qemu-e2k/target-s390x/op_helper.c
Blue Swirl 2050396801 Use uintptr_t for various op related functions
Use uintptr_t instead of void * or unsigned long in
several op related functions, env->mem_io_pc and
GETPC() macro.

Reviewed-by: Stefan Weil <sw@weilnetz.de>
Signed-off-by: Blue Swirl <blauwirbel@gmail.com>
2012-04-14 14:23:37 +00:00

3025 lines
75 KiB
C

/*
* S/390 helper routines
*
* Copyright (c) 2009 Ulrich Hecht
* Copyright (c) 2009 Alexander Graf
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
#include "cpu.h"
#include "dyngen-exec.h"
#include "host-utils.h"
#include "helper.h"
#include <string.h>
#include "kvm.h"
#include "qemu-timer.h"
#ifdef CONFIG_KVM
#include <linux/kvm.h>
#endif
#if !defined (CONFIG_USER_ONLY)
#include "sysemu.h"
#endif
/*****************************************************************************/
/* Softmmu support */
#if !defined (CONFIG_USER_ONLY)
#include "softmmu_exec.h"
#define MMUSUFFIX _mmu
#define SHIFT 0
#include "softmmu_template.h"
#define SHIFT 1
#include "softmmu_template.h"
#define SHIFT 2
#include "softmmu_template.h"
#define SHIFT 3
#include "softmmu_template.h"
/* try to fill the TLB and return an exception if error. If retaddr is
NULL, it means that the function was called in C code (i.e. not
from generated code or from helper.c) */
/* XXX: fix it to restore all registers */
void tlb_fill(CPUS390XState *env1, target_ulong addr, int is_write, int mmu_idx,
uintptr_t retaddr)
{
TranslationBlock *tb;
CPUS390XState *saved_env;
int ret;
saved_env = env;
env = env1;
ret = cpu_s390x_handle_mmu_fault(env, addr, is_write, mmu_idx);
if (unlikely(ret != 0)) {
if (likely(retaddr)) {
/* now we have a real cpu fault */
tb = tb_find_pc(retaddr);
if (likely(tb)) {
/* the PC is inside the translated code. It means that we have
a virtual CPU fault */
cpu_restore_state(tb, env, retaddr);
}
}
cpu_loop_exit(env);
}
env = saved_env;
}
#endif
/* #define DEBUG_HELPER */
#ifdef DEBUG_HELPER
#define HELPER_LOG(x...) qemu_log(x)
#else
#define HELPER_LOG(x...)
#endif
/* raise an exception */
void HELPER(exception)(uint32_t excp)
{
HELPER_LOG("%s: exception %d\n", __FUNCTION__, excp);
env->exception_index = excp;
cpu_loop_exit(env);
}
#ifndef CONFIG_USER_ONLY
static void mvc_fast_memset(CPUS390XState *env, uint32_t l, uint64_t dest,
uint8_t byte)
{
target_phys_addr_t dest_phys;
target_phys_addr_t len = l;
void *dest_p;
uint64_t asc = env->psw.mask & PSW_MASK_ASC;
int flags;
if (mmu_translate(env, dest, 1, asc, &dest_phys, &flags)) {
stb(dest, byte);
cpu_abort(env, "should never reach here");
}
dest_phys |= dest & ~TARGET_PAGE_MASK;
dest_p = cpu_physical_memory_map(dest_phys, &len, 1);
memset(dest_p, byte, len);
cpu_physical_memory_unmap(dest_p, 1, len, len);
}
static void mvc_fast_memmove(CPUS390XState *env, uint32_t l, uint64_t dest,
uint64_t src)
{
target_phys_addr_t dest_phys;
target_phys_addr_t src_phys;
target_phys_addr_t len = l;
void *dest_p;
void *src_p;
uint64_t asc = env->psw.mask & PSW_MASK_ASC;
int flags;
if (mmu_translate(env, dest, 1, asc, &dest_phys, &flags)) {
stb(dest, 0);
cpu_abort(env, "should never reach here");
}
dest_phys |= dest & ~TARGET_PAGE_MASK;
if (mmu_translate(env, src, 0, asc, &src_phys, &flags)) {
ldub(src);
cpu_abort(env, "should never reach here");
}
src_phys |= src & ~TARGET_PAGE_MASK;
dest_p = cpu_physical_memory_map(dest_phys, &len, 1);
src_p = cpu_physical_memory_map(src_phys, &len, 0);
memmove(dest_p, src_p, len);
cpu_physical_memory_unmap(dest_p, 1, len, len);
cpu_physical_memory_unmap(src_p, 0, len, len);
}
#endif
/* and on array */
uint32_t HELPER(nc)(uint32_t l, uint64_t dest, uint64_t src)
{
int i;
unsigned char x;
uint32_t cc = 0;
HELPER_LOG("%s l %d dest %" PRIx64 " src %" PRIx64 "\n",
__FUNCTION__, l, dest, src);
for (i = 0; i <= l; i++) {
x = ldub(dest + i) & ldub(src + i);
if (x) {
cc = 1;
}
stb(dest + i, x);
}
return cc;
}
/* xor on array */
uint32_t HELPER(xc)(uint32_t l, uint64_t dest, uint64_t src)
{
int i;
unsigned char x;
uint32_t cc = 0;
HELPER_LOG("%s l %d dest %" PRIx64 " src %" PRIx64 "\n",
__FUNCTION__, l, dest, src);
#ifndef CONFIG_USER_ONLY
/* xor with itself is the same as memset(0) */
if ((l > 32) && (src == dest) &&
(src & TARGET_PAGE_MASK) == ((src + l) & TARGET_PAGE_MASK)) {
mvc_fast_memset(env, l + 1, dest, 0);
return 0;
}
#else
if (src == dest) {
memset(g2h(dest), 0, l + 1);
return 0;
}
#endif
for (i = 0; i <= l; i++) {
x = ldub(dest + i) ^ ldub(src + i);
if (x) {
cc = 1;
}
stb(dest + i, x);
}
return cc;
}
/* or on array */
uint32_t HELPER(oc)(uint32_t l, uint64_t dest, uint64_t src)
{
int i;
unsigned char x;
uint32_t cc = 0;
HELPER_LOG("%s l %d dest %" PRIx64 " src %" PRIx64 "\n",
__FUNCTION__, l, dest, src);
for (i = 0; i <= l; i++) {
x = ldub(dest + i) | ldub(src + i);
if (x) {
cc = 1;
}
stb(dest + i, x);
}
return cc;
}
/* memmove */
void HELPER(mvc)(uint32_t l, uint64_t dest, uint64_t src)
{
int i = 0;
int x = 0;
uint32_t l_64 = (l + 1) / 8;
HELPER_LOG("%s l %d dest %" PRIx64 " src %" PRIx64 "\n",
__FUNCTION__, l, dest, src);
#ifndef CONFIG_USER_ONLY
if ((l > 32) &&
(src & TARGET_PAGE_MASK) == ((src + l) & TARGET_PAGE_MASK) &&
(dest & TARGET_PAGE_MASK) == ((dest + l) & TARGET_PAGE_MASK)) {
if (dest == (src + 1)) {
mvc_fast_memset(env, l + 1, dest, ldub(src));
return;
} else if ((src & TARGET_PAGE_MASK) != (dest & TARGET_PAGE_MASK)) {
mvc_fast_memmove(env, l + 1, dest, src);
return;
}
}
#else
if (dest == (src + 1)) {
memset(g2h(dest), ldub(src), l + 1);
return;
} else {
memmove(g2h(dest), g2h(src), l + 1);
return;
}
#endif
/* handle the parts that fit into 8-byte loads/stores */
if (dest != (src + 1)) {
for (i = 0; i < l_64; i++) {
stq(dest + x, ldq(src + x));
x += 8;
}
}
/* slow version crossing pages with byte accesses */
for (i = x; i <= l; i++) {
stb(dest + i, ldub(src + i));
}
}
/* compare unsigned byte arrays */
uint32_t HELPER(clc)(uint32_t l, uint64_t s1, uint64_t s2)
{
int i;
unsigned char x,y;
uint32_t cc;
HELPER_LOG("%s l %d s1 %" PRIx64 " s2 %" PRIx64 "\n",
__FUNCTION__, l, s1, s2);
for (i = 0; i <= l; i++) {
x = ldub(s1 + i);
y = ldub(s2 + i);
HELPER_LOG("%02x (%c)/%02x (%c) ", x, x, y, y);
if (x < y) {
cc = 1;
goto done;
} else if (x > y) {
cc = 2;
goto done;
}
}
cc = 0;
done:
HELPER_LOG("\n");
return cc;
}
/* compare logical under mask */
uint32_t HELPER(clm)(uint32_t r1, uint32_t mask, uint64_t addr)
{
uint8_t r,d;
uint32_t cc;
HELPER_LOG("%s: r1 0x%x mask 0x%x addr 0x%" PRIx64 "\n", __FUNCTION__, r1,
mask, addr);
cc = 0;
while (mask) {
if (mask & 8) {
d = ldub(addr);
r = (r1 & 0xff000000UL) >> 24;
HELPER_LOG("mask 0x%x %02x/%02x (0x%" PRIx64 ") ", mask, r, d,
addr);
if (r < d) {
cc = 1;
break;
} else if (r > d) {
cc = 2;
break;
}
addr++;
}
mask = (mask << 1) & 0xf;
r1 <<= 8;
}
HELPER_LOG("\n");
return cc;
}
/* store character under mask */
void HELPER(stcm)(uint32_t r1, uint32_t mask, uint64_t addr)
{
uint8_t r;
HELPER_LOG("%s: r1 0x%x mask 0x%x addr 0x%lx\n", __FUNCTION__, r1, mask,
addr);
while (mask) {
if (mask & 8) {
r = (r1 & 0xff000000UL) >> 24;
stb(addr, r);
HELPER_LOG("mask 0x%x %02x (0x%lx) ", mask, r, addr);
addr++;
}
mask = (mask << 1) & 0xf;
r1 <<= 8;
}
HELPER_LOG("\n");
}
/* 64/64 -> 128 unsigned multiplication */
void HELPER(mlg)(uint32_t r1, uint64_t v2)
{
#if HOST_LONG_BITS == 64 && defined(__GNUC__)
/* assuming 64-bit hosts have __uint128_t */
__uint128_t res = (__uint128_t)env->regs[r1 + 1];
res *= (__uint128_t)v2;
env->regs[r1] = (uint64_t)(res >> 64);
env->regs[r1 + 1] = (uint64_t)res;
#else
mulu64(&env->regs[r1 + 1], &env->regs[r1], env->regs[r1 + 1], v2);
#endif
}
/* 128 -> 64/64 unsigned division */
void HELPER(dlg)(uint32_t r1, uint64_t v2)
{
uint64_t divisor = v2;
if (!env->regs[r1]) {
/* 64 -> 64/64 case */
env->regs[r1] = env->regs[r1+1] % divisor;
