qemu/target/arm/neon_helper.c
Alex Bennée 24f91e81b6 target/*/cpu.h: remove softfloat.h
As cpu.h is another typically widely included file which doesn't need
full access to the softfloat API we can remove the includes from here
as well. Where they do need types it's typically for float_status and
the rounding modes so we move that to softfloat-types.h as well.

As a result of not having softfloat in every cpu.h call we now need to
add it to various helpers that do need the full softfloat.h
definitions.

Signed-off-by: Alex Bennée <alex.bennee@linaro.org>
Reviewed-by: Philippe Mathieu-Daudé <f4bug@amsat.org>
Reviewed-by: Richard Henderson <richard.henderson@linaro.org>
[For PPC parts]
Acked-by: David Gibson <david@gibson.dropbear.id.au>
2018-02-21 10:20:24 +00:00

2258 lines
57 KiB
C

/*
* ARM NEON vector operations.
*
* Copyright (c) 2007, 2008 CodeSourcery.
* Written by Paul Brook
*
* This code is licensed under the GNU GPL v2.
*/
#include "qemu/osdep.h"
#include "cpu.h"
#include "exec/exec-all.h"
#include "exec/helper-proto.h"
#include "fpu/softfloat.h"
#define SIGNBIT (uint32_t)0x80000000
#define SIGNBIT64 ((uint64_t)1 << 63)
#define SET_QC() env->vfp.xregs[ARM_VFP_FPSCR] |= CPSR_Q
#define NEON_TYPE1(name, type) \
typedef struct \
{ \
type v1; \
} neon_##name;
#ifdef HOST_WORDS_BIGENDIAN
#define NEON_TYPE2(name, type) \
typedef struct \
{ \
type v2; \
type v1; \
} neon_##name;
#define NEON_TYPE4(name, type) \
typedef struct \
{ \
type v4; \
type v3; \
type v2; \
type v1; \
} neon_##name;
#else
#define NEON_TYPE2(name, type) \
typedef struct \
{ \
type v1; \
type v2; \
} neon_##name;
#define NEON_TYPE4(name, type) \
typedef struct \
{ \
type v1; \
type v2; \
type v3; \
type v4; \
} neon_##name;
#endif
NEON_TYPE4(s8, int8_t)
NEON_TYPE4(u8, uint8_t)
NEON_TYPE2(s16, int16_t)
NEON_TYPE2(u16, uint16_t)
NEON_TYPE1(s32, int32_t)
NEON_TYPE1(u32, uint32_t)
#undef NEON_TYPE4
#undef NEON_TYPE2
#undef NEON_TYPE1
/* Copy from a uint32_t to a vector structure type. */
#define NEON_UNPACK(vtype, dest, val) do { \
union { \
vtype v; \
uint32_t i; \
} conv_u; \
conv_u.i = (val); \
dest = conv_u.v; \
} while(0)
/* Copy from a vector structure type to a uint32_t. */
#define NEON_PACK(vtype, dest, val) do { \
union { \
vtype v; \
uint32_t i; \
} conv_u; \
conv_u.v = (val); \
dest = conv_u.i; \
} while(0)
#define NEON_DO1 \
NEON_FN(vdest.v1, vsrc1.v1, vsrc2.v1);
#define NEON_DO2 \
NEON_FN(vdest.v1, vsrc1.v1, vsrc2.v1); \
NEON_FN(vdest.v2, vsrc1.v2, vsrc2.v2);
#define NEON_DO4 \
NEON_FN(vdest.v1, vsrc1.v1, vsrc2.v1); \
NEON_FN(vdest.v2, vsrc1.v2, vsrc2.v2); \
NEON_FN(vdest.v3, vsrc1.v3, vsrc2.v3); \
NEON_FN(vdest.v4, vsrc1.v4, vsrc2.v4);
#define NEON_VOP_BODY(vtype, n) \
{ \
uint32_t res; \
vtype vsrc1; \
vtype vsrc2; \
vtype vdest; \
NEON_UNPACK(vtype, vsrc1, arg1); \
NEON_UNPACK(vtype, vsrc2, arg2); \
NEON_DO##n; \
NEON_PACK(vtype, res, vdest); \
return res; \
}
#define NEON_VOP(name, vtype, n) \
uint32_t HELPER(glue(neon_,name))(uint32_t arg1, uint32_t arg2) \
NEON_VOP_BODY(vtype, n)
#define NEON_VOP_ENV(name, vtype, n) \
uint32_t HELPER(glue(neon_,name))(CPUARMState *env, uint32_t arg1, uint32_t arg2) \
NEON_VOP_BODY(vtype, n)
/* Pairwise operations. */
/* For 32-bit elements each segment only contains a single element, so
the elementwise and pairwise operations are the same. */
#define NEON_PDO2 \
NEON_FN(vdest.v1, vsrc1.v1, vsrc1.v2); \
NEON_FN(vdest.v2, vsrc2.v1, vsrc2.v2);
#define NEON_PDO4 \
NEON_FN(vdest.v1, vsrc1.v1, vsrc1.v2); \
NEON_FN(vdest.v2, vsrc1.v3, vsrc1.v4); \
NEON_FN(vdest.v3, vsrc2.v1, vsrc2.v2); \
NEON_FN(vdest.v4, vsrc2.v3, vsrc2.v4); \
#define NEON_POP(name, vtype, n) \
uint32_t HELPER(glue(neon_,name))(uint32_t arg1, uint32_t arg2) \
{ \
uint32_t res; \
vtype vsrc1; \
vtype vsrc2; \
vtype vdest; \
NEON_UNPACK(vtype, vsrc1, arg1); \
NEON_UNPACK(vtype, vsrc2, arg2); \
NEON_PDO##n; \
NEON_PACK(vtype, res, vdest); \
return res; \
}
/* Unary operators. */
#define NEON_VOP1(name, vtype, n) \
uint32_t HELPER(glue(neon_,name))(uint32_t arg) \
{ \
vtype vsrc1; \
vtype vdest; \
NEON_UNPACK(vtype, vsrc1, arg); \
NEON_DO##n; \
NEON_PACK(vtype, arg, vdest); \
return arg; \
}
#define NEON_USAT(dest, src1, src2, type) do { \
uint32_t tmp = (uint32_t)src1 + (uint32_t)src2; \
if (tmp != (type)tmp) { \
SET_QC(); \
dest = ~0; \
} else { \
dest = tmp; \
}} while(0)
#define NEON_FN(dest, src1, src2) NEON_USAT(dest, src1, src2, uint8_t)
NEON_VOP_ENV(qadd_u8, neon_u8, 4)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) NEON_USAT(dest, src1, src2, uint16_t)
NEON_VOP_ENV(qadd_u16, neon_u16, 2)
#undef NEON_FN
#undef NEON_USAT
uint32_t HELPER(neon_qadd_u32)(CPUARMState *env, uint32_t a, uint32_t b)
{
uint32_t res = a + b;
if (res < a) {
SET_QC();
res = ~0;
}
return res;
}
uint64_t HELPER(neon_qadd_u64)(CPUARMState *env, uint64_t src1, uint64_t src2)
{
uint64_t res;
res = src1 + src2;
if (res < src1) {
SET_QC();
res = ~(uint64_t)0;
}
return res;
}
#define NEON_SSAT(dest, src1, src2, type) do { \
int32_t tmp = (uint32_t)src1 + (uint32_t)src2; \
if (tmp != (type)tmp) { \
SET_QC(); \
if (src2 > 0) { \
tmp = (1 << (sizeof(type) * 8 - 1)) - 1; \
} else { \
tmp = 1 << (sizeof(type) * 8 - 1); \
} \
} \
dest = tmp; \
} while(0)
#define NEON_FN(dest, src1, src2) NEON_SSAT(dest, src1, src2, int8_t)
NEON_VOP_ENV(qadd_s8, neon_s8, 4)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) NEON_SSAT(dest, src1, src2, int16_t)
NEON_VOP_ENV(qadd_s16, neon_s16, 2)
#undef NEON_FN
#undef NEON_SSAT
uint32_t HELPER(neon_qadd_s32)(CPUARMState *env, uint32_t a, uint32_t b)
{
uint32_t res = a + b;
if (((res ^ a) & SIGNBIT) && !((a ^ b) & SIGNBIT)) {
SET_QC();
res = ~(((int32_t)a >> 31) ^ SIGNBIT);
}
return res;
}
uint64_t HELPER(neon_qadd_s64)(CPUARMState *env, uint64_t src1, uint64_t src2)
{
uint64_t res;
res = src1 + src2;
if (((res ^ src1) & SIGNBIT64) && !((src1 ^ src2) & SIGNBIT64)) {
SET_QC();
res = ((int64_t)src1 >> 63) ^ ~SIGNBIT64;
}
return res;
}
/* Unsigned saturating accumulate of signed value
*
* Op1/Rn is treated as signed
* Op2/Rd is treated as unsigned
*
* Explicit casting is used to ensure the correct sign extension of
* inputs. The result is treated as a unsigned value and saturated as such.
*
* We use a macro for the 8/16 bit cases which expects signed integers of va,
* vb, and vr for interim calculation and an unsigned 32 bit result value r.
*/
#define USATACC(bits, shift) \
do { \
va = sextract32(a, shift, bits); \
vb = extract32(b, shift, bits); \
vr = va + vb; \
if (vr > UINT##bits##_MAX) { \
SET_QC(); \
vr = UINT##bits##_MAX; \
} else if (vr < 0) { \
SET_QC(); \
vr = 0; \
} \
r = deposit32(r, shift, bits, vr); \
} while (0)
uint32_t HELPER(neon_uqadd_s8)(CPUARMState *env, uint32_t a, uint32_t b)
{
int16_t va, vb, vr;
uint32_t r = 0;
USATACC(8, 0);
USATACC(8, 8);
USATACC(8, 16);
USATACC(8, 24);
return r;
}
uint32_t HELPER(neon_uqadd_s16)(CPUARMState *env, uint32_t a, uint32_t b)
{
int32_t va, vb, vr;
uint64_t r = 0;
USATACC(16, 0);
USATACC(16, 16);
return r;
}
#undef USATACC
uint32_t HELPER(neon_uqadd_s32)(CPUARMState *env, uint32_t a, uint32_t b)
{
int64_t va = (int32_t)a;
int64_t vb = (uint32_t)b;
int64_t vr = va + vb;
if (vr > UINT32_MAX) {
SET_QC();
vr = UINT32_MAX;
} else if (vr < 0) {
SET_QC();
vr = 0;
}
return vr;
}
uint64_t HELPER(neon_uqadd_s64)(CPUARMState *env, uint64_t a, uint64_t b)
{
uint64_t res;
res = a + b;
/* We only need to look at the pattern of SIGN bits to detect
* +ve/-ve saturation
*/
if (~a & b & ~res & SIGNBIT64) {
SET_QC();
res = UINT64_MAX;
} else if (a & ~b & res & SIGNBIT64) {
SET_QC();
res = 0;
}
return res;
}
/* Signed saturating accumulate of unsigned value
*
* Op1/Rn is treated as unsigned
* Op2/Rd is treated as signed
*
* The result is treated as a signed value and saturated as such
*
* We use a macro for the 8/16 bit cases which expects signed integers of va,
* vb, and vr for interim calculation and an unsigned 32 bit result value r.
*/
#define SSATACC(bits, shift) \
do { \
va = extract32(a, shift, bits); \
vb = sextract32(b, shift, bits); \
vr = va + vb; \
if (vr > INT##bits##_MAX) { \
SET_QC(); \
vr = INT##bits##_MAX; \
} else if (vr < INT##bits##_MIN) { \
SET_QC(); \
vr = INT##bits##_MIN; \
} \
r = deposit32(r, shift, bits, vr); \
} while (0)
uint32_t HELPER(neon_sqadd_u8)(CPUARMState *env, uint32_t a, uint32_t b)
{
int16_t va, vb, vr;
uint32_t r = 0;
SSATACC(8, 0);
SSATACC(8, 8);
SSATACC(8, 16);
SSATACC(8, 24);
return r;
}
uint32_t HELPER(neon_sqadd_u16)(CPUARMState *env, uint32_t a, uint32_t b)
{
int32_t va, vb, vr;
uint32_t r = 0;
SSATACC(16, 0);
SSATACC(16, 16);
return r;
}
#undef SSATACC
uint32_t HELPER(neon_sqadd_u32)(CPUARMState *env, uint32_t a, uint32_t b)
{
int64_t res;
int64_t op1 = (uint32_t)a;
int64_t op2 = (int32_t)b;
res = op1 + op2;
if (res > INT32_MAX) {
SET_QC();
res = INT32_MAX;
} else if (res < INT32_MIN) {
SET_QC();
res = INT32_MIN;
}
return res;
}
uint64_t HELPER(neon_sqadd_u64)(CPUARMState *env, uint64_t a, uint64_t b)
{
uint64_t res;
res = a + b;
/* We only need to look at the pattern of SIGN bits to detect an overflow */
if (((a & res)
| (~b & res)
| (a & ~b)) & SIGNBIT64) {
SET_QC();
res = INT64_MAX;
}
return res;
}
#define NEON_USAT(dest, src1, src2, type) do { \
uint32_t tmp = (uint32_t)src1 - (uint32_t)src2; \
if (tmp != (type)tmp) { \
SET_QC(); \
dest = 0; \
} else { \
dest = tmp; \
}} while(0)
#define NEON_FN(dest, src1, src2) NEON_USAT(dest, src1, src2, uint8_t)
NEON_VOP_ENV(qsub_u8, neon_u8, 4)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) NEON_USAT(dest, src1, src2, uint16_t)
NEON_VOP_ENV(qsub_u16, neon_u16, 2)
#undef NEON_FN
#undef NEON_USAT
uint32_t HELPER(neon_qsub_u32)(CPUARMState *env, uint32_t a, uint32_t b)
{
uint32_t res = a - b;
if (res > a) {
SET_QC();
res = 0;
}
return res;
}
uint64_t HELPER(neon_qsub_u64)(CPUARMState *env, uint64_t src1, uint64_t src2)
{
uint64_t res;
if (src1 < src2) {
SET_QC();
res = 0;
} else {
res = src1 - src2;
}
return res;
}
#define NEON_SSAT(dest, src1, src2, type) do { \
int32_t tmp = (uint32_t)src1 - (uint32_t)src2; \
if (tmp != (type)tmp) { \
SET_QC(); \
if (src2 < 0) { \
tmp = (1 << (sizeof(type) * 8 - 1)) - 1; \
} else { \
tmp = 1 << (sizeof(type) * 8 - 1); \
} \
} \
dest = tmp; \
} while(0)
#define NEON_FN(dest, src1, src2) NEON_SSAT(dest, src1, src2, int8_t)
NEON_VOP_ENV(qsub_s8, neon_s8, 4)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) NEON_SSAT(dest, src1, src2, int16_t)
NEON_VOP_ENV(qsub_s16, neon_s16, 2)
#undef NEON_FN
#undef NEON_SSAT
uint32_t HELPER(neon_qsub_s32)(CPUARMState *env, uint32_t a, uint32_t b)
{
uint32_t res = a - b;
if (((res ^ a) & SIGNBIT) && ((a ^ b) & SIGNBIT)) {
SET_QC();
res = ~(((int32_t)a >> 31) ^ SIGNBIT);
}
return res;
}
uint64_t HELPER(neon_qsub_s64)(CPUARMState *env, uint64_t src1, uint64_t src2)
{
uint64_t res;
res = src1 - src2;
if (((res ^ src1) & SIGNBIT64) && ((src1 ^ src2) & SIGNBIