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qemu-e2k/target-i386/ops_template.h

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/*
* i386 micro operations (included several times to generate
* different operand sizes)
*
* Copyright (c) 2003 Fabrice Bellard
*
* 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, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#define DATA_BITS (1 << (3 + SHIFT))
#define SHIFT_MASK (DATA_BITS - 1)
#define SIGN_MASK (((target_ulong)1) << (DATA_BITS - 1))
#if DATA_BITS <= 32
#define SHIFT1_MASK 0x1f
#else
#define SHIFT1_MASK 0x3f
#endif
#if DATA_BITS == 8
#define SUFFIX b
#define DATA_TYPE uint8_t
#define DATA_STYPE int8_t
#define DATA_MASK 0xff
#elif DATA_BITS == 16
#define SUFFIX w
#define DATA_TYPE uint16_t
#define DATA_STYPE int16_t
#define DATA_MASK 0xffff
#elif DATA_BITS == 32
#define SUFFIX l
#define DATA_TYPE uint32_t
#define DATA_STYPE int32_t
#define DATA_MASK 0xffffffff
#elif DATA_BITS == 64
#define SUFFIX q
#define DATA_TYPE uint64_t
#define DATA_STYPE int64_t
#define DATA_MASK 0xffffffffffffffffULL
#else
#error unhandled operand size
#endif
/* dynamic flags computation */
static int glue(compute_all_add, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
target_long src1, src2;
src1 = CC_SRC;
src2 = CC_DST - CC_SRC;
cf = (DATA_TYPE)CC_DST < (DATA_TYPE)src1;
pf = parity_table[(uint8_t)CC_DST];
af = (CC_DST ^ src1 ^ src2) & 0x10;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = lshift((src1 ^ src2 ^ -1) & (src1 ^ CC_DST), 12 - DATA_BITS) & CC_O;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_c_add, SUFFIX)(void)
{
int cf;
target_long src1;
src1 = CC_SRC;
cf = (DATA_TYPE)CC_DST < (DATA_TYPE)src1;
return cf;
}
static int glue(compute_all_adc, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
target_long src1, src2;
src1 = CC_SRC;
src2 = CC_DST - CC_SRC - 1;
cf = (DATA_TYPE)CC_DST <= (DATA_TYPE)src1;
pf = parity_table[(uint8_t)CC_DST];
af = (CC_DST ^ src1 ^ src2) & 0x10;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = lshift((src1 ^ src2 ^ -1) & (src1 ^ CC_DST), 12 - DATA_BITS) & CC_O;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_c_adc, SUFFIX)(void)
{
int cf;
target_long src1;
src1 = CC_SRC;
cf = (DATA_TYPE)CC_DST <= (DATA_TYPE)src1;
return cf;
}
static int glue(compute_all_sub, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
cf = (DATA_TYPE)src1 < (DATA_TYPE)src2;
pf = parity_table[(uint8_t)CC_DST];
af = (CC_DST ^ src1 ^ src2) & 0x10;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = lshift((src1 ^ src2) & (src1 ^ CC_DST), 12 - DATA_BITS) & CC_O;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_c_sub, SUFFIX)(void)
{
int cf;
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
cf = (DATA_TYPE)src1 < (DATA_TYPE)src2;
return cf;
}
static int glue(compute_all_sbb, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
target_long src1, src2;
src1 = CC_DST + CC_SRC + 1;
src2 = CC_SRC;
cf = (DATA_TYPE)src1 <= (DATA_TYPE)src2;
pf = parity_table[(uint8_t)CC_DST];
af = (CC_DST ^ src1 ^ src2) & 0x10;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = lshift((src1 ^ src2) & (src1 ^ CC_DST), 12 - DATA_BITS) & CC_O;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_c_sbb, SUFFIX)(void)
{
int cf;
target_long src1, src2;
src1 = CC_DST + CC_SRC + 1;
src2 = CC_SRC;
cf = (DATA_TYPE)src1 <= (DATA_TYPE)src2;
return cf;
}
static int glue(compute_all_logic, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
cf = 0;
pf = parity_table[(uint8_t)CC_DST];
af = 0;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = 0;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_c_logic, SUFFIX)(void)
{
return 0;
}
static int glue(compute_all_inc, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