env->regs[r1+1] = env->regs[r1+1] / divisor;
return;
} else {
#if HOST_LONG_BITS == 64 && defined(__GNUC__)
/* assuming 64-bit hosts have __uint128_t */
__uint128_t dividend = (((__uint128_t)env->regs[r1]) << 64) |
(env->regs[r1+1]);
__uint128_t quotient = dividend / divisor;
env->regs[r1+1] = quotient;
__uint128_t remainder = dividend % divisor;
env->regs[r1] = remainder;
#else
/* 32-bit hosts would need special wrapper functionality - just abort if
we encounter such a case; it's very unlikely anyways. */
cpu_abort(env, "128 -> 64/64 division not implemented\n");
#endif
}
}
static inline uint64_t get_address(int x2, int b2, int d2)
{
uint64_t r = d2;
if (x2) {
r += env->regs[x2];
}
if (b2) {
r += env->regs[b2];
}
/* 31-Bit mode */
if (!(env->psw.mask & PSW_MASK_64)) {
r &= 0x7fffffff;
}
return r;
}
static inline uint64_t get_address_31fix(int reg)
{
uint64_t r = env->regs[reg];
/* 31-Bit mode */
if (!(env->psw.mask & PSW_MASK_64)) {
r &= 0x7fffffff;
}
return r;
}
/* search string (c is byte to search, r2 is string, r1 end of string) */
uint32_t HELPER(srst)(uint32_t c, uint32_t r1, uint32_t r2)
{
uint64_t i;
uint32_t cc = 2;
uint64_t str = get_address_31fix(r2);
uint64_t end = get_address_31fix(r1);
HELPER_LOG("%s: c %d *r1 0x%" PRIx64 " *r2 0x%" PRIx64 "\n", __FUNCTION__,
c, env->regs[r1], env->regs[r2]);
for (i = str; i != end; i++) {
if (ldub(i) == c) {
env->regs[r1] = i;
cc = 1;
break;
}
}
return cc;
}
/* unsigned string compare (c is string terminator) */
uint32_t HELPER(clst)(uint32_t c, uint32_t r1, uint32_t r2)
{
uint64_t s1 = get_address_31fix(r1);
uint64_t s2 = get_address_31fix(r2);
uint8_t v1, v2;
uint32_t cc;
c = c & 0xff;
#ifdef CONFIG_USER_ONLY
if (!c) {
HELPER_LOG("%s: comparing '%s' and '%s'\n",
__FUNCTION__, (char*)g2h(s1), (char*)g2h(s2));
}
#endif
for (;;) {
v1 = ldub(s1);
v2 = ldub(s2);
if ((v1 == c || v2 == c) || (v1 != v2)) {
break;
}
s1++;
s2++;
}
if (v1 == v2) {
cc = 0;
} else {
cc = (v1 < v2) ? 1 : 2;
/* FIXME: 31-bit mode! */
env->regs[r1] = s1;
env->regs[r2] = s2;
}
return cc;
}
/* move page */
void HELPER(mvpg)(uint64_t r0, uint64_t r1, uint64_t r2)
{
/* XXX missing r0 handling */
#ifdef CONFIG_USER_ONLY
int i;
for (i = 0; i < TARGET_PAGE_SIZE; i++) {
stb(r1 + i, ldub(r2 + i));
}
#else
mvc_fast_memmove(env, TARGET_PAGE_SIZE, r1, r2);
#endif
}
/* string copy (c is string terminator) */
void HELPER(mvst)(uint32_t c, uint32_t r1, uint32_t r2)
{
uint64_t dest = get_address_31fix(r1);
uint64_t src = get_address_31fix(r2);
uint8_t v;
c = c & 0xff;
#ifdef CONFIG_USER_ONLY
if (!c) {
HELPER_LOG("%s: copy '%s' to 0x%lx\n", __FUNCTION__, (char*)g2h(src),
dest);
}
#endif
for (;;) {
v = ldub(src);
stb(dest, v);
if (v == c) {
break;
}
src++;
dest++;
}
env->regs[r1] = dest; /* FIXME: 31-bit mode! */
}
/* compare and swap 64-bit */
uint32_t HELPER(csg)(uint32_t r1, uint64_t a2, uint32_t r3)
{
/* FIXME: locking? */
uint32_t cc;
uint64_t v2 = ldq(a2);
if (env->regs[r1] == v2) {
cc = 0;
stq(a2, env->regs[r3]);
} else {
cc = 1;
env->regs[r1] = v2;
}
return cc;
}
/* compare double and swap 64-bit */
uint32_t HELPER(cdsg)(uint32_t r1, uint64_t a2, uint32_t r3)
{
/* FIXME: locking? */
uint32_t cc;
uint64_t v2_hi = ldq(a2);
uint64_t v2_lo = ldq(a2 + 8);
uint64_t v1_hi = env->regs[r1];
uint64_t v1_lo = env->regs[r1 + 1];
if ((v1_hi == v2_hi) && (v1_lo == v2_lo)) {
cc = 0;
stq(a2, env->regs[r3]);
stq(a2 + 8, env->regs[r3 + 1]);
} else {
cc = 1;
env->regs[r1] = v2_hi;
env->regs[r1 + 1] = v2_lo;
}
return cc;
}
/* compare and swap 32-bit */
uint32_t HELPER(cs)(uint32_t r1, uint64_t a2, uint32_t r3)
{
/* FIXME: locking? */
uint32_t cc;
HELPER_LOG("%s: r1 %d a2 0x%lx r3 %d\n", __FUNCTION__, r1, a2, r3);
uint32_t v2 = ldl(a2);
if (((uint32_t)env->regs[r1]) == v2) {
cc = 0;
stl(a2, (uint32_t)env->regs[r3]);
} else {
cc = 1;
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) | v2;
}
return cc;
}
static uint32_t helper_icm(uint32_t r1, uint64_t address, uint32_t mask)
{
int pos = 24; /* top of the lower half of r1 */
uint64_t rmask = 0xff000000ULL;
uint8_t val = 0;
int ccd = 0;
uint32_t cc = 0;
while (mask) {
if (mask & 8) {
env->regs[r1] &= ~rmask;
val = ldub(address);
if ((val & 0x80) && !ccd) {
cc = 1;
}
ccd = 1;
if (val && cc == 0) {
cc = 2;
}
env->regs[r1] |= (uint64_t)val << pos;
address++;
}
mask = (mask << 1) & 0xf;
pos -= 8;
rmask >>= 8;
}
return cc;
}
/* execute instruction
this instruction executes an insn modified with the contents of r1
it does not change the executed instruction in memory
it does not change the program counter
in other words: tricky...
currently implemented by interpreting the cases it is most commonly used in
*/
uint32_t HELPER(ex)(uint32_t cc, uint64_t v1, uint64_t addr, uint64_t ret)
{
uint16_t insn = lduw_code(addr);
HELPER_LOG("%s: v1 0x%lx addr 0x%lx insn 0x%x\n", __FUNCTION__, v1, addr,
insn);
if ((insn & 0xf0ff) == 0xd000) {
uint32_t l, insn2, b1, b2, d1, d2;
l = v1 & 0xff;
insn2 = ldl_code(addr + 2);
b1 = (insn2 >> 28) & 0xf;
b2 = (insn2 >> 12) & 0xf;
d1 = (insn2 >> 16) & 0xfff;
d2 = insn2 & 0xfff;
switch (insn & 0xf00) {
case 0x200:
helper_mvc(l, get_address(0, b1, d1), get_address(0, b2, d2));
break;
case 0x500:
cc = helper_clc(l, get_address(0, b1, d1), get_address(0, b2, d2));
break;
case 0x700:
cc = helper_xc(l, get_address(0, b1, d1), get_address(0, b2, d2));
break;
case 0xc00:
helper_tr(l, get_address(0, b1, d1), get_address(0, b2, d2));
break;
default:
goto abort;
break;
}
} else if ((insn & 0xff00) == 0x0a00) {
/* supervisor call */
HELPER_LOG("%s: svc %ld via execute\n", __FUNCTION__, (insn|v1) & 0xff);
env->psw.addr = ret - 4;
env->int_svc_code = (insn|v1) & 0xff;
env->int_svc_ilc = 4;
helper_exception(EXCP_SVC);
} else if ((insn & 0xff00) == 0xbf00) {
uint32_t insn2, r1, r3, b2, d2;
insn2 = ldl_code(addr + 2);
r1 = (insn2 >> 20) & 0xf;
r3 = (insn2 >> 16) & 0xf;
b2 = (insn2 >> 12) & 0xf;
d2 = insn2 & 0xfff;
cc = helper_icm(r1, get_address(0, b2, d2), r3);
} else {
abort:
cpu_abort(env, "EXECUTE on instruction prefix 0x%x not implemented\n",
insn);
}
return cc;
}
/* absolute value 32-bit */
uint32_t HELPER(abs_i32)(int32_t val)
{
if (val < 0) {
return -val;
} else {
return val;
}
}
/* negative absolute value 32-bit */
int32_t HELPER(nabs_i32)(int32_t val)
{
if (val < 0) {
return val;
} else {
return -val;
}
}
/* absolute value 64-bit */
uint64_t HELPER(abs_i64)(int64_t val)
{
HELPER_LOG("%s: val 0x%" PRIx64 "\n", __FUNCTION__, val);
if (val < 0) {
return -val;
} else {
return val;
}
}
/* negative absolute value 64-bit */
int64_t HELPER(nabs_i64)(int64_t val)
{
if (val < 0) {
return val;
} else {
return -val;
}
}
/* add with carry 32-bit unsigned */
uint32_t HELPER(addc_u32)(uint32_t cc, uint32_t v1, uint32_t v2)
{
uint32_t res;
res = v1 + v2;
if (cc & 2) {
res++;
}
return res;
}
/* store character under mask high operates on the upper half of r1 */
void HELPER(stcmh)(uint32_t r1, uint64_t address, uint32_t mask)
{
int pos = 56; /* top of the upper half of r1 */
while (mask) {
if (mask & 8) {
stb(address, (env->regs[r1] >> pos) & 0xff);
address++;
}
mask = (mask << 1) & 0xf;
pos -= 8;
}
}
/* insert character under mask high; same as icm, but operates on the
upper half of r1 */
uint32_t HELPER(icmh)(uint32_t r1, uint64_t address, uint32_t mask)
{
int pos = 56; /* top of the upper half of r1 */
uint64_t rmask = 0xff00000000000000ULL;
uint8_t val = 0;
int ccd = 0;
uint32_t cc = 0;
while (mask) {
if (mask & 8) {
env->regs[r1] &= ~rmask;
val = ldub(address);
if ((val & 0x80) && !ccd) {
cc = 1;
}
ccd = 1;
if (val && cc == 0) {
cc = 2;
}
env->regs[r1] |= (uint64_t)val << pos;
address++;
}
mask = (mask << 1) & 0xf;
pos -= 8;
rmask >>= 8;
}
return cc;
}
/* insert psw mask and condition code into r1 */
void HELPER(ipm)(uint32_t cc, uint32_t r1)
{
uint64_t r = env->regs[r1];
r &= 0xffffffff00ffffffULL;
r |= (cc << 28) | ( (env->psw.mask >> 40) & 0xf );
env->regs[r1] = r;
HELPER_LOG("%s: cc %d psw.mask 0x%lx r1 0x%lx\n", __FUNCTION__,
cc, env->psw.mask, r);
}
/* load access registers r1 to r3 from memory at a2 */
void HELPER(lam)(uint32_t r1, uint64_t a2, uint32_t r3)
{
int i;
for (i = r1;; i = (i + 1) % 16) {
env->aregs[i] = ldl(a2);
a2 += 4;
if (i == r3) {
break;
}
}
}
/* store access registers r1 to r3 in memory at a2 */
void HELPER(stam)(uint32_t r1, uint64_t a2, uint32_t r3)
{
int i;
for (i = r1;; i = (i + 1) % 16) {
stl(a2, env->aregs[i]);
a2 += 4;
if (i == r3) {
break;
}
}
}
/* move long */
uint32_t HELPER(mvcl)(uint32_t r1, uint32_t r2)
{
uint64_t destlen = env->regs[r1 + 1] & 0xffffff;
uint64_t dest = get_address_31fix(r1);
uint64_t srclen = env->regs[r2 + 1] & 0xffffff;
uint64_t src = get_address_31fix(r2);
uint8_t pad = src >> 24;
uint8_t v;
uint32_t cc;
if (destlen == srclen) {
cc = 0;
} else if (destlen < srclen) {
cc = 1;
} else {
cc = 2;
}
if (srclen > destlen) {
srclen = destlen;
}
for (; destlen && srclen; src++, dest++, destlen--, srclen--) {
v = ldub(src);
stb(dest, v);
}
for (; destlen; dest++, destlen--) {
stb(dest, pad);
}
env->regs[r1 + 1] = destlen;
/* can't use srclen here, we trunc'ed it */
env->regs[r2 + 1] -= src - env->regs[r2];
env->regs[r1] = dest;
env->regs[r2] = src;
return cc;
}
/* move long extended another memcopy insn with more bells and whistles */
uint32_t HELPER(mvcle)(uint32_t r1, uint64_t a2, uint32_t r3)
{
uint64_t destlen = env->regs[r1 + 1];
uint64_t dest = env->regs[r1];
uint64_t srclen = env->regs[r3 + 1];
uint64_t src = env->regs[r3];
uint8_t pad = a2 & 0xff;
uint8_t v;
uint32_t cc;
if (!(env->psw.mask & PSW_MASK_64)) {
destlen = (uint32_t)destlen;
srclen = (uint32_t)srclen;
dest &= 0x7fffffff;
src &= 0x7fffffff;
}
if (destlen == srclen) {
cc = 0;
} else if (destlen < srclen) {
cc = 1;
} else {
cc = 2;
}
if (srclen > destlen) {
srclen = destlen;
}
for (; destlen && srclen; src++, dest++, destlen--, srclen--) {
v = ldub(src);
stb(dest, v);
}
for (; destlen; dest++, destlen--) {
stb(dest, pad);
}
env->regs[r1 + 1] = destlen;
/* can't use srclen here, we trunc'ed it */
/* FIXME: 31-bit mode! */
env->regs[r3 + 1] -= src - env->regs[r3];
env->regs[r1] = dest;
env->regs[r3] = src;
return cc;
}
/* compare logical long extended memcompare insn with padding */
uint32_t HELPER(clcle)(uint32_t r1, uint64_t a2, uint32_t r3)
{
uint64_t destlen = env->regs[r1 + 1];
uint64_t dest = get_address_31fix(r1);
uint64_t srclen = env->regs[r3 + 1];
uint64_t src = get_address_31fix(r3);
uint8_t pad = a2 & 0xff;
uint8_t v1 = 0,v2 = 0;
uint32_t cc = 0;
if (!(destlen || srclen)) {
return cc;
}
if (srclen > destlen) {
srclen = destlen;
}
for (; destlen || srclen; src++, dest++, destlen--, srclen--) {
v1 = srclen ? ldub(src) : pad;
v2 = destlen ? ldub(dest) : pad;
if (v1 != v2) {
cc = (v1 < v2) ? 1 : 2;
break;
}
}
env->regs[r1 + 1] = destlen;
/* can't use srclen here, we trunc'ed it */
env->regs[r3 + 1] -= src - env->regs[r3];
env->regs[r1] = dest;
env->regs[r3] = src;
return cc;
}
/* subtract unsigned v2 from v1 with borrow */
uint32_t HELPER(slb)(uint32_t cc, uint32_t r1, uint32_t v2)
{
uint32_t v1 = env->regs[r1];
uint32_t res = v1 + (~v2) + (cc >> 1);
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) | res;
if (cc & 2) {
/* borrow */
return v1 ? 1 : 0;
} else {
return v1 ? 3 : 2;
}
}
/* subtract unsigned v2 from v1 with borrow */
uint32_t HELPER(slbg)(uint32_t cc, uint32_t r1, uint64_t v1, uint64_t v2)
{
uint64_t res = v1 + (~v2) + (cc >> 1);
env->regs[r1] = res;
if (cc & 2) {
/* borrow */
return v1 ? 1 : 0;
} else {
return v1 ? 3 : 2;
}
}
static inline int float_comp_to_cc(int float_compare)
{
switch (float_compare) {
case float_relation_equal:
return 0;
case float_relation_less:
return 1;
case float_relation_greater:
return 2;
case float_relation_unordered:
return 3;
default:
cpu_abort(env, "unknown return value for float compare\n");
}
}
/* condition codes for binary FP ops */
static uint32_t set_cc_f32(float32 v1, float32 v2)
{
return float_comp_to_cc(float32_compare_quiet(v1, v2, &env->fpu_status));
}
static uint32_t set_cc_f64(float64 v1, float64 v2)
{
return float_comp_to_cc(float64_compare_quiet(v1, v2, &env->fpu_status));
}
/* condition codes for unary FP ops */
static uint32_t set_cc_nz_f32(float32 v)
{
if (float32_is_any_nan(v)) {
return 3;
} else if (float32_is_zero(v)) {
return 0;
} else if (float32_is_neg(v)) {
return 1;
} else {
return 2;
}
}
static uint32_t set_cc_nz_f64(float64 v)
{
if (float64_is_any_nan(v)) {
return 3;
} else if (float64_is_zero(v)) {
return 0;
} else if (float64_is_neg(v)) {
return 1;
} else {
return 2;
}
}
static uint32_t set_cc_nz_f128(float128 v)
{
if (float128_is_any_nan(v)) {
return 3;
} else if (float128_is_zero(v)) {
return 0;
} else if (float128_is_neg(v)) {
return 1;
} else {
return 2;
}
}
/* convert 32-bit int to 64-bit float */
void HELPER(cdfbr)(uint32_t f1, int32_t v2)
{
HELPER_LOG("%s: converting %d to f%d\n", __FUNCTION__, v2, f1);
env->fregs[f1].d = int32_to_float64(v2, &env->fpu_status);
}
/* convert 32-bit int to 128-bit float */
void HELPER(cxfbr)(uint32_t f1, int32_t v2)
{
CPU_QuadU v1;
v1.q = int32_to_float128(v2, &env->fpu_status);
env->fregs[f1].ll = v1.ll.upper;
env->fregs[f1 + 2].ll = v1.ll.lower;
}
/* convert 64-bit int to 32-bit float */
void HELPER(cegbr)(uint32_t f1, int64_t v2)
{
HELPER_LOG("%s: converting %ld to f%d\n", __FUNCTION__, v2, f1);
env->fregs[f1].l.upper = int64_to_float32(v2, &env->fpu_status);
}
/* convert 64-bit int to 64-bit float */
void HELPER(cdgbr)(uint32_t f1, int64_t v2)
{
HELPER_LOG("%s: converting %ld to f%d\n", __FUNCTION__, v2, f1);
env->fregs[f1].d = int64_to_float64(v2, &env->fpu_status);
}
/* convert 64-bit int to 128-bit float */
void HELPER(cxgbr)(uint32_t f1, int64_t v2)
{
CPU_QuadU x1;
x1.q = int64_to_float128(v2, &env->fpu_status);
HELPER_LOG("%s: converted %ld to 0x%lx and 0x%lx\n", __FUNCTION__, v2,
x1.ll.upper, x1.ll.lower);
env->fregs[f1].ll = x1.ll.upper;
env->fregs[f1 + 2].ll = x1.ll.lower;
}
/* convert 32-bit int to 32-bit float */
void HELPER(cefbr)(uint32_t f1, int32_t v2)
{
env->fregs[f1].l.upper = int32_to_float32(v2, &env->fpu_status);
HELPER_LOG("%s: converting %d to 0x%d in f%d\n", __FUNCTION__, v2,
env->fregs[f1].l.upper, f1);
}
/* 32-bit FP addition RR */
uint32_t HELPER(aebr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].l.upper = float32_add(env->fregs[f1].l.upper,
env->fregs[f2].l.upper,
&env->fpu_status);
HELPER_LOG("%s: adding 0x%d resulting in 0x%d in f%d\n", __FUNCTION__,
env->fregs[f2].l.upper, env->fregs[f1].l.upper, f1);
return set_cc_nz_f32(env->fregs[f1].l.upper);
}
/* 64-bit FP addition RR */
uint32_t HELPER(adbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = float64_add(env->fregs[f1].d, env->fregs[f2].d,
&env->fpu_status);
HELPER_LOG("%s: adding 0x%ld resulting in 0x%ld in f%d\n", __FUNCTION__,
env->fregs[f2].d, env->fregs[f1].d, f1);
return set_cc_nz_f64(env->fregs[f1].d);
}
/* 32-bit FP subtraction RR */
uint32_t HELPER(sebr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].l.upper = float32_sub(env->fregs[f1].l.upper,
env->fregs[f2].l.upper,
&env->fpu_status);
HELPER_LOG("%s: adding 0x%d resulting in 0x%d in f%d\n", __FUNCTION__,
env->fregs[f2].l.upper, env->fregs[f1].l.upper, f1);
return set_cc_nz_f32(env->fregs[f1].l.upper);
}
/* 64-bit FP subtraction RR */
uint32_t HELPER(sdbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = float64_sub(env->fregs[f1].d, env->fregs[f2].d,
&env->fpu_status);
HELPER_LOG("%s: subtracting 0x%ld resulting in 0x%ld in f%d\n",
__FUNCTION__, env->fregs[f2].d, env->fregs[f1].d, f1);
return set_cc_nz_f64(env->fregs[f1].d);
}
/* 32-bit FP division RR */
void HELPER(debr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].l.upper = float32_div(env->fregs[f1].l.upper,
env->fregs[f2].l.upper,
&env->fpu_status);
}
/* 128-bit FP division RR */
void HELPER(dxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU v1;
v1.ll.upper = env->fregs[f1].ll;
v1.ll.lower = env->fregs[f1 + 2].ll;
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
CPU_QuadU res;
res.q = float128_div(v1.q, v2.q, &env->fpu_status);
env->fregs[f1].ll = res.ll.upper;
env->fregs[f1 + 2].ll = res.ll.lower;
}
/* 64-bit FP multiplication RR */
void HELPER(mdbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = float64_mul(env->fregs[f1].d, env->fregs[f2].d,
&env->fpu_status);
}
/* 128-bit FP multiplication RR */
void HELPER(mxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU v1;
v1.ll.upper = env->fregs[f1].ll;
v1.ll.lower = env->fregs[f1 + 2].ll;
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
CPU_QuadU res;
res.q = float128_mul(v1.q, v2.q, &env->fpu_status);
env->fregs[f1].ll = res.ll.upper;
env->fregs[f1 + 2].ll = res.ll.lower;
}
/* convert 32-bit float to 64-bit float */
void HELPER(ldebr)(uint32_t r1, uint32_t r2)
{
env->fregs[r1].d = float32_to_float64(env->fregs[r2].l.upper,
&env->fpu_status);
}
/* convert 128-bit float to 64-bit float */
void HELPER(ldxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU x2;
x2.ll.upper = env->fregs[f2].ll;
x2.ll.lower = env->fregs[f2 + 2].ll;
env->fregs[f1].d = float128_to_float64(x2.q, &env->fpu_status);
HELPER_LOG("%s: to 0x%ld\n", __FUNCTION__, env->fregs[f1].d);
}
/* convert 64-bit float to 128-bit float */
void HELPER(lxdbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU res;
res.q = float64_to_float128(env->fregs[f2].d, &env->fpu_status);
env->fregs[f1].ll = res.ll.upper;
env->fregs[f1 + 2].ll = res.ll.lower;
}
/* convert 64-bit float to 32-bit float */
void HELPER(ledbr)(uint32_t f1, uint32_t f2)
{
float64 d2 = env->fregs[f2].d;
env->fregs[f1].l.upper = float64_to_float32(d2, &env->fpu_status);
}
/* convert 128-bit float to 32-bit float */
void HELPER(lexbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU x2;
x2.ll.upper = env->fregs[f2].ll;
x2.ll.lower = env->fregs[f2 + 2].ll;
env->fregs[f1].l.upper = float128_to_float32(x2.q, &env->fpu_status);
HELPER_LOG("%s: to 0x%d\n", __FUNCTION__, env->fregs[f1].l.upper);
}
/* absolute value of 32-bit float */
uint32_t HELPER(lpebr)(uint32_t f1, uint32_t f2)
{
float32 v1;
float32 v2 = env->fregs[f2].d;
v1 = float32_abs(v2);
env->fregs[f1].d = v1;
return set_cc_nz_f32(v1);
}
/* absolute value of 64-bit float */
uint32_t HELPER(lpdbr)(uint32_t f1, uint32_t f2)
{
float64 v1;
float64 v2 = env->fregs[f2].d;
v1 = float64_abs(v2);
env->fregs[f1].d = v1;
return set_cc_nz_f64(v1);
}
/* absolute value of 128-bit float */
uint32_t HELPER(lpxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU v1;
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
v1.q = float128_abs(v2.q);
env->fregs[f1].ll = v1.ll.upper;
env->fregs[f1 + 2].ll = v1.ll.lower;
return set_cc_nz_f128(v1.q);
}
/* load and test 64-bit float */
uint32_t HELPER(ltdbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = env->fregs[f2].d;
return set_cc_nz_f64(env->fregs[f1].d);
}
/* load and test 32-bit float */
uint32_t HELPER(ltebr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].l.upper = env->fregs[f2].l.upper;
return set_cc_nz_f32(env->fregs[f1].l.upper);
}
/* load and test 128-bit float */
uint32_t HELPER(ltxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU x;
x.ll.upper = env->fregs[f2].ll;
x.ll.lower = env->fregs[f2 + 2].ll;
env->fregs[f1].ll = x.ll.upper;
env->fregs[f1 + 2].ll = x.ll.lower;
return set_cc_nz_f128(x.q);
}
/* load complement of 32-bit float */
uint32_t HELPER(lcebr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].l.upper = float32_chs(env->fregs[f2].l.upper);
return set_cc_nz_f32(env->fregs[f1].l.upper);
}
/* load complement of 64-bit float */
uint32_t HELPER(lcdbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = float64_chs(env->fregs[f2].d);
return set_cc_nz_f64(env->fregs[f1].d);
}
/* load complement of 128-bit float */
uint32_t HELPER(lcxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU x1, x2;
x2.ll.upper = env->fregs[f2].ll;
x2.ll.lower = env->fregs[f2 + 2].ll;
x1.q = float128_chs(x2.q);
env->fregs[f1].ll = x1.ll.upper;
env->fregs[f1 + 2].ll = x1.ll.lower;
return set_cc_nz_f128(x1.q);
}
/* 32-bit FP addition RM */
void HELPER(aeb)(uint32_t f1, uint32_t val)
{
float32 v1 = env->fregs[f1].l.upper;
CPU_FloatU v2;
v2.l = val;
HELPER_LOG("%s: adding 0x%d from f%d and 0x%d\n", __FUNCTION__,
v1, f1, v2.f);
env->fregs[f1].l.upper = float32_add(v1, v2.f, &env->fpu_status);
}
/* 32-bit FP division RM */
void HELPER(deb)(uint32_t f1, uint32_t val)
{
float32 v1 = env->fregs[f1].l.upper;
CPU_FloatU v2;
v2.l = val;
HELPER_LOG("%s: dividing 0x%d from f%d by 0x%d\n", __FUNCTION__,
v1, f1, v2.f);
env->fregs[f1].l.upper = float32_div(v1, v2.f, &env->fpu_status);
}
/* 32-bit FP multiplication RM */
void HELPER(meeb)(uint32_t f1, uint32_t val)
{
float32 v1 = env->fregs[f1].l.upper;
CPU_FloatU v2;
v2.l = val;
HELPER_LOG("%s: multiplying 0x%d from f%d and 0x%d\n", __FUNCTION__,
v1, f1, v2.f);
env->fregs[f1].l.upper = float32_mul(v1, v2.f, &env->fpu_status);
}
/* 32-bit FP compare RR */
uint32_t HELPER(cebr)(uint32_t f1, uint32_t f2)
{
float32 v1 = env->fregs[f1].l.upper;
float32 v2 = env->fregs[f2].l.upper;
HELPER_LOG("%s: comparing 0x%d from f%d and 0x%d\n", __FUNCTION__,
v1, f1, v2);
return set_cc_f32(v1, v2);
}
/* 64-bit FP compare RR */
uint32_t HELPER(cdbr)(uint32_t f1, uint32_t f2)
{
float64 v1 = env->fregs[f1].d;
float64 v2 = env->fregs[f2].d;
HELPER_LOG("%s: comparing 0x%ld from f%d and 0x%ld\n", __FUNCTION__,
v1, f1, v2);
return set_cc_f64(v1, v2);
}
/* 128-bit FP compare RR */
uint32_t HELPER(cxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU v1;
v1.ll.upper = env->fregs[f1].ll;
v1.ll.lower = env->fregs[f1 + 2].ll;
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
return float_comp_to_cc(float128_compare_quiet(v1.q, v2.q,
&env->fpu_status));
}
/* 64-bit FP compare RM */
uint32_t HELPER(cdb)(uint32_t f1, uint64_t a2)
{
float64 v1 = env->fregs[f1].d;
CPU_DoubleU v2;
v2.ll = ldq(a2);
HELPER_LOG("%s: comparing 0x%ld from f%d and 0x%lx\n", __FUNCTION__, v1,
f1, v2.d);
return set_cc_f64(v1, v2.d);
}
/* 64-bit FP addition RM */
uint32_t HELPER(adb)(uint32_t f1, uint64_t a2)
{
float64 v1 = env->fregs[f1].d;
CPU_DoubleU v2;
v2.ll = ldq(a2);
HELPER_LOG("%s: adding 0x%lx from f%d and 0x%lx\n", __FUNCTION__,
v1, f1, v2.d);
env->fregs[f1].d = v1 = float64_add(v1, v2.d, &env->fpu_status);
return set_cc_nz_f64(v1);
}
/* 32-bit FP subtraction RM */
void HELPER(seb)(uint32_t f1, uint32_t val)
{
float32 v1 = env->fregs[f1].l.upper;
CPU_FloatU v2;
v2.l = val;
env->fregs[f1].l.upper = float32_sub(v1, v2.f, &env->fpu_status);
}
/* 64-bit FP subtraction RM */
uint32_t HELPER(sdb)(uint32_t f1, uint64_t a2)
{
float64 v1 = env->fregs[f1].d;
CPU_DoubleU v2;
v2.ll = ldq(a2);
env->fregs[f1].d = v1 = float64_sub(v1, v2.d, &env->fpu_status);
return set_cc_nz_f64(v1);
}
/* 64-bit FP multiplication RM */
void HELPER(mdb)(uint32_t f1, uint64_t a2)
{
float64 v1 = env->fregs[f1].d;
CPU_DoubleU v2;
v2.ll = ldq(a2);
HELPER_LOG("%s: multiplying 0x%lx from f%d and 0x%ld\n", __FUNCTION__,
v1, f1, v2.d);
env->fregs[f1].d = float64_mul(v1, v2.d, &env->fpu_status);
}
/* 64-bit FP division RM */
void HELPER(ddb)(uint32_t f1, uint64_t a2)
{
float64 v1 = env->fregs[f1].d;
CPU_DoubleU v2;
v2.ll = ldq(a2);
HELPER_LOG("%s: dividing 0x%lx from f%d by 0x%ld\n", __FUNCTION__,
v1, f1, v2.d);
env->fregs[f1].d = float64_div(v1, v2.d, &env->fpu_status);
}
static void set_round_mode(int m3)
{
switch (m3) {
case 0:
/* current mode */
break;
case 1:
/* biased round no nearest */
case 4:
/* round to nearest */
set_float_rounding_mode(float_round_nearest_even, &env->fpu_status);
break;
case 5:
/* round to zero */
set_float_rounding_mode(float_round_to_zero, &env->fpu_status);
break;
case 6:
/* round to +inf */
set_float_rounding_mode(float_round_up, &env->fpu_status);
break;
case 7:
/* round to -inf */
set_float_rounding_mode(float_round_down, &env->fpu_status);
break;
}
}
/* convert 32-bit float to 64-bit int */
uint32_t HELPER(cgebr)(uint32_t r1, uint32_t f2, uint32_t m3)
{
float32 v2 = env->fregs[f2].l.upper;
set_round_mode(m3);
env->regs[r1] = float32_to_int64(v2, &env->fpu_status);
return set_cc_nz_f32(v2);
}
/* convert 64-bit float to 64-bit int */
uint32_t HELPER(cgdbr)(uint32_t r1, uint32_t f2, uint32_t m3)
{
float64 v2 = env->fregs[f2].d;
set_round_mode(m3);
env->regs[r1] = float64_to_int64(v2, &env->fpu_status);
return set_cc_nz_f64(v2);
}
/* convert 128-bit float to 64-bit int */
uint32_t HELPER(cgxbr)(uint32_t r1, uint32_t f2, uint32_t m3)
{
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
set_round_mode(m3);
env->regs[r1] = float128_to_int64(v2.q, &env->fpu_status);
if (float128_is_any_nan(v2.q)) {
return 3;
} else if (float128_is_zero(v2.q)) {
return 0;
} else if (float128_is_neg(v2.q)) {
return 1;
} else {
return 2;
}
}
/* convert 32-bit float to 32-bit int */
uint32_t HELPER(cfebr)(uint32_t r1, uint32_t f2, uint32_t m3)
{
float32 v2 = env->fregs[f2].l.upper;
set_round_mode(m3);
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) |
float32_to_int32(v2, &env->fpu_status);
return set_cc_nz_f32(v2);
}
/* convert 64-bit float to 32-bit int */
uint32_t HELPER(cfdbr)(uint32_t r1, uint32_t f2, uint32_t m3)
{
float64 v2 = env->fregs[f2].d;
set_round_mode(m3);
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) |
float64_to_int32(v2, &env->fpu_status);
return set_cc_nz_f64(v2);
}
/* convert 128-bit float to 32-bit int */
uint32_t HELPER(cfxbr)(uint32_t r1, uint32_t f2, uint32_t m3)
{
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) |
float128_to_int32(v2.q, &env->fpu_status);
return set_cc_nz_f128(v2.q);
}
/* load 32-bit FP zero */
void HELPER(lzer)(uint32_t f1)
{
env->fregs[f1].l.upper = float32_zero;
}
/* load 64-bit FP zero */
void HELPER(lzdr)(uint32_t f1)
{
env->fregs[f1].d = float64_zero;
}
/* load 128-bit FP zero */
void HELPER(lzxr)(uint32_t f1)
{
CPU_QuadU x;
x.q = float64_to_float128(float64_zero, &env->fpu_status);
env->fregs[f1].ll = x.ll.upper;
env->fregs[f1 + 1].ll = x.ll.lower;
}
/* 128-bit FP subtraction RR */
uint32_t HELPER(sxbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU v1;
v1.ll.upper = env->fregs[f1].ll;
v1.ll.lower = env->fregs[f1 + 2].ll;
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
CPU_QuadU res;
res.q = float128_sub(v1.q, v2.q, &env->fpu_status);
env->fregs[f1].ll = res.ll.upper;
env->fregs[f1 + 2].ll = res.ll.lower;
return set_cc_nz_f128(res.q);
}
/* 128-bit FP addition RR */
uint32_t HELPER(axbr)(uint32_t f1, uint32_t f2)
{
CPU_QuadU v1;
v1.ll.upper = env->fregs[f1].ll;
v1.ll.lower = env->fregs[f1 + 2].ll;
CPU_QuadU v2;
v2.ll.upper = env->fregs[f2].ll;
v2.ll.lower = env->fregs[f2 + 2].ll;
CPU_QuadU res;
res.q = float128_add(v1.q, v2.q, &env->fpu_status);
env->fregs[f1].ll = res.ll.upper;
env->fregs[f1 + 2].ll = res.ll.lower;
return set_cc_nz_f128(res.q);
}
/* 32-bit FP multiplication RR */
void HELPER(meebr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].l.upper = float32_mul(env->fregs[f1].l.upper,
env->fregs[f2].l.upper,
&env->fpu_status);
}
/* 64-bit FP division RR */
void HELPER(ddbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = float64_div(env->fregs[f1].d, env->fregs[f2].d,
&env->fpu_status);
}
/* 64-bit FP multiply and add RM */
void HELPER(madb)(uint32_t f1, uint64_t a2, uint32_t f3)
{
HELPER_LOG("%s: f1 %d a2 0x%lx f3 %d\n", __FUNCTION__, f1, a2, f3);
CPU_DoubleU v2;
v2.ll = ldq(a2);
env->fregs[f1].d = float64_add(env->fregs[f1].d,
float64_mul(v2.d, env->fregs[f3].d,
&env->fpu_status),
&env->fpu_status);
}
/* 64-bit FP multiply and add RR */
void HELPER(madbr)(uint32_t f1, uint32_t f3, uint32_t f2)
{
HELPER_LOG("%s: f1 %d f2 %d f3 %d\n", __FUNCTION__, f1, f2, f3);
env->fregs[f1].d = float64_add(float64_mul(env->fregs[f2].d,
env->fregs[f3].d,
&env->fpu_status),
env->fregs[f1].d, &env->fpu_status);
}
/* 64-bit FP multiply and subtract RR */
void HELPER(msdbr)(uint32_t f1, uint32_t f3, uint32_t f2)
{
HELPER_LOG("%s: f1 %d f2 %d f3 %d\n", __FUNCTION__, f1, f2, f3);
env->fregs[f1].d = float64_sub(float64_mul(env->fregs[f2].d,
env->fregs[f3].d,
&env->fpu_status),
env->fregs[f1].d, &env->fpu_status);
}
/* 32-bit FP multiply and add RR */
void HELPER(maebr)(uint32_t f1, uint32_t f3, uint32_t f2)
{
env->fregs[f1].l.upper = float32_add(env->fregs[f1].l.upper,
float32_mul(env->fregs[f2].l.upper,
env->fregs[f3].l.upper,
&env->fpu_status),
&env->fpu_status);
}
/* convert 32-bit float to 64-bit float */
void HELPER(ldeb)(uint32_t f1, uint64_t a2)
{
uint32_t v2;
v2 = ldl(a2);
env->fregs[f1].d = float32_to_float64(v2,
&env->fpu_status);
}
/* convert 64-bit float to 128-bit float */
void HELPER(lxdb)(uint32_t f1, uint64_t a2)
{
CPU_DoubleU v2;
v2.ll = ldq(a2);
CPU_QuadU v1;
v1.q = float64_to_float128(v2.d, &env->fpu_status);
env->fregs[f1].ll = v1.ll.upper;
env->fregs[f1 + 2].ll = v1.ll.lower;
}
/* test data class 32-bit */
uint32_t HELPER(tceb)(uint32_t f1, uint64_t m2)
{
float32 v1 = env->fregs[f1].l.upper;
int neg = float32_is_neg(v1);
uint32_t cc = 0;
HELPER_LOG("%s: v1 0x%lx m2 0x%lx neg %d\n", __FUNCTION__, (long)v1, m2, neg);
if ((float32_is_zero(v1) && (m2 & (1 << (11-neg)))) ||
(float32_is_infinity(v1) && (m2 & (1 << (5-neg)))) ||
(float32_is_any_nan(v1) && (m2 & (1 << (3-neg)))) ||
(float32_is_signaling_nan(v1) && (m2 & (1 << (1-neg))))) {
cc = 1;
} else if (m2 & (1 << (9-neg))) {
/* assume normalized number */
cc = 1;
}
/* FIXME: denormalized? */
return cc;
}
/* test data class 64-bit */
uint32_t HELPER(tcdb)(uint32_t f1, uint64_t m2)
{
float64 v1 = env->fregs[f1].d;
int neg = float64_is_neg(v1);
uint32_t cc = 0;
HELPER_LOG("%s: v1 0x%lx m2 0x%lx neg %d\n", __FUNCTION__, v1, m2, neg);
if ((float64_is_zero(v1) && (m2 & (1 << (11-neg)))) ||
(float64_is_infinity(v1) && (m2 & (1 << (5-neg)))) ||
(float64_is_any_nan(v1) && (m2 & (1 << (3-neg)))) ||
(float64_is_signaling_nan(v1) && (m2 & (1 << (1-neg))))) {
cc = 1;
} else if (m2 & (1 << (9-neg))) {
/* assume normalized number */
cc = 1;
}
/* FIXME: denormalized? */
return cc;
}
/* test data class 128-bit */
uint32_t HELPER(tcxb)(uint32_t f1, uint64_t m2)
{
CPU_QuadU v1;
uint32_t cc = 0;
v1.ll.upper = env->fregs[f1].ll;
v1.ll.lower = env->fregs[f1 + 2].ll;
int neg = float128_is_neg(v1.q);
if ((float128_is_zero(v1.q) && (m2 & (1 << (11-neg)))) ||
(float128_is_infinity(v1.q) && (m2 & (1 << (5-neg)))) ||
(float128_is_any_nan(v1.q) && (m2 & (1 << (3-neg)))) ||
(float128_is_signaling_nan(v1.q) && (m2 & (1 << (1-neg))))) {
cc = 1;
} else if (m2 & (1 << (9-neg))) {
/* assume normalized number */
cc = 1;
}
/* FIXME: denormalized? */
return cc;
}
/* find leftmost one */
uint32_t HELPER(flogr)(uint32_t r1, uint64_t v2)
{
uint64_t res = 0;
uint64_t ov2 = v2;
while (!(v2 & 0x8000000000000000ULL) && v2) {
v2 <<= 1;
res++;
}
if (!v2) {
env->regs[r1] = 64;
env->regs[r1 + 1] = 0;
return 0;
} else {
env->regs[r1] = res;
env->regs[r1 + 1] = ov2 & ~(0x8000000000000000ULL >> res);
return 2;
}
}
/* square root 64-bit RR */
void HELPER(sqdbr)(uint32_t f1, uint32_t f2)
{
env->fregs[f1].d = float64_sqrt(env->fregs[f2].d, &env->fpu_status);
}
/* checksum */
void HELPER(cksm)(uint32_t r1, uint32_t r2)
{
uint64_t src = get_address_31fix(r2);
uint64_t src_len = env->regs[(r2 + 1) & 15];
uint64_t cksm = (uint32_t)env->regs[r1];
while (src_len >= 4) {
cksm += ldl(src);
/* move to next word */
src_len -= 4;
src += 4;
}
switch (src_len) {
case 0:
break;
case 1:
cksm += ldub(src) << 24;
break;
case 2:
cksm += lduw(src) << 16;
break;
case 3:
cksm += lduw(src) << 16;
cksm += ldub(src + 2) << 8;
break;
}
/* indicate we've processed everything */
env->regs[r2] = src + src_len;
env->regs[(r2 + 1) & 15] = 0;
/* store result */
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) |
((uint32_t)cksm + (cksm >> 32));
}
static inline uint32_t cc_calc_ltgt_32(CPUS390XState *env, int32_t src,
int32_t dst)
{
if (src == dst) {
return 0;
} else if (src < dst) {
return 1;
} else {
return 2;
}
}
static inline uint32_t cc_calc_ltgt0_32(CPUS390XState *env, int32_t dst)
{
return cc_calc_ltgt_32(env, dst, 0);
}
static inline uint32_t cc_calc_ltgt_64(CPUS390XState *env, int64_t src,
int64_t dst)
{
if (src == dst) {
return 0;
} else if (src < dst) {
return 1;
} else {
return 2;
}
}
static inline uint32_t cc_calc_ltgt0_64(CPUS390XState *env, int64_t dst)
{
return cc_calc_ltgt_64(env, dst, 0);
}
static inline uint32_t cc_calc_ltugtu_32(CPUS390XState *env, uint32_t src,
uint32_t dst)
{
if (src == dst) {
return 0;
} else if (src < dst) {
return 1;
} else {
return 2;
}
}
static inline uint32_t cc_calc_ltugtu_64(CPUS390XState *env, uint64_t src,
uint64_t dst)
{
if (src == dst) {
return 0;
} else if (src < dst) {
return 1;
} else {
return 2;
}
}
static inline uint32_t cc_calc_tm_32(CPUS390XState *env, uint32_t val, uint32_t mask)
{
HELPER_LOG("%s: val 0x%x mask 0x%x\n", __FUNCTION__, val, mask);
uint16_t r = val & mask;
if (r == 0 || mask == 0) {
return 0;
} else if (r == mask) {
return 3;
} else {
return 1;
}
}
/* set condition code for test under mask */
static inline uint32_t cc_calc_tm_64(CPUS390XState *env, uint64_t val, uint32_t mask)
{
uint16_t r = val & mask;
HELPER_LOG("%s: val 0x%lx mask 0x%x r 0x%x\n", __FUNCTION__, val, mask, r);
if (r == 0 || mask == 0) {
return 0;
} else if (r == mask) {
return 3;
} else {
while (!(mask & 0x8000)) {
mask <<= 1;
val <<= 1;
}
if (val & 0x8000) {
return 2;
} else {
return 1;
}
}
}
static inline uint32_t cc_calc_nz(CPUS390XState *env, uint64_t dst)
{
return !!dst;
}
static inline uint32_t cc_calc_add_64(CPUS390XState *env, int64_t a1, int64_t a2,
int64_t ar)
{
if ((a1 > 0 && a2 > 0 && ar < 0) || (a1 < 0 && a2 < 0 && ar > 0)) {
return 3; /* overflow */
} else {
if (ar < 0) {
return 1;
} else if (ar > 0) {
return 2;
} else {
return 0;
}
}
}
static inline uint32_t cc_calc_addu_64(CPUS390XState *env, uint64_t a1, uint64_t a2,
uint64_t ar)
{
if (ar == 0) {
if (a1) {
return 2;
} else {
return 0;
}
} else {
if (ar < a1 || ar < a2) {
return 3;
} else {
return 1;
}
}
}
static inline uint32_t cc_calc_sub_64(CPUS390XState *env, int64_t a1, int64_t a2,
int64_t ar)
{
if ((a1 > 0 && a2 < 0 && ar < 0) || (a1 < 0 && a2 > 0 && ar > 0)) {
return 3; /* overflow */
} else {
if (ar < 0) {
return 1;
} else if (ar > 0) {
return 2;
} else {
return 0;
}
}
}
static inline uint32_t cc_calc_subu_64(CPUS390XState *env, uint64_t a1, uint64_t a2,
uint64_t ar)
{
if (ar == 0) {
return 2;
} else {
if (a2 > a1) {
return 1;
} else {
return 3;
}
}
}
static inline uint32_t cc_calc_abs_64(CPUS390XState *env, int64_t dst)
{
if ((uint64_t)dst == 0x8000000000000000ULL) {
return 3;
} else if (dst) {
return 1;
} else {
return 0;
}
}
static inline uint32_t cc_calc_nabs_64(CPUS390XState *env, int64_t dst)
{
return !!dst;
}
static inline uint32_t cc_calc_comp_64(CPUS390XState *env, int64_t dst)
{
if ((uint64_t)dst == 0x8000000000000000ULL) {
return 3;
} else if (dst < 0) {
return 1;
} else if (dst > 0) {
return 2;
} else {
return 0;
}
}
static inline uint32_t cc_calc_add_32(CPUS390XState *env, int32_t a1, int32_t a2,
int32_t ar)
{
if ((a1 > 0 && a2 > 0 && ar < 0) || (a1 < 0 && a2 < 0 && ar > 0)) {
return 3; /* overflow */
} else {
if (ar < 0) {
return 1;
} else if (ar > 0) {
return 2;
} else {
return 0;
}
}
}
static inline uint32_t cc_calc_addu_32(CPUS390XState *env, uint32_t a1, uint32_t a2,
uint32_t ar)
{
if (ar == 0) {
if (a1) {
return 2;
} else {
return 0;
}
} else {
if (ar < a1 || ar < a2) {
return 3;
} else {
return 1;
}
}
}
static inline uint32_t cc_calc_sub_32(CPUS390XState *env, int32_t a1, int32_t a2,
int32_t ar)
{
if ((a1 > 0 && a2 < 0 && ar < 0) || (a1 < 0 && a2 > 0 && ar > 0)) {
return 3; /* overflow */
} else {
if (ar < 0) {
return 1;
} else if (ar > 0) {
return 2;
} else {
return 0;
}
}
}
static inline uint32_t cc_calc_subu_32(CPUS390XState *env, uint32_t a1, uint32_t a2,
uint32_t ar)
{
if (ar == 0) {
return 2;
} else {
if (a2 > a1) {
return 1;
} else {
return 3;
}
}
}
static inline uint32_t cc_calc_abs_32(CPUS390XState *env, int32_t dst)
{
if ((uint32_t)dst == 0x80000000UL) {
return 3;
} else if (dst) {
return 1;
} else {
return 0;
}
}
static inline uint32_t cc_calc_nabs_32(CPUS390XState *env, int32_t dst)
{
return !!dst;
}
static inline uint32_t cc_calc_comp_32(CPUS390XState *env, int32_t dst)
{
if ((uint32_t)dst == 0x80000000UL) {
return 3;
} else if (dst < 0) {
return 1;
} else if (dst > 0) {
return 2;
} else {
return 0;
}
}
/* calculate condition code for insert character under mask insn */
static inline uint32_t cc_calc_icm_32(CPUS390XState *env, uint32_t mask, uint32_t val)
{
HELPER_LOG("%s: mask 0x%x val %d\n", __FUNCTION__, mask, val);
uint32_t cc;
if (mask == 0xf) {
if (!val) {
return 0;
} else if (val & 0x80000000) {
return 1;
} else {
return 2;
}
}
if (!val || !mask) {
cc = 0;
} else {
while (mask != 1) {
mask >>= 1;
val >>= 8;
}
if (val & 0x80) {
cc = 1;
} else {
cc = 2;
}
}
return cc;
}
static inline uint32_t cc_calc_slag(CPUS390XState *env, uint64_t src, uint64_t shift)
{
uint64_t mask = ((1ULL << shift) - 1ULL) << (64 - shift);
uint64_t match, r;
/* check if the sign bit stays the same */
if (src & (1ULL << 63)) {
match = mask;
} else {
match = 0;
}
if ((src & mask) != match) {
/* overflow */
return 3;
}
r = ((src << shift) & ((1ULL << 63) - 1)) | (src & (1ULL << 63));
if ((int64_t)r == 0) {
return 0;
} else if ((int64_t)r < 0) {
return 1;
}
return 2;
}
static inline uint32_t do_calc_cc(CPUS390XState *env, uint32_t cc_op, uint64_t src,
uint64_t dst, uint64_t vr)
{
uint32_t r = 0;
switch (cc_op) {
case CC_OP_CONST0:
case CC_OP_CONST1:
case CC_OP_CONST2:
case CC_OP_CONST3:
/* cc_op value _is_ cc */
r = cc_op;
break;
case CC_OP_LTGT0_32:
r = cc_calc_ltgt0_32(env, dst);
break;
case CC_OP_LTGT0_64:
r = cc_calc_ltgt0_64(env, dst);
break;
case CC_OP_LTGT_32:
r = cc_calc_ltgt_32(env, src, dst);
break;
case CC_OP_LTGT_64:
r = cc_calc_ltgt_64(env, src, dst);
break;
case CC_OP_LTUGTU_32:
r = cc_calc_ltugtu_32(env, src, dst);
break;
case CC_OP_LTUGTU_64:
r = cc_calc_ltugtu_64(env, src, dst);
break;
case CC_OP_TM_32:
r = cc_calc_tm_32(env, src, dst);
break;
case CC_OP_TM_64:
r = cc_calc_tm_64(env, src, dst);
break;
case CC_OP_NZ:
r = cc_calc_nz(env, dst);
break;
case CC_OP_ADD_64:
r = cc_calc_add_64(env, src, dst, vr);
break;
case CC_OP_ADDU_64:
r = cc_calc_addu_64(env, src, dst, vr);
break;
case CC_OP_SUB_64:
r = cc_calc_sub_64(env, src, dst, vr);
break;
case CC_OP_SUBU_64:
r = cc_calc_subu_64(env, src, dst, vr);
break;
case CC_OP_ABS_64:
r = cc_calc_abs_64(env, dst);
break;
case CC_OP_NABS_64:
r = cc_calc_nabs_64(env, dst);
break;
case CC_OP_COMP_64:
r = cc_calc_comp_64(env, dst);
break;
case CC_OP_ADD_32:
r = cc_calc_add_32(env, src, dst, vr);
break;
case CC_OP_ADDU_32:
r = cc_calc_addu_32(env, src, dst, vr);
break;
case CC_OP_SUB_32:
r = cc_calc_sub_32(env, src, dst, vr);
break;
case CC_OP_SUBU_32:
r = cc_calc_subu_32(env, src, dst, vr);
break;
case CC_OP_ABS_32:
r = cc_calc_abs_64(env, dst);
break;
case CC_OP_NABS_32:
r = cc_calc_nabs_64(env, dst);
break;
case CC_OP_COMP_32:
r = cc_calc_comp_32(env, dst);
break;
case CC_OP_ICM:
r = cc_calc_icm_32(env, src, dst);
break;
case CC_OP_SLAG:
r = cc_calc_slag(env, src, dst);
break;
case CC_OP_LTGT_F32:
r = set_cc_f32(src, dst);
break;
case CC_OP_LTGT_F64:
r = set_cc_f64(src, dst);
break;
case CC_OP_NZ_F32:
r = set_cc_nz_f32(dst);
break;
case CC_OP_NZ_F64:
r = set_cc_nz_f64(dst);
break;
default:
cpu_abort(env, "Unknown CC operation: %s\n", cc_name(cc_op));
}
HELPER_LOG("%s: %15s 0x%016lx 0x%016lx 0x%016lx = %d\n", __FUNCTION__,
cc_name(cc_op), src, dst, vr, r);
return r;
}
uint32_t calc_cc(CPUS390XState *env, uint32_t cc_op, uint64_t src, uint64_t dst,
uint64_t vr)
{
return do_calc_cc(env, cc_op, src, dst, vr);
}
uint32_t HELPER(calc_cc)(uint32_t cc_op, uint64_t src, uint64_t dst,
uint64_t vr)
{
return do_calc_cc(env, cc_op, src, dst, vr);
}
uint64_t HELPER(cvd)(int32_t bin)
{
/* positive 0 */
uint64_t dec = 0x0c;
int shift = 4;
if (bin < 0) {
bin = -bin;
dec = 0x0d;
}
for (shift = 4; (shift < 64) && bin; shift += 4) {
int current_number = bin % 10;
dec |= (current_number) << shift;
bin /= 10;
}
return dec;
}
void HELPER(unpk)(uint32_t len, uint64_t dest, uint64_t src)
{
int len_dest = len >> 4;
int len_src = len & 0xf;
uint8_t b;
int second_nibble = 0;
dest += len_dest;
src += len_src;
/* last byte is special, it only flips the nibbles */
b = ldub(src);
stb(dest, (b << 4) | (b >> 4));
src--;
len_src--;
/* now pad every nibble with 0xf0 */
while (len_dest > 0) {
uint8_t cur_byte = 0;
if (len_src > 0) {
cur_byte = ldub(src);
}
len_dest--;
dest--;
/* only advance one nibble at a time */
if (second_nibble) {
cur_byte >>= 4;
len_src--;
src--;
}
second_nibble = !second_nibble;
/* digit */
cur_byte = (cur_byte & 0xf);
/* zone bits */
cur_byte |= 0xf0;
stb(dest, cur_byte);
}
}
void HELPER(tr)(uint32_t len, uint64_t array, uint64_t trans)
{
int i;
for (i = 0; i <= len; i++) {
uint8_t byte = ldub(array + i);
uint8_t new_byte = ldub(trans + byte);
stb(array + i, new_byte);
}
}
#ifndef CONFIG_USER_ONLY
void HELPER(load_psw)(uint64_t mask, uint64_t addr)
{
load_psw(env, mask, addr);
cpu_loop_exit(env);
}
static void program_interrupt(CPUS390XState *env, uint32_t code, int ilc)
{
qemu_log("program interrupt at %#" PRIx64 "\n", env->psw.addr);
if (kvm_enabled()) {
#ifdef CONFIG_KVM
kvm_s390_interrupt(env, KVM_S390_PROGRAM_INT, code);
#endif
} else {
env->int_pgm_code = code;
env->int_pgm_ilc = ilc;
env->exception_index = EXCP_PGM;
cpu_loop_exit(env);
}
}
static void ext_interrupt(CPUS390XState *env, int type, uint32_t param,
uint64_t param64)
{
cpu_inject_ext(env, type, param, param64);
}
int sclp_service_call(CPUS390XState *env, uint32_t sccb, uint64_t code)
{
int r = 0;
int shift = 0;
#ifdef DEBUG_HELPER
printf("sclp(0x%x, 0x%" PRIx64 ")\n", sccb, code);
#endif
if (sccb & ~0x7ffffff8ul) {
fprintf(stderr, "KVM: invalid sccb address 0x%x\n", sccb);
r = -1;
goto out;
}
switch(code) {
case SCLP_CMDW_READ_SCP_INFO:
case SCLP_CMDW_READ_SCP_INFO_FORCED:
while ((ram_size >> (20 + shift)) > 65535) {
shift++;
}
stw_phys(sccb + SCP_MEM_CODE, ram_size >> (20 + shift));
stb_phys(sccb + SCP_INCREMENT, 1 << shift);
stw_phys(sccb + SCP_RESPONSE_CODE, 0x10);
if (kvm_enabled()) {
#ifdef CONFIG_KVM
kvm_s390_interrupt_internal(env, KVM_S390_INT_SERVICE,
sccb & ~3, 0, 1);
#endif
} else {
env->psw.addr += 4;
ext_interrupt(env, EXT_SERVICE, sccb & ~3, 0);
}
break;
default:
#ifdef DEBUG_HELPER
printf("KVM: invalid sclp call 0x%x / 0x%" PRIx64 "x\n", sccb, code);
#endif
r = -1;
break;
}
out:
return r;
}
/* SCLP service call */
uint32_t HELPER(servc)(uint32_t r1, uint64_t r2)
{
if (sclp_service_call(env, r1, r2)) {
return 3;
}
return 0;
}
/* DIAG */
uint64_t HELPER(diag)(uint32_t num, uint64_t mem, uint64_t code)
{
uint64_t r;
switch (num) {
case 0x500:
/* KVM hypercall */
r = s390_virtio_hypercall(env, mem, code);
break;
case 0x44:
/* yield */
r = 0;
break;
case 0x308:
/* ipl */
r = 0;
break;
default:
r = -1;
break;
}
if (r) {
program_interrupt(env, PGM_OPERATION, ILC_LATER_INC);
}
return r;
}
/* Store CPU ID */
void HELPER(stidp)(uint64_t a1)
{
stq(a1, env->cpu_num);
}
/* Set Prefix */
void HELPER(spx)(uint64_t a1)
{
uint32_t prefix;
prefix = ldl(a1);
env->psa = prefix & 0xfffff000;
qemu_log("prefix: %#x\n", prefix);
tlb_flush_page(env, 0);
tlb_flush_page(env, TARGET_PAGE_SIZE);
}
/* Set Clock */
uint32_t HELPER(sck)(uint64_t a1)
{
/* XXX not implemented - is it necessary? */
return 0;
}
static inline uint64_t clock_value(CPUS390XState *env)
{
uint64_t time;
time = env->tod_offset +
time2tod(qemu_get_clock_ns(vm_clock) - env->tod_basetime);
return time;
}
/* Store Clock */
uint32_t HELPER(stck)(uint64_t a1)
{
stq(a1, clock_value(env));
return 0;
}
/* Store Clock Extended */
uint32_t HELPER(stcke)(uint64_t a1)
{
stb(a1, 0);
/* basically the same value as stck */
stq(a1 + 1, clock_value(env) | env->cpu_num);
/* more fine grained than stck */
stq(a1 + 9, 0);
/* XXX programmable fields */
stw(a1 + 17, 0);
return 0;
}
/* Set Clock Comparator */
void HELPER(sckc)(uint64_t a1)
{
uint64_t time = ldq(a1);
if (time == -1ULL) {
return;
}
/* difference between now and then */
time -= clock_value(env);
/* nanoseconds */
time = (time * 125) >> 9;
qemu_mod_timer(env->tod_timer, qemu_get_clock_ns(vm_clock) + time);
}
/* Store Clock Comparator */
void HELPER(stckc)(uint64_t a1)
{
/* XXX implement */
stq(a1, 0);
}
/* Set CPU Timer */
void HELPER(spt)(uint64_t a1)
{
uint64_t time = ldq(a1);
if (time == -1ULL) {
return;
}
/* nanoseconds */
time = (time * 125) >> 9;
qemu_mod_timer(env->cpu_timer, qemu_get_clock_ns(vm_clock) + time);
}
/* Store CPU Timer */
void HELPER(stpt)(uint64_t a1)
{
/* XXX implement */
stq(a1, 0);
}
/* Store System Information */
uint32_t HELPER(stsi)(uint64_t a0, uint32_t r0, uint32_t r1)
{
int cc = 0;
int sel1, sel2;
if ((r0 & STSI_LEVEL_MASK) <= STSI_LEVEL_3 &&
((r0 & STSI_R0_RESERVED_MASK) || (r1 & STSI_R1_RESERVED_MASK))) {
/* valid function code, invalid reserved bits */
program_interrupt(env, PGM_SPECIFICATION, 2);
}
sel1 = r0 & STSI_R0_SEL1_MASK;
sel2 = r1 & STSI_R1_SEL2_MASK;
/* XXX: spec exception if sysib is not 4k-aligned */
switch (r0 & STSI_LEVEL_MASK) {
case STSI_LEVEL_1:
if ((sel1 == 1) && (sel2 == 1)) {
/* Basic Machine Configuration */
struct sysib_111 sysib;
memset(&sysib, 0, sizeof(sysib));
ebcdic_put(sysib.manuf, "QEMU ", 16);
/* same as machine type number in STORE CPU ID */
ebcdic_put(sysib.type, "QEMU", 4);
/* same as model number in STORE CPU ID */
ebcdic_put(sysib.model, "QEMU ", 16);
ebcdic_put(sysib.sequence, "QEMU ", 16);
ebcdic_put(sysib.plant, "QEMU", 4);
cpu_physical_memory_rw(a0, (uint8_t*)&sysib, sizeof(sysib), 1);
} else if ((sel1 == 2) && (sel2 == 1)) {
/* Basic Machine CPU */
struct sysib_121 sysib;
memset(&sysib, 0, sizeof(sysib));
/* XXX make different for different CPUs? */
ebcdic_put(sysib.sequence, "QEMUQEMUQEMUQEMU", 16);
ebcdic_put(sysib.plant, "QEMU", 4);
stw_p(&sysib.cpu_addr, env->cpu_num);
cpu_physical_memory_rw(a0, (uint8_t*)&sysib, sizeof(sysib), 1);
} else if ((sel1 == 2) && (sel2 == 2)) {
/* Basic Machine CPUs */
struct sysib_122 sysib;
memset(&sysib, 0, sizeof(sysib));
stl_p(&sysib.capability, 0x443afc29);
/* XXX change when SMP comes */
stw_p(&sysib.total_cpus, 1);
stw_p(&sysib.active_cpus, 1);
stw_p(&sysib.standby_cpus, 0);
stw_p(&sysib.reserved_cpus, 0);
cpu_physical_memory_rw(a0, (uint8_t*)&sysib, sizeof(sysib), 1);
} else {
cc = 3;
}
break;
case STSI_LEVEL_2:
{
if ((sel1 == 2) && (sel2 == 1)) {
/* LPAR CPU */
struct sysib_221 sysib;
memset(&sysib, 0, sizeof(sysib));
/* XXX make different for different CPUs? */
ebcdic_put(sysib.sequence, "QEMUQEMUQEMUQEMU", 16);
ebcdic_put(sysib.plant, "QEMU", 4);
stw_p(&sysib.cpu_addr, env->cpu_num);
stw_p(&sysib.cpu_id, 0);
cpu_physical_memory_rw(a0, (uint8_t*)&sysib, sizeof(sysib), 1);
} else if ((sel1 == 2) && (sel2 == 2)) {
/* LPAR CPUs */
struct sysib_222 sysib;
memset(&sysib, 0, sizeof(sysib));
stw_p(&sysib.lpar_num, 0);
sysib.lcpuc = 0;
/* XXX change when SMP comes */
stw_p(&sysib.total_cpus, 1);
stw_p(&sysib.conf_cpus, 1);
stw_p(&sysib.standby_cpus, 0);
stw_p(&sysib.reserved_cpus, 0);
ebcdic_put(sysib.name, "QEMU ", 8);
stl_p(&sysib.caf, 1000);
stw_p(&sysib.dedicated_cpus, 0);
stw_p(&sysib.shared_cpus, 0);
cpu_physical_memory_rw(a0, (uint8_t*)&sysib, sizeof(sysib), 1);
} else {
cc = 3;
}
break;
}
case STSI_LEVEL_3:
{
if ((sel1 == 2) && (sel2 == 2)) {
/* VM CPUs */
struct sysib_322 sysib;
memset(&sysib, 0, sizeof(sysib));
sysib.count = 1;
/* XXX change when SMP comes */
stw_p(&sysib.vm[0].total_cpus, 1);
stw_p(&sysib.vm[0].conf_cpus, 1);
stw_p(&sysib.vm[0].standby_cpus, 0);
stw_p(&sysib.vm[0].reserved_cpus, 0);
ebcdic_put(sysib.vm[0].name, "KVMguest", 8);
stl_p(&sysib.vm[0].caf, 1000);
ebcdic_put(sysib.vm[0].cpi, "KVM/Linux ", 16);
cpu_physical_memory_rw(a0, (uint8_t*)&sysib, sizeof(sysib), 1);
} else {
cc = 3;
}
break;
}
case STSI_LEVEL_CURRENT:
env->regs[0] = STSI_LEVEL_3;
break;
default:
cc = 3;
break;
}
return cc;
}
void HELPER(lctlg)(uint32_t r1, uint64_t a2, uint32_t r3)
{
int i;
uint64_t src = a2;
for (i = r1;; i = (i + 1) % 16) {
env->cregs[i] = ldq(src);
HELPER_LOG("load ctl %d from 0x%" PRIx64 " == 0x%" PRIx64 "\n",
i, src, env->cregs[i]);
src += sizeof(uint64_t);
if (i == r3) {
break;
}
}
tlb_flush(env, 1);
}
void HELPER(lctl)(uint32_t r1, uint64_t a2, uint32_t r3)
{
int i;
uint64_t src = a2;
for (i = r1;; i = (i + 1) % 16) {
env->cregs[i] = (env->cregs[i] & 0xFFFFFFFF00000000ULL) | ldl(src);
src += sizeof(uint32_t);
if (i == r3) {
break;
}
}
tlb_flush(env, 1);
}
void HELPER(stctg)(uint32_t r1, uint64_t a2, uint32_t r3)
{
int i;
uint64_t dest = a2;
for (i = r1;; i = (i + 1) % 16) {
stq(dest, env->cregs[i]);
dest += sizeof(uint64_t);
if (i == r3) {
break;
}
}
}
void HELPER(stctl)(uint32_t r1, uint64_t a2, uint32_t r3)
{
int i;
uint64_t dest = a2;
for (i = r1;; i = (i + 1) % 16) {
stl(dest, env->cregs[i]);
dest += sizeof(uint32_t);
if (i == r3) {
break;
}
}
}
uint32_t HELPER(tprot)(uint64_t a1, uint64_t a2)
{
/* XXX implement */
return 0;
}
/* insert storage key extended */
uint64_t HELPER(iske)(uint64_t r2)
{
uint64_t addr = get_address(0, 0, r2);
if (addr > ram_size) {
return 0;
}
return env->storage_keys[addr / TARGET_PAGE_SIZE];
}
/* set storage key extended */
void HELPER(sske)(uint32_t r1, uint64_t r2)
{
uint64_t addr = get_address(0, 0, r2);
if (addr > ram_size) {
return;
}
env->storage_keys[addr / TARGET_PAGE_SIZE] = r1;
}
/* reset reference bit extended */
uint32_t HELPER(rrbe)(uint32_t r1, uint64_t r2)
{
uint8_t re;
uint8_t key;
if (r2 > ram_size) {
return 0;
}
key = env->storage_keys[r2 / TARGET_PAGE_SIZE];
re = key & (SK_R | SK_C);
env->storage_keys[r2 / TARGET_PAGE_SIZE] = (key & ~SK_R);
/*
* cc
*
* 0 Reference bit zero; change bit zero
* 1 Reference bit zero; change bit one
* 2 Reference bit one; change bit zero
* 3 Reference bit one; change bit one
*/
return re >> 1;
}
/* compare and swap and purge */
uint32_t HELPER(csp)(uint32_t r1, uint32_t r2)
{
uint32_t cc;
uint32_t o1 = env->regs[r1];
uint64_t a2 = get_address_31fix(r2) & ~3ULL;
uint32_t o2 = ldl(a2);
if (o1 == o2) {
stl(a2, env->regs[(r1 + 1) & 15]);
if (env->regs[r2] & 0x3) {
/* flush TLB / ALB */
tlb_flush(env, 1);
}
cc = 0;
} else {
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) | o2;
cc = 1;
}
return cc;
}
static uint32_t mvc_asc(int64_t l, uint64_t a1, uint64_t mode1, uint64_t a2,
uint64_t mode2)
{
target_ulong src, dest;
int flags, cc = 0, i;
if (!l) {
return 0;
} else if (l > 256) {
/* max 256 */
l = 256;
cc = 3;
}
if (mmu_translate(env, a1 & TARGET_PAGE_MASK, 1, mode1, &dest, &flags)) {
cpu_loop_exit(env);
}
dest |= a1 & ~TARGET_PAGE_MASK;
if (mmu_translate(env, a2 & TARGET_PAGE_MASK, 0, mode2, &src, &flags)) {
cpu_loop_exit(env);
}
src |= a2 & ~TARGET_PAGE_MASK;
/* XXX replace w/ memcpy */
for (i = 0; i < l; i++) {
/* XXX be more clever */
if ((((dest + i) & TARGET_PAGE_MASK) != (dest & TARGET_PAGE_MASK)) ||
(((src + i) & TARGET_PAGE_MASK) != (src & TARGET_PAGE_MASK))) {
mvc_asc(l - i, a1 + i, mode1, a2 + i, mode2);
break;
}
stb_phys(dest + i, ldub_phys(src + i));
}
return cc;
}
uint32_t HELPER(mvcs)(uint64_t l, uint64_t a1, uint64_t a2)
{
HELPER_LOG("%s: %16" PRIx64 " %16" PRIx64 " %16" PRIx64 "\n",
__FUNCTION__, l, a1, a2);
return mvc_asc(l, a1, PSW_ASC_SECONDARY, a2, PSW_ASC_PRIMARY);
}
uint32_t HELPER(mvcp)(uint64_t l, uint64_t a1, uint64_t a2)
{
HELPER_LOG("%s: %16" PRIx64 " %16" PRIx64 " %16" PRIx64 "\n",
__FUNCTION__, l, a1, a2);
return mvc_asc(l, a1, PSW_ASC_PRIMARY, a2, PSW_ASC_SECONDARY);
}
uint32_t HELPER(sigp)(uint64_t order_code, uint32_t r1, uint64_t cpu_addr)
{
int cc = 0;
HELPER_LOG("%s: %016" PRIx64 " %08x %016" PRIx64 "\n",
__FUNCTION__, order_code, r1, cpu_addr);
/* Remember: Use "R1 or R1+1, whichever is the odd-numbered register"
as parameter (input). Status (output) is always R1. */
switch (order_code) {
case SIGP_SET_ARCH:
/* switch arch */
break;
case SIGP_SENSE:
/* enumerate CPU status */
if (cpu_addr) {
/* XXX implement when SMP comes */
return 3;
}
env->regs[r1] &= 0xffffffff00000000ULL;
cc = 1;
break;
#if !defined (CONFIG_USER_ONLY)
case SIGP_RESTART:
qemu_system_reset_request();
cpu_loop_exit(env);
break;
case SIGP_STOP:
qemu_system_shutdown_request();
cpu_loop_exit(env);
break;
#endif
default:
/* unknown sigp */
fprintf(stderr, "XXX unknown sigp: 0x%" PRIx64 "\n", order_code);
cc = 3;
}
return cc;
}
void HELPER(sacf)(uint64_t a1)
{
HELPER_LOG("%s: %16" PRIx64 "\n", __FUNCTION__, a1);
switch (a1 & 0xf00) {
case 0x000:
env->psw.mask &= ~PSW_MASK_ASC;
env->psw.mask |= PSW_ASC_PRIMARY;
break;
case 0x100:
env->psw.mask &= ~PSW_MASK_ASC;
env->psw.mask |= PSW_ASC_SECONDARY;
break;
case 0x300:
env->psw.mask &= ~PSW_MASK_ASC;
env->psw.mask |= PSW_ASC_HOME;
break;
default:
qemu_log("unknown sacf mode: %" PRIx64 "\n", a1);
program_interrupt(env, PGM_SPECIFICATION, 2);
break;
}
}
/* invalidate pte */
void HELPER(ipte)(uint64_t pte_addr, uint64_t vaddr)
{
uint64_t page = vaddr & TARGET_PAGE_MASK;
uint64_t pte = 0;
/* XXX broadcast to other CPUs */
/* XXX Linux is nice enough to give us the exact pte address.
According to spec we'd have to find it out ourselves */
/* XXX Linux is fine with overwriting the pte, the spec requires
us to only set the invalid bit */
stq_phys(pte_addr, pte | _PAGE_INVALID);
/* XXX we exploit the fact that Linux passes the exact virtual
address here - it's not obliged to! */
tlb_flush_page(env, page);
/* XXX 31-bit hack */
if (page & 0x80000000) {
tlb_flush_page(env, page & ~0x80000000);
} else {
tlb_flush_page(env, page | 0x80000000);
}
}
/* flush local tlb */
void HELPER(ptlb)(void)
{
tlb_flush(env, 1);
}
/* store using real address */
void HELPER(stura)(uint64_t addr, uint32_t v1)
{
stw_phys(get_address(0, 0, addr), v1);
}
/* load real address */
uint32_t HELPER(lra)(uint64_t addr, uint32_t r1)
{
uint32_t cc = 0;
int old_exc = env->exception_index;
uint64_t asc = env->psw.mask & PSW_MASK_ASC;
uint64_t ret;
int flags;
/* XXX incomplete - has more corner cases */
if (!(env->psw.mask & PSW_MASK_64) && (addr >> 32)) {
program_interrupt(env, PGM_SPECIAL_OP, 2);
}
env->exception_index = old_exc;
if (mmu_translate(env, addr, 0, asc, &ret, &flags)) {
cc = 3;
}
if (env->exception_index == EXCP_PGM) {
ret = env->int_pgm_code | 0x80000000;
} else {
ret |= addr & ~TARGET_PAGE_MASK;
}
env->exception_index = old_exc;
if (!(env->psw.mask & PSW_MASK_64)) {
env->regs[r1] = (env->regs[r1] & 0xffffffff00000000ULL) | (ret & 0xffffffffULL);
} else {
env->regs[r1] = ret;
}
return cc;
}
#endif