2) << 32;
the_insn |= ((ULong)b2) << 28;
the_insn |= ((ULong)d2) << 16;
the_insn |= ((ULong)r1) << 12;
return emit_6bytes(p, the_insn);
}
static UChar *
emit_RXY(UChar *p, ULong op, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
ULong the_insn = op;
the_insn |= ((ULong)r1) << 36;
the_insn |= ((ULong)x2) << 32;
the_insn |= ((ULong)b2) << 28;
the_insn |= ((ULong)dl2) << 16;
the_insn |= ((ULong)dh2) << 8;
return emit_6bytes(p, the_insn);
}
static UChar *
emit_S(UChar *p, UInt op, UChar b2, UShort d2)
{
ULong the_insn = op;
the_insn |= ((ULong)b2) << 12;
the_insn |= ((ULong)d2) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_SI(UChar *p, UInt op, UChar i2, UChar b1, UShort d1)
{
ULong the_insn = op;
the_insn |= ((ULong)i2) << 16;
the_insn |= ((ULong)b1) << 12;
the_insn |= ((ULong)d1) << 0;
return emit_4bytes(p, the_insn);
}
static UChar *
emit_SIL(UChar *p, ULong op, UChar b1, UShort d1, UShort i2)
{
ULong the_insn = op;
the_insn |= ((ULong)b1) << 28;
the_insn |= ((ULong)d1) << 16;
the_insn |= ((ULong)i2) << 0;
return emit_6bytes(p, the_insn);
}
static UChar *
emit_SIY(UChar *p, ULong op, UChar i2, UChar b1, UShort dl1, UChar dh1)
{
ULong the_insn = op;
the_insn |= ((ULong)i2) << 32;
the_insn |= ((ULong)b1) << 28;
the_insn |= ((ULong)dl1) << 16;
the_insn |= ((ULong)dh1) << 8;
return emit_6bytes(p, the_insn);
}
static UChar *
emit_SSa(UChar *p, ULong op, UChar l, UChar b1, UShort d1, UChar b2, UShort d2)
{
ULong the_insn = op;
the_insn |= ((ULong)l) << 32;
the_insn |= ((ULong)b1) << 28;
the_insn |= ((ULong)d1) << 16;
the_insn |= ((ULong)b2) << 12;
the_insn |= ((ULong)d2) << 0;
return emit_6bytes(p, the_insn);
}
/*------------------------------------------------------------*/
/*--- Functions to emit particular instructions ---*/
/*------------------------------------------------------------*/
static UChar *
s390_emit_AR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "ar", r1, r2);
return emit_RR(p, 0x1a00, r1, r2);
}
static UChar *
s390_emit_AGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "agr", r1, r2);
return emit_RRE(p, 0xb9080000, r1, r2);
}
static UChar *
s390_emit_A(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "a", r1, d2, x2, b2);
return emit_RX(p, 0x5a000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_AY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ay", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000005aULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_AG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ag", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000008ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_AFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "afi", r1, i2);
return emit_RIL(p, 0xc20900000000ULL, r1, i2);
}
static UChar *
s390_emit_AGFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "agfi", r1, i2);
return emit_RIL(p, 0xc20800000000ULL, r1, i2);
}
static UChar *
s390_emit_AH(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "ah", r1, d2, x2, b2);
return emit_RX(p, 0x4a000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_AHY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ahy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000007aULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_AHI(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "ahi", r1, (Int)(Short)i2);
return emit_RI(p, 0xa70a0000, r1, i2);
}
static UChar *
s390_emit_AGHI(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "aghi", r1, (Int)(Short)i2);
return emit_RI(p, 0xa70b0000, r1, i2);
}
static UChar *
s390_emit_AGSI(UChar *p, UChar i2, UChar b1, UShort dl1, UChar dh1)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, SDXB, INT), "agsi", dh1, dl1, 0, b1, (Int)(Char)i2);
return emit_SIY(p, 0xeb000000007aULL, i2, b1, dl1, dh1);
}
static UChar *
s390_emit_ASI(UChar *p, UChar i2, UChar b1, UShort dl1, UChar dh1)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, SDXB, INT), "asi", dh1, dl1, 0, b1, (Int)(Char)i2);
return emit_SIY(p, 0xeb000000006aULL, i2, b1, dl1, dh1);
}
static UChar *
s390_emit_NR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "nr", r1, r2);
return emit_RR(p, 0x1400, r1, r2);
}
static UChar *
s390_emit_NGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "ngr", r1, r2);
return emit_RRE(p, 0xb9800000, r1, r2);
}
static UChar *
s390_emit_N(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "n", r1, d2, x2, b2);
return emit_RX(p, 0x54000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_NY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ny", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000054ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_NG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ng", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000080ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_NIHF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "nihf", r1, i2);
return emit_RIL(p, 0xc00a00000000ULL, r1, i2);
}
static UChar *
s390_emit_NILF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "nilf", r1, i2);
return emit_RIL(p, 0xc00b00000000ULL, r1, i2);
}
static UChar *
s390_emit_NILL(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "nill", r1, i2);
return emit_RI(p, 0xa5070000, r1, i2);
}
static UChar *
s390_emit_BASR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "basr", r1, r2);
return emit_RR(p, 0x0d00, r1, r2);
}
static UChar *
s390_emit_BCR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(XMNM, GPR), S390_XMNM_BCR, r1, r2);
return emit_RR(p, 0x0700, r1, r2);
}
static UChar *
s390_emit_BRC(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(XMNM, PCREL), S390_XMNM_BRC, r1, (Int)(Short)i2);
return emit_RI(p, 0xa7040000, r1, i2);
}
static UChar *
s390_emit_BRCL(UChar *p, UChar r1, ULong i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(XMNM, PCREL), S390_XMNM_BRCL, r1, i2);
return emit_RIL(p, 0xc00400000000ULL, r1, i2);
}
static UChar *
s390_emit_CR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "cr", r1, r2);
return emit_RR(p, 0x1900, r1, r2);
}
static UChar *
s390_emit_CGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "cgr", r1, r2);
return emit_RRE(p, 0xb9200000, r1, r2);
}
static UChar *
s390_emit_C(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "c", r1, d2, x2, b2);
return emit_RX(p, 0x59000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_CY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "cy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000059ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_CG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "cg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000020ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_CFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "cfi", r1, i2);
return emit_RIL(p, 0xc20d00000000ULL, r1, i2);
}
static UChar *
s390_emit_CGFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "cgfi", r1, i2);
return emit_RIL(p, 0xc20c00000000ULL, r1, i2);
}
static UChar *
s390_emit_CS(UChar *p, UChar r1, UChar r3, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, UDXB), "cs", r1, r3, d2, 0, b2);
return emit_RS(p, 0xba000000, r1, r3, b2, d2);
}
static UChar *
s390_emit_CSY(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "csy", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb0000000014ULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_CSG(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "csg", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb0000000030ULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_CDS(UChar *p, UChar r1, UChar r3, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, UDXB), "cds", r1, r3, d2, 0, b2);
return emit_RS(p, 0xbb000000, r1, r3, b2, d2);
}
static UChar *
s390_emit_CDSY(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "cdsy", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb0000000031ULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_CDSG(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "cdsg", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb000000003eULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_CLR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "clr", r1, r2);
return emit_RR(p, 0x1500, r1, r2);
}
static UChar *
s390_emit_CLGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "clgr", r1, r2);
return emit_RRE(p, 0xb9210000, r1, r2);
}
static UChar *
s390_emit_CL(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "cl", r1, d2, x2, b2);
return emit_RX(p, 0x55000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_CLY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "cly", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000055ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_CLG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "clg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000021ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_CLFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "clfi", r1, i2);
return emit_RIL(p, 0xc20f00000000ULL, r1, i2);
}
static UChar *
s390_emit_CLGFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "clgfi", r1, i2);
return emit_RIL(p, 0xc20e00000000ULL, r1, i2);
}
static UChar *
s390_emit_DR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "dr", r1, r2);
return emit_RR(p, 0x1d00, r1, r2);
}
static UChar *
s390_emit_D(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "d", r1, d2, x2, b2);
return emit_RX(p, 0x5d000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_DLR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "dlr", r1, r2);
return emit_RRE(p, 0xb9970000, r1, r2);
}
static UChar *
s390_emit_DLGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "dlgr", r1, r2);
return emit_RRE(p, 0xb9870000, r1, r2);
}
static UChar *
s390_emit_DL(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "dl", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000097ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_DLG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "dlg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000087ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_DSGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "dsgr", r1, r2);
return emit_RRE(p, 0xb90d0000, r1, r2);
}
static UChar *
s390_emit_DSG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "dsg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000000dULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_XR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "xr", r1, r2);
return emit_RR(p, 0x1700, r1, r2);
}
static UChar *
s390_emit_XGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "xgr", r1, r2);
return emit_RRE(p, 0xb9820000, r1, r2);
}
static UChar *
s390_emit_X(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "x", r1, d2, x2, b2);
return emit_RX(p, 0x57000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_XY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "xy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000057ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_XG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "xg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000082ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_XIHF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "xihf", r1, i2);
return emit_RIL(p, 0xc00600000000ULL, r1, i2);
}
static UChar *
s390_emit_XILF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "xilf", r1, i2);
return emit_RIL(p, 0xc00700000000ULL, r1, i2);
}
static UChar *
s390_emit_XC(UChar *p, UInt l, UChar b1, UShort d1, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, UDLB, UDXB), "xc", d1, l, b1, d2, 0, b2);
return emit_SSa(p, 0xd70000000000ULL, l, b1, d1, b2, d2);
}
static UChar *
s390_emit_FLOGR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "flogr", r1, r2);
return emit_RRE(p, 0xb9830000, r1, r2);
}
static UChar *
s390_emit_IC(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "ic", r1, d2, x2, b2);
return emit_RX(p, 0x43000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_ICY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "icy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000073ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_IIHF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "iihf", r1, i2);
return emit_RIL(p, 0xc00800000000ULL, r1, i2);
}
static UChar *
s390_emit_IIHH(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "iihh", r1, i2);
return emit_RI(p, 0xa5000000, r1, i2);
}
static UChar *
s390_emit_IIHL(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "iihl", r1, i2);
return emit_RI(p, 0xa5010000, r1, i2);
}
static UChar *
s390_emit_IILF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "iilf", r1, i2);
return emit_RIL(p, 0xc00900000000ULL, r1, i2);
}
static UChar *
s390_emit_IILH(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "iilh", r1, i2);
return emit_RI(p, 0xa5020000, r1, i2);
}
static UChar *
s390_emit_IILL(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "iill", r1, i2);
return emit_RI(p, 0xa5030000, r1, i2);
}
static UChar *
s390_emit_IPM(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(MNM, GPR), "ipm", r1);
return emit_RRE(p, 0xb2220000, r1, r2);
}
static UChar *
s390_emit_LR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lr", r1, r2);
return emit_RR(p, 0x1800, r1, r2);
}
static UChar *
s390_emit_LGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lgr", r1, r2);
return emit_RRE(p, 0xb9040000, r1, r2);
}
static UChar *
s390_emit_LGFR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lgfr", r1, r2);
return emit_RRE(p, 0xb9140000, r1, r2);
}
static UChar *
s390_emit_L(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "l", r1, d2, x2, b2);
return emit_RX(p, 0x58000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_LY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ly", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000058ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000004ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LGF(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lgf", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000014ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LGFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "lgfi", r1, i2);
return emit_RIL(p, 0xc00100000000ULL, r1, i2);
}
static UChar *
s390_emit_LTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "ltr", r1, r2);
return emit_RR(p, 0x1200, r1, r2);
}
static UChar *
s390_emit_LTGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "ltgr", r1, r2);
return emit_RRE(p, 0xb9020000, r1, r2);
}
static UChar *
s390_emit_LT(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lt", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000012ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LTG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ltg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000002ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LBR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lbr", r1, r2);
return emit_RRE(p, 0xb9260000, r1, r2);
}
static UChar *
s390_emit_LGBR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lgbr", r1, r2);
return emit_RRE(p, 0xb9060000, r1, r2);
}
static UChar *
s390_emit_LB(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lb", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000076ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LGB(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lgb", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000077ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LCR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lcr", r1, r2);
return emit_RR(p, 0x1300, r1, r2);
}
static UChar *
s390_emit_LCGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lcgr", r1, r2);
return emit_RRE(p, 0xb9030000, r1, r2);
}
static UChar *
s390_emit_LHR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lhr", r1, r2);
return emit_RRE(p, 0xb9270000, r1, r2);
}
static UChar *
s390_emit_LGHR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "lghr", r1, r2);
return emit_RRE(p, 0xb9070000, r1, r2);
}
static UChar *
s390_emit_LH(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "lh", r1, d2, x2, b2);
return emit_RX(p, 0x48000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_LHY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lhy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000078ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LGH(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "lgh", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000015ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LHI(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "lhi", r1, (Int)(Short)i2);
return emit_RI(p, 0xa7080000, r1, i2);
}
static UChar *
s390_emit_LGHI(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "lghi", r1, (Int)(Short)i2);
return emit_RI(p, 0xa7090000, r1, i2);
}
static UChar *
s390_emit_LLGFR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "llgfr", r1, r2);
return emit_RRE(p, 0xb9160000, r1, r2);
}
static UChar *
s390_emit_LLGF(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "llgf", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000016ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LLCR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "llcr", r1, r2);
return emit_RRE(p, 0xb9940000, r1, r2);
}
static UChar *
s390_emit_LLGCR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "llgcr", r1, r2);
return emit_RRE(p, 0xb9840000, r1, r2);
}
static UChar *
s390_emit_LLC(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "llc", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000094ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LLGC(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "llgc", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000090ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LLHR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "llhr", r1, r2);
return emit_RRE(p, 0xb9950000, r1, r2);
}
static UChar *
s390_emit_LLGHR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "llghr", r1, r2);
return emit_RRE(p, 0xb9850000, r1, r2);
}
static UChar *
s390_emit_LLH(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "llh", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000095ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LLGH(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "llgh", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000091ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LLILF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "llilf", r1, i2);
return emit_RIL(p, 0xc00f00000000ULL, r1, i2);
}
static UChar *
s390_emit_LLILH(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "llilh", r1, i2);
return emit_RI(p, 0xa50e0000, r1, i2);
}
static UChar *
s390_emit_LLILL(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "llill", r1, i2);
return emit_RI(p, 0xa50f0000, r1, i2);
}
static UChar *
s390_emit_MR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "mr", r1, r2);
return emit_RR(p, 0x1c00, r1, r2);
}
static UChar *
s390_emit_M(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "m", r1, d2, x2, b2);
return emit_RX(p, 0x5c000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_MFY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "mfy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000005cULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_MH(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "mh", r1, d2, x2, b2);
return emit_RX(p, 0x4c000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_MHY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "mhy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000007cULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_MHI(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "mhi", r1, (Int)(Short)i2);
return emit_RI(p, 0xa70c0000, r1, i2);
}
static UChar *
s390_emit_MLR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "mlr", r1, r2);
return emit_RRE(p, 0xb9960000, r1, r2);
}
static UChar *
s390_emit_MLGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "mlgr", r1, r2);
return emit_RRE(p, 0xb9860000, r1, r2);
}
static UChar *
s390_emit_ML(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "ml", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000096ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_MLG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "mlg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000086ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_MSR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "msr", r1, r2);
return emit_RRE(p, 0xb2520000, r1, r2);
}
static UChar *
s390_emit_MSGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "msgr", r1, r2);
return emit_RRE(p, 0xb90c0000, r1, r2);
}
static UChar *
s390_emit_MS(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "ms", r1, d2, x2, b2);
return emit_RX(p, 0x71000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_MSY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "msy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000051ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_MSG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "msg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000000cULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_MSFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "msfi", r1, i2);
return emit_RIL(p, 0xc20100000000ULL, r1, i2);
}
static UChar *
s390_emit_MSGFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, INT), "msgfi", r1, i2);
return emit_RIL(p, 0xc20000000000ULL, r1, i2);
}
static UChar *
s390_emit_MVC(UChar *p, UInt l, UChar b1, UShort d1, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, UDLB, UDXB), "mvc", d1, l, b1, d2, 0, b2);
return emit_SSa(p, 0xd20000000000ULL, l, b1, d1, b2, d2);
}
static UChar *
s390_emit_MVI(UChar *p, UChar i2, UChar b1, UShort d1)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, UDXB, INT), "mvi", d1, 0, b1, i2);
return emit_SI(p, 0x92000000, i2, b1, d1);
}
static UChar *
s390_emit_MVHHI(UChar *p, UChar b1, UShort d1, UShort i2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, UDXB, INT), "mvhhi", d1, 0, b1, i2);
return emit_SIL(p, 0xe54400000000ULL, b1, d1, i2);
}
static UChar *
s390_emit_MVHI(UChar *p, UChar b1, UShort d1, UShort i2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, UDXB, INT), "mvhi", d1, 0, b1, i2);
return emit_SIL(p, 0xe54c00000000ULL, b1, d1, i2);
}
static UChar *
s390_emit_MVGHI(UChar *p, UChar b1, UShort d1, UShort i2)
{
vassert(s390_host_has_gie);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, UDXB, INT), "mvghi", d1, 0, b1, i2);
return emit_SIL(p, 0xe54800000000ULL, b1, d1, i2);
}
static UChar *
s390_emit_OR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "or", r1, r2);
return emit_RR(p, 0x1600, r1, r2);
}
static UChar *
s390_emit_OGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "ogr", r1, r2);
return emit_RRE(p, 0xb9810000, r1, r2);
}
static UChar *
s390_emit_O(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "o", r1, d2, x2, b2);
return emit_RX(p, 0x56000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_OY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "oy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000056ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_OG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "og", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000081ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_OIHF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "oihf", r1, i2);
return emit_RIL(p, 0xc00c00000000ULL, r1, i2);
}
static UChar *
s390_emit_OILF(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "oilf", r1, i2);
return emit_RIL(p, 0xc00d00000000ULL, r1, i2);
}
static UChar *
s390_emit_OILL(UChar *p, UChar r1, UShort i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "oill", r1, i2);
return emit_RI(p, 0xa50b0000, r1, i2);
}
static UChar *
s390_emit_SLL(UChar *p, UChar r1, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "sll", r1, d2, 0, b2);
return emit_RS(p, 0x89000000, r1, 0, b2, d2);
}
static UChar *
s390_emit_SLLG(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "sllg", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb000000000dULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_SRA(UChar *p, UChar r1, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "sra", r1, d2, 0, b2);
return emit_RS(p, 0x8a000000, r1, 0, b2, d2);
}
static UChar *
s390_emit_SRAG(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "srag", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb000000000aULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_SRL(UChar *p, UChar r1, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "srl", r1, d2, 0, b2);
return emit_RS(p, 0x88000000, r1, 0, b2, d2);
}
static UChar *
s390_emit_SRLG(UChar *p, UChar r1, UChar r3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, SDXB), "srlg", r1, r3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb000000000cULL, r1, r3, b2, dl2, dh2);
}
static UChar *
s390_emit_ST(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "st", r1, d2, x2, b2);
return emit_RX(p, 0x50000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_STY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "sty", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000050ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_STG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "stg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000024ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_STC(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "stc", r1, d2, x2, b2);
return emit_RX(p, 0x42000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_STCY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "stcy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000072ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_STH(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "sth", r1, d2, x2, b2);
return emit_RX(p, 0x40000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_STHY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "sthy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000070ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_SR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "sr", r1, r2);
return emit_RR(p, 0x1b00, r1, r2);
}
static UChar *
s390_emit_SGR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, GPR), "sgr", r1, r2);
return emit_RRE(p, 0xb9090000, r1, r2);
}
static UChar *
s390_emit_S(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "s", r1, d2, x2, b2);
return emit_RX(p, 0x5b000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_SY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "sy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000005bULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_SG(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "sg", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe30000000009ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_SH(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UDXB), "sh", r1, d2, x2, b2);
return emit_RX(p, 0x4b000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_SHY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, SDXB), "shy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xe3000000007bULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_SLFI(UChar *p, UChar r1, UInt i2)
{
vassert(s390_host_has_eimm);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "slfi", r1, i2);
return emit_RIL(p, 0xc20500000000ULL, r1, i2);
}
static UChar *
s390_emit_SLGFI(UChar *p, UChar r1, UInt i2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, UINT), "slgfi", r1, i2);
return emit_RIL(p, 0xc20400000000ULL, r1, i2);
}
static UChar *
s390_emit_LDR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "ldr", r1, r2);
return emit_RR(p, 0x2800, r1, r2);
}
static UChar *
s390_emit_LE(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, UDXB), "le", r1, d2, x2, b2);
return emit_RX(p, 0x78000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_LD(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, UDXB), "ld", r1, d2, x2, b2);
return emit_RX(p, 0x68000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_LEY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, SDXB), "ley", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xed0000000064ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LDY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, SDXB), "ldy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xed0000000065ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_LFPC(UChar *p, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(MNM, UDXB), "lfpc", d2, 0, b2);
return emit_S(p, 0xb29d0000, b2, d2);
}
static UChar *
s390_emit_LDGR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_fgx);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, GPR), "ldgr", r1, r2);
return emit_RRE(p, 0xb3c10000, r1, r2);
}
static UChar *
s390_emit_LGDR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_fgx);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, FPR), "lgdr", r1, r2);
return emit_RRE(p, 0xb3cd0000, r1, r2);
}
static UChar *
s390_emit_LZER(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(MNM, FPR), "lzer", r1);
return emit_RRE(p, 0xb3740000, r1, r2);
}
static UChar *
s390_emit_LZDR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(MNM, FPR), "lzdr", r1);