target_long src1, src2;
src1 = CC_DST - 1;
src2 = 1;
cf = CC_SRC;
pf = parity_table[(uint8_t)CC_DST];
af = (CC_DST ^ src1 ^ src2) & 0x10;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = ((CC_DST & DATA_MASK) == SIGN_MASK) << 11;
return cf | pf | af | zf | sf | of;
}
#if DATA_BITS == 32
static int glue(compute_c_inc, SUFFIX)(void)
{
return CC_SRC;
}
#endif
static int glue(compute_all_dec, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
target_long src1, src2;
src1 = CC_DST + 1;
src2 = 1;
cf = CC_SRC;
pf = parity_table[(uint8_t)CC_DST];
af = (CC_DST ^ src1 ^ src2) & 0x10;
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = ((CC_DST & DATA_MASK) == ((target_ulong)SIGN_MASK - 1)) << 11;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_all_shl, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
cf = (CC_SRC >> (DATA_BITS - 1)) & CC_C;
pf = parity_table[(uint8_t)CC_DST];
af = 0; /* undefined */
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
/* of is defined if shift count == 1 */
of = lshift(CC_SRC ^ CC_DST, 12 - DATA_BITS) & CC_O;
return cf | pf | af | zf | sf | of;
}
static int glue(compute_c_shl, SUFFIX)(void)
{
return (CC_SRC >> (DATA_BITS - 1)) & CC_C;
}
#if DATA_BITS == 32
static int glue(compute_c_sar, SUFFIX)(void)
{
return CC_SRC & 1;
}
#endif
static int glue(compute_all_sar, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
cf = CC_SRC & 1;
pf = parity_table[(uint8_t)CC_DST];
af = 0; /* undefined */
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
/* of is defined if shift count == 1 */
of = lshift(CC_SRC ^ CC_DST, 12 - DATA_BITS) & CC_O;
return cf | pf | af | zf | sf | of;
}
#if DATA_BITS == 32
static int glue(compute_c_mul, SUFFIX)(void)
{
int cf;
cf = (CC_SRC != 0);
return cf;
}
#endif
/* NOTE: we compute the flags like the P4. On olders CPUs, only OF and
CF are modified and it is slower to do that. */
static int glue(compute_all_mul, SUFFIX)(void)
{
int cf, pf, af, zf, sf, of;
cf = (CC_SRC != 0);
pf = parity_table[(uint8_t)CC_DST];
af = 0; /* undefined */
zf = ((DATA_TYPE)CC_DST == 0) << 6;
sf = lshift(CC_DST, 8 - DATA_BITS) & 0x80;
of = cf << 11;
return cf | pf | af | zf | sf | of;
}
/* various optimized jumps cases */
void OPPROTO glue(op_jb_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
if ((DATA_TYPE)src1 < (DATA_TYPE)src2)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jz_sub, SUFFIX)(void)
{
if ((DATA_TYPE)CC_DST == 0)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jnz_sub, SUFFIX)(void)
{
if ((DATA_TYPE)CC_DST != 0)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jbe_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
if ((DATA_TYPE)src1 <= (DATA_TYPE)src2)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_js_sub, SUFFIX)(void)
{
if (CC_DST & SIGN_MASK)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jl_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
if ((DATA_STYPE)src1 < (DATA_STYPE)src2)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jle_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
if ((DATA_STYPE)src1 <= (DATA_STYPE)src2)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
/* oldies */
#if DATA_BITS >= 16
void OPPROTO glue(op_loopnz, SUFFIX)(void)
{
if ((DATA_TYPE)ECX != 0 && !(T0 & CC_Z))
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_loopz, SUFFIX)(void)
{
if ((DATA_TYPE)ECX != 0 && (T0 & CC_Z))
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jz_ecx, SUFFIX)(void)
{
if ((DATA_TYPE)ECX == 0)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
void OPPROTO glue(op_jnz_ecx, SUFFIX)(void)
{
if ((DATA_TYPE)ECX != 0)
GOTO_LABEL_PARAM(1);
FORCE_RET();
}
#endif
/* various optimized set cases */
void OPPROTO glue(op_setb_T0_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
T0 = ((DATA_TYPE)src1 < (DATA_TYPE)src2);
}
void OPPROTO glue(op_setz_T0_sub, SUFFIX)(void)
{
T0 = ((DATA_TYPE)CC_DST == 0);
}
void OPPROTO glue(op_setbe_T0_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
T0 = ((DATA_TYPE)src1 <= (DATA_TYPE)src2);
}
void OPPROTO glue(op_sets_T0_sub, SUFFIX)(void)
{
T0 = lshift(CC_DST, -(DATA_BITS - 1)) & 1;
}
void OPPROTO glue(op_setl_T0_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
T0 = ((DATA_STYPE)src1 < (DATA_STYPE)src2);
}
void OPPROTO glue(op_setle_T0_sub, SUFFIX)(void)
{
target_long src1, src2;
src1 = CC_DST + CC_SRC;
src2 = CC_SRC;
T0 = ((DATA_STYPE)src1 <= (DATA_STYPE)src2);
}
/* shifts */
void OPPROTO glue(glue(op_shl, SUFFIX), _T0_T1)(void)
{
int count;
count = T1 & SHIFT1_MASK;
T0 = T0 << count;
FORCE_RET();
}
void OPPROTO glue(glue(op_shr, SUFFIX), _T0_T1)(void)
{
int count;
count = T1 & SHIFT1_MASK;
T0 &= DATA_MASK;
T0 = T0 >> count;
FORCE_RET();
}
void OPPROTO glue(glue(op_sar, SUFFIX), _T0_T1)(void)
{
int count;
target_long src;
count = T1 & SHIFT1_MASK;
src = (DATA_STYPE)T0;
T0 = src >> count;
FORCE_RET();
}
#undef MEM_WRITE
#include "ops_template_mem.h"
#define MEM_WRITE 0
#include "ops_template_mem.h"
#if !defined(CONFIG_USER_ONLY)
#define MEM_WRITE 1
#include "ops_template_mem.h"
#define MEM_WRITE 2
#include "ops_template_mem.h"
#endif
/* bit operations */
#if DATA_BITS >= 16
void OPPROTO glue(glue(op_bt, SUFFIX), _T0_T1_cc)(void)
{
int count;
count = T1 & SHIFT_MASK;
CC_SRC = T0 >> count;
}
void OPPROTO glue(glue(op_bts, SUFFIX), _T0_T1_cc)(void)
{
int count;
count = T1 & SHIFT_MASK;
T1 = T0 >> count;
T0 |= (((target_long)1) << count);
}
void OPPROTO glue(glue(op_btr, SUFFIX), _T0_T1_cc)(void)
{
int count;
count = T1 & SHIFT_MASK;
T1 = T0 >> count;
T0 &= ~(((target_long)1) << count);
}
void OPPROTO glue(glue(op_btc, SUFFIX), _T0_T1_cc)(void)
{
int count;
count = T1 & SHIFT_MASK;
T1 = T0 >> count;
T0 ^= (((target_long)1) << count);
}
void OPPROTO glue(glue(op_add_bit, SUFFIX), _A0_T1)(void)
{
A0 += ((DATA_STYPE)T1 >> (3 + SHIFT)) << SHIFT;
}
void OPPROTO glue(glue(op_bsf, SUFFIX), _T0_cc)(void)
{
int count;
target_long res;
res = T0 & DATA_MASK;
if (res != 0) {
count = 0;
while ((res & 1) == 0) {
count++;
res >>= 1;
}
T1 = count;
CC_DST = 1; /* ZF = 0 */
} else {
CC_DST = 0; /* ZF = 1 */
}
FORCE_RET();
}
void OPPROTO glue(glue(op_bsr, SUFFIX), _T0_cc)(void)
{
int count;
target_long res;
res = T0 & DATA_MASK;
if (res != 0) {
count = DATA_BITS - 1;
while ((res & SIGN_MASK) == 0) {
count--;
res <<= 1;
}
T1 = count;
CC_DST = 1; /* ZF = 0 */
} else {
CC_DST = 0; /* ZF = 1 */
}
FORCE_RET();
}
#endif
#if DATA_BITS == 32
void OPPROTO op_update_bt_cc(void)
{
CC_SRC = T1;
}
#endif
/* string operations */
void OPPROTO glue(op_movl_T0_Dshift, SUFFIX)(void)
{
T0 = DF << SHIFT;
}
/* port I/O */
#if DATA_BITS <= 32
void OPPROTO glue(glue(op_out, SUFFIX), _T0_T1)(void)
{
glue(cpu_out, SUFFIX)(env, T0, T1 & DATA_MASK);
}
void OPPROTO glue(glue(op_in, SUFFIX), _T0_T1)(void)
{
T1 = glue(cpu_in, SUFFIX)(env, T0);
}
void OPPROTO glue(glue(op_in, SUFFIX), _DX_T0)(void)
{
T0 = glue(cpu_in, SUFFIX)(env, EDX & 0xffff);
}
void OPPROTO glue(glue(op_out, SUFFIX), _DX_T0)(void)
{
glue(cpu_out, SUFFIX)(env, EDX & 0xffff, T0);
}
void OPPROTO glue(glue(op_check_io, SUFFIX), _T0)(void)
{
glue(glue(check_io, SUFFIX), _T0)();
}
void OPPROTO glue(glue(op_check_io, SUFFIX), _DX)(void)
{
glue(glue(check_io, SUFFIX), _DX)();
}
#endif
#undef DATA_BITS
#undef SHIFT_MASK
#undef SHIFT1_MASK
#undef SIGN_MASK
#undef DATA_TYPE
#undef DATA_STYPE
#undef DATA_MASK
#undef SUFFIX
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