return emit_RRE(p, 0xb3750000, r1, r2);
}
static UChar *
s390_emit_SFPC(UChar *p, UChar r1)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(MNM, GPR), "sfpc", r1);
return emit_RRE(p, 0xb3840000, r1, 0);
}
static UChar *
s390_emit_STE(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, UDXB), "ste", r1, d2, x2, b2);
return emit_RX(p, 0x70000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_STD(UChar *p, UChar r1, UChar x2, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, UDXB), "std", r1, d2, x2, b2);
return emit_RX(p, 0x60000000, r1, x2, b2, d2);
}
static UChar *
s390_emit_STEY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, SDXB), "stey", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xed0000000066ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_STDY(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, SDXB), "stdy", r1, dh2, dl2, x2, b2);
return emit_RXY(p, 0xed0000000067ULL, r1, x2, b2, dl2, dh2);
}
static UChar *
s390_emit_STFPC(UChar *p, UChar b2, UShort d2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC2(MNM, UDXB), "stfpc", d2, 0, b2);
return emit_S(p, 0xb29c0000, b2, d2);
}
static UChar *
s390_emit_AEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "aebr", r1, r2);
return emit_RRE(p, 0xb30a0000, r1, r2);
}
static UChar *
s390_emit_ADBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "adbr", r1, r2);
return emit_RRE(p, 0xb31a0000, r1, r2);
}
static UChar *
s390_emit_AXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "axbr", r1, r2);
return emit_RRE(p, 0xb34a0000, r1, r2);
}
static UChar *
s390_emit_CEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cebr", r1, r2);
return emit_RRE(p, 0xb3090000, r1, r2);
}
static UChar *
s390_emit_CDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cdbr", r1, r2);
return emit_RRE(p, 0xb3190000, r1, r2);
}
static UChar *
s390_emit_CXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cxbr", r1, r2);
return emit_RRE(p, 0xb3490000, r1, r2);
}
static UChar *
s390_emit_CEFBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cefbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT),
"cefbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3940000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDFBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cdfbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT),
"cdfbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3950000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXFBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cxfbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT),
"cxfbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3960000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CEGBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cegbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT),
"cegbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3a40000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDGBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cdgbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT),
"cdgbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3a50000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXGBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cxgbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT),
"cxgbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3a60000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CELFBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "celfbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3900000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDLFBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cdlfbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3910000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXLFBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cxlfbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3920000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CELGBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "celgbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3a00000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDLGBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cdlgbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3a10000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXLGBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cxlgbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3a20000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLFEBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clfebr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb39c0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLFDBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clfdbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb39d0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLFXBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clfxbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb39e0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLGEBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clgebr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3ac0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLGDBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clgdbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3ad0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLGXBR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clgxbr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3ae0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CFEBR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cfebr", r1, r3, r2);
return emit_RRF3(p, 0xb3980000, r3, r1, r2);
}
static UChar *
s390_emit_CFDBR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cfdbr", r1, r3, r2);
return emit_RRF3(p, 0xb3990000, r3, r1, r2);
}
static UChar *
s390_emit_CFXBR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cfxbr", r1, r3, r2);
return emit_RRF3(p, 0xb39a0000, r3, r1, r2);
}
static UChar *
s390_emit_CGEBR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cgebr", r1, r3, r2);
return emit_RRF3(p, 0xb3a80000, r3, r1, r2);
}
static UChar *
s390_emit_CGDBR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cgdbr", r1, r3, r2);
return emit_RRF3(p, 0xb3a90000, r3, r1, r2);
}
static UChar *
s390_emit_CGXBR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cgxbr", r1, r3, r2);
return emit_RRF3(p, 0xb3aa0000, r3, r1, r2);
}
static UChar *
s390_emit_DEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "debr", r1, r2);
return emit_RRE(p, 0xb30d0000, r1, r2);
}
static UChar *
s390_emit_DDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "ddbr", r1, r2);
return emit_RRE(p, 0xb31d0000, r1, r2);
}
static UChar *
s390_emit_DXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "dxbr", r1, r2);
return emit_RRE(p, 0xb34d0000, r1, r2);
}
static UChar *
s390_emit_LCEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lcebr", r1, r2);
return emit_RRE(p, 0xb3030000, r1, r2);
}
static UChar *
s390_emit_LCDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lcdbr", r1, r2);
return emit_RRE(p, 0xb3130000, r1, r2);
}
static UChar *
s390_emit_LCXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lcxbr", r1, r2);
return emit_RRE(p, 0xb3430000, r1, r2);
}
static UChar *
s390_emit_LDEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "ldebr", r1, r2);
return emit_RRE(p, 0xb3040000, r1, r2);
}
static UChar *
s390_emit_LXDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lxdbr", r1, r2);
return emit_RRE(p, 0xb3050000, r1, r2);
}
static UChar *
s390_emit_LXEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lxebr", r1, r2);
return emit_RRE(p, 0xb3060000, r1, r2);
}
static UChar *
s390_emit_LNEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lnebr", r1, r2);
return emit_RRE(p, 0xb3010000, r1, r2);
}
static UChar *
s390_emit_LNDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lndbr", r1, r2);
return emit_RRE(p, 0xb3110000, r1, r2);
}
static UChar *
s390_emit_LNXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lnxbr", r1, r2);
return emit_RRE(p, 0xb3410000, r1, r2);
}
static UChar *
s390_emit_LPEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lpebr", r1, r2);
return emit_RRE(p, 0xb3000000, r1, r2);
}
static UChar *
s390_emit_LPDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lpdbr", r1, r2);
return emit_RRE(p, 0xb3100000, r1, r2);
}
static UChar *
s390_emit_LPXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "lpxbr", r1, r2);
return emit_RRE(p, 0xb3400000, r1, r2);
}
static UChar *
s390_emit_LEDBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, FPR), "ledbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT),
"ledbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3440000, m3, m4, r1, r2);
}
static UChar *
s390_emit_LDXBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, FPR), "ldxbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT),
"ldxbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3450000, m3, m4, r1, r2);
}
static UChar *
s390_emit_LEXBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, FPR), "lexbr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT),
"lexbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3460000, m3, m4, r1, r2);
}
static UChar *
s390_emit_FIEBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, UINT, FPR), "fiebr", r1, m3, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT),
"fiebra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3570000, m3, m4, r1, r2);
}
static UChar *
s390_emit_FIDBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, UINT, FPR), "fidbr", r1, m3, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT),
"fidbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb35f0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_FIXBRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, UINT, FPR), "fixbr", r1, m3, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT),
"fixbra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3470000, m3, m4, r1, r2);
}
static UChar *
s390_emit_MEEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "meebr", r1, r2);
return emit_RRE(p, 0xb3170000, r1, r2);
}
static UChar *
s390_emit_MDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "mdbr", r1, r2);
return emit_RRE(p, 0xb31c0000, r1, r2);
}
static UChar *
s390_emit_MXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "mxbr", r1, r2);
return emit_RRE(p, 0xb34c0000, r1, r2);
}
static UChar *
s390_emit_MAEBR(UChar *p, UChar r1, UChar r3, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "maebr", r1, r3, r2);
return emit_RRF(p, 0xb30e0000, r1, r3, r2);
}
static UChar *
s390_emit_MADBR(UChar *p, UChar r1, UChar r3, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "madbr", r1, r3, r2);
return emit_RRF(p, 0xb31e0000, r1, r3, r2);
}
static UChar *
s390_emit_MSEBR(UChar *p, UChar r1, UChar r3, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "msebr", r1, r3, r2);
return emit_RRF(p, 0xb30f0000, r1, r3, r2);
}
static UChar *
s390_emit_MSDBR(UChar *p, UChar r1, UChar r3, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "msdbr", r1, r3, r2);
return emit_RRF(p, 0xb31f0000, r1, r3, r2);
}
static UChar *
s390_emit_SQEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "sqebr", r1, r2);
return emit_RRE(p, 0xb3140000, r1, r2);
}
static UChar *
s390_emit_SQDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "sqdbr", r1, r2);
return emit_RRE(p, 0xb3150000, r1, r2);
}
static UChar *
s390_emit_SQXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "sqxbr", r1, r2);
return emit_RRE(p, 0xb3160000, r1, r2);
}
static UChar *
s390_emit_SEBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "sebr", r1, r2);
return emit_RRE(p, 0xb30b0000, r1, r2);
}
static UChar *
s390_emit_SDBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "sdbr", r1, r2);
return emit_RRE(p, 0xb31b0000, r1, r2);
}
static UChar *
s390_emit_SXBR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "sxbr", r1, r2);
return emit_RRE(p, 0xb34b0000, r1, r2);
}
static UChar *
s390_emit_ADTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "adtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "adtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3d20000, r3, m4, r1, r2);
}
static UChar *
s390_emit_AXTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "axtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "axtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3da0000, r3, m4, r1, r2);
}
static UChar *
s390_emit_CDTR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cdtr", r1, r2);
return emit_RRE(p, 0xb3e40000, r1, r2);
}
static UChar *
s390_emit_CXTR(UChar *p, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cxtr", r1, r2);
return emit_RRE(p, 0xb3ec0000, r1, r2);
}
static UChar *
s390_emit_CDGTRA(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0);
vassert(m3 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m3 == 0)
s390_disasm(ENC3(MNM, FPR, GPR), "cdgtr", r1, r2);
else
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cdgtra", r1, m3, r2, m4);
}
return emit_RRF2(p, 0xb3f10000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXGTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0);
/* rounding mode m3 is not considered, as the corresponding
IRop (Iop_I64StoD128) does not take rounding mode. */
vassert(m3 == 0);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, GPR), "cxgtr", r1, r2);
return emit_RRF2(p, 0xb3f90000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDFTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cdftr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9510000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXFTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cxftr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9590000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDLFTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cdlftr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9530000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXLFTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cxlftr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb95b0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CDLGTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cdlgtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9520000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CXLGTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, GPR, UINT), "cxlgtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb95a0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CEDTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cedtr", r1, r2);
return emit_RRE(p, 0xb3f40000, r1, r2);
}
static UChar *
s390_emit_CEXTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, FPR, FPR), "cextr", r1, r2);
return emit_RRE(p, 0xb3fc0000, r1, r2);
}
static UChar *
s390_emit_CFDTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "cfdtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9410000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CFXTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "cfxtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9490000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CGDTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0);
vassert(s390_host_has_fpext || m3 < 1 || m3 > 7);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cgdtr", r1, m3, r2);
return emit_RRF2(p, 0xb3e10000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CGXTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0);
vassert(s390_host_has_fpext || m3 < 1 || m3 > 7);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, FPR), "cgxtr", r1, m3, r2);
return emit_RRF2(p, 0xb3e90000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLFDTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clfdtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9430000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLFXTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clfxtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb94b0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLGDTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clgdtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb9420000, m3, m4, r1, r2);
}
static UChar *
s390_emit_CLGXTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(m4 == 0);
vassert(s390_host_has_dfp);
vassert(s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, GPR, UINT, FPR, UINT), "clgxtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb94a0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_DDTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "ddtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "ddtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3d10000, r3, m4, r1, r2);
}
static UChar *
s390_emit_DXTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "dxtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "dxtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3d90000, r3, m4, r1, r2);
}
static UChar *
s390_emit_EEDTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, FPR), "eedtr", r1, r2);
return emit_RRE(p, 0xb3e50000, r1, r2);
}
static UChar *
s390_emit_EEXTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, FPR), "eextr", r1, r2);
return emit_RRE(p, 0xb3ed0000, r1, r2);
}
static UChar *
s390_emit_ESDTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, FPR), "esdtr", r1, r2);
return emit_RRE(p, 0xb3e70000, r1, r2);
}
static UChar *
s390_emit_ESXTR(UChar *p, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC3(MNM, GPR, FPR), "esxtr", r1, r2);
return emit_RRE(p, 0xb3ef0000, r1, r2);
}
static UChar *
s390_emit_IEDTR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, GPR), "iedtr", r1, r3, r2);
return emit_RRF(p, 0xb3f60000, r3, r1, r2);
}
static UChar *
s390_emit_IEXTR(UChar *p, UChar r3, UChar r1, UChar r2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, GPR), "iextr", r1, r3, r2);
return emit_RRF(p, 0xb3fe0000, r3, r1, r2);
}
static UChar *
s390_emit_LDETR(UChar *p, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, UINT), "ldetr", r1, r2, m4);
return emit_RRF5(p, 0xb3d40000, m4, r1, r2);
}
static UChar *
s390_emit_LXDTR(UChar *p, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, UINT), "lxdtr", r1, r2, m4);
return emit_RRF5(p, 0xb3dc0000, m4, r1, r2);
}
static UChar *
s390_emit_LEDTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0);
vassert(s390_host_has_fpext || m3 < 1 || m3 > 7);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT), "ledtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3d50000, m3, m4, r1, r2);
}
static UChar *
s390_emit_LDXTR(UChar *p, UChar m3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0);
vassert(s390_host_has_fpext || m3 < 1 || m3 > 7);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, UINT, FPR, UINT), "ldxtr", r1, m3, r2, m4);
return emit_RRF2(p, 0xb3dd0000, m3, m4, r1, r2);
}
static UChar *
s390_emit_MDTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "mdtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "mdtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3d00000, r3, m4, r1, r2);
}
static UChar *
s390_emit_MXTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "mxtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "mxtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3d80000, r3, m4, r1, r2);
}
static UChar *
emit_E(UChar *p, UInt op)
{
ULong the_insn = op;
return emit_2bytes(p, the_insn);
}
static UChar *
s390_emit_PFPO(UChar *p)
{
vassert(s390_host_has_pfpo);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
s390_disasm(ENC1(MNM), "pfpo");
}
return emit_E(p, 0x010a);
}
static UChar *
s390_emit_QADTR(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "qadtr", r1, r3, r2, m4);
return emit_RRF4(p, 0xb3f50000, r3, m4, r1, r2);
}
static UChar *
s390_emit_QAXTR(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "qaxtr", r1, r3, r2, m4);
return emit_RRF4(p, 0xb3fd0000, r3, m4, r1, r2);
}
static UChar *
s390_emit_RRDTR(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, FPR, GPR, UINT), "rrdtr", r1, r3, r2, m4);
return emit_RRF4(p, 0xb3f70000, r3, m4, r1, r2);
}
static UChar *
s390_emit_RRXTR(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC5(MNM, FPR, FPR, GPR, UINT), "rrxtr", r1, r3, r2, m4);
return emit_RRF4(p, 0xb3ff0000, r3, m4, r1, r2);
}
static UChar *
s390_emit_SDTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "sdtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "sdtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3d30000, r3, m4, r1, r2);
}
static UChar *
s390_emit_SXTRA(UChar *p, UChar r3, UChar m4, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
vassert(m4 == 0 || s390_host_has_fpext);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM)) {
if (m4 == 0)
s390_disasm(ENC4(MNM, FPR, FPR, FPR), "sxtr", r1, r2, r3);
else
s390_disasm(ENC5(MNM, FPR, FPR, FPR, UINT), "sxtra", r1, r2, r3, m4);
}
return emit_RRF4(p, 0xb3db0000, r3, m4, r1, r2);
}
static UChar *
s390_emit_SLDT(UChar *p, UChar r3, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, UDXB), "sldt", r1, r3, 0, 0, r2);
return emit_RXF(p, 0xED0000000040ULL, r3, 0, r2, 0, r1);
}
static UChar *
s390_emit_SLXT(UChar *p, UChar r3, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, UDXB), "slxt", r1, r3, 0, 0, r2);
return emit_RXF(p, 0xED0000000048ULL, r3, 0, r2, 0, r1);
}
static UChar *
s390_emit_SRDT(UChar *p, UChar r3, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, UDXB), "srdt", r1, r3, 0, 0, r2);
return emit_RXF(p, 0xED0000000041ULL, r3, 0, r2, 0, r1);
}
static UChar *
s390_emit_SRXT(UChar *p, UChar r3, UChar r1, UChar r2)
{
vassert(s390_host_has_dfp);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, FPR, FPR, UDXB), "srxt", r1, r3, 0, 0, r2);
return emit_RXF(p, 0xED0000000049ULL, r3, 0, r2, 0, r1);
}
static UChar *
s390_emit_LOCGR(UChar *p, UChar m3, UChar r1, UChar r2)
{
vassert(s390_host_has_lsc);
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, GPR, UINT), "locgr", r1, r2, m3);
return emit_RRF3(p, 0xb9e20000, m3, r1, r2);
}
static UChar *
s390_emit_LOC(UChar *p, UChar r1, UChar m3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, SDXB), "loc", r1, m3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb00000000f2ULL, r1, m3, b2, dl2, dh2);
}
static UChar *
s390_emit_LOCG(UChar *p, UChar r1, UChar m3, UChar b2, UShort dl2, UChar dh2)
{
if (UNLIKELY(vex_traceflags & VEX_TRACE_ASM))
s390_disasm(ENC4(MNM, GPR, UINT, SDXB), "locg", r1, m3, dh2, dl2, 0, b2);
return emit_RSY(p, 0xeb00000000e2ULL, r1, m3, b2, dl2, dh2);
}
/* Provide a symbolic name for register "R0" */
#define R0 0
/* Split up a 20-bit displacement into its high and low piece
suitable for passing as function arguments */
#define DISP20(d) (((UInt)d) & 0xFFF), ((((UInt)d) >> 12) & 0xFF)
/*---------------------------------------------------------------*/
/*--- Helper functions ---*/
/*---------------------------------------------------------------*/
static __inline__ Bool
uint_fits_signed_16bit(UInt val)
{
UInt v = val & 0xFFFFu;
/* sign extend */
v = (Int)(v << 16) >> 16;
return val == v;
}
static __inline__ Bool
ulong_fits_signed_16bit(ULong val)
{
ULong v = val & 0xFFFFu;
/* sign extend */
v = (Long)(v << 48) >> 48;
return val == v;
}
static __inline__ Bool
ulong_fits_signed_32bit(ULong val)
{
ULong v = val & 0xFFFFFFFFu;
/* sign extend */
v = (Long)(v << 32) >> 32;
return val == v;
}
static __inline__ Bool
ulong_fits_unsigned_32bit(ULong val)
{
return (val & 0xFFFFFFFFu) == val;
}
/* Load a 64-bit immediate VAL into register REG. */
static UChar *
s390_emit_load_64imm(UChar *p, UChar reg, ULong val)
{
if (ulong_fits_signed_16bit(val)) {
return s390_emit_LGHI(p, reg, val);
}
if (s390_host_has_eimm) {
if (ulong_fits_unsigned_32bit(val)) {
return s390_emit_LLILF(p, reg, val);
}
if (ulong_fits_signed_32bit(val)) {
/* LGFI's sign extension will recreate the correct 64-bit value */
return s390_emit_LGFI(p, reg, val);
}
/* Do it in two steps: upper half [0:31] and lower half [32:63] */
p = s390_emit_IIHF(p, reg, val >> 32);
return s390_emit_IILF(p, reg, val & 0xFFFFFFFF);
}
/* Fall back */
if (ulong_fits_unsigned_32bit(val)) {
p = s390_emit_LLILH(p, reg, (val >> 16) & 0xFFFF); /* sets val[32:47]
val[0:31] = 0 */
p = s390_emit_IILL(p, reg, val & 0xFFFF); /* sets val[48:63] */
return p;
}
p = s390_emit_IIHH(p, reg, (val >> 48) & 0xFFFF);
p = s390_emit_IIHL(p, reg, (val >> 32) & 0xFFFF);
p = s390_emit_IILH(p, reg, (val >> 16) & 0xFFFF);
p = s390_emit_IILL(p, reg, val & 0xFFFF);
return p;
}
/* Load a 32-bit immediate VAL into register REG. */
static UChar *
s390_emit_load_32imm(UChar *p, UChar reg, UInt val)
{
if (uint_fits_signed_16bit(val)) {
/* LHI's sign extension will recreate the correct 32-bit value */
return s390_emit_LHI(p, reg, val);
}
if (s390_host_has_eimm) {
return s390_emit_IILF(p, reg, val);
}
/* val[0:15] --> (val >> 16) & 0xFFFF
val[16:31] --> val & 0xFFFF */
p = s390_emit_IILH(p, reg, (val >> 16) & 0xFFFF);
return s390_emit_IILL(p, reg, val & 0xFFFF);
}
/*------------------------------------------------------------*/
/*--- Wrapper functions ---*/
/*------------------------------------------------------------*/
/* r1[32:63],r1+1[32:63] = r1+1[32:63] * memory[op2addr][0:31] */
static UChar *
s390_emit_MFYw(UChar *p, UChar r1, UChar x, UChar b, UShort dl, UChar dh)
{
if (s390_host_has_gie) {
return s390_emit_MFY(p, r1, x, b, dl, dh);
}
/* Load from memory into R0, then MULTIPLY with R1 */
p = s390_emit_LY(p, R0, x, b, dl, dh);
return s390_emit_MR(p, r1, R0);
}
/* r1[32:63] = r1[32:63] * memory[op2addr][0:15] */
static UChar *
s390_emit_MHYw(UChar *p, UChar r1, UChar x, UChar b, UShort dl, UChar dh)
{
if (s390_host_has_gie) {
return s390_emit_MHY(p, r1, x, b, dl, dh);
}
/* Load from memory into R0, then MULTIPLY with R1 */
p = s390_emit_LHY(p, R0, x, b, dl, dh);
return s390_emit_MSR(p, r1, R0);
}
/* r1[32:63] = r1[32:63] * i2 */
static UChar *
s390_emit_MSFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_gie) {
return s390_emit_MSFI(p, r1, i2);
}
/* Load I2 into R0; then MULTIPLY R0 with R1 */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_MSR(p, r1, R0);
}
/* r1[32:63] = r1[32:63] & i2 */
static UChar *
s390_emit_NILFw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_NILF(p, r1, i2);
}
/* Load I2 into R0; then AND R0 with R1 */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_NR(p, r1, R0);
}
/* r1[32:63] = r1[32:63] | i2 */
static UChar *
s390_emit_OILFw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_OILF(p, r1, i2);
}
/* Load I2 into R0; then AND R0 with R1 */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_OR(p, r1, R0);
}
/* r1[32:63] = r1[32:63] ^ i2 */
static UChar *
s390_emit_XILFw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_XILF(p, r1, i2);
}
/* Load I2 into R0; then AND R0 with R1 */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_XR(p, r1, R0);
}
/* r1[32:63] = sign_extend(r2[56:63]) */
static UChar *
s390_emit_LBRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LBR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2); /* r1 = r2 */
p = s390_emit_SLL(p, r1, R0, 24); /* r1 = r1 << 24 */
return s390_emit_SRA(p, r1, R0, 24); /* r1 = r1 >>a 24 */
}
/* r1[0:63] = sign_extend(r2[56:63]) */
static UChar *
s390_emit_LGBRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LGBR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2); /* r1 = r2 */
p = s390_emit_SLLG(p, r1, r1, R0, DISP20(56)); /* r1 = r1 << 56 */
return s390_emit_SRAG(p, r1, r1, R0, DISP20(56)); /* r1 = r1 >>a 56 */
}
/* r1[32:63] = sign_extend(r2[48:63]) */
static UChar *
s390_emit_LHRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LHR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2); /* r1 = r2 */
p = s390_emit_SLL(p, r1, R0, 16); /* r1 = r1 << 16 */
return s390_emit_SRA(p, r1, R0, 16); /* r1 = r1 >>a 16 */
}
/* r1[0:63] = sign_extend(r2[48:63]) */
static UChar *
s390_emit_LGHRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LGHR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2); /* r1 = r2 */
p = s390_emit_SLLG(p, r1, r1, R0, DISP20(48)); /* r1 = r1 << 48 */
return s390_emit_SRAG(p, r1, r1, R0, DISP20(48)); /* r1 = r1 >>a 48 */
}
/* r1[0:63] = sign_extend(i2) */
static UChar *
s390_emit_LGFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_LGFI(p, r1, i2);
}
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_LGFR(p, r1, R0);
}
/* r1[32:63] = zero_extend($r2[56:63]) */
static UChar *
s390_emit_LLCRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LLCR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2);
p = s390_emit_LHI(p, R0, 0xFF);
return s390_emit_NR(p, r1, R0);
}
/* r1[0:63] = zero_extend($r2[56:63]) */
static UChar *
s390_emit_LLGCRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LLGCR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2);
p = s390_emit_LLILL(p, R0, 0xFF);
return s390_emit_NGR(p, r1, R0);
}
/* r1[32:63] = zero_extend(r2[48:63]) */
static UChar *
s390_emit_LLHRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LLHR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2);
p = s390_emit_LLILL(p, R0, 0xFFFF);
return s390_emit_NR(p, r1, R0);
}
/* r1[0:63] = zero_extend(r2[48:63]) */
static UChar *
s390_emit_LLGHRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_eimm) {
return s390_emit_LLGHR(p, r1, r2);
}
p = s390_emit_LR(p, r1, r2);
p = s390_emit_LLILL(p, R0, 0xFFFF);
return s390_emit_NGR(p, r1, R0);
}
/* r1[32:63] = zero_extend(mem[op2addr][0:7]) */
static UChar *
s390_emit_LLCw(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl, UChar dh)
{
if (s390_host_has_eimm) {
return s390_emit_LLC(p, r1, x2, b2, dl, dh);
}
if (dh == 0) {
p = s390_emit_IC(p, r1, x2, b2, dl);
} else {
p = s390_emit_ICY(p, r1, x2, b2, dl, dh);
}
p = s390_emit_LLILL(p, R0, 0xFF);
return s390_emit_NR(p, r1, R0);
}
/* r1[32:63] = zero_extend(mem[op2addr][0:15]) */
static UChar *
s390_emit_LLHw(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl, UChar dh)
{
if (s390_host_has_eimm) {
return s390_emit_LLH(p, r1, x2, b2, dl, dh);
}
p = s390_emit_LLGH(p, r1, x2, b2, dl, dh);
p = s390_emit_LLILL(p, R0, 0xFFFF);
return s390_emit_NR(p, r1, R0);
}
/* r1[0:63] = zero_extend(i2) */
static UChar *
s390_emit_LLILFw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_LLILF(p, r1, i2);
}
p = s390_emit_LLILH(p, r1, (i2 >> 16) & 0xFFFF); /* i2[0:15] */
return s390_emit_OILL(p, r1, i2 & 0xFFFF);
}
/* r1[32:63] = r1[32:63] + i2 */
static UChar *
s390_emit_AFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_AFI(p, r1, i2);
}
/* Load 32 bit immediate to R0 then add */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_AR(p, r1, R0);
}
/* r1[32:63] = r1[32:63] - i2 */
static UChar *
s390_emit_SLFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_SLFI(p, r1, i2);
}
/* Load 32 bit immediate to R0 then subtract */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_SR(p, r1, R0);
}
/* r1[0:63] = r1[0:63] - zero_extend(i2) */
static UChar *
s390_emit_SLGFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_SLGFI(p, r1, i2);
}
/* Load zero-extended 32 bit immediate to R0 then subtract */
p = s390_emit_load_64imm(p, R0, i2);
return s390_emit_SGR(p, r1, R0);
}
static UChar *
s390_emit_LTw(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl, UChar dh)
{
if (s390_host_has_eimm) {
return s390_emit_LT(p, r1, x2, b2, dl, dh);
}
/* Load 32 bit from memory to R0 then compare */
if (dh == 0) {
p = s390_emit_L(p, R0, x2, b2, dl);
} else {
p = s390_emit_LY(p, R0, x2, b2, dl, dh);
}
return s390_emit_LTR(p, r1, R0);
}
static UChar *
s390_emit_LTGw(UChar *p, UChar r1, UChar x2, UChar b2, UShort dl, UChar dh)
{
if (s390_host_has_eimm) {
return s390_emit_LTG(p, r1, x2, b2, dl, dh);
}
/* Load 64 bit from memory to R0 then compare */
p = s390_emit_LG(p, R0, x2, b2, dl, dh);
return s390_emit_LTGR(p, r1, R0);
}
static UChar *
s390_emit_CFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_CFI(p, r1, i2);
}
/* Load 32 bit immediate to R0 then compare */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_CR(p, r1, R0);
}
static UChar *
s390_emit_CLFIw(UChar *p, UChar r1, UInt i2)
{
if (s390_host_has_eimm) {
return s390_emit_CLFI(p, r1, i2);
}
/* Load 32 bit immediate to R0 then compare */
p = s390_emit_load_32imm(p, R0, i2);
return s390_emit_CLR(p, r1, R0);
}
static UChar *
s390_emit_LGDRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_fgx) {
return s390_emit_LGDR(p, r1, r2);
}
/* Store the FPR at memory[sp - 8]. This is safe because SP grows towards
smaller addresses and is 8-byte aligned. Then load the GPR from that
memory location/ */
p = s390_emit_STDY(p, r2, R0, S390_REGNO_STACK_POINTER, DISP20(-8));
return s390_emit_LG(p, r1, R0, S390_REGNO_STACK_POINTER, DISP20(-8));
}
static UChar *
s390_emit_LDGRw(UChar *p, UChar r1, UChar r2)
{
if (s390_host_has_fgx) {
return s390_emit_LDGR(p, r1, r2);
}
/* Store the GPR at memory[sp - 8]. This is safe because SP grows towards
smaller addresses and is 8-byte aligned. Then load the FPR from that
memory location/ */
p = s390_emit_STG(p, r2, R0, S390_REGNO_STACK_POINTER, DISP20(-8));
return s390_emit_LDY(p, r1, R0, S390_REGNO_STACK_POINTER, DISP20(-8));
}
/*---------------------------------------------------------------*/
/*--- Constructors for the various s390_insn kinds ---*/
/*---------------------------------------------------------------*/
s390_insn *
s390_insn_load(UChar size, HReg dst, s390_amode *src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_LOAD;
insn->size = size;
insn->variant.load.src = src;
insn->variant.load.dst = dst;
vassert(size == 1 || size == 2 || size == 4 || size == 8);
return insn;
}
s390_insn *
s390_insn_store(UChar size, s390_amode *dst, HReg src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_STORE;
insn->size = size;
insn->variant.store.src = src;
insn->variant.store.dst = dst;
vassert(size == 1 || size == 2 || size == 4 || size == 8);
return insn;
}
s390_insn *
s390_insn_move(UChar size, HReg dst, HReg src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_MOVE;
insn->size = size;
insn->variant.move.src = src;
insn->variant.move.dst = dst;
vassert(size == 1 || size == 2 || size == 4 || size == 8);
return insn;
}
s390_insn *
s390_insn_memcpy(UChar size, s390_amode *dst, s390_amode *src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
/* This insn will be mapped to MVC which requires base register
plus 12-bit displacement */
vassert(src->tag == S390_AMODE_B12);
vassert(dst->tag == S390_AMODE_B12);
insn->tag = S390_INSN_MEMCPY;
insn->size = size;
insn->variant.memcpy.src = src;
insn->variant.memcpy.dst = dst;
vassert(size == 1 || size == 2 || size == 4 || size == 8);
return insn;
}
s390_insn *
s390_insn_cond_move(UChar size, s390_cc_t cond, HReg dst, s390_opnd_RMI src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_COND_MOVE;
insn->size = size;
insn->variant.cond_move.cond = cond;
insn->variant.cond_move.src = src;
insn->variant.cond_move.dst = dst;
vassert(size == 1 || size == 2 || size == 4 || size == 8);
return insn;
}
s390_insn *
s390_insn_load_immediate(UChar size, HReg dst, ULong value)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_LOAD_IMMEDIATE;
insn->size = size;
insn->variant.load_immediate.dst = dst;
insn->variant.load_immediate.value = value;
return insn;
}
s390_insn *
s390_insn_alu(UChar size, s390_alu_t tag, HReg dst, s390_opnd_RMI op2)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_ALU;
insn->size = size;
insn->variant.alu.tag = tag;
insn->variant.alu.dst = dst;
insn->variant.alu.op2 = op2;
return insn;
}
s390_insn *
s390_insn_mul(UChar size, HReg dst_hi, HReg dst_lo, s390_opnd_RMI op2,
Bool signed_multiply)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(! hregIsVirtual(dst_hi));
vassert(! hregIsVirtual(dst_lo));
insn->tag = signed_multiply ? S390_INSN_SMUL : S390_INSN_UMUL;
insn->size = size;
insn->variant.mul.dst_hi = dst_hi;
insn->variant.mul.dst_lo = dst_lo;
insn->variant.mul.op2 = op2;
return insn;
}
s390_insn *
s390_insn_div(UChar size, HReg op1_hi, HReg op1_lo, s390_opnd_RMI op2,
Bool signed_divide)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
vassert(! hregIsVirtual(op1_hi));
vassert(! hregIsVirtual(op1_lo));
insn->tag = signed_divide ? S390_INSN_SDIV : S390_INSN_UDIV;
insn->size = size;
insn->variant.div.op1_hi = op1_hi;
insn->variant.div.op1_lo = op1_lo;
insn->variant.div.op2 = op2;
return insn;
}
s390_insn *
s390_insn_divs(UChar size, HReg rem, HReg op1, s390_opnd_RMI op2)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 8);
vassert(! hregIsVirtual(op1));
vassert(! hregIsVirtual(rem));
insn->tag = S390_INSN_DIVS;
insn->size = size;
insn->variant.divs.rem = rem; /* remainder */
insn->variant.divs.op1 = op1; /* also quotient */
insn->variant.divs.op2 = op2;
return insn;
}
s390_insn *
s390_insn_clz(UChar size, HReg num_bits, HReg clobber, s390_opnd_RMI src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 8);
vassert(! hregIsVirtual(num_bits));
vassert(! hregIsVirtual(clobber));
insn->tag = S390_INSN_CLZ;
insn->size = size;
insn->variant.clz.num_bits = num_bits;
insn->variant.clz.clobber = clobber;
insn->variant.clz.src = src;
return insn;
}
s390_insn *
s390_insn_unop(UChar size, s390_unop_t tag, HReg dst, s390_opnd_RMI opnd)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_UNOP;
insn->size = size;
insn->variant.unop.tag = tag;
insn->variant.unop.dst = dst;
insn->variant.unop.src = opnd;
return insn;
}
s390_insn *
s390_insn_test(UChar size, s390_opnd_RMI src)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_TEST;
insn->size = size;
insn->variant.test.src = src;
return insn;
}
s390_insn *
s390_insn_cc2bool(HReg dst, s390_cc_t cond)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_CC2BOOL;
insn->size = 0; /* does not matter */
insn->variant.cc2bool.cond = cond;
insn->variant.cc2bool.dst = dst;
return insn;
}
s390_insn *
s390_insn_cas(UChar size, HReg op1, s390_amode *op2, HReg op3, HReg old_mem)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
vassert(hregNumber(op2->x) == 0);
vassert(op2->tag == S390_AMODE_B12 || op2->tag == S390_AMODE_B20);
insn->tag = S390_INSN_CAS;
insn->size = size;
insn->variant.cas.op1 = op1;
insn->variant.cas.op2 = op2;
insn->variant.cas.op3 = op3;
insn->variant.cas.old_mem = old_mem;
return insn;
}
s390_insn *
s390_insn_cdas(UChar size, HReg op1_high, HReg op1_low, s390_amode *op2,
HReg op3_high, HReg op3_low, HReg old_mem_high, HReg old_mem_low,
HReg scratch)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
s390_cdas *cdas = LibVEX_Alloc_inline(sizeof(s390_cdas));
vassert(size == 4 || size == 8);
vassert(hregNumber(op2->x) == 0);
vassert(hregNumber(scratch) == 1); /* r0,r1 used as scratch reg pair */
vassert(op2->tag == S390_AMODE_B12 || op2->tag == S390_AMODE_B20);
insn->tag = S390_INSN_CDAS;
insn->size = size;
insn->variant.cdas.details = cdas;
cdas->op1_high = op1_high;
cdas->op1_low = op1_low;
cdas->op2 = op2;
cdas->op3_high = op3_high;
cdas->op3_low = op3_low;
cdas->old_mem_high = old_mem_high;
cdas->old_mem_low = old_mem_low;
cdas->scratch = scratch;
return insn;
}
s390_insn *
s390_insn_compare(UChar size, HReg src1, s390_opnd_RMI src2,
Bool signed_comparison)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_COMPARE;
insn->size = size;
insn->variant.compare.src1 = src1;
insn->variant.compare.src2 = src2;
insn->variant.compare.signed_comparison = signed_comparison;
return insn;
}
s390_insn *
s390_insn_helper_call(s390_cc_t cond, Addr64 target, UInt num_args,
const HChar *name, RetLoc rloc)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
s390_helper_call *helper_call = LibVEX_Alloc_inline(sizeof(s390_helper_call));
insn->tag = S390_INSN_HELPER_CALL;
insn->size = 0; /* does not matter */
insn->variant.helper_call.details = helper_call;
helper_call->cond = cond;
helper_call->target = target;
helper_call->num_args = num_args;
helper_call->name = name;
helper_call->rloc = rloc;
vassert(is_sane_RetLoc(rloc));
return insn;
}
s390_insn *
s390_insn_bfp_triop(UChar size, s390_bfp_triop_t tag, HReg dst, HReg op2,
HReg op3)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_BFP_TRIOP;
insn->size = size;
insn->variant.bfp_triop.tag = tag;
insn->variant.bfp_triop.dst = dst;
insn->variant.bfp_triop.op2 = op2;
insn->variant.bfp_triop.op3 = op3;
return insn;
}
s390_insn *
s390_insn_bfp_binop(UChar size, s390_bfp_binop_t tag, HReg dst, HReg op2)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_BFP_BINOP;
insn->size = size;
insn->variant.bfp_binop.tag = tag;
insn->variant.bfp_binop.dst_hi = dst;
insn->variant.bfp_binop.op2_hi = op2;
insn->variant.bfp_binop.dst_lo = INVALID_HREG;
insn->variant.bfp_binop.op2_lo = INVALID_HREG;
return insn;
}
s390_insn *
s390_insn_bfp_unop(UChar size, s390_bfp_unop_t tag, HReg dst, HReg op)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_BFP_UNOP;
insn->size = size;
insn->variant.bfp_unop.tag = tag;
insn->variant.bfp_unop.dst_hi = dst;
insn->variant.bfp_unop.op_hi = op;
insn->variant.bfp_unop.dst_lo = INVALID_HREG;
insn->variant.bfp_unop.op_lo = INVALID_HREG;
return insn;
}
s390_insn *
s390_insn_bfp_compare(UChar size, HReg dst, HReg op1, HReg op2)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_BFP_COMPARE;
insn->size = size;
insn->variant.bfp_compare.dst = dst;
insn->variant.bfp_compare.op1_hi = op1;
insn->variant.bfp_compare.op2_hi = op2;
insn->variant.bfp_compare.op1_lo = INVALID_HREG;
insn->variant.bfp_compare.op2_lo = INVALID_HREG;
return insn;
}
s390_insn *
s390_insn_bfp_convert(UChar size, s390_bfp_conv_t tag, HReg dst, HReg op,
s390_bfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_BFP_CONVERT;
insn->size = size;
insn->variant.bfp_convert.tag = tag;
insn->variant.bfp_convert.dst_hi = dst;
insn->variant.bfp_convert.op_hi = op;
insn->variant.bfp_convert.dst_lo = INVALID_HREG;
insn->variant.bfp_convert.op_lo = INVALID_HREG;
insn->variant.bfp_convert.rounding_mode = rounding_mode;
return insn;
}
/* Check validity of a register pair for 128-bit FP. Valid register
pairs are (0,2), (1,3), (4, 6), (5, 7), (8, 10), (9, 11), (12, 14),
and (13, 15). */
static Bool
is_valid_fp128_regpair(HReg hi, HReg lo)
{
UInt hi_regno = hregNumber(hi);
UInt lo_regno = hregNumber(lo);
if (lo_regno != hi_regno + 2) return False;
if ((hi_regno & 0x2) != 0) return False;
return True;
}
s390_insn *
s390_insn_bfp128_binop(UChar size, s390_bfp_binop_t tag, HReg dst_hi,
HReg dst_lo, HReg op2_hi, HReg op2_lo)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 16);
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(is_valid_fp128_regpair(op2_hi, op2_lo));
insn->tag = S390_INSN_BFP_BINOP;
insn->size = size;
insn->variant.bfp_binop.tag = tag;
insn->variant.bfp_binop.dst_hi = dst_hi;
insn->variant.bfp_binop.dst_lo = dst_lo;
insn->variant.bfp_binop.op2_hi = op2_hi;
insn->variant.bfp_binop.op2_lo = op2_lo;
return insn;
}
s390_insn *
s390_insn_bfp128_unop(UChar size, s390_bfp_unop_t tag, HReg dst_hi,
HReg dst_lo, HReg op_hi, HReg op_lo)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 16);
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(is_valid_fp128_regpair(op_hi, op_lo));
insn->tag = S390_INSN_BFP_UNOP;
insn->size = size;
insn->variant.bfp_unop.tag = tag;
insn->variant.bfp_unop.dst_hi = dst_hi;
insn->variant.bfp_unop.dst_lo = dst_lo;
insn->variant.bfp_unop.op_hi = op_hi;
insn->variant.bfp_unop.op_lo = op_lo;
return insn;
}
s390_insn *
s390_insn_bfp128_compare(UChar size, HReg dst, HReg op1_hi, HReg op1_lo,
HReg op2_hi, HReg op2_lo)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 16);
vassert(is_valid_fp128_regpair(op1_hi, op1_lo));
vassert(is_valid_fp128_regpair(op2_hi, op2_lo));
insn->tag = S390_INSN_BFP_COMPARE;
insn->size = size;
insn->variant.bfp_compare.dst = dst;
insn->variant.bfp_compare.op1_hi = op1_hi;
insn->variant.bfp_compare.op1_lo = op1_lo;
insn->variant.bfp_compare.op2_hi = op2_hi;
insn->variant.bfp_compare.op2_lo = op2_lo;
return insn;
}
s390_insn *
s390_insn_bfp128_convert(UChar size, s390_bfp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op_hi, HReg op_lo,
s390_bfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
if (size == 16) {
/* From smaller or equal size to 16 bytes */
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(hregIsInvalid(op_lo)
|| is_valid_fp128_regpair(op_hi, op_lo));
} else {
/* From 16 bytes to smaller size */
vassert(is_valid_fp128_regpair(op_hi, op_lo));
}
insn->tag = S390_INSN_BFP_CONVERT;
insn->size = size;
insn->variant.bfp_convert.tag = tag;
insn->variant.bfp_convert.dst_hi = dst_hi;
insn->variant.bfp_convert.dst_lo = dst_lo;
insn->variant.bfp_convert.op_hi = op_hi;
insn->variant.bfp_convert.op_lo = op_lo;
insn->variant.bfp_convert.rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_bfp128_convert_to(UChar size, s390_bfp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op)
{
/* Conversion to bfp128 never requires a rounding mode. Provide default
rounding mode. It will not be used when emitting insns. */
s390_bfp_round_t rounding_mode = S390_BFP_ROUND_NEAREST_EVEN;
return s390_insn_bfp128_convert(size, tag, dst_hi, dst_lo, op,
INVALID_HREG, rounding_mode);
}
s390_insn *
s390_insn_bfp128_convert_from(UChar size, s390_bfp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op_hi, HReg op_lo,
s390_bfp_round_t rounding_mode)
{
return s390_insn_bfp128_convert(size, tag, dst_hi, dst_lo, op_hi, op_lo,
rounding_mode);
}
s390_insn *
s390_insn_dfp_binop(UChar size, s390_dfp_binop_t tag, HReg dst, HReg op2,
HReg op3, s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
s390_dfp_binop *dfp_binop = LibVEX_Alloc_inline(sizeof(s390_dfp_binop));
vassert(size == 8);
insn->tag = S390_INSN_DFP_BINOP;
insn->size = size;
insn->variant.dfp_binop.details = dfp_binop;
dfp_binop->tag = tag;
dfp_binop->dst_hi = dst;
dfp_binop->op2_hi = op2;
dfp_binop->op3_hi = op3;
dfp_binop->dst_lo = INVALID_HREG;
dfp_binop->op2_lo = INVALID_HREG;
dfp_binop->op3_lo = INVALID_HREG;
dfp_binop->rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_dfp_unop(UChar size, s390_dfp_unop_t tag, HReg dst, HReg op)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 8);
insn->tag = S390_INSN_DFP_UNOP;
insn->size = size;
insn->variant.dfp_unop.tag = tag;
insn->variant.dfp_unop.dst_hi = dst;
insn->variant.dfp_unop.op_hi = op;
insn->variant.dfp_unop.dst_lo = INVALID_HREG;
insn->variant.dfp_unop.op_lo = INVALID_HREG;
return insn;
}
s390_insn *
s390_insn_dfp_intop(UChar size, s390_dfp_intop_t tag, HReg dst, HReg op2,
HReg op3)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 8);
insn->tag = S390_INSN_DFP_INTOP;
insn->size = size;
insn->variant.dfp_intop.tag = tag;
insn->variant.dfp_intop.dst_hi = dst;
insn->variant.dfp_intop.op2 = op2;
insn->variant.dfp_intop.op3_hi = op3;
insn->variant.dfp_intop.dst_lo = INVALID_HREG;
insn->variant.dfp_intop.op3_lo = INVALID_HREG;
return insn;
}
s390_insn *
s390_insn_dfp_compare(UChar size, s390_dfp_cmp_t tag, HReg dst,
HReg op1, HReg op2)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 8);
insn->tag = S390_INSN_DFP_COMPARE;
insn->size = size;
insn->variant.dfp_compare.tag = tag;
insn->variant.dfp_compare.dst = dst;
insn->variant.dfp_compare.op1_hi = op1;
insn->variant.dfp_compare.op2_hi = op2;
insn->variant.dfp_compare.op1_lo = INVALID_HREG;
insn->variant.dfp_compare.op2_lo = INVALID_HREG;
return insn;
}
s390_insn *
s390_insn_dfp_convert(UChar size, s390_dfp_conv_t tag, HReg dst, HReg op,
s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_DFP_CONVERT;
insn->size = size;
insn->variant.dfp_convert.tag = tag;
insn->variant.dfp_convert.dst_hi = dst;
insn->variant.dfp_convert.op_hi = op;
insn->variant.dfp_convert.dst_lo = INVALID_HREG;
insn->variant.dfp_convert.op_lo = INVALID_HREG;
insn->variant.dfp_convert.rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_dfp_reround(UChar size, HReg dst, HReg op2, HReg op3,
s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 8);
insn->tag = S390_INSN_DFP_REROUND;
insn->size = size;
insn->variant.dfp_reround.dst_hi = dst;
insn->variant.dfp_reround.op2 = op2;
insn->variant.dfp_reround.op3_hi = op3;
insn->variant.dfp_reround.dst_lo = INVALID_HREG;
insn->variant.dfp_reround.op3_lo = INVALID_HREG;
insn->variant.dfp_reround.rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_fp_convert(UChar size, s390_fp_conv_t tag, HReg dst, HReg op,
HReg r1, s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
s390_fp_convert *fp_convert = LibVEX_Alloc_inline(sizeof(s390_fp_convert));
vassert(size == 4 || size == 8);
insn->tag = S390_INSN_FP_CONVERT;
insn->size = size;
insn->variant.fp_convert.details = fp_convert;
fp_convert->tag = tag;
fp_convert->dst_hi = dst;
fp_convert->op_hi = op;
fp_convert->r1 = r1;
fp_convert->dst_lo = INVALID_HREG;
fp_convert->op_lo = INVALID_HREG;
fp_convert->rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_fp128_convert(UChar size, s390_fp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op_hi, HReg op_lo, HReg r1,
s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
s390_fp_convert *fp_convert = LibVEX_Alloc_inline(sizeof(s390_fp_convert));
vassert(size == 16);
insn->tag = S390_INSN_FP_CONVERT;
insn->size = size;
insn->variant.fp_convert.details = fp_convert;
fp_convert->tag = tag;
fp_convert->dst_hi = dst_hi;
fp_convert->dst_lo = dst_lo;
fp_convert->op_hi = op_hi;
fp_convert->r1 = r1;
fp_convert->op_lo = op_lo;
fp_convert->rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_dfp128_binop(UChar size, s390_dfp_binop_t tag, HReg dst_hi,
HReg dst_lo, HReg op2_hi, HReg op2_lo, HReg op3_hi,
HReg op3_lo, s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
s390_dfp_binop *dfp_binop = LibVEX_Alloc_inline(sizeof(s390_dfp_binop));
vassert(size == 16);
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(is_valid_fp128_regpair(op2_hi, op2_lo));
vassert(is_valid_fp128_regpair(op3_hi, op3_lo));
insn->tag = S390_INSN_DFP_BINOP;
insn->size = size;
insn->variant.dfp_binop.details = dfp_binop;
dfp_binop->tag = tag;
dfp_binop->dst_hi = dst_hi;
dfp_binop->dst_lo = dst_lo;
dfp_binop->op2_hi = op2_hi;
dfp_binop->op2_lo = op2_lo;
dfp_binop->op3_hi = op3_hi;
dfp_binop->op3_lo = op3_lo;
dfp_binop->rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_dfp128_unop(UChar size, s390_dfp_unop_t tag, HReg dst,
HReg op_hi, HReg op_lo)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
/* destination is an 8 byte integer value */
vassert(size == 8);
vassert(is_valid_fp128_regpair(op_hi, op_lo));
insn->tag = S390_INSN_DFP_UNOP;
insn->size = size;
insn->variant.dfp_unop.tag = tag;
insn->variant.dfp_unop.dst_hi = dst;
insn->variant.dfp_unop.dst_lo = INVALID_HREG;
insn->variant.dfp_unop.op_hi = op_hi;
insn->variant.dfp_unop.op_lo = op_lo;
return insn;
}
s390_insn *
s390_insn_dfp128_intop(UChar size, s390_dfp_intop_t tag, HReg dst_hi,
HReg dst_lo, HReg op2, HReg op3_hi, HReg op3_lo)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 16);
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(is_valid_fp128_regpair(op3_hi, op3_lo));
insn->tag = S390_INSN_DFP_INTOP;
insn->size = size;
insn->variant.dfp_intop.tag = tag;
insn->variant.dfp_intop.dst_hi = dst_hi;
insn->variant.dfp_intop.dst_lo = dst_lo;
insn->variant.dfp_intop.op2 = op2;
insn->variant.dfp_intop.op3_hi = op3_hi;
insn->variant.dfp_intop.op3_lo = op3_lo;
return insn;
}
s390_insn *
s390_insn_dfp128_compare(UChar size, s390_dfp_cmp_t tag, HReg dst, HReg op1_hi,
HReg op1_lo, HReg op2_hi, HReg op2_lo)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 16);
vassert(is_valid_fp128_regpair(op1_hi, op1_lo));
vassert(is_valid_fp128_regpair(op2_hi, op2_lo));
insn->tag = S390_INSN_DFP_COMPARE;
insn->size = size;
insn->variant.dfp_compare.tag = tag;
insn->variant.dfp_compare.dst = dst;
insn->variant.dfp_compare.op1_hi = op1_hi;
insn->variant.dfp_compare.op1_lo = op1_lo;
insn->variant.dfp_compare.op2_hi = op2_hi;
insn->variant.dfp_compare.op2_lo = op2_lo;
return insn;
}
static s390_insn *
s390_insn_dfp128_convert(UChar size, s390_dfp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op_hi, HReg op_lo,
s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
if (size == 16) {
/* From smaller size to 16 bytes */
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(hregIsInvalid(op_lo));
} else {
/* From 16 bytes to smaller size */
vassert(is_valid_fp128_regpair(op_hi, op_lo));
}
insn->tag = S390_INSN_DFP_CONVERT;
insn->size = size;
insn->variant.dfp_convert.tag = tag;
insn->variant.dfp_convert.dst_hi = dst_hi;
insn->variant.dfp_convert.dst_lo = dst_lo;
insn->variant.dfp_convert.op_hi = op_hi;
insn->variant.dfp_convert.op_lo = op_lo;
insn->variant.dfp_convert.rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_dfp128_convert_to(UChar size, s390_dfp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op)
{
/* Conversion to dfp128 never requires a rounding mode. Provide default
rounding mode. It will not be used when emitting insns. */
s390_dfp_round_t rounding_mode = S390_DFP_ROUND_NEAREST_EVEN_4;
return s390_insn_dfp128_convert(size, tag, dst_hi, dst_lo, op,
INVALID_HREG, rounding_mode);
}
s390_insn *
s390_insn_dfp128_convert_from(UChar size, s390_dfp_conv_t tag, HReg dst_hi,
HReg dst_lo, HReg op_hi, HReg op_lo,
s390_dfp_round_t rounding_mode)
{
return s390_insn_dfp128_convert(size, tag, dst_hi, dst_lo, op_hi, op_lo,
rounding_mode);
}
s390_insn *
s390_insn_dfp128_reround(UChar size, HReg dst_hi, HReg dst_lo, HReg op2,
HReg op3_hi, HReg op3_lo,
s390_dfp_round_t rounding_mode)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 16);
vassert(is_valid_fp128_regpair(dst_hi, dst_lo));
vassert(is_valid_fp128_regpair(op3_hi, op3_lo));
insn->tag = S390_INSN_DFP_REROUND;
insn->size = size;
insn->variant.dfp_reround.dst_hi = dst_hi;
insn->variant.dfp_reround.dst_lo = dst_lo;
insn->variant.dfp_reround.op2 = op2;
insn->variant.dfp_reround.op3_hi = op3_hi;
insn->variant.dfp_reround.op3_lo = op3_lo;
insn->variant.dfp_reround.rounding_mode = rounding_mode;
return insn;
}
s390_insn *
s390_insn_mfence(void)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_MFENCE;
insn->size = 0; /* not needed */
return insn;
}
s390_insn *
s390_insn_mimm(UChar size, s390_amode *dst, ULong value)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
/* This insn will be mapped to insns that require base register
plus 12-bit displacement */
vassert(dst->tag == S390_AMODE_B12);
insn->tag = S390_INSN_MIMM;
insn->size = size;
insn->variant.mimm.dst = dst;
insn->variant.mimm.value = value;
return insn;
}
s390_insn *
s390_insn_madd(UChar size, s390_amode *dst, UChar delta, ULong value)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(size == 4 || size == 8);
/* This insn will be mapped to an ASI or AGSI so we can only allow base
register plus 12-bit / 20-bit displacement. */
vassert(dst->tag == S390_AMODE_B12 || dst->tag == S390_AMODE_B20);
/* ASI and AGSI require the GIE facility */
vassert(s390_host_has_gie);
insn->tag = S390_INSN_MADD;
insn->size = size;
insn->variant.madd.dst = dst;
insn->variant.madd.delta = delta;
insn->variant.madd.value = value;
return insn;
}
s390_insn *
s390_insn_set_fpc_bfprm(UChar size, HReg mode)
{
vassert(size == 4);
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_SET_FPC_BFPRM;
insn->size = size;
insn->variant.set_fpc_bfprm.mode = mode;
return insn;
}
s390_insn *
s390_insn_set_fpc_dfprm(UChar size, HReg mode)
{
vassert(size == 4);
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_SET_FPC_DFPRM;
insn->size = size;
insn->variant.set_fpc_dfprm.mode = mode;
return insn;
}
s390_insn *
s390_insn_xdirect(s390_cc_t cond, Addr64 dst, s390_amode *guest_IA,
Bool to_fast_entry)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(guest_IA->tag == S390_AMODE_B12);
insn->tag = S390_INSN_XDIRECT;
insn->size = 0; /* does not matter */
insn->variant.xdirect.cond = cond;
insn->variant.xdirect.dst = dst;
insn->variant.xdirect.guest_IA = guest_IA;
insn->variant.xdirect.to_fast_entry = to_fast_entry;
return insn;
}
s390_insn *
s390_insn_xindir(s390_cc_t cond, HReg dst, s390_amode *guest_IA)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(guest_IA->tag == S390_AMODE_B12);
insn->tag = S390_INSN_XINDIR;
insn->size = 0; /* does not matter */
insn->variant.xindir.cond = cond;
insn->variant.xindir.dst = dst;
insn->variant.xindir.guest_IA = guest_IA;
return insn;
}
s390_insn *
s390_insn_xassisted(s390_cc_t cond, HReg dst, s390_amode *guest_IA,
IRJumpKind kind)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(guest_IA->tag == S390_AMODE_B12);
insn->tag = S390_INSN_XASSISTED;
insn->size = 0; /* does not matter */
insn->variant.xassisted.cond = cond;
insn->variant.xassisted.dst = dst;
insn->variant.xassisted.guest_IA = guest_IA;
insn->variant.xassisted.kind = kind;
return insn;
}
s390_insn *
s390_insn_evcheck(s390_amode *counter, s390_amode *fail_addr)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
vassert(counter->tag == S390_AMODE_B12);
vassert(fail_addr->tag == S390_AMODE_B12);
insn->tag = S390_INSN_EVCHECK;
insn->size = 0; /* does not matter */
insn->variant.evcheck.counter = counter;
insn->variant.evcheck.fail_addr = fail_addr;
return insn;
}
s390_insn *
s390_insn_profinc(void)
{
s390_insn *insn = LibVEX_Alloc_inline(sizeof(s390_insn));
insn->tag = S390_INSN_PROFINC;
insn->size = 0; /* does not matter */
return insn;
}
/*---------------------------------------------------------------*/
/*--- Debug print ---*/
/*---------------------------------------------------------------*/
static const HChar *
s390_cc_as_string(s390_cc_t cc)
{
switch (cc) {
case S390_CC_NEVER: return "never";
case S390_CC_OVFL: return "overflow";
case S390_CC_H: return "greater than"; /* A > B ; high */
case S390_CC_NLE: return "not low or equal";
case S390_CC_L: return "less than"; /* A < B ; low */
case S390_CC_NHE: return "not high or equal";
case S390_CC_LH: return "low or high";
case S390_CC_NE: return "not equal"; /* A != B ; not zero */
case S390_CC_E: return "equal"; /* A == B ; zero */
case S390_CC_NLH: return "not low or high";
case S390_CC_HE: return "greater or equal"; /* A >= B ; high or equal*/
case S390_CC_NL: return "not low"; /* not low */
case S390_CC_LE: return "less or equal"; /* A <= B ; low or equal */
case S390_CC_NH: return "not high";
case S390_CC_NO: return "not overflow";
case S390_CC_ALWAYS: return "always";
default:
vpanic("s390_cc_as_string");
}
}
static const HChar *
s390_jump_kind_as_string(IRJumpKind kind)
{
switch (kind) {
case Ijk_Boring: return "Boring";
case Ijk_Call: return "Call";
case Ijk_Ret: return "Return";
case Ijk_ClientReq: return "ClientReq";
case Ijk_Yield: return "Yield";
case Ijk_EmWarn: return "EmWarn";
case Ijk_EmFail: return "EmFail";
case Ijk_NoDecode: return "NoDecode";
case Ijk_MapFail: return "MapFail";
case Ijk_InvalICache: return "Invalidate";
case Ijk_NoRedir: return "NoRedir";
case Ijk_SigTRAP: return "SigTRAP";
case Ijk_SigSEGV: return "SigSEGV";
case Ijk_SigBUS: return "SigBUS";
case Ijk_Sys_syscall: return "Sys_syscall";
default:
vpanic("s390_jump_kind_as_string");
}
}
/* Helper function for writing out a V insn */
static void
s390_sprintf(HChar *buf, const HChar *fmt, ...)
{
HChar *p;
ULong value;
va_list args;
va_start(args, fmt);
p = buf;
for ( ; *fmt; ++fmt) {
Int c = *fmt;
if (c != '%') {
*p++ = c;
continue;
}
c = *++fmt; /* next char */
switch (c) {
case '%':
*p++ = c; /* %% */
continue;
case 's': /* %s */
p += vex_sprintf(p, "%s", va_arg(args, HChar *));
continue;
case 'M': /* %M = mnemonic */
p += vex_sprintf(p, "%-8s", va_arg(args, HChar *));
continue;
case 'R': /* %R = register */
p += vex_sprintf(p, "%s", s390_hreg_as_string(va_arg(args, HReg)));
continue;
case 'A': /* %A = amode */
p += vex_sprintf(p, "%s",
s390_amode_as_string(va_arg(args, s390_amode *)));
continue;
case 'G': /* %G = guest state @ offset */
p += vex_sprintf(p, "guest[%u]", va_arg(args, UInt));
continue;
case 'C': /* %C = condition code */
p += vex_sprintf(p, "%s", s390_cc_as_string(va_arg(args, s390_cc_t)));
continue;
case 'J': /* &J = jump kind */
p += vex_sprintf(p, "%s",
s390_jump_kind_as_string(va_arg(args, IRJumpKind)));
continue;
case 'L': { /* %L = argument list in helper call*/
UInt i, num_args;
num_args = va_arg(args, UInt);
for (i = 0; i < num_args; ++i) {
if (i != 0) p += vex_sprintf(p, ", ");
p += vex_sprintf(p, "r%u", s390_gprno_from_arg_index(i));
}
continue;
}
case 'O': { /* %O = RMI operand */
s390_opnd_RMI *op = va_arg(args, s390_opnd_RMI *);
switch (op->tag) {
case S390_OPND_REG:
p += vex_sprintf(p, "%s", s390_hreg_as_string(op->variant.reg));
continue;
case S390_OPND_AMODE:
p += vex_sprintf(p, "%s", s390_amode_as_string(op->variant.am));
continue;
case S390_OPND_IMMEDIATE:
value = op->variant.imm;
goto print_value;
default:
goto fail;
}
}
case 'I': /* %I = immediate value */
value = va_arg(args, ULong);
goto print_value;
print_value:
if ((Long)value < 0)
p += vex_sprintf(p, "%lld", (Long)value);
else if (value < 100)
p += vex_sprintf(p, "%llu", value);
else
p += vex_sprintf(p, "0x%llx", value);
continue;
default:
goto fail;
}
}
*p = '\0';
va_end(args);
return;
fail: vpanic("s390_printf");
}
/* Decompile the given insn into a static buffer and return it */
const HChar *
s390_insn_as_string(const s390_insn *insn)
{
static HChar buf[300]; // large enough
const HChar *op;
HChar *p;
buf[0] = '\0';
switch (insn->tag) {
case S390_INSN_LOAD:
s390_sprintf(buf, "%M %R,%A", "v-load", insn->variant.load.dst,
insn->variant.load.src);
break;
case S390_INSN_STORE:
s390_sprintf(buf, "%M %R,%A", "v-store", insn->variant.store.src,
insn->variant.store.dst);
break;
case S390_INSN_MOVE:
s390_sprintf(buf, "%M %R,%R", "v-move", insn->variant.move.dst,
insn->variant.move.src);
break;
case S390_INSN_MEMCPY:
s390_sprintf(buf, "%M %A,%A", "v-memcpy", insn->variant.memcpy.dst,
insn->variant.memcpy.src);
break;
case S390_INSN_COND_MOVE:
s390_sprintf(buf, "%M if (%C) %R,%O", "v-move",
insn->variant.cond_move.cond, insn->variant.cond_move.dst,
&insn->variant.cond_move.src);
break;
case S390_INSN_LOAD_IMMEDIATE:
s390_sprintf(buf, "%M %R,%I", "v-loadi", insn->variant.load_immediate.dst,
insn->variant.load_immediate.value);
break;
case S390_INSN_ALU:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: op = "v-add"; break;
case S390_ALU_SUB: op = "v-sub"; break;
case S390_ALU_MUL: op = "v-mul"; break;
case S390_ALU_AND: op = "v-and"; break;
case S390_ALU_OR: op = "v-or"; break;
case S390_ALU_XOR: op = "v-xor"; break;
case S390_ALU_LSH: op = "v-lsh"; break;
case S390_ALU_RSH: op = "v-rsh"; break;
case S390_ALU_RSHA: op = "v-rsha"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%O", op, insn->variant.alu.dst, /* also op1 */
&insn->variant.alu.op2);
break;
case S390_INSN_SMUL:
case S390_INSN_UMUL:
if (insn->tag == S390_INSN_SMUL) {
op = "v-muls";
} else {
op = "v-mulu";
}
s390_sprintf(buf, "%M %R,%O", op, insn->variant.mul.dst_hi,
&insn->variant.mul.op2);
break;
case S390_INSN_SDIV:
case S390_INSN_UDIV:
if (insn->tag == S390_INSN_SDIV) {
op = "v-divs";
} else {
op = "v-divu";
}
s390_sprintf(buf, "%M %R,%O", op, insn->variant.div.op1_hi,
&insn->variant.div.op2);
break;
case S390_INSN_DIVS:
s390_sprintf(buf, "%M %R,%O", "v-divsi", insn->variant.divs.op1,
&insn->variant.divs.op2);
break;
case S390_INSN_CLZ:
s390_sprintf(buf, "%M %R,%O", "v-clz", insn->variant.clz.num_bits,
&insn->variant.clz.src);
break;
case S390_INSN_UNOP:
switch (insn->variant.unop.tag) {
case S390_ZERO_EXTEND_8:
case S390_ZERO_EXTEND_16:
case S390_ZERO_EXTEND_32:
op = "v-zerox";
break;
case S390_SIGN_EXTEND_8:
case S390_SIGN_EXTEND_16:
case S390_SIGN_EXTEND_32:
op = "v-signx";
break;
case S390_NEGATE:
op = "v-neg";
break;
default:
goto fail;
}
s390_sprintf(buf, "%M %R,%O", op, insn->variant.unop.dst,
&insn->variant.unop.src);
break;
case S390_INSN_TEST:
s390_sprintf(buf, "%M %O", "v-test", &insn->variant.test.src);
break;
case S390_INSN_CC2BOOL:
s390_sprintf(buf, "%M %R,%C", "v-cc2b", insn->variant.cc2bool.dst,
insn->variant.cc2bool.cond);
break;
case S390_INSN_CAS:
s390_sprintf(buf, "%M %R,%A,%R,%R", "v-cas", insn->variant.cas.op1,
insn->variant.cas.op2, insn->variant.cas.op3,
insn->variant.cas.old_mem);
break;
case S390_INSN_CDAS: {
s390_cdas *cdas = insn->variant.cdas.details;
s390_sprintf(buf, "%M %R,%R,%A,%R,%R,%R,%R", "v-cdas",
cdas->op1_high, cdas->op1_low, cdas->op2, cdas->op3_high,
cdas->op3_low, cdas->old_mem_high, cdas->old_mem_low);
break;
}
case S390_INSN_COMPARE:
if (insn->variant.compare.signed_comparison) {
op = "v-cmps";
} else {
op = "v-cmpu";
}
s390_sprintf(buf, "%M %R,%O", op, insn->variant.compare.src1,
&insn->variant.compare.src2);
break;
case S390_INSN_HELPER_CALL: {
s390_helper_call *helper_call = insn->variant.helper_call.details;
s390_sprintf(buf, "%M if (%C) %s{%I}(%L)", "v-call",
helper_call->cond,
helper_call->name,
helper_call->target,
helper_call->num_args);
return buf; /* avoid printing "size = ..." which is meaningless */
}
case S390_INSN_BFP_TRIOP:
switch (insn->variant.bfp_triop.tag) {
case S390_BFP_MADD: op = "v-fmadd"; break;
case S390_BFP_MSUB: op = "v-fmsub"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R,%R", op,
insn->variant.bfp_triop.dst /* op1 same as dst */,
insn->variant.bfp_triop.op2, insn->variant.bfp_triop.op3);
break;
case S390_INSN_BFP_BINOP:
switch (insn->variant.bfp_binop.tag) {
case S390_BFP_ADD: op = "v-fadd"; break;
case S390_BFP_SUB: op = "v-fsub"; break;
case S390_BFP_MUL: op = "v-fmul"; break;
case S390_BFP_DIV: op = "v-fdiv"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R", op,
insn->variant.bfp_binop.dst_hi /* op1 same as dst */,
insn->variant.bfp_binop.op2_hi);
break;
case S390_INSN_BFP_COMPARE:
s390_sprintf(buf, "%M %R,%R,%R", "v-fcmp", insn->variant.bfp_compare.dst,
insn->variant.bfp_compare.op1_hi,
insn->variant.bfp_compare.op2_hi);
break;
case S390_INSN_BFP_UNOP:
switch (insn->variant.bfp_unop.tag) {
case S390_BFP_ABS: op = "v-fabs"; break;
case S390_BFP_NABS: op = "v-fnabs"; break;
case S390_BFP_NEG: op = "v-fneg"; break;
case S390_BFP_SQRT: op = "v-fsqrt"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R", op, insn->variant.bfp_unop.dst_hi,
insn->variant.bfp_unop.op_hi);
break;
case S390_INSN_BFP_CONVERT:
switch (insn->variant.bfp_convert.tag) {
case S390_BFP_I32_TO_F32:
case S390_BFP_I32_TO_F64:
case S390_BFP_I32_TO_F128:
case S390_BFP_I64_TO_F32:
case S390_BFP_I64_TO_F64:
case S390_BFP_I64_TO_F128: op = "v-i2f"; break;
case S390_BFP_U32_TO_F32:
case S390_BFP_U32_TO_F64:
case S390_BFP_U32_TO_F128:
case S390_BFP_U64_TO_F32:
case S390_BFP_U64_TO_F64:
case S390_BFP_U64_TO_F128: op = "v-u2f"; break;
case S390_BFP_F32_TO_I32:
case S390_BFP_F32_TO_I64:
case S390_BFP_F64_TO_I32:
case S390_BFP_F64_TO_I64:
case S390_BFP_F128_TO_I32:
case S390_BFP_F128_TO_I64: op = "v-f2i"; break;
case S390_BFP_F32_TO_U32:
case S390_BFP_F32_TO_U64:
case S390_BFP_F64_TO_U32:
case S390_BFP_F64_TO_U64:
case S390_BFP_F128_TO_U32:
case S390_BFP_F128_TO_U64: op = "v-f2u"; break;
case S390_BFP_F32_TO_F64:
case S390_BFP_F32_TO_F128:
case S390_BFP_F64_TO_F32:
case S390_BFP_F64_TO_F128:
case S390_BFP_F128_TO_F32:
case S390_BFP_F128_TO_F64: op = "v-f2f"; break;
case S390_BFP_F32_TO_F32I:
case S390_BFP_F64_TO_F64I:
case S390_BFP_F128_TO_F128I: op = "v-f2fi"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R", op, insn->variant.bfp_convert.dst_hi,
insn->variant.bfp_convert.op_hi);
break;
case S390_INSN_DFP_BINOP: {
s390_dfp_binop *dfp_binop = insn->variant.dfp_binop.details;
switch (dfp_binop->tag) {
case S390_DFP_ADD: op = "v-dadd"; break;
case S390_DFP_SUB: op = "v-dsub"; break;
case S390_DFP_MUL: op = "v-dmul"; break;
case S390_DFP_DIV: op = "v-ddiv"; break;
case S390_DFP_QUANTIZE: op = "v-dqua"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R,%R", op, dfp_binop->dst_hi,
dfp_binop->op2_hi, dfp_binop->op3_hi);
break;
}
case S390_INSN_DFP_UNOP:
switch (insn->variant.dfp_unop.tag) {
case S390_DFP_EXTRACT_EXP_D64:
case S390_DFP_EXTRACT_EXP_D128: op = "v-d2exp"; break;
case S390_DFP_EXTRACT_SIG_D64:
case S390_DFP_EXTRACT_SIG_D128: op = "v-d2sig"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R", op, insn->variant.dfp_unop.dst_hi,
insn->variant.dfp_unop.op_hi);
break;
case S390_INSN_DFP_INTOP:
switch (insn->variant.dfp_intop.tag) {
case S390_DFP_SHIFT_LEFT: op = "v-dshl"; break;
case S390_DFP_SHIFT_RIGHT: op = "v-dshr"; break;
case S390_DFP_INSERT_EXP: op = "v-diexp"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R,%R", op, insn->variant.dfp_intop.dst_hi,
insn->variant.dfp_intop.op2,
insn->variant.dfp_intop.op3_hi);
break;
case S390_INSN_DFP_COMPARE:
switch (insn->variant.dfp_compare.tag) {
case S390_DFP_COMPARE: op = "v-dcmp"; break;
case S390_DFP_COMPARE_EXP: op = "v-dcmpexp"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R,%R", op, insn->variant.dfp_compare.dst,
insn->variant.dfp_compare.op1_hi,
insn->variant.dfp_compare.op2_hi);
break;
case S390_INSN_DFP_CONVERT:
switch (insn->variant.dfp_convert.tag) {
case S390_DFP_D32_TO_D64:
case S390_DFP_D64_TO_D32:
case S390_DFP_D64_TO_D128:
case S390_DFP_D128_TO_D64: op = "v-d2d"; break;
case S390_DFP_I32_TO_D64:
case S390_DFP_I32_TO_D128:
case S390_DFP_I64_TO_D64:
case S390_DFP_I64_TO_D128: op = "v-i2d"; break;
case S390_DFP_U32_TO_D64:
case S390_DFP_U32_TO_D128:
case S390_DFP_U64_TO_D64:
case S390_DFP_U64_TO_D128: op = "v-u2d"; break;
case S390_DFP_D64_TO_I32:
case S390_DFP_D128_TO_I32:
case S390_DFP_D64_TO_I64:
case S390_DFP_D128_TO_I64: op = "v-d2i"; break;
case S390_DFP_D64_TO_U32:
case S390_DFP_D64_TO_U64:
case S390_DFP_D128_TO_U32:
case S390_DFP_D128_TO_U64: op = "v-d2u"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R", op, insn->variant.dfp_convert.dst_hi,
insn->variant.dfp_convert.op_hi);
break;
case S390_INSN_DFP_REROUND:
s390_sprintf(buf, "%M %R,%R,%R", "v-drrnd",
insn->variant.dfp_reround.dst_hi,
insn->variant.dfp_reround.op2,
insn->variant.dfp_reround.op3_hi);
break;
case S390_INSN_FP_CONVERT: {
s390_fp_convert *fp_convert = insn->variant.fp_convert.details;
switch (fp_convert->tag) {
case S390_FP_F32_TO_D32:
case S390_FP_F32_TO_D64:
case S390_FP_F32_TO_D128:
case S390_FP_F64_TO_D32:
case S390_FP_F64_TO_D64:
case S390_FP_F64_TO_D128:
case S390_FP_F128_TO_D32:
case S390_FP_F128_TO_D64:
case S390_FP_F128_TO_D128: op = "v-f2d"; break;
case S390_FP_D32_TO_F32:
case S390_FP_D32_TO_F64:
case S390_FP_D32_TO_F128:
case S390_FP_D64_TO_F32:
case S390_FP_D64_TO_F64:
case S390_FP_D64_TO_F128:
case S390_FP_D128_TO_F32:
case S390_FP_D128_TO_F64:
case S390_FP_D128_TO_F128: op = "v-d2f"; break;
default: goto fail;
}
s390_sprintf(buf, "%M %R,%R", op, fp_convert->dst_hi,
fp_convert->op_hi);
break;
}
case S390_INSN_MFENCE:
s390_sprintf(buf, "%M", "v-mfence");
return buf; /* avoid printing "size = ..." which is meaningless */
case S390_INSN_MIMM:
s390_sprintf(buf, "%M %A,%I", "v-mimm", insn->variant.mimm.dst,
insn->variant.mimm.value);
break;
case S390_INSN_MADD:
s390_sprintf(buf, "%M %A += %I (= %I)", "v-madd",
insn->variant.madd.dst,
(Long)(Char)insn->variant.madd.delta,
insn->variant.madd.value);
break;
case S390_INSN_SET_FPC_BFPRM:
s390_sprintf(buf, "%M %R", "v-set-fpc-bfprm",
insn->variant.set_fpc_bfprm.mode);
break;
case S390_INSN_SET_FPC_DFPRM:
s390_sprintf(buf, "%M %R", "v-set-fpc-dfprm",
insn->variant.set_fpc_dfprm.mode);
break;
case S390_INSN_EVCHECK:
s390_sprintf(buf, "%M counter = %A, fail-addr = %A", "v-evcheck",
insn->variant.evcheck.counter,
insn->variant.evcheck.fail_addr);
return buf; /* avoid printing "size = ..." which is meaningless */
case S390_INSN_PROFINC:
s390_sprintf(buf, "%M", "v-profinc");
return buf; /* avoid printing "size = ..." which is meaningless */
case S390_INSN_XDIRECT:
s390_sprintf(buf, "%M if (%C) %A = %I %s", "v-xdirect",
insn->variant.xdirect.cond,
insn->variant.xdirect.guest_IA,
insn->variant.xdirect.dst,
insn->variant.xdirect.to_fast_entry ? "fast" : "slow");
return buf; /* avoid printing "size = ..." which is meaningless */
case S390_INSN_XINDIR:
s390_sprintf(buf, "%M if (%C) %A = %R", "v-xindir",
insn->variant.xindir.cond,
insn->variant.xindir.guest_IA,
insn->variant.xindir.dst);
return buf; /* avoid printing "size = ..." which is meaningless */
case S390_INSN_XASSISTED:
s390_sprintf(buf, "%M if (%C) %J %A = %R", "v-xassisted",
insn->variant.xassisted.cond,
insn->variant.xassisted.kind,
insn->variant.xassisted.guest_IA,
insn->variant.xassisted.dst);
return buf; /* avoid printing "size = ..." which is meaningless */
default: goto fail;
}
/* Write out how many bytes are involved in the operation */
{
UInt len, i;
for (p = buf; *p; ++p)
continue;
len = p - buf;
if (len < 32) {
for (i = len; i < 32; ++i)
p += vex_sprintf(p, " ");
} else {
p += vex_sprintf(p, "\t");
}
}
/* Special cases first */
switch (insn->tag) {
case S390_INSN_UNOP:
switch (insn->variant.unop.tag) {
case S390_SIGN_EXTEND_8:
case S390_ZERO_EXTEND_8: p += vex_sprintf(p, "1 -> "); goto common;
case S390_SIGN_EXTEND_16:
case S390_ZERO_EXTEND_16: p += vex_sprintf(p, "2 -> "); goto common;
case S390_SIGN_EXTEND_32:
case S390_ZERO_EXTEND_32: p += vex_sprintf(p, "4 -> "); goto common;
default:
goto common;
}
case S390_INSN_BFP_CONVERT:
switch (insn->variant.bfp_convert.tag) {
case S390_BFP_I32_TO_F32:
case S390_BFP_I32_TO_F64:
case S390_BFP_I32_TO_F128:
case S390_BFP_U32_TO_F32:
case S390_BFP_U32_TO_F64:
case S390_BFP_U32_TO_F128:
case S390_BFP_F32_TO_I32:
case S390_BFP_F32_TO_I64:
case S390_BFP_F32_TO_U32:
case S390_BFP_F32_TO_U64:
case S390_BFP_F32_TO_F64:
case S390_BFP_F32_TO_F128: p += vex_sprintf(p, "4 -> "); goto common;
case S390_BFP_I64_TO_F32:
case S390_BFP_I64_TO_F64:
case S390_BFP_I64_TO_F128:
case S390_BFP_U64_TO_F32:
case S390_BFP_U64_TO_F64:
case S390_BFP_U64_TO_F128:
case S390_BFP_F64_TO_I32:
case S390_BFP_F64_TO_I64:
case S390_BFP_F64_TO_U32:
case S390_BFP_F64_TO_U64:
case S390_BFP_F64_TO_F32:
case S390_BFP_F64_TO_F128: p += vex_sprintf(p, "8 -> "); goto common;
case S390_BFP_F128_TO_I32:
case S390_BFP_F128_TO_I64:
case S390_BFP_F128_TO_U32:
case S390_BFP_F128_TO_U64:
case S390_BFP_F128_TO_F32:
case S390_BFP_F128_TO_F64: p += vex_sprintf(p, "16 -> "); goto common;
default:
goto common;
}
case S390_INSN_DFP_CONVERT:
switch (insn->variant.dfp_convert.tag) {
case S390_DFP_D32_TO_D64:
case S390_DFP_I32_TO_D64:
case S390_DFP_I32_TO_D128:
case S390_DFP_U32_TO_D64:
case S390_DFP_U32_TO_D128: p += vex_sprintf(p, "4 -> "); goto common;
case S390_DFP_D64_TO_D32:
case S390_DFP_D64_TO_D128:
case S390_DFP_I64_TO_D64:
case S390_DFP_I64_TO_D128:
case S390_DFP_U64_TO_D64:
case S390_DFP_U64_TO_D128:
case S390_DFP_D64_TO_I32:
case S390_DFP_D64_TO_I64:
case S390_DFP_D64_TO_U32:
case S390_DFP_D64_TO_U64: p += vex_sprintf(p, "8 -> "); goto common;
case S390_DFP_D128_TO_D64:
case S390_DFP_D128_TO_I32:
case S390_DFP_D128_TO_I64:
case S390_DFP_D128_TO_U32:
case S390_DFP_D128_TO_U64: p += vex_sprintf(p, "16 -> "); goto common;
default:
goto common;
}
case S390_INSN_FP_CONVERT: {
s390_fp_convert *fp_convert = insn->variant.fp_convert.details;
switch (fp_convert->tag) {
case S390_FP_F32_TO_D32:
case S390_FP_F32_TO_D64:
case S390_FP_F32_TO_D128:
case S390_FP_D32_TO_F32:
case S390_FP_D32_TO_F64:
case S390_FP_D32_TO_F128: p += vex_sprintf(p, "4 -> "); goto common;
case S390_FP_F64_TO_D32:
case S390_FP_F64_TO_D64:
case S390_FP_F64_TO_D128:
case S390_FP_D64_TO_F32:
case S390_FP_D64_TO_F64:
case S390_FP_D64_TO_F128: p += vex_sprintf(p, "8 -> "); goto common;
case S390_FP_F128_TO_D32:
case S390_FP_F128_TO_D64:
case S390_FP_F128_TO_D128:
case S390_FP_D128_TO_F32:
case S390_FP_D128_TO_F64:
case S390_FP_D128_TO_F128: p += vex_sprintf(p, "16 -> "); goto common;
default:
goto common;
}
}
default:
goto common;
}
/* Common case */
common:
vex_sprintf(p, "%u bytes", (UInt)insn->size);
return buf;
fail: vpanic("s390_insn_as_string");
}
/* Load NUM bytes from memory into register REG using addressing mode AM. */
static UChar *
s390_emit_load_mem(UChar *p, UInt num, UChar reg, const s390_amode *am)
{
UInt b = hregNumber(am->b);
UInt x = hregNumber(am->x); /* 0 for B12 and B20 */
UInt d = am->d;
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
switch (num) {
case 1: return s390_emit_IC(p, reg, x, b, d);
case 2: return s390_emit_LH(p, reg, x, b, d);
case 4: return s390_emit_L(p, reg, x, b, d);
case 8: return s390_emit_LG(p, reg, x, b, DISP20(d));
default: goto fail;
}
break;
case S390_AMODE_B20:
case S390_AMODE_BX20:
switch (num) {
case 1: return s390_emit_ICY(p, reg, x, b, DISP20(d));
case 2: return s390_emit_LHY(p, reg, x, b, DISP20(d));
case 4: return s390_emit_LY(p, reg, x, b, DISP20(d));
case 8: return s390_emit_LG(p, reg, x, b, DISP20(d));
default: goto fail;
}
break;
default: goto fail;
}
fail:
vpanic("s390_emit_load_mem");
}
/* Load condition code into register REG */
static UChar *
s390_emit_load_cc(UChar *p, UChar reg)
{
p = s390_emit_LGHI(p, reg, 0); /* Clear out, cc not affected */
p = s390_emit_IPM(p, reg, reg);
/* Shift 28 bits to the right --> [0,1,2,3] */
return s390_emit_SRL(p, reg, 0, 28); /* REG = cc */
}
/*---------------------------------------------------------------*/
/*--- Code generation ---*/
/*---------------------------------------------------------------*/
/* Do not load more bytes than requested. */
static UChar *
s390_insn_load_emit(UChar *buf, const s390_insn *insn)
{
UInt r, x, b, d;
const s390_amode *src;
src = insn->variant.load.src;
r = hregNumber(insn->variant.load.dst);
if (hregClass(insn->variant.load.dst) == HRcFlt64) {
b = hregNumber(src->b);
x = hregNumber(src->x); /* 0 for B12 and B20 */
d = src->d;
switch (insn->size) {
case 4:
switch (src->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_LE(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_LEY(buf, r, x, b, DISP20(d));
}
break;
case 8:
switch (src->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_LD(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_LDY(buf, r, x, b, DISP20(d));
}
break;
}
vpanic("s390_insn_load_emit");
}
/* Integer stuff */
return s390_emit_load_mem(buf, insn->size, r, src);
}
static UChar *
s390_insn_store_emit(UChar *buf, const s390_insn *insn)
{
UInt r, x, b, d;
const s390_amode *dst;
dst = insn->variant.store.dst;
r = hregNumber(insn->variant.store.src);
b = hregNumber(dst->b);
x = hregNumber(dst->x); /* 0 for B12 and B20 */
d = dst->d;
if (hregClass(insn->variant.store.src) == HRcFlt64) {
switch (insn->size) {
case 4:
switch (dst->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_STE(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_STEY(buf, r, x, b, DISP20(d));
}
break;
case 8:
switch (dst->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_STD(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_STDY(buf, r, x, b, DISP20(d));
}
break;
}
vpanic("s390_insn_store_emit");
}
/* Integer stuff */
switch (insn->size) {
case 1:
switch (dst->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_STC(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_STCY(buf, r, x, b, DISP20(d));
}
break;
case 2:
switch (dst->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_STH(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_STHY(buf, r, x, b, DISP20(d));
}
break;
case 4:
switch (dst->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_ST(buf, r, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_STY(buf, r, x, b, DISP20(d));
}
break;
case 8:
return s390_emit_STG(buf, r, x, b, DISP20(d));
default:
break;
}
vpanic("s390_insn_store_emit");
}
static UChar *
s390_insn_move_emit(UChar *buf, const s390_insn *insn)
{
UInt dst, src;
HRegClass dst_class, src_class;
dst = hregNumber(insn->variant.move.dst);
src = hregNumber(insn->variant.move.src);
dst_class = hregClass(insn->variant.move.dst);
src_class = hregClass(insn->variant.move.src);
if (dst_class == src_class) {
if (dst_class == HRcInt64)
return s390_emit_LGR(buf, dst, src);
if (dst_class == HRcFlt64)
return s390_emit_LDR(buf, dst, src);
} else {
if (dst_class == HRcFlt64 && src_class == HRcInt64) {
if (insn->size == 4) {
buf = s390_emit_SLLG(buf, R0, src, 0, DISP20(32)); /* r0 = src << 32 */
return s390_emit_LDGRw(buf, dst, R0);
} else {
return s390_emit_LDGRw(buf, dst, src);
}
}
if (dst_class == HRcInt64 && src_class == HRcFlt64) {
if (insn->size == 4) {
buf = s390_emit_LGDRw(buf, dst, src);
return s390_emit_SRLG(buf, dst, dst, 0, DISP20(32)); /* dst >>= 32 */
} else {
return s390_emit_LGDRw(buf, dst, src);
}
}
/* A move between floating point registers and general purpose
registers of different size should never occur and indicates
an error elsewhere. */
}
vpanic("s390_insn_move_emit");
}
static UChar *
s390_insn_memcpy_emit(UChar *buf, const s390_insn *insn)
{
s390_amode *dst = insn->variant.memcpy.dst;
s390_amode *src = insn->variant.memcpy.src;
return s390_emit_MVC(buf, insn->size - 1, hregNumber(dst->b), dst->d,
hregNumber(src->b), src->d);
}
static UChar *
s390_insn_load_immediate_emit(UChar *buf, const s390_insn *insn)
{
UInt r;
ULong value = insn->variant.load_immediate.value;
r = hregNumber(insn->variant.load_immediate.dst);
if (hregClass(insn->variant.load_immediate.dst) == HRcFlt64) {
vassert(value == 0);
switch (insn->size) {
case 4: return s390_emit_LZER(buf, r, value);
case 8: return s390_emit_LZDR(buf, r, value);
}
vpanic("s390_insn_load_immediate_emit");
}
switch (insn->size) {
case 1:
case 2:
/* Load the immediate values as a 4 byte value. That does not hurt as
those extra bytes will not be looked at. Fall through .... */
case 4:
return s390_emit_load_32imm(buf, r, value);
case 8:
return s390_emit_load_64imm(buf, r, value);
}
vpanic("s390_insn_load_immediate_emit");
}
/* There is no easy way to do ALU operations on 1-byte or 2-byte operands.
So we simply perform a 4-byte operation. Doing so uses possibly undefined
bits and produces an undefined result in those extra bit positions. But
upstream does not look at those positions, so this is OK. */
static UChar *
s390_insn_alu_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI op2;
UInt dst;
dst = hregNumber(insn->variant.alu.dst);
op2 = insn->variant.alu.op2;
/* Second operand is in a register */
if (op2.tag == S390_OPND_REG) {
UInt r2 = hregNumber(op2.variant.reg);
switch (insn->size) {
case 1:
case 2:
case 4:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: return s390_emit_AR(buf, dst, r2);
case S390_ALU_SUB: return s390_emit_SR(buf, dst, r2);
case S390_ALU_MUL: return s390_emit_MSR(buf, dst, r2);
case S390_ALU_AND: return s390_emit_NR(buf, dst, r2);
case S390_ALU_OR: return s390_emit_OR(buf, dst, r2);
case S390_ALU_XOR: return s390_emit_XR(buf, dst, r2);
case S390_ALU_LSH: return s390_emit_SLL(buf, dst, r2, 0);
case S390_ALU_RSH: return s390_emit_SRL(buf, dst, r2, 0);
case S390_ALU_RSHA: return s390_emit_SRA(buf, dst, r2, 0);
}
goto fail;
case 8:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: return s390_emit_AGR(buf, dst, r2);
case S390_ALU_SUB: return s390_emit_SGR(buf, dst, r2);
case S390_ALU_MUL: return s390_emit_MSGR(buf, dst, r2);
case S390_ALU_AND: return s390_emit_NGR(buf, dst, r2);
case S390_ALU_OR: return s390_emit_OGR(buf, dst, r2);
case S390_ALU_XOR: return s390_emit_XGR(buf, dst, r2);
case S390_ALU_LSH: return s390_emit_SLLG(buf, dst, dst, r2, DISP20(0));
case S390_ALU_RSH: return s390_emit_SRLG(buf, dst, dst, r2, DISP20(0));
case S390_ALU_RSHA: return s390_emit_SRAG(buf, dst, dst, r2, DISP20(0));
}
goto fail;
}
goto fail;
}
/* 2nd operand is in memory */
if (op2.tag == S390_OPND_AMODE) {
UInt b, x, d;
const s390_amode *src = op2.variant.am;
b = hregNumber(src->b);
x = hregNumber(src->x); /* 0 for B12 and B20 */
d = src->d;
/* Shift operands are special here as there are no opcodes that
allow a memory operand. So we first load the 2nd operand into
some register. R0 is used to save restore the contents of the
chosen register.. */
if (insn->variant.alu.tag == S390_ALU_LSH ||
insn->variant.alu.tag == S390_ALU_RSH ||
insn->variant.alu.tag == S390_ALU_RSHA) {
UInt b2;
/* Choose a register (other than DST or R0) into which to stick the
shift amount. The following works because r15 is reserved and
thusly dst != 15. */
vassert(dst != 15); /* extra paranoia */
b2 = (dst + 1) % 16;
buf = s390_emit_LGR(buf, R0, b2); /* save */
/* Loading SRC to B2 does not modify R0. */
buf = s390_emit_load_mem(buf, insn->size, b2, src);
if (insn->size == 8) {
switch (insn->variant.alu.tag) {
case S390_ALU_LSH:
buf = s390_emit_SLLG(buf, dst, dst, b2, DISP20(0));
break;
case S390_ALU_RSH:
buf = s390_emit_SRLG(buf, dst, dst, b2, DISP20(0));
break;
case S390_ALU_RSHA:
buf = s390_emit_SRAG(buf, dst, dst, b2, DISP20(0));
break;
default: /* unreachable */
goto fail;
}
} else {
switch (insn->variant.alu.tag) {
case S390_ALU_LSH:
buf = s390_emit_SLL(buf, dst, b2, 0);
break;
case S390_ALU_RSH:
buf = s390_emit_SRL(buf, dst, b2, 0);
break;
case S390_ALU_RSHA:
buf = s390_emit_SRA(buf, dst, b2, 0);
break;
default: /* unreachable */
goto fail;
}
}
return s390_emit_LGR(buf, b2, R0); /* restore */
}
switch (insn->size) {
case 1:
/* Move the byte from memory into scratch register r0 */
buf = s390_emit_load_mem(buf, 1, R0, src);
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: return s390_emit_AR(buf, dst, R0);
case S390_ALU_SUB: return s390_emit_SR(buf, dst, R0);
case S390_ALU_MUL: return s390_emit_MSR(buf, dst, R0);
case S390_ALU_AND: return s390_emit_NR(buf, dst, R0);
case S390_ALU_OR: return s390_emit_OR(buf, dst, R0);
case S390_ALU_XOR: return s390_emit_XR(buf, dst, R0);
case S390_ALU_LSH:
case S390_ALU_RSH:
case S390_ALU_RSHA: ; /* avoid GCC warning */
}
goto fail;
case 2:
switch (src->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD:
return s390_emit_AH(buf, dst, x, b, d);
case S390_ALU_SUB:
return s390_emit_SH(buf, dst, x, b, d);
case S390_ALU_MUL:
return s390_emit_MH(buf, dst, x, b, d);
/* For bitwise operations: Move two bytes from memory into scratch
register r0; then perform operation */
case S390_ALU_AND:
buf = s390_emit_LH(buf, R0, x, b, d);
return s390_emit_NR(buf, dst, R0);
case S390_ALU_OR:
buf = s390_emit_LH(buf, R0, x, b, d);
return s390_emit_OR(buf, dst, R0);
case S390_ALU_XOR:
buf = s390_emit_LH(buf, R0, x, b, d);
return s390_emit_XR(buf, dst, R0);
case S390_ALU_LSH:
case S390_ALU_RSH:
case S390_ALU_RSHA: ; /* avoid GCC warning */
}
goto fail;
case S390_AMODE_B20:
case S390_AMODE_BX20:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD:
return s390_emit_AHY(buf, dst, x, b, DISP20(d));
case S390_ALU_SUB:
return s390_emit_SHY(buf, dst, x, b, DISP20(d));
case S390_ALU_MUL:
return s390_emit_MHYw(buf, dst, x, b, DISP20(d));
/* For bitwise operations: Move two bytes from memory into scratch
register r0; then perform operation */
case S390_ALU_AND:
buf = s390_emit_LHY(buf, R0, x, b, DISP20(d));
return s390_emit_NR(buf, dst, R0);
case S390_ALU_OR:
buf = s390_emit_LHY(buf, R0, x, b, DISP20(d));
return s390_emit_OR(buf, dst, R0);
case S390_ALU_XOR:
buf = s390_emit_LHY(buf, R0, x, b, DISP20(d));
return s390_emit_XR(buf, dst, R0);
case S390_ALU_LSH:
case S390_ALU_RSH:
case S390_ALU_RSHA: ; /* avoid GCC warning */
}
goto fail;
}
goto fail;
case 4:
switch (src->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: return s390_emit_A(buf, dst, x, b, d);
case S390_ALU_SUB: return s390_emit_S(buf, dst, x, b, d);
case S390_ALU_MUL: return s390_emit_MS(buf, dst, x, b, d);
case S390_ALU_AND: return s390_emit_N(buf, dst, x, b, d);
case S390_ALU_OR: return s390_emit_O(buf, dst, x, b, d);
case S390_ALU_XOR: return s390_emit_X(buf, dst, x, b, d);
case S390_ALU_LSH:
case S390_ALU_RSH:
case S390_ALU_RSHA: ; /* avoid GCC warning */
}
goto fail;
case S390_AMODE_B20:
case S390_AMODE_BX20:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: return s390_emit_AY(buf, dst, x, b, DISP20(d));
case S390_ALU_SUB: return s390_emit_SY(buf, dst, x, b, DISP20(d));
case S390_ALU_MUL: return s390_emit_MSY(buf, dst, x, b, DISP20(d));
case S390_ALU_AND: return s390_emit_NY(buf, dst, x, b, DISP20(d));
case S390_ALU_OR: return s390_emit_OY(buf, dst, x, b, DISP20(d));
case S390_ALU_XOR: return s390_emit_XY(buf, dst, x, b, DISP20(d));
case S390_ALU_LSH:
case S390_ALU_RSH:
case S390_ALU_RSHA: ; /* avoid GCC warning */
}
goto fail;
}
goto fail;
case 8:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD: return s390_emit_AG(buf, dst, x, b, DISP20(d));
case S390_ALU_SUB: return s390_emit_SG(buf, dst, x, b, DISP20(d));
case S390_ALU_MUL: return s390_emit_MSG(buf, dst, x, b, DISP20(d));
case S390_ALU_AND: return s390_emit_NG(buf, dst, x, b, DISP20(d));
case S390_ALU_OR: return s390_emit_OG(buf, dst, x, b, DISP20(d));
case S390_ALU_XOR: return s390_emit_XG(buf, dst, x, b, DISP20(d));
case S390_ALU_LSH:
case S390_ALU_RSH:
case S390_ALU_RSHA: ; /* avoid GCC warning */
}
goto fail;
}
goto fail;
}
/* 2nd operand is an immediate value */
if (op2.tag == S390_OPND_IMMEDIATE) {
ULong value;
/* No masking of the value is required as it is not sign extended */
value = op2.variant.imm;
switch (insn->size) {
case 1:
case 2:
/* There is no 1-byte opcode. Do the computation in
2 bytes. The extra byte will be ignored. */
switch (insn->variant.alu.tag) {
case S390_ALU_ADD:
return s390_emit_AHI(buf, dst, value);
case S390_ALU_SUB:
return s390_emit_SLFIw(buf, dst, value);
case S390_ALU_MUL:
return s390_emit_MHI(buf, dst, value);
case S390_ALU_AND: return s390_emit_NILL(buf, dst, value);
case S390_ALU_OR: return s390_emit_OILL(buf, dst, value);
case S390_ALU_XOR:
/* There is no XILL instruction. Load the immediate value into
R0 and combine with the destination register. */
buf = s390_emit_LHI(buf, R0, value);
return s390_emit_XR(buf, dst, R0);
case S390_ALU_LSH:
return s390_emit_SLL(buf, dst, 0, value);
case S390_ALU_RSH:
return s390_emit_SRL(buf, dst, 0, value);
case S390_ALU_RSHA:
return s390_emit_SRA(buf, dst, 0, value);
}
goto fail;
case 4:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD:
if (uint_fits_signed_16bit(value)) {
return s390_emit_AHI(buf, dst, value);
}
return s390_emit_AFIw(buf, dst, value);
case S390_ALU_SUB: return s390_emit_SLFIw(buf, dst, value);
case S390_ALU_MUL: return s390_emit_MSFIw(buf, dst, value);
case S390_ALU_AND: return s390_emit_NILFw(buf, dst, value);
case S390_ALU_OR: return s390_emit_OILFw(buf, dst, value);
case S390_ALU_XOR: return s390_emit_XILFw(buf, dst, value);
case S390_ALU_LSH: return s390_emit_SLL(buf, dst, 0, value);
case S390_ALU_RSH: return s390_emit_SRL(buf, dst, 0, value);
case S390_ALU_RSHA: return s390_emit_SRA(buf, dst, 0, value);
}
goto fail;
case 8:
switch (insn->variant.alu.tag) {
case S390_ALU_ADD:
if (ulong_fits_signed_16bit(value)) {
return s390_emit_AGHI(buf, dst, value);
}
if (ulong_fits_signed_32bit(value) && s390_host_has_eimm) {
return s390_emit_AGFI(buf, dst, value);
}
/* Load constant into R0 then add */
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_AGR(buf, dst, R0);
case S390_ALU_SUB:
if (ulong_fits_unsigned_32bit(value)) {
return s390_emit_SLGFIw(buf, dst, value);
}
/* Load value into R0; then subtract from destination reg */
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_SGR(buf, dst, R0);
case S390_ALU_MUL:
if (ulong_fits_signed_32bit(value) && s390_host_has_gie) {
return s390_emit_MSGFI(buf, dst, value);
}
/* Load constant into R0 then add */
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_MSGR(buf, dst, R0);
/* Do it in two steps: upper half [0:31] and lower half [32:63] */
case S390_ALU_AND:
if (s390_host_has_eimm) {
buf = s390_emit_NIHF(buf, dst, value >> 32);
return s390_emit_NILF(buf, dst, value & 0xFFFFFFFF);
}
/* Load value into R0; then combine with destination reg */
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_NGR(buf, dst, R0);
case S390_ALU_OR:
if (s390_host_has_eimm) {
buf = s390_emit_OIHF(buf, dst, value >> 32);
return s390_emit_OILF(buf, dst, value & 0xFFFFFFFF);
}
/* Load value into R0; then combine with destination reg */
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_OGR(buf, dst, R0);
case S390_ALU_XOR:
if (s390_host_has_eimm) {
buf = s390_emit_XIHF(buf, dst, value >> 32);
return s390_emit_XILF(buf, dst, value & 0xFFFFFFFF);
}
/* Load value into R0; then combine with destination reg */
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_XGR(buf, dst, R0);
/* No special considerations for long displacement here. Only the six
least significant bits of VALUE will be taken; all other bits are
ignored. So the DH2 bits are irrelevant and do not influence the
shift operation, independent of whether long-displacement is available
or not. */
case S390_ALU_LSH: return s390_emit_SLLG(buf, dst, dst, 0, DISP20(value));
case S390_ALU_RSH: return s390_emit_SRLG(buf, dst, dst, 0, DISP20(value));
case S390_ALU_RSHA: return s390_emit_SRAG(buf, dst, dst, 0, DISP20(value));
}
goto fail;
}
goto fail;
}
fail:
vpanic("s390_insn_alu_emit");
}
static UChar *
s390_widen_emit(UChar *buf, const s390_insn *insn, UInt from_size,
Bool sign_extend)
{
s390_opnd_RMI opnd = insn->variant.unop.src;
switch (opnd.tag) {
case S390_OPND_REG: {
UChar r1 = hregNumber(insn->variant.unop.dst);
UChar r2 = hregNumber(opnd.variant.reg);
switch (from_size) {
case 1:
/* Widening to a half-word is implemented like widening to a word
because the upper half-word will not be looked at. */
if (insn->size == 4 || insn->size == 2) { /* 8 --> 32 8 --> 16 */
if (sign_extend)
return s390_emit_LBRw(buf, r1, r2);
else
return s390_emit_LLCRw(buf, r1, r2);
}
if (insn->size == 8) { /* 8 --> 64 */
if (sign_extend)
return s390_emit_LGBRw(buf, r1, r2);
else
return s390_emit_LLGCRw(buf, r1, r2);
}
goto fail;
case 2:
if (insn->size == 4) { /* 16 --> 32 */
if (sign_extend)
return s390_emit_LHRw(buf, r1, r2);
else
return s390_emit_LLHRw(buf, r1, r2);
}
if (insn->size == 8) { /* 16 --> 64 */
if (sign_extend)
return s390_emit_LGHRw(buf, r1, r2);
else
return s390_emit_LLGHRw(buf, r1, r2);
}
goto fail;
case 4:
if (insn->size == 8) { /* 32 --> 64 */
if (sign_extend)
return s390_emit_LGFR(buf, r1, r2);
else
return s390_emit_LLGFR(buf, r1, r2);
}
goto fail;
default: /* unexpected "from" size */
goto fail;
}
}
case S390_OPND_AMODE: {
UChar r1 = hregNumber(insn->variant.unop.dst);
const s390_amode *src = opnd.variant.am;
UChar b = hregNumber(src->b);
UChar x = hregNumber(src->x);
Int d = src->d;
switch (from_size) {
case 1:
if (insn->size == 4 || insn->size == 2) {
if (sign_extend)
return s390_emit_LB(buf, r1, x, b, DISP20(d));
else
return s390_emit_LLCw(buf, r1, x, b, DISP20(d));
}
if (insn->size == 8) {
if (sign_extend)
return s390_emit_LGB(buf, r1, x, b, DISP20(d));
else
return s390_emit_LLGC(buf, r1, x, b, DISP20(d));
}
goto fail;
case 2:
if (insn->size == 4) { /* 16 --> 32 */
if (sign_extend == 0)
return s390_emit_LLHw(buf, r1, x, b, DISP20(d));
switch (src->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
return s390_emit_LH(buf, r1, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
return s390_emit_LHY(buf, r1, x, b, DISP20(d));
}
goto fail;
}
if (insn->size == 8) { /* 16 --> 64 */
if (sign_extend)
return s390_emit_LGH(buf, r1, x, b, DISP20(d));
else
return s390_emit_LLGH(buf, r1, x, b, DISP20(d));
}
goto fail;
case 4:
if (insn->size == 8) { /* 32 --> 64 */
if (sign_extend)
return s390_emit_LGF(buf, r1, x, b, DISP20(d));
else
return s390_emit_LLGF(buf, r1, x, b, DISP20(d));
}
goto fail;
default: /* unexpected "from" size */
goto fail;
}
}
case S390_OPND_IMMEDIATE: {
UChar r1 = hregNumber(insn->variant.unop.dst);
ULong value = opnd.variant.imm;
switch (from_size) {
case 1:
if (insn->size == 4 || insn->size == 2) { /* 8 --> 32 8 --> 16 */
if (sign_extend) {
/* host can do the sign extension to 16-bit; LHI does the rest */
return s390_emit_LHI(buf, r1, (Short)(Char)(UChar)value);
} else {
return s390_emit_LHI(buf, r1, value);
}
}
if (insn->size == 8) { /* 8 --> 64 */
if (sign_extend) {
/* host can do the sign extension to 16-bit; LGHI does the rest */
return s390_emit_LGHI(buf, r1, (Short)(Char)(UChar)value);
} else {
return s390_emit_LGHI(buf, r1, value);
}
}
goto fail;
case 2:
if (insn->size == 4) { /* 16 --> 32 */
return s390_emit_LHI(buf, r1, value);
}
if (insn->size == 8) { /* 16 --> 64 */
if (sign_extend)
return s390_emit_LGHI(buf, r1, value);
else
return s390_emit_LLILL(buf, r1, value);
}
goto fail;
case 4:
if (insn->size == 8) { /* 32 --> 64 */
if (sign_extend)
return s390_emit_LGFIw(buf, r1, value);
else
return s390_emit_LLILFw(buf, r1, value);
}
goto fail;
default: /* unexpected "from" size */
goto fail;
}
}
}
fail:
vpanic("s390_widen_emit");
}
static UChar *
s390_negate_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI opnd;
opnd = insn->variant.unop.src;
switch (opnd.tag) {
case S390_OPND_REG: {
UChar r1 = hregNumber(insn->variant.unop.dst);
UChar r2 = hregNumber(opnd.variant.reg);
switch (insn->size) {
case 1:
case 2:
case 4:
return s390_emit_LCR(buf, r1, r2);
case 8:
return s390_emit_LCGR(buf, r1, r2);
default:
goto fail;
}
}
case S390_OPND_AMODE: {
UChar r1 = hregNumber(insn->variant.unop.dst);
/* Load bytes into scratch register R0, then negate */
buf = s390_emit_load_mem(buf, insn->size, R0, opnd.variant.am);
switch (insn->size) {
case 1:
case 2:
case 4:
return s390_emit_LCR(buf, r1, R0);
case 8:
return s390_emit_LCGR(buf, r1, R0);
default:
goto fail;
}
}
case S390_OPND_IMMEDIATE: {
UChar r1 = hregNumber(insn->variant.unop.dst);
ULong value = opnd.variant.imm;
value = ~value + 1; /* two's complement */
switch (insn->size) {
case 1:
case 2:
/* Load the immediate values as a 4 byte value. That does not hurt as
those extra bytes will not be looked at. Fall through .... */
case 4:
return s390_emit_load_32imm(buf, r1, value);
case 8:
return s390_emit_load_64imm(buf, r1, value);
default:
goto fail;
}
}
}
fail:
vpanic("s390_negate_emit");
}
static UChar *
s390_insn_unop_emit(UChar *buf, const s390_insn *insn)
{
switch (insn->variant.unop.tag) {
case S390_ZERO_EXTEND_8: return s390_widen_emit(buf, insn, 1, 0);
case S390_ZERO_EXTEND_16: return s390_widen_emit(buf, insn, 2, 0);
case S390_ZERO_EXTEND_32: return s390_widen_emit(buf, insn, 4, 0);
case S390_SIGN_EXTEND_8: return s390_widen_emit(buf, insn, 1, 1);
case S390_SIGN_EXTEND_16: return s390_widen_emit(buf, insn, 2, 1);
case S390_SIGN_EXTEND_32: return s390_widen_emit(buf, insn, 4, 1);
case S390_NEGATE: return s390_negate_emit(buf, insn);
}
vpanic("s390_insn_unop_emit");
}
/* Only 4-byte and 8-byte operands are handled. 1-byte and 2-byte
comparisons will have been converted to 4-byte comparisons in
s390_isel_cc and should not occur here. */
static UChar *
s390_insn_test_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI opnd;
opnd = insn->variant.test.src;
switch (opnd.tag) {
case S390_OPND_REG: {
UInt reg = hregNumber(opnd.variant.reg);
switch (insn->size) {
case 4:
return s390_emit_LTR(buf, reg, reg);
case 8:
return s390_emit_LTGR(buf, reg, reg);
default:
goto fail;
}
}
case S390_OPND_AMODE: {
const s390_amode *am = opnd.variant.am;
UChar b = hregNumber(am->b);
UChar x = hregNumber(am->x);
Int d = am->d;
switch (insn->size) {
case 4:
return s390_emit_LTw(buf, R0, x, b, DISP20(d));
case 8:
return s390_emit_LTGw(buf, R0, x, b, DISP20(d));
default:
goto fail;
}
}
case S390_OPND_IMMEDIATE: {
ULong value = opnd.variant.imm;
switch (insn->size) {
case 4:
buf = s390_emit_load_32imm(buf, R0, value);
return s390_emit_LTR(buf, R0, R0);
case 8:
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_LTGR(buf, R0, R0);
default:
goto fail;
}
}
default:
goto fail;
}
fail:
vpanic("s390_insn_test_emit");
}
static UChar *
s390_insn_cc2bool_emit(UChar *buf, const s390_insn *insn)
{
UChar r1 = hregNumber(insn->variant.cc2bool.dst);
s390_cc_t cond = insn->variant.cc2bool.cond;
/* Make the destination register be 1 or 0, depending on whether
the relevant condition holds. A 64-bit value is computed. */
if (cond == S390_CC_ALWAYS)
return s390_emit_LGHI(buf, r1, 1); /* r1 = 1 */
buf = s390_emit_load_cc(buf, r1); /* r1 = cc */
buf = s390_emit_LGHI(buf, R0, cond); /* r0 = mask */
buf = s390_emit_SLLG(buf, r1, R0, r1, DISP20(0)); /* r1 = mask << cc */
buf = s390_emit_SRLG(buf, r1, r1, 0, DISP20(3)); /* r1 = r1 >> 3 */
buf = s390_emit_NILL(buf, r1, 1); /* r1 = r1 & 0x1 */
return buf;
}
/* Only 4-byte and 8-byte operands are handled. */
static UChar *
s390_insn_cas_emit(UChar *buf, const s390_insn *insn)
{
UChar r1, r3, b, old;
Int d;
s390_amode *am;
r1 = hregNumber(insn->variant.cas.op1); /* expected value */
r3 = hregNumber(insn->variant.cas.op3);
old= hregNumber(insn->variant.cas.old_mem);
am = insn->variant.cas.op2;
b = hregNumber(am->b);
d = am->d;
vassert(am->tag == S390_AMODE_B12 || am->tag == S390_AMODE_B20);
switch (insn->size) {
case 4:
/* r1 must not be overwritten. So copy it to R0 and let CS clobber it */
buf = s390_emit_LR(buf, R0, r1);
if (am->tag == S390_AMODE_B12)
buf = s390_emit_CS(buf, R0, r3, b, d);
else
buf = s390_emit_CSY(buf, R0, r3, b, DISP20(d));
/* Now copy R0 which has the old memory value to OLD */
return s390_emit_LR(buf, old, R0);
case 8:
/* r1 must not be overwritten. So copy it to R0 and let CS clobber it */
buf = s390_emit_LGR(buf, R0, r1);
buf = s390_emit_CSG(buf, R0, r3, b, DISP20(d));
/* Now copy R0 which has the old memory value to OLD */
return s390_emit_LGR(buf, old, R0);
default:
goto fail;
}
fail:
vpanic("s390_insn_cas_emit");
}
/* Only 4-byte and 8-byte operands are handled. */
static UChar *
s390_insn_cdas_emit(UChar *buf, const s390_insn *insn)
{
UChar r1, r1p1, r3, /*r3p1,*/ b, old_high, old_low, scratch;
Int d;
s390_amode *am;
s390_cdas *cdas = insn->variant.cdas.details;
r1 = hregNumber(cdas->op1_high); /* expected value */
r1p1 = hregNumber(cdas->op1_low); /* expected value */
r3 = hregNumber(cdas->op3_high);
/* r3p1 = hregNumber(cdas->op3_low); */ /* unused */
old_high = hregNumber(cdas->old_mem_high);
old_low = hregNumber(cdas->old_mem_low);
scratch = hregNumber(cdas->scratch);
am = cdas->op2;
b = hregNumber(am->b);
d = am->d;
vassert(scratch == 1);
vassert(am->tag == S390_AMODE_B12 || am->tag == S390_AMODE_B20);
switch (insn->size) {
case 4:
/* r1, r1+1 must not be overwritten. So copy them to R0,scratch
and let CDS/CDSY clobber it */
buf = s390_emit_LR(buf, R0, r1);
buf = s390_emit_LR(buf, scratch, r1p1);
if (am->tag == S390_AMODE_B12)
buf = s390_emit_CDS(buf, R0, r3, b, d);
else
buf = s390_emit_CDSY(buf, R0, r3, b, DISP20(d));
/* Now copy R0,scratch which has the old memory value to OLD */
buf = s390_emit_LR(buf, old_high, R0);
buf = s390_emit_LR(buf, old_low, scratch);
return buf;
case 8:
/* r1, r1+1 must not be overwritten. So copy them to R0,scratch
and let CDSG clobber it */
buf = s390_emit_LGR(buf, R0, r1);
buf = s390_emit_LGR(buf, scratch, r1p1);
buf = s390_emit_CDSG(buf, R0, r3, b, DISP20(d));
/* Now copy R0,scratch which has the old memory value to OLD */
buf = s390_emit_LGR(buf, old_high, R0);
buf = s390_emit_LGR(buf, old_low, scratch);
return buf;
default:
goto fail;
}
fail:
vpanic("s390_insn_cdas_emit");
}
/* Only 4-byte and 8-byte comparisons are handled. 1-byte and 2-byte
comparisons will have been converted to 4-byte comparisons in
s390_isel_cc and should not occur here. */
static UChar *
s390_insn_compare_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI op2;
HReg op1;
Bool signed_comparison;
op1 = insn->variant.compare.src1;
op2 = insn->variant.compare.src2;
signed_comparison = insn->variant.compare.signed_comparison;
switch (op2.tag) {
case S390_OPND_REG: {
UInt r1 = hregNumber(op1);
UInt r2 = hregNumber(op2.variant.reg);
switch (insn->size) {
case 4:
if (signed_comparison)
return s390_emit_CR(buf, r1, r2);
else
return s390_emit_CLR(buf, r1, r2);
case 8:
if (signed_comparison)
return s390_emit_CGR(buf, r1, r2);
else
return s390_emit_CLGR(buf, r1, r2);
default:
goto fail;
}
}
case S390_OPND_AMODE: {
UChar r1 = hregNumber(op1);
const s390_amode *am = op2.variant.am;
UChar b = hregNumber(am->b);
UChar x = hregNumber(am->x);
Int d = am->d;
switch (insn->size) {
case 4:
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
if (signed_comparison)
return s390_emit_C(buf, r1, x, b, d);
else
return s390_emit_CL(buf, r1, x, b, d);
case S390_AMODE_B20:
case S390_AMODE_BX20:
if (signed_comparison)
return s390_emit_CY(buf, r1, x, b, DISP20(d));
else
return s390_emit_CLY(buf, r1, x, b, DISP20(d));
}
goto fail;
case 8:
if (signed_comparison)
return s390_emit_CG(buf, r1, x, b, DISP20(d));
else
return s390_emit_CLG(buf, r1, x, b, DISP20(d));
default:
goto fail;
}
}
case S390_OPND_IMMEDIATE: {
UChar r1 = hregNumber(op1);
ULong value = op2.variant.imm;
switch (insn->size) {
case 4:
if (signed_comparison)
return s390_emit_CFIw(buf, r1, value);
else
return s390_emit_CLFIw(buf, r1, value);
case 8:
if (s390_host_has_eimm) {
if (signed_comparison) {
if (ulong_fits_signed_32bit(value))
return s390_emit_CGFI(buf, r1, value);
} else {
if (ulong_fits_unsigned_32bit(value))
return s390_emit_CLGFI(buf, r1, value);
}
}
buf = s390_emit_load_64imm(buf, R0, value);
if (signed_comparison)
return s390_emit_CGR(buf, r1, R0);
else
return s390_emit_CLGR(buf, r1, R0);
default:
goto fail;
}
}
default:
goto fail;
}
fail:
vpanic("s390_insn_compare_emit");
}
static UChar *
s390_insn_mul_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI op2;
UChar r1;
Bool signed_multiply;
/* The register number identifying the register pair */
r1 = hregNumber(insn->variant.mul.dst_hi);
op2 = insn->variant.mul.op2;
signed_multiply = insn->tag == S390_INSN_SMUL;
switch (op2.tag) {
case S390_OPND_REG: {
UInt r2 = hregNumber(op2.variant.reg);
switch (insn->size) {
case 1:
case 2:
case 4:
if (signed_multiply)
return s390_emit_MR(buf, r1, r2);
else
return s390_emit_MLR(buf, r1, r2);
case 8:
if (signed_multiply)
vpanic("s390_insn_mul_emit");
else
return s390_emit_MLGR(buf, r1, r2);
default:
goto fail;
}
}
case S390_OPND_AMODE: {
const s390_amode *am = op2.variant.am;
UChar b = hregNumber(am->b);
UChar x = hregNumber(am->x);
Int d = am->d;
switch (insn->size) {
case 1:
case 2:
/* Load bytes into scratch register R0, then multiply */
buf = s390_emit_load_mem(buf, insn->size, R0, am);
if (signed_multiply)
return s390_emit_MR(buf, r1, R0);
else
return s390_emit_MLR(buf, r1, R0);
case 4:
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
if (signed_multiply)
return s390_emit_M(buf, r1, x, b, d);
else
return s390_emit_ML(buf, r1, x, b, DISP20(d));
case S390_AMODE_B20:
case S390_AMODE_BX20:
if (signed_multiply)
return s390_emit_MFYw(buf, r1, x, b, DISP20(d));
else
return s390_emit_ML(buf, r1, x, b, DISP20(d));
}
goto fail;
case 8:
if (signed_multiply)
vpanic("s390_insn_mul_emit");
else
return s390_emit_MLG(buf, r1, x, b, DISP20(d));
default:
goto fail;
}
}
case S390_OPND_IMMEDIATE: {
ULong value = op2.variant.imm;
switch (insn->size) {
case 1:
case 2:
case 4:
buf = s390_emit_load_32imm(buf, R0, value);
if (signed_multiply)
return s390_emit_MR(buf, r1, R0);
else
return s390_emit_MLR(buf, r1, R0);
case 8:
buf = s390_emit_load_64imm(buf, R0, value);
if (signed_multiply)
vpanic("s390_insn_mul_emit");
else
return s390_emit_MLGR(buf, r1, R0);
default:
goto fail;
}
}
default:
goto fail;
}
fail:
vpanic("s390_insn_mul_emit");
}
static UChar *
s390_insn_div_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI op2;
UChar r1;
Bool signed_divide;
r1 = hregNumber(insn->variant.div.op1_hi);
op2 = insn->variant.div.op2;
signed_divide = insn->tag == S390_INSN_SDIV;
switch (op2.tag) {
case S390_OPND_REG: {
UInt r2 = hregNumber(op2.variant.reg);
switch (insn->size) {
case 4:
if (signed_divide)
return s390_emit_DR(buf, r1, r2);
else
return s390_emit_DLR(buf, r1, r2);
case 8:
if (signed_divide)
vpanic("s390_insn_div_emit");
else
return s390_emit_DLGR(buf, r1, r2);
default:
goto fail;
}
}
case S390_OPND_AMODE: {
const s390_amode *am = op2.variant.am;
UChar b = hregNumber(am->b);
UChar x = hregNumber(am->x);
Int d = am->d;
switch (insn->size) {
case 4:
switch (am->tag) {
case S390_AMODE_B12:
case S390_AMODE_BX12:
if (signed_divide)
return s390_emit_D(buf, r1, x, b, d);
else
return s390_emit_DL(buf, r1, x, b, DISP20(d));
case S390_AMODE_B20:
case S390_AMODE_BX20:
if (signed_divide) {
buf = s390_emit_LY(buf, R0, x, b, DISP20(d));
return s390_emit_DR(buf, r1, R0);
} else
return s390_emit_DL(buf, r1, x, b, DISP20(d));
}
goto fail;
case 8:
if (signed_divide)
vpanic("s390_insn_div_emit");
else
return s390_emit_DLG(buf, r1, x, b, DISP20(d));
default:
goto fail;
}
}
case S390_OPND_IMMEDIATE: {
ULong value = op2.variant.imm;
switch (insn->size) {
case 4:
buf = s390_emit_load_32imm(buf, R0, value);
if (signed_divide)
return s390_emit_DR(buf, r1, R0);
else
return s390_emit_DLR(buf, r1, R0);
case 8:
buf = s390_emit_load_64imm(buf, R0, value);
if (signed_divide)
vpanic("s390_insn_div_emit");
else
return s390_emit_DLGR(buf, r1, R0);
default:
goto fail;
}
}
default:
goto fail;
}
fail:
vpanic("s390_insn_div_emit");
}
static UChar *
s390_insn_divs_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI op2;
UChar r1;
r1 = hregNumber(insn->variant.divs.rem);
op2 = insn->variant.divs.op2;
switch (op2.tag) {
case S390_OPND_REG: {
UInt r2 = hregNumber(op2.variant.reg);
return s390_emit_DSGR(buf, r1, r2);
}
case S390_OPND_AMODE: {
const s390_amode *am = op2.variant.am;
UChar b = hregNumber(am->b);
UChar x = hregNumber(am->x);
Int d = am->d;
return s390_emit_DSG(buf, r1, x, b, DISP20(d));
}
case S390_OPND_IMMEDIATE: {
ULong value = op2.variant.imm;
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_DSGR(buf, r1, R0);
}
default:
goto fail;
}
fail:
vpanic("s390_insn_divs_emit");
}
static UChar *
s390_insn_clz_emit(UChar *buf, const s390_insn *insn)
{
s390_opnd_RMI src;
UChar r1, r1p1, r2, *p;
r1 = hregNumber(insn->variant.clz.num_bits);
r1p1 = hregNumber(insn->variant.clz.clobber);
vassert((r1 & 0x1) == 0);
vassert(r1p1 == r1 + 1);
p = buf;
src = insn->variant.clz.src;
/* Get operand and move it to r2 */
switch (src.tag) {
case S390_OPND_REG:
r2 = hregNumber(src.variant.reg);
break;
case S390_OPND_AMODE: {
const s390_amode *am = src.variant.am;
UChar b = hregNumber(am->b);
UChar x = hregNumber(am->x);
Int d = am->d;
p = s390_emit_LG(p, R0, x, b, DISP20(d));
r2 = R0;
break;
}
case S390_OPND_IMMEDIATE: {
ULong value = src.variant.imm;
p = s390_emit_load_64imm(p, R0, value);
r2 = R0;
break;
}
default:
goto fail;
}
/* Use FLOGR if you can */
if (s390_host_has_eimm) {
return s390_emit_FLOGR(p, r1, r2);
}
/*
r0 = r2;
r1 = 64;
while (r0 != 0) {
r1 -= 1;
r0 >>= 1;
}
*/
p = s390_emit_LTGR(p, R0, r2);
p = s390_emit_LLILL(p, r1, 64);
p = s390_emit_BRC(p, S390_CC_E, (4 + 4 + 6 + 4 + 4)/ 2); /* 4 bytes */
p = s390_emit_AGHI(p, r1, (UShort)-1); /* r1 -= 1; 4 bytes */
p = s390_emit_SRLG(p, R0, R0, R0, DISP20(1)); /* r0 >>= 1; 6 bytes */
p = s390_emit_LTGR(p, R0, R0); /* set cc 4 bytes */
p = s390_emit_BRC(p, S390_CC_NE, /* 4 bytes */
(UShort)(-(4 + 6 + 4) / 2));
return p;
fail:
vpanic("s390_insn_clz_emit");
}
/* Returns a value == BUF to denote failure, != BUF to denote success. */
static UChar *
s390_insn_helper_call_emit(UChar *buf, const s390_insn *insn)
{
s390_cc_t cond;
ULong target;
UChar *ptmp = buf;
s390_helper_call *helper_call = insn->variant.helper_call.details;
cond = helper_call->cond;
target = helper_call->target;
if (cond != S390_CC_ALWAYS
&& helper_call->rloc.pri != RLPri_None) {
/* The call might not happen (it isn't unconditional) and it
returns a result. In this case we will need to generate a
control flow diamond to put 0x555..555 in the return
register(s) in the case where the call doesn't happen. If
this ever becomes necessary, maybe copy code from the ARM
equivalent. Until that day, just give up. */
return buf; /* To denote failure. */
}
if (cond != S390_CC_ALWAYS) {
/* So we have something like this
if (cond) call X;
Y: ...
We convert this into
if (! cond) goto Y; // BRC opcode; 4 bytes
call X;
Y:
*/
/* 4 bytes (a BRC insn) to be filled in here */
buf += 4;
}
/* Load the target address into a register, that
(a) is not used for passing parameters to the helper and
(b) can be clobbered by the callee
(c) is not special to the BASR insn
r1 is the only choice.
Also, need to arrange for the return address be put into the
link-register */
buf = s390_emit_load_64imm(buf, 1, target);
/* Stash away the client's FPC register because the helper might change it. */
buf = s390_emit_STFPC(buf, S390_REGNO_STACK_POINTER, S390_OFFSET_SAVED_FPC_C);
buf = s390_emit_BASR(buf, S390_REGNO_LINK_REGISTER, 1); // call helper
buf = s390_emit_LFPC(buf, S390_REGNO_STACK_POINTER, // restore FPC
S390_OFFSET_SAVED_FPC_C);
if (cond != S390_CC_ALWAYS) {
Int delta = buf - ptmp;
delta >>= 1; /* immediate constant is #half-words */
vassert(delta > 0 && delta < (1 << 16));
s390_emit_BRC(ptmp, s390_cc_invert(cond), delta);
}
return buf;
}
static UChar *
s390_insn_cond_move_emit(UChar *buf, const s390_insn *insn)
{
HReg dst;
s390_opnd_RMI src;
s390_cc_t cond;
UChar *p, *ptmp = 0; /* avoid compiler warnings */
cond = insn->variant.cond_move.cond;
dst = insn->variant.cond_move.dst;
src = insn->variant.cond_move.src;
if (cond == S390_CC_NEVER) return buf;
p = buf;
if (s390_host_has_lsc) {
/* LOCx is not the preferred way to implement an unconditional load. */
if (cond != S390_CC_ALWAYS) goto use_branch_insn;
switch (src.tag) {
case S390_OPND_REG:
return s390_emit_LOCGR(p, cond, hregNumber(dst),
hregNumber(src.variant.reg));
case S390_OPND_AMODE: {
const s390_amode *am = src.variant.am;
/* We cannot use LOCx for loads less than 4 bytes. In that case
load into R0 and then use LOCGR. Do the same if the amode uses
an index register. */
if (insn->size < 4 ||
am->tag == S390_AMODE_BX12 || am->tag == S390_AMODE_BX20) {
p = s390_emit_load_mem(p, insn->size, R0, am);
p = s390_emit_LOCGR(p, cond, hregNumber(dst), R0);
return p;
}
vassert(am->tag == S390_AMODE_B12 || am->tag == S390_AMODE_B20);
vassert(insn->size == 4 || insn->size == 8);
UInt b = hregNumber(am->b);
UInt d = am->d;
if (insn->size == 4) {
return s390_emit_LOC(p, hregNumber(dst), cond, b, DISP20(d));
}
return s390_emit_LOCG(p, hregNumber(dst), cond, b, DISP20(d));
}
case S390_OPND_IMMEDIATE: {
ULong value = src.variant.imm;
/* Load value into R0, then use LOCGR */
if (insn->size <= 4) {
p = s390_emit_load_32imm(p, R0, value);
return s390_emit_LOCGR(p, cond, hregNumber(dst), R0);
}
vassert(insn->size == 8);
p = s390_emit_load_64imm(p, R0, value);
return s390_emit_LOCGR(p, cond, hregNumber(dst), R0);
}
}
}
use_branch_insn:
/* Branch (if cond fails) over move instrs */
if (cond != S390_CC_ALWAYS) {
/* Don't know how many bytes to jump over yet.
Make space for a BRC instruction (4 bytes) and fill in later. */
ptmp = p; /* to be filled in here */
p += 4;
}
// cond true: move src => dst
switch (src.tag) {
case S390_OPND_REG:
p = s390_emit_LGR(p, hregNumber(dst), hregNumber(src.variant.reg));
break;
case S390_OPND_AMODE:
p = s390_emit_load_mem(p, insn->size, hregNumber(dst), src.variant.am);
break;
case S390_OPND_IMMEDIATE: {
ULong value = src.variant.imm;
UInt r = hregNumber(dst);
switch (insn->size) {
case 1:
case 2:
/* Load the immediate values as a 4 byte value. That does not hurt as
those extra bytes will not be looked at. Fall through .... */
case 4:
p = s390_emit_load_32imm(p, r, value);
break;
case 8:
p = s390_emit_load_64imm(p, r, value);
break;
}
break;
}
default:
goto fail;
}
if (cond != S390_CC_ALWAYS) {
Int delta = p - ptmp;
delta >>= 1; /* immediate constant is #half-words */
vassert(delta > 0 && delta < (1 << 16));
s390_emit_BRC(ptmp, s390_cc_invert(cond), delta);
}
return p;
fail:
vpanic("s390_insn_cond_move_emit");
}
static UChar *
s390_insn_bfp_triop_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.bfp_triop.dst);
UInt r2 = hregNumber(insn->variant.bfp_triop.op2);
UInt r3 = hregNumber(insn->variant.bfp_triop.op3);
switch (insn->size) {
case 4:
switch (insn->variant.bfp_triop.tag) {
case S390_BFP_MADD: return s390_emit_MAEBR(buf, r1, r3, r2);
case S390_BFP_MSUB: return s390_emit_MSEBR(buf, r1, r3, r2);
default: goto fail;
}
break;
case 8:
switch (insn->variant.bfp_triop.tag) {
case S390_BFP_MADD: return s390_emit_MADBR(buf, r1, r3, r2);
case S390_BFP_MSUB: return s390_emit_MSDBR(buf, r1, r3, r2);
default: goto fail;
}
break;
default: goto fail;
}
fail:
vpanic("s390_insn_bfp_triop_emit");
}
static UChar *
s390_insn_bfp_binop_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.bfp_binop.dst_hi);
UInt r2 = hregNumber(insn->variant.bfp_binop.op2_hi);
switch (insn->size) {
case 4:
switch (insn->variant.bfp_binop.tag) {
case S390_BFP_ADD: return s390_emit_AEBR(buf, r1, r2);
case S390_BFP_SUB: return s390_emit_SEBR(buf, r1, r2);
case S390_BFP_MUL: return s390_emit_MEEBR(buf, r1, r2);
case S390_BFP_DIV: return s390_emit_DEBR(buf, r1, r2);
default: goto fail;
}
break;
case 8:
switch (insn->variant.bfp_binop.tag) {
case S390_BFP_ADD: return s390_emit_ADBR(buf, r1, r2);
case S390_BFP_SUB: return s390_emit_SDBR(buf, r1, r2);
case S390_BFP_MUL: return s390_emit_MDBR(buf, r1, r2);
case S390_BFP_DIV: return s390_emit_DDBR(buf, r1, r2);
default: goto fail;
}
break;
case 16:
switch (insn->variant.bfp_binop.tag) {
case S390_BFP_ADD: return s390_emit_AXBR(buf, r1, r2);
case S390_BFP_SUB: return s390_emit_SXBR(buf, r1, r2);
case S390_BFP_MUL: return s390_emit_MXBR(buf, r1, r2);
case S390_BFP_DIV: return s390_emit_DXBR(buf, r1, r2);
default: goto fail;
}
break;
default: goto fail;
}
fail:
vpanic("s390_insn_bfp_binop_emit");
}
static UChar *
s390_insn_bfp_unop_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.bfp_unop.dst_hi);
UInt r2 = hregNumber(insn->variant.bfp_unop.op_hi);
switch (insn->variant.bfp_unop.tag) {
case S390_BFP_ABS:
switch (insn->size) {
case 4: return s390_emit_LPEBR(buf, r1, r2);
case 8: return s390_emit_LPDBR(buf, r1, r2);
case 16: return s390_emit_LPXBR(buf, r1, r2);
default: goto fail;
}
break;
case S390_BFP_NABS:
switch (insn->size) {
case 4: return s390_emit_LNEBR(buf, r1, r2);
case 8: return s390_emit_LNDBR(buf, r1, r2);
case 16: return s390_emit_LNXBR(buf, r1, r2);
default: goto fail;
}
break;
case S390_BFP_NEG:
switch (insn->size) {
case 4: return s390_emit_LCEBR(buf, r1, r2);
case 8: return s390_emit_LCDBR(buf, r1, r2);
case 16: return s390_emit_LCXBR(buf, r1, r2);
default: goto fail;
}
break;
case S390_BFP_SQRT:
switch (insn->size) {
case 4: return s390_emit_SQEBR(buf, r1, r2);
case 8: return s390_emit_SQDBR(buf, r1, r2);
case 16: return s390_emit_SQXBR(buf, r1, r2);
default: goto fail;
}
break;
default: goto fail;
}
fail:
vpanic("s390_insn_bfp_unop_emit");
}
static UChar *
s390_insn_bfp_convert_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.bfp_convert.dst_hi);
UInt r2 = hregNumber(insn->variant.bfp_convert.op_hi);
s390_bfp_round_t m3 = insn->variant.bfp_convert.rounding_mode;
/* The IEEE-inexact-exception control is not modelled. So the
m4 field is 0 (which is what GCC does, too) */
const UInt m4 = 0;
switch (insn->variant.bfp_convert.tag) {
/* Convert to fixed */
case S390_BFP_F32_TO_I32: return s390_emit_CFEBR(buf, m3, r1, r2);
case S390_BFP_F64_TO_I32: return s390_emit_CFDBR(buf, m3, r1, r2);
case S390_BFP_F128_TO_I32: return s390_emit_CFXBR(buf, m3, r1, r2);
case S390_BFP_F32_TO_I64: return s390_emit_CGEBR(buf, m3, r1, r2);
case S390_BFP_F64_TO_I64: return s390_emit_CGDBR(buf, m3, r1, r2);
case S390_BFP_F128_TO_I64: return s390_emit_CGXBR(buf, m3, r1, r2);
/* Convert to logical */
case S390_BFP_F32_TO_U32: return s390_emit_CLFEBR(buf, m3, m4, r1, r2);
case S390_BFP_F64_TO_U32: return s390_emit_CLFDBR(buf, m3, m4, r1, r2);
case S390_BFP_F128_TO_U32: return s390_emit_CLFXBR(buf, m3, m4, r1, r2);
case S390_BFP_F32_TO_U64: return s390_emit_CLGEBR(buf, m3, m4, r1, r2);
case S390_BFP_F64_TO_U64: return s390_emit_CLGDBR(buf, m3, m4, r1, r2);
case S390_BFP_F128_TO_U64: return s390_emit_CLGXBR(buf, m3, m4, r1, r2);
/* Convert from fixed */
case S390_BFP_I32_TO_F32: return s390_emit_CEFBRA(buf, m3, m4, r1, r2);
case S390_BFP_I32_TO_F64: return s390_emit_CDFBRA(buf, 0, m4, r1, r2);
case S390_BFP_I32_TO_F128: return s390_emit_CXFBRA(buf, 0, m4, r1, r2);
case S390_BFP_I64_TO_F32: return s390_emit_CEGBRA(buf, m3, m4, r1, r2);
case S390_BFP_I64_TO_F64: return s390_emit_CDGBRA(buf, m3, m4, r1, r2);
case S390_BFP_I64_TO_F128: return s390_emit_CXGBRA(buf, 0, m4, r1, r2);
/* Convert from logical */
case S390_BFP_U32_TO_F32: return s390_emit_CELFBR(buf, m3, m4, r1, r2);
case S390_BFP_U32_TO_F64: return s390_emit_CDLFBR(buf, m3, m4, r1, r2);
case S390_BFP_U32_TO_F128: return s390_emit_CXLFBR(buf, m3, m4, r1, r2);
case S390_BFP_U64_TO_F32: return s390_emit_CELGBR(buf, m3, m4, r1, r2);
case S390_BFP_U64_TO_F64: return s390_emit_CDLGBR(buf, m3, m4, r1, r2);
case S390_BFP_U64_TO_F128: return s390_emit_CXLGBR(buf, m3, m4, r1, r2);
/* Load lengthened */
case S390_BFP_F32_TO_F64: return s390_emit_LDEBR(buf, r1, r2);
case S390_BFP_F32_TO_F128: return s390_emit_LXEBR(buf, r1, r2);
case S390_BFP_F64_TO_F128: return s390_emit_LXDBR(buf, r1, r2);
/* Load rounded */
case S390_BFP_F64_TO_F32: return s390_emit_LEDBRA(buf, m3, m4, r1, r2);
case S390_BFP_F128_TO_F32: return s390_emit_LEXBRA(buf, m3, m4, r1, r2);
case S390_BFP_F128_TO_F64: return s390_emit_LDXBRA(buf, m3, m4, r1, r2);
/* Load FP integer */
case S390_BFP_F32_TO_F32I: return s390_emit_FIEBRA(buf, m3, m4, r1, r2);
case S390_BFP_F64_TO_F64I: return s390_emit_FIDBRA(buf, m3, m4, r1, r2);
case S390_BFP_F128_TO_F128I: return s390_emit_FIXBRA(buf, m3, m4, r1, r2);
default: goto fail;
}
fail:
vpanic("s390_insn_bfp_convert_emit");
}
static UChar *
s390_insn_bfp_compare_emit(UChar *buf, const s390_insn *insn)
{
UInt dst = hregNumber(insn->variant.bfp_compare.dst);
UInt r1 = hregNumber(insn->variant.bfp_compare.op1_hi);
UInt r2 = hregNumber(insn->variant.bfp_compare.op2_hi);
switch (insn->size) {
case 4: buf = s390_emit_CEBR(buf, r1, r2); break;
case 8: buf = s390_emit_CDBR(buf, r1, r2); break;
case 16: buf = s390_emit_CXBR(buf, r1, r2); break;
default: goto fail;
}
return s390_emit_load_cc(buf, dst); /* Load condition code into DST */
fail:
vpanic("s390_insn_bfp_compare_emit");
}
static UChar *
s390_insn_dfp_binop_emit(UChar *buf, const s390_insn *insn)
{
s390_dfp_binop *dfp_binop = insn->variant.dfp_binop.details;
UInt r1 = hregNumber(dfp_binop->dst_hi);
UInt r2 = hregNumber(dfp_binop->op2_hi);
UInt r3 = hregNumber(dfp_binop->op3_hi);
s390_dfp_round_t m4 = dfp_binop->rounding_mode;
switch (insn->size) {
case 8:
switch (dfp_binop->tag) {
case S390_DFP_ADD: return s390_emit_ADTRA(buf, r3, m4, r1, r2);
case S390_DFP_SUB: return s390_emit_SDTRA(buf, r3, m4, r1, r2);
case S390_DFP_MUL: return s390_emit_MDTRA(buf, r3, m4, r1, r2);
case S390_DFP_DIV: return s390_emit_DDTRA(buf, r3, m4, r1, r2);
case S390_DFP_QUANTIZE: return s390_emit_QADTR(buf, r3, m4, r1, r2);
default: goto fail;
}
break;
case 16:
switch (dfp_binop->tag) {
case S390_DFP_ADD: return s390_emit_AXTRA(buf, r3, m4, r1, r2);
case S390_DFP_SUB: return s390_emit_SXTRA(buf, r3, m4, r1, r2);
case S390_DFP_MUL: return s390_emit_MXTRA(buf, r3, m4, r1, r2);
case S390_DFP_DIV: return s390_emit_DXTRA(buf, r3, m4, r1, r2);
case S390_DFP_QUANTIZE: return s390_emit_QAXTR(buf, r3, m4, r1, r2);
default: goto fail;
}
break;
default: goto fail;
}
fail:
vpanic("s390_insn_dfp_binop_emit");
}
static UChar *
s390_insn_dfp_reround_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.dfp_reround.dst_hi);
UInt r2 = hregNumber(insn->variant.dfp_reround.op2);
UInt r3 = hregNumber(insn->variant.dfp_reround.op3_hi);
s390_dfp_round_t m4 = insn->variant.dfp_reround.rounding_mode;
switch (insn->size) {
case 8:
return s390_emit_RRDTR(buf, r3, m4, r1, r2);
case 16:
return s390_emit_RRXTR(buf, r3, m4, r1, r2);
default: goto fail;
}
fail:
vpanic("s390_insn_dfp_reround_emit");
}
static UChar *
s390_insn_dfp_unop_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.dfp_unop.dst_hi);
UInt r2 = hregNumber(insn->variant.dfp_unop.op_hi);
switch (insn->variant.dfp_unop.tag) {
case S390_DFP_EXTRACT_EXP_D64: return s390_emit_EEDTR(buf, r1, r2); break;
case S390_DFP_EXTRACT_EXP_D128: return s390_emit_EEXTR(buf, r1, r2); break;
case S390_DFP_EXTRACT_SIG_D64: return s390_emit_ESDTR(buf, r1, r2); break;
case S390_DFP_EXTRACT_SIG_D128: return s390_emit_ESXTR(buf, r1, r2); break;
default: goto fail;
}
fail:
vpanic("s390_insn_dfp_unop_emit");
}
static UChar *
s390_insn_dfp_intop_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.dfp_intop.dst_hi);
UInt r2 = hregNumber(insn->variant.dfp_intop.op2);
UInt r3 = hregNumber(insn->variant.dfp_intop.op3_hi);
switch (insn->size) {
case 8:
switch (insn->variant.dfp_intop.tag) {
case S390_DFP_SHIFT_LEFT: return s390_emit_SLDT(buf, r3, r1, r2);
case S390_DFP_SHIFT_RIGHT: return s390_emit_SRDT(buf, r3, r1, r2);
case S390_DFP_INSERT_EXP: return s390_emit_IEDTR(buf, r3, r1, r2);
default: goto fail;
}
break;
case 16:
switch (insn->variant.dfp_intop.tag) {
case S390_DFP_SHIFT_LEFT: return s390_emit_SLXT(buf, r3, r1, r2);
case S390_DFP_SHIFT_RIGHT: return s390_emit_SRXT(buf, r3, r1, r2);
case S390_DFP_INSERT_EXP: return s390_emit_IEXTR(buf, r3, r1, r2);
default: goto fail;
}
break;
default: goto fail;
}
fail:
vpanic("s390_insn_dfp_intop_emit");
}
static UChar *
s390_insn_dfp_compare_emit(UChar *buf, const s390_insn *insn)
{
UInt dst = hregNumber(insn->variant.dfp_compare.dst);
UInt r1 = hregNumber(insn->variant.dfp_compare.op1_hi);
UInt r2 = hregNumber(insn->variant.dfp_compare.op2_hi);
switch (insn->size) {
case 8:
switch(insn->variant.dfp_compare.tag) {
case S390_DFP_COMPARE: buf = s390_emit_CDTR(buf, r1, r2); break;
case S390_DFP_COMPARE_EXP: buf = s390_emit_CEDTR(buf, r1, r2); break;
default: goto fail;
}
break;
case 16:
switch(insn->variant.dfp_compare.tag) {
case S390_DFP_COMPARE: buf = s390_emit_CXTR(buf, r1, r2); break;
case S390_DFP_COMPARE_EXP: buf = s390_emit_CEXTR(buf, r1, r2); break;
default: goto fail;
}
break;
default: goto fail;
}
return s390_emit_load_cc(buf, dst); /* Load condition code into DST */
fail:
vpanic("s390_insn_dfp_compare_emit");
}
static UChar *
s390_insn_dfp_convert_emit(UChar *buf, const s390_insn *insn)
{
UInt r1 = hregNumber(insn->variant.dfp_convert.dst_hi);
UInt r2 = hregNumber(insn->variant.dfp_convert.op_hi);
s390_dfp_round_t m3 = insn->variant.dfp_convert.rounding_mode;
/* The IEEE-inexact-exception control is not modelled. So the
m4 field is 0 (which is what GCC does, too) */
const UInt m4 = 0;
switch (insn->variant.dfp_convert.tag) {
/* Convert to fixed */
case S390_DFP_D64_TO_I32: return s390_emit_CFDTR(buf, m3, m4, r1, r2);
case S390_DFP_D128_TO_I32: return s390_emit_CFXTR(buf, m3, m4, r1, r2);
case S390_DFP_D64_TO_I64: return s390_emit_CGDTR(buf, m3, m4, r1, r2);
case S390_DFP_D128_TO_I64: return s390_emit_CGXTR(buf, m3, m4, r1, r2);
/* Convert to logical */
case S390_DFP_D64_TO_U32: return s390_emit_CLFDTR(buf, m3, m4, r1, r2);
case S390_DFP_D128_TO_U32: return s390_emit_CLFXTR(buf, m3, m4, r1, r2);
case S390_DFP_D64_TO_U64: return s390_emit_CLGDTR(buf, m3, m4, r1, r2);
case S390_DFP_D128_TO_U64: return s390_emit_CLGXTR(buf, m3, m4, r1, r2);
/* Convert from fixed */
case S390_DFP_I32_TO_D64: return s390_emit_CDFTR(buf, 0, m4, r1, r2);
case S390_DFP_I32_TO_D128: return s390_emit_CXFTR(buf, 0, m4, r1, r2);
case S390_DFP_I64_TO_D64: return s390_emit_CDGTRA(buf, m3, m4, r1, r2);
case S390_DFP_I64_TO_D128: return s390_emit_CXGTR(buf, 0, m4, r1, r2);
/* Convert from logical */
case S390_DFP_U32_TO_D64: return s390_emit_CDLFTR(buf, m3, m4, r1, r2);
case S390_DFP_U64_TO_D64: return s390_emit_CDLGTR(buf, m3, m4, r1, r2);
case S390_DFP_U32_TO_D128: return s390_emit_CXLFTR(buf, m3, m4, r1, r2);
case S390_DFP_U64_TO_D128: return s390_emit_CXLGTR(buf, m3, m4, r1, r2);
/* Load lengthened */
case S390_DFP_D32_TO_D64: return s390_emit_LDETR(buf, m4, r1, r2);
case S390_DFP_D64_TO_D128: return s390_emit_LXDTR(buf, m4, r1, r2);
/* Load rounded */
case S390_DFP_D64_TO_D32: return s390_emit_LEDTR(buf, m3, m4, r1, r2);
case S390_DFP_D128_TO_D64: return s390_emit_LDXTR(buf, m3, m4, r1, r2);
default: goto fail;
}
fail:
vpanic("s390_insn_dfp_convert_emit");
}
static UChar *
s390_insn_fp_convert_emit(UChar *buf, const s390_insn *insn)
{
UInt pfpo;
s390_fp_convert *fp_convert = insn->variant.fp_convert.details;
s390_dfp_round_t rm = fp_convert->rounding_mode;
vassert(rm < 2 || rm > 7);
switch (fp_convert->tag) {
case S390_FP_F32_TO_D32: pfpo = S390_PFPO_F32_TO_D32 << 8; break;
case S390_FP_F32_TO_D64: pfpo = S390_PFPO_F32_TO_D64 << 8; break;
case S390_FP_F32_TO_D128: pfpo = S390_PFPO_F32_TO_D128 << 8; break;
case S390_FP_F64_TO_D32: pfpo = S390_PFPO_F64_TO_D32 << 8; break;
case S390_FP_F64_TO_D64: pfpo = S390_PFPO_F64_TO_D64 << 8; break;
case S390_FP_F64_TO_D128: pfpo = S390_PFPO_F64_TO_D128 << 8; break;
case S390_FP_F128_TO_D32: pfpo = S390_PFPO_F128_TO_D32 << 8; break;
case S390_FP_F128_TO_D64: pfpo = S390_PFPO_F128_TO_D64 << 8; break;
case S390_FP_F128_TO_D128: pfpo = S390_PFPO_F128_TO_D128 << 8; break;
case S390_FP_D32_TO_F32: pfpo = S390_PFPO_D32_TO_F32 << 8; break;
case S390_FP_D32_TO_F64: pfpo = S390_PFPO_D32_TO_F64 << 8; break;
case S390_FP_D32_TO_F128: pfpo = S390_PFPO_D32_TO_F128 << 8; break;
case S390_FP_D64_TO_F32: pfpo = S390_PFPO_D64_TO_F32 << 8; break;
case S390_FP_D64_TO_F64: pfpo = S390_PFPO_D64_TO_F64 << 8; break;
case S390_FP_D64_TO_F128: pfpo = S390_PFPO_D64_TO_F128 << 8; break;
case S390_FP_D128_TO_F32: pfpo = S390_PFPO_D128_TO_F32 << 8; break;
case S390_FP_D128_TO_F64: pfpo = S390_PFPO_D128_TO_F64 << 8; break;
case S390_FP_D128_TO_F128: pfpo = S390_PFPO_D128_TO_F128 << 8; break;
default: goto fail;
}
pfpo = pfpo | rm;
buf = s390_emit_load_32imm(buf, R0, pfpo);
buf = s390_emit_PFPO(buf);
return buf;
fail:
vpanic("s390_insn_fp_convert_emit");
}
static UChar *
s390_insn_mfence_emit(UChar *buf, const s390_insn *insn)
{
return s390_emit_BCR(buf, 0xF, 0x0);
}
static UChar *
s390_insn_mimm_emit(UChar *buf, const s390_insn *insn)
{
s390_amode *am = insn->variant.mimm.dst;
UChar b = hregNumber(am->b);
Int d = am->d;
ULong value = insn->variant.mimm.value;
if (value == 0) {
return s390_emit_XC(buf, insn->size - 1, b, d, b, d);
}
if (insn->size == 1) {
return s390_emit_MVI(buf, value & 0xFF, b, d);
}
if (s390_host_has_gie && ulong_fits_signed_16bit(value)) {
value &= 0xFFFF;
switch (insn->size) {
case 2: return s390_emit_MVHHI(buf, b, d, value);
case 4: return s390_emit_MVHI(buf, b, d, value);
case 8: return s390_emit_MVGHI(buf, b, d, value);
}
} else {
// Load value to R0, then store.
switch (insn->size) {
case 2:
buf = s390_emit_LHI(buf, R0, value & 0xFFFF);
return s390_emit_STH(buf, R0, 0, b, d);
case 4:
buf = s390_emit_load_32imm(buf, R0, value);
return s390_emit_ST(buf, R0, 0, b, d);
case 8:
buf = s390_emit_load_64imm(buf, R0, value);
return s390_emit_STG(buf, R0, 0, b, DISP20(d));
}
}
vpanic("s390_insn_mimm_emit");
}
static UChar *
s390_insn_madd_emit(UChar *buf, const s390_insn *insn)
{
s390_amode *am = insn->variant.madd.dst;
UChar b = hregNumber(am->b);
Int d = am->d;
if (insn->size == 4) {
return s390_emit_ASI(buf, insn->variant.madd.delta, b, DISP20(d));
}
return s390_emit_AGSI(buf, insn->variant.madd.delta, b, DISP20(d));
}
static UChar *
s390_insn_set_fpc_bfprm_emit(UChar *buf, const s390_insn *insn)
{
UInt mode = hregNumber(insn->variant.set_fpc_bfprm.mode);
/* Copy FPC from guest state to R0 and OR in the new rounding mode */
buf = s390_emit_L(buf, R0, 0, S390_REGNO_GUEST_STATE_POINTER,
S390X_GUEST_OFFSET(guest_fpc)); // r0 = guest_fpc
buf = s390_emit_NILL(buf, R0, 0xFFF8); /* Clear out right-most 3 bits */
buf = s390_emit_OR(buf, R0, mode); /* OR in the new rounding mode */
buf = s390_emit_SFPC(buf, R0); /* Load FPC register from R0 */
return buf;
}
static UChar *
s390_insn_set_fpc_dfprm_emit(UChar *buf, const s390_insn *insn)
{
UInt mode = hregNumber(insn->variant.set_fpc_dfprm.mode);
/* Copy FPC from guest state to R0 and OR in the new rounding mode */
buf = s390_emit_L(buf, R0, 0, S390_REGNO_GUEST_STATE_POINTER,
S390X_GUEST_OFFSET(guest_fpc)); // r0 = guest_fpc
/* DFP rounding mode is set at bit position 25:27 in FPC register */
buf = s390_emit_NILL(buf, R0, 0xFF8F); /* Clear out 25:27 bits */
buf = s390_emit_SLL(buf, mode, 0, 4); /* bring mode to 25:27 bits */
buf = s390_emit_OR(buf, R0, mode); /* OR in the new rounding mode */
buf = s390_emit_SFPC(buf, R0); /* Load FPC register from R0 */
return buf;
}
/* Define convenience functions needed for translation chaining.
Any changes need to be applied to the functions in concert. */
static __inline__ Bool
s390_insn_is_BRCL(const UChar *p, UChar condition)
{
return p[0] == 0xc0 && p[1] == ((condition << 4) | 0x04);
}
static __inline__ Bool
s390_insn_is_BR(const UChar *p, UChar reg)
{
return p[0] == 0x07 && p[1] == (0xF0 | reg); /* BCR 15,reg */
}
/* The length of the BASR insn */
#define S390_BASR_LEN 2
/* Load the 64-bit VALUE into REG. Note that this function must NOT
optimise the generated code by looking at the value. I.e. using
LGHI if value == 0 would be very wrong. */
static UChar *
s390_tchain_load64(UChar *buf, UChar regno, ULong value)
{
UChar *begin = buf;
if (s390_host_has_eimm) {
/* Do it in two steps: upper half [0:31] and lower half [32:63] */
buf = s390_emit_IIHF(buf, regno, value >> 32);
buf = s390_emit_IILF(buf, regno, value & 0xFFFFFFFF);
} else {
buf = s390_emit_IILL(buf, regno, value & 0xFFFF);
value >>= 16;
buf = s390_emit_IILH(buf, regno, value & 0xFFFF);
value >>= 16;
buf = s390_emit_IIHL(buf, regno, value & 0xFFFF);
value >>= 16;
buf = s390_emit_IIHH(buf, regno, value & 0xFFFF);
}
vassert(buf - begin == s390_tchain_load64_len());
return buf;
}
/* Return number of bytes generated by s390_tchain_load64 */
static UInt
s390_tchain_load64_len(void)
{
if (s390_host_has_eimm) {
return 6 + 6; /* IIHF + IILF */
}
return 4 + 4 + 4 + 4; /* IIHH + IIHL + IILH + IILL */
}
/* Verify that CODE is the code sequence generated by s390_tchain_load64
to load VALUE into REGNO. Return pointer to the byte following the
insn sequence. */
static const UChar *
s390_tchain_verify_load64(const UChar *code, UChar regno, ULong value)
{
UInt regmask = regno << 4;
UInt hw;
if (s390_host_has_eimm) {
/* Check for IIHF */
vassert(code[0] == 0xC0);
vassert(code[1] == (0x08 | regmask));
vassert(*(const UInt *)&code[2] == (value >> 32));
/* Check for IILF */
vassert(code[6] == 0xC0);
vassert(code[7] == (0x09 | regmask));
vassert(*(const UInt *)&code[8] == (value & 0xFFFFFFFF));
} else {
/* Check for IILL */
hw = value & 0xFFFF;
vassert(code[0] == 0xA5);
vassert(code[1] == (0x03 | regmask));
vassert(code[2] == (hw >> 8));
vassert(code[3] == (hw & 0xFF));
/* Check for IILH */
hw = (value >> 16) & 0xFFFF;
vassert(code[4] == 0xA5);
vassert(code[5] == (0x02 | regmask));
vassert(code[6] == (hw >> 8));
vassert(code[7] == (hw & 0xFF));
/* Check for IIHL */
hw = (value >> 32) & 0xFFFF;
vassert(code[8] == 0xA5);
vassert(code[9] == (0x01 | regmask));
vassert(code[10] == (hw >> 8));
vassert(code[11] == (hw & 0xFF));
/* Check for IIHH */
hw = (value >> 48) & 0xFFFF;
vassert(code[12] == 0xA5);
vassert(code[13] == (0x00 | regmask));
vassert(code[14] == (hw >> 8));
vassert(code[15] == (hw & 0xFF));
}
return code + s390_tchain_load64_len();
}
/* CODE points to the code sequence as generated by s390_tchain_load64.
Change the loaded value to IMM64. Return pointer to the byte following
the patched code sequence. */
static UChar *
s390_tchain_patch_load64(UChar *code, ULong imm64)
{
if (s390_host_has_eimm) {
/* Patch IIHF */
*(UInt *)&code[2] = imm64 >> 32;
/* Patch IILF */
*(UInt *)&code[8] = imm64 & 0xFFFFFFFF;
} else {
code[3] = imm64 & 0xFF; imm64 >>= 8;
code[2] = imm64 & 0xFF; imm64 >>= 8;
code[7] = imm64 & 0xFF; imm64 >>= 8;
code[6] = imm64 & 0xFF; imm64 >>= 8;
code[11] = imm64 & 0xFF; imm64 >>= 8;
code[10] = imm64 & 0xFF; imm64 >>= 8;
code[15] = imm64 & 0xFF; imm64 >>= 8;
code[14] = imm64 & 0xFF; imm64 >>= 8;
}
return code + s390_tchain_load64_len();
}
/* NB: what goes on here has to be very closely coordinated with the
chainXDirect_S390 and unchainXDirect_S390 below. */
static UChar *
s390_insn_xdirect_emit(UChar *buf, const s390_insn *insn,
const void *disp_cp_chain_me_to_slowEP,
const void *disp_cp_chain_me_to_fastEP)
{
/* We're generating chain-me requests here, so we need to be
sure this is actually allowed -- no-redir translations can't
use chain-me's. Hence: */
vassert(disp_cp_chain_me_to_slowEP != NULL);
vassert(disp_cp_chain_me_to_fastEP != NULL);
/* Use ptmp for backpatching conditional jumps. */
UChar *ptmp = buf;
/* First off, if this is conditional, create a conditional
jump over the rest of it. */
s390_cc_t cond = insn->variant.xdirect.cond;
if (cond != S390_CC_ALWAYS) {
/* So we have something like this
if (cond) do_xdirect;
Y: ...
We convert this into
if (! cond) goto Y; // BRC opcode; 4 bytes
do_xdirect;
Y:
*/
/* 4 bytes (a BRC insn) to be filled in here */
buf += 4;
}
/* Update the guest IA. */
buf = s390_emit_load_64imm(buf, R0, insn->variant.xdirect.dst);
const s390_amode *amode = insn->variant.xdirect.guest_IA;
vassert(amode->tag == S390_AMODE_B12);
UInt b = hregNumber(amode->b);
UInt d = amode->d;
buf = s390_emit_STG(buf, R0, 0, b, DISP20(d));
/* Load the chosen entry point into the scratch reg */
const void *disp_cp_chain_me;
disp_cp_chain_me =
insn->variant.xdirect.to_fast_entry ? disp_cp_chain_me_to_fastEP
: disp_cp_chain_me_to_slowEP;
/* Get the address of the beginning of the load64 code sequence into %r1.
Do not change the register! This is part of the protocol with the
dispatcher. */
buf = s390_emit_BASR(buf, 1, R0);
/* --- FIRST PATCHABLE BYTE follows (must not modify %r1) --- */
Addr64 addr = (Addr)disp_cp_chain_me;
buf = s390_tchain_load64(buf, S390_REGNO_TCHAIN_SCRATCH, addr);
/* goto *tchain_scratch */
buf = s390_emit_BCR(buf, S390_CC_ALWAYS, S390_REGNO_TCHAIN_SCRATCH);
/* --- END of PATCHABLE BYTES --- */
/* Fix up the conditional jump, if there was one. */
if (cond != S390_CC_ALWAYS) {
Int delta = buf - ptmp;
delta >>= 1; /* immediate constant is #half-words */
vassert(delta > 0 && delta < (1 << 16));
s390_emit_BRC(ptmp, s390_cc_invert(cond), delta);
}
return buf;
}
/* Return the number of patchable bytes from an xdirect insn. */
static UInt
s390_xdirect_patchable_len(void)
{
return s390_tchain_load64_len() + S390_BASR_LEN;
}
static UChar *
s390_insn_xindir_emit(UChar *buf, const s390_insn *insn,
const void *disp_cp_xindir)
{
/* We're generating transfers that could lead indirectly to a
chain-me, so we need to be sure this is actually allowed --
no-redir translations are not allowed to reach normal
translations without going through the scheduler. That means
no XDirects or XIndirs out from no-redir translations.
Hence: */
vassert(disp_cp_xindir != NULL);
/* Use ptmp for backpatching conditional jumps. */
UChar *ptmp = buf;
/* First off, if this is conditional, create a conditional
jump over the rest of it. */
s390_cc_t cond = insn->variant.xdirect.cond;
if (cond != S390_CC_ALWAYS) {
/* So we have something like this
if (cond) do_xdirect;
Y: ...
We convert this into
if (! cond) goto Y; // BRC opcode; 4 bytes
do_xdirect;
Y:
*/
/* 4 bytes (a BRC insn) to be filled in here */
buf += 4;
}
/* Update the guest IA with the address in xdirect.dst. */
const s390_amode *amode = insn->variant.xindir.guest_IA;
vassert(amode->tag == S390_AMODE_B12);
UInt b = hregNumber(amode->b);
UInt d = amode->d;
UInt regno = hregNumber(insn->variant.xindir.dst);
buf = s390_emit_STG(buf, regno, 0, b, DISP20(d));
/* load tchain_scratch, #disp_indir */
buf = s390_tchain_load64(buf, S390_REGNO_TCHAIN_SCRATCH,
(Addr)disp_cp_xindir);
/* goto *tchain_direct */
buf = s390_emit_BCR(buf, S390_CC_ALWAYS, S390_REGNO_TCHAIN_SCRATCH);
/* Fix up the conditional jump, if there was one. */
if (cond != S390_CC_ALWAYS) {
Int delta = buf - ptmp;
delta >>= 1; /* immediate constant is #half-words */
vassert(delta > 0 && delta < (1 << 16));
s390_emit_BRC(ptmp, s390_cc_invert(cond), delta);
}
return buf;
}
static UChar *
s390_insn_xassisted_emit(UChar *buf, const s390_insn *insn,
const void *disp_cp_xassisted)
{
/* Use ptmp for backpatching conditional jumps. */
UChar *ptmp = buf;
/* First off, if this is conditional, create a conditional
jump over the rest of it. */
s390_cc_t cond = insn->variant.xdirect.cond;
if (cond != S390_CC_ALWAYS) {
/* So we have something like this
if (cond) do_xdirect;
Y: ...
We convert this into
if (! cond) goto Y; // BRC opcode; 4 bytes
do_xdirect;
Y:
*/
/* 4 bytes (a BRC insn) to be filled in here */
buf += 4;
}
/* Update the guest IA with the address in xassisted.dst. */
const s390_amode *amode = insn->variant.xassisted.guest_IA;
vassert(amode->tag == S390_AMODE_B12);
UInt b = hregNumber(amode->b);
UInt d = amode->d;
UInt regno = hregNumber(insn->variant.xassisted.dst);
buf = s390_emit_STG(buf, regno, 0, b, DISP20(d));
UInt trcval = 0;
switch (insn->variant.xassisted.kind) {
case Ijk_ClientReq: trcval = VEX_TRC_JMP_CLIENTREQ; break;
case Ijk_Sys_syscall: trcval = VEX_TRC_JMP_SYS_SYSCALL; break;
case Ijk_Yield: trcval = VEX_TRC_JMP_YIELD; break;
case Ijk_EmWarn: trcval = VEX_TRC_JMP_EMWARN; break;
case Ijk_EmFail: trcval = VEX_TRC_JMP_EMFAIL; break;
case Ijk_MapFail: trcval = VEX_TRC_JMP_MAPFAIL; break;
case Ijk_NoDecode: trcval = VEX_TRC_JMP_NODECODE; break;
case Ijk_InvalICache: trcval = VEX_TRC_JMP_INVALICACHE; break;
case Ijk_NoRedir: trcval = VEX_TRC_JMP_NOREDIR; break;
case Ijk_SigTRAP: trcval = VEX_TRC_JMP_SIGTRAP; break;
case Ijk_SigSEGV: trcval = VEX_TRC_JMP_SIGSEGV; break;
case Ijk_Boring: trcval = VEX_TRC_JMP_BORING; break;
/* We don't expect to see the following being assisted. */
case Ijk_Ret:
case Ijk_Call:
/* fallthrough */
default:
ppIRJumpKind(insn->variant.xassisted.kind);
vpanic("s390_insn_xassisted_emit: unexpected jump kind");
}
vassert(trcval != 0);
/* guest_state_pointer = trcval */
buf = s390_emit_LGHI(buf, S390_REGNO_GUEST_STATE_POINTER, trcval);
/* load tchain_scratch, #disp_assisted */
buf = s390_tchain_load64(buf, S390_REGNO_TCHAIN_SCRATCH,
(Addr)disp_cp_xassisted);
/* goto *tchain_direct */
buf = s390_emit_BCR(buf, S390_CC_ALWAYS, S390_REGNO_TCHAIN_SCRATCH);
/* Fix up the conditional jump, if there was one. */
if (cond != S390_CC_ALWAYS) {
Int delta = buf - ptmp;
delta >>= 1; /* immediate constant is #half-words */
vassert(delta > 0 && delta < (1 << 16));
s390_emit_BRC(ptmp, s390_cc_invert(cond), delta);
}
return buf;
}
/* Pseudo code:
guest_state[host_EvC_COUNTER] -= 1;
if (guest_state[host_EvC_COUNTER] >= 0) goto nofail;
goto guest_state[host_EvC_FAILADDR];
nofail: ;
The dispatch counter is a 32-bit value. */
static UChar *
s390_insn_evcheck_emit(UChar *buf, const s390_insn *insn,
VexEndness endness_host)
{
s390_amode *amode;
UInt b, d;
UChar *code_begin, *code_end;
code_begin = buf;
amode = insn->variant.evcheck.counter;
vassert(amode->tag == S390_AMODE_B12);
b = hregNumber(amode->b);
d = amode->d;
/* Decrement the dispatch counter in the guest state */
if (s390_host_has_gie) {
buf = s390_emit_ASI(buf, -1, b, DISP20(d)); /* 6 bytes */
} else {
buf = s390_emit_LHI(buf, R0, -1); /* 4 bytes */
buf = s390_emit_A(buf, R0, 0, b, d); /* 4 bytes */
buf = s390_emit_ST(buf, R0, 0, b, d); /* 4 bytes */
}
/* Jump over the next insn if >= 0 */
buf = s390_emit_BRC(buf, S390_CC_HE, (4 + 6 + 2) / 2); /* 4 bytes */
/* Computed goto to fail_address */
amode = insn->variant.evcheck.fail_addr;
b = hregNumber(amode->b);
d = amode->d;
buf = s390_emit_LG(buf, S390_REGNO_TCHAIN_SCRATCH, 0, b, DISP20(d)); /* 6 bytes */
buf = s390_emit_BCR(buf, S390_CC_ALWAYS, S390_REGNO_TCHAIN_SCRATCH); /* 2 bytes */
code_end = buf;
/* Make sure the size of the generated code is identical to the size
returned by evCheckSzB_S390 */
vassert(evCheckSzB_S390() == code_end - code_begin);
return buf;
}
static UChar *
s390_insn_profinc_emit(UChar *buf,
const s390_insn *insn __attribute__((unused)))
{
/* Generate a code template to increment a memory location whose
address will be known later as an immediate value. This code
template will be patched once the memory location is known.
For now we do this with address == 0. */
buf = s390_tchain_load64(buf, S390_REGNO_TCHAIN_SCRATCH, 0);
if (s390_host_has_gie) {
buf = s390_emit_AGSI(buf, 1, S390_REGNO_TCHAIN_SCRATCH, DISP20(0));
} else {
buf = s390_emit_LGHI(buf, R0, 1);
buf = s390_emit_AG( buf, R0, 0, S390_REGNO_TCHAIN_SCRATCH, DISP20(0));
buf = s390_emit_STG(buf, R0, 0, S390_REGNO_TCHAIN_SCRATCH, DISP20(0));
}
return buf;
}
Int
emit_S390Instr(Bool *is_profinc, UChar *buf, Int nbuf, const s390_insn *insn,
Bool mode64, VexEndness endness_host,
const void *disp_cp_chain_me_to_slowEP,
const void *disp_cp_chain_me_to_fastEP,
const void *disp_cp_xindir,
const void *disp_cp_xassisted)
{
UChar *end;
/* Used to be 48 bytes. Make sure it stays low */
vassert(sizeof(s390_insn) == 32);
switch (insn->tag) {
case S390_INSN_LOAD:
end = s390_insn_load_emit(buf, insn);
break;
case S390_INSN_STORE:
end = s390_insn_store_emit(buf, insn);
break;
case S390_INSN_MOVE:
end = s390_insn_move_emit(buf, insn);
break;
case S390_INSN_MEMCPY:
end = s390_insn_memcpy_emit(buf, insn);
break;
case S390_INSN_COND_MOVE:
end = s390_insn_cond_move_emit(buf, insn);
break;
case S390_INSN_LOAD_IMMEDIATE:
end = s390_insn_load_immediate_emit(buf, insn);
break;
case S390_INSN_ALU:
end = s390_insn_alu_emit(buf, insn);
break;
case S390_INSN_SMUL:
case S390_INSN_UMUL:
end = s390_insn_mul_emit(buf, insn);
break;
case S390_INSN_SDIV:
case S390_INSN_UDIV:
end = s390_insn_div_emit(buf, insn);
break;
case S390_INSN_DIVS:
end = s390_insn_divs_emit(buf, insn);
break;
case S390_INSN_CLZ:
end = s390_insn_clz_emit(buf, insn);
break;
case S390_INSN_UNOP:
end = s390_insn_unop_emit(buf, insn);
break;
case S390_INSN_TEST:
end = s390_insn_test_emit(buf, insn);
break;
case S390_INSN_CC2BOOL:
end = s390_insn_cc2bool_emit(buf, insn);
break;
case S390_INSN_CAS:
end = s390_insn_cas_emit(buf, insn);
break;
case S390_INSN_CDAS:
end = s390_insn_cdas_emit(buf, insn);
break;
case S390_INSN_COMPARE:
end = s390_insn_compare_emit(buf, insn);
break;
case S390_INSN_HELPER_CALL:
end = s390_insn_helper_call_emit(buf, insn);
if (end == buf) goto fail;
break;
case S390_INSN_BFP_TRIOP:
end = s390_insn_bfp_triop_emit(buf, insn);
break;
case S390_INSN_BFP_BINOP:
end = s390_insn_bfp_binop_emit(buf, insn);
break;
case S390_INSN_BFP_UNOP:
end = s390_insn_bfp_unop_emit(buf, insn);
break;
case S390_INSN_BFP_COMPARE:
end = s390_insn_bfp_compare_emit(buf, insn);
break;
case S390_INSN_BFP_CONVERT:
end = s390_insn_bfp_convert_emit(buf, insn);
break;
case S390_INSN_DFP_BINOP:
end = s390_insn_dfp_binop_emit(buf, insn);
break;
case S390_INSN_DFP_UNOP:
end = s390_insn_dfp_unop_emit(buf, insn);
break;
case S390_INSN_DFP_INTOP:
end = s390_insn_dfp_intop_emit(buf, insn);
break;
case S390_INSN_DFP_COMPARE:
end = s390_insn_dfp_compare_emit(buf, insn);
break;
case S390_INSN_DFP_CONVERT:
end = s390_insn_dfp_convert_emit(buf, insn);
break;
case S390_INSN_DFP_REROUND:
end = s390_insn_dfp_reround_emit(buf, insn);
break;
case S390_INSN_FP_CONVERT:
end = s390_insn_fp_convert_emit(buf, insn);
break;
case S390_INSN_MFENCE:
end = s390_insn_mfence_emit(buf, insn);
break;
case S390_INSN_MIMM:
end = s390_insn_mimm_emit(buf, insn);
break;
case S390_INSN_MADD:
end = s390_insn_madd_emit(buf, insn);
break;
case S390_INSN_SET_FPC_BFPRM:
end = s390_insn_set_fpc_bfprm_emit(buf, insn);
break;
case S390_INSN_SET_FPC_DFPRM:
end = s390_insn_set_fpc_dfprm_emit(buf, insn);
break;
case S390_INSN_PROFINC:
end = s390_insn_profinc_emit(buf, insn);
/* Tell the caller .. */
vassert(*is_profinc == False);
*is_profinc = True;
break;
case S390_INSN_EVCHECK:
end = s390_insn_evcheck_emit(buf, insn, endness_host);
break;
case S390_INSN_XDIRECT:
end = s390_insn_xdirect_emit(buf, insn, disp_cp_chain_me_to_slowEP,
disp_cp_chain_me_to_fastEP);
break;
case S390_INSN_XINDIR:
end = s390_insn_xindir_emit(buf, insn, disp_cp_xindir);
break;
case S390_INSN_XASSISTED:
end = s390_insn_xassisted_emit(buf, insn, disp_cp_xassisted);
break;
fail:
default:
vpanic("emit_S390Instr");
}
vassert(end - buf <= nbuf);
return end - buf;
}
/* Return the number of bytes emitted for an S390_INSN_EVCHECK.
See s390_insn_evcheck_emit */
Int
evCheckSzB_S390(void)
{
return s390_host_has_gie ? 18 : 24;
}
/* Patch the counter address into CODE_TO_PATCH as previously
generated by s390_insn_profinc_emit. */
VexInvalRange
patchProfInc_S390(VexEndness endness_host,
void *code_to_patch, const ULong *location_of_counter)
{
vassert(sizeof(ULong *) == 8);
s390_tchain_verify_load64(code_to_patch, S390_REGNO_TCHAIN_SCRATCH, 0);
UChar *p = s390_tchain_patch_load64(code_to_patch,
(Addr)location_of_counter);
UInt len = p - (UChar *)code_to_patch;
VexInvalRange vir = { (HWord)code_to_patch, len };
return vir;
}
/* NB: what goes on here has to be very closely coordinated with the
s390_insn_xdirect_emit code above. */
VexInvalRange
chainXDirect_S390(VexEndness endness_host,
void *place_to_chain,
const void *disp_cp_chain_me_EXPECTED,
const void *place_to_jump_to)
{
vassert(endness_host == VexEndnessBE);
/* What we're expecting to see @ PLACE_TO_CHAIN is:
load tchain_scratch, #disp_cp_chain_me_EXPECTED
goto *tchain_scratch
*/
const UChar *next;
next = s390_tchain_verify_load64(place_to_chain, S390_REGNO_TCHAIN_SCRATCH,
(Addr)disp_cp_chain_me_EXPECTED);
vassert(s390_insn_is_BR(next, S390_REGNO_TCHAIN_SCRATCH));
/* And what we want to change it to is either:
(general case):
load tchain_scratch, #place_to_jump_to
goto *tchain_scratch
---OR---
in the case where the displacement is small enough
BRCL delta where delta is in half-words
invalid opcodes
In both cases the replacement has the same length as the original.
To remain sane & verifiable,
(1) limit the displacement for the short form to
(say) +/- one billion, so as to avoid wraparound
off-by-ones
(2) even if the short form is applicable, once every (say)
1024 times use the long form anyway, so as to maintain
verifiability
*/
/* This is the delta we need to put into a BRCL insn. Note, that the
offset in BRCL is in half-words. Hence division by 2. */
Long delta =
(Long)((const UChar *)place_to_jump_to - (const UChar *)place_to_chain) / 2;
Bool shortOK = delta >= -1000*1000*1000 && delta < 1000*1000*1000;
static UInt shortCTR = 0; /* DO NOT MAKE NON-STATIC */
if (shortOK) {
shortCTR++; // thread safety bleh
if (0 == (shortCTR & 0x3FF)) {
shortOK = False;
if (0)
vex_printf("QQQ chainXDirect_S390: shortCTR = %u, "
"using long jmp\n", shortCTR);
}
}
/* And make the modifications. */
UChar *p = (UChar *)place_to_chain;
if (shortOK) {
p = s390_emit_BRCL(p, S390_CC_ALWAYS, delta); /* 6 bytes */
/* Make sure that BRCL fits into the patchable part of an xdirect
code sequence */
vassert(6 <= s390_xdirect_patchable_len());
/* Fill remaining bytes with 0x00 (invalid opcode) */
Int i;
for (i = 0; i < s390_xdirect_patchable_len() - 6; ++i)
p[i] = 0x00;
} else {
/*
load tchain_scratch, #place_to_jump_to
goto *tchain_scratch
*/
Addr64 addr = (Addr)place_to_jump_to;
p = s390_tchain_load64(p, S390_REGNO_TCHAIN_SCRATCH, addr);
/* There is not need to emit a BCR here, as it is already there. */
}
UInt len = p - (UChar *)place_to_chain;
VexInvalRange vir = { (HWord)place_to_chain, len };
return vir;
}
/* NB: what goes on here has to be very closely coordinated with the
s390_insn_xdirect_emit code above. */
VexInvalRange
unchainXDirect_S390(VexEndness endness_host,
void *place_to_unchain,
const void *place_to_jump_to_EXPECTED,
const void *disp_cp_chain_me)
{
vassert(endness_host == VexEndnessBE);
/* What we're expecting to see @ PLACE_TO_UNCHAIN:
load tchain_scratch, #place_to_jump_to_EXPECTED
goto *tchain_scratch
---OR---
in the case where the displacement falls within 32 bits
BRCL delta
invalid opcodes
*/
UChar *p = place_to_unchain;
Bool uses_short_form = False;
if (s390_insn_is_BRCL(p, S390_CC_ALWAYS)) {
/* Looks like the short form */
Int num_hw = *(Int *)&p[2];
Int delta = 2 *num_hw;
vassert(p + delta == place_to_jump_to_EXPECTED);
Int i;
for (i = 0; i < s390_xdirect_patchable_len() - 6; ++i)
vassert(p[6+i] == 0x00);
uses_short_form = True;
} else {
/* Should be the long form */
const UChar *next;
next = s390_tchain_verify_load64(p, S390_REGNO_TCHAIN_SCRATCH,
(Addr)place_to_jump_to_EXPECTED);
/* Check for BR *tchain_scratch */
vassert(s390_insn_is_BR(next, S390_REGNO_TCHAIN_SCRATCH));
}
/* And what we want to change it to is:
load tchain_scratch, #disp_cp_chain_me
goto *tchain_scratch
*/
/* Get the address of the beginning of the load64 code sequence into %r1.
Do not change the register! This is part of the protocol with the
dispatcher.
Note: the incoming argument PLACE_TO_CHAIN points to the beginning of the
load64 insn sequence. That sequence is prefixed with a BASR to get its
address (see s390_insn_xdirect_emit). */
p = s390_emit_BASR(p - S390_BASR_LEN, 1, R0);
Addr64 addr = (Addr)disp_cp_chain_me;
p = s390_tchain_load64(p, S390_REGNO_TCHAIN_SCRATCH, addr);
/* Emit the BCR in case the short form was used. In case of the long
form, the BCR is already there. */
if (uses_short_form)
s390_emit_BCR(p, S390_CC_ALWAYS, S390_REGNO_TCHAIN_SCRATCH);
UInt len = p - (UChar *)place_to_unchain;
VexInvalRange vir = { (HWord)place_to_unchain, len };
return vir;
}
/*---------------------------------------------------------------*/
/*--- end host_s390_defs.c ---*/
/*---------------------------------------------------------------*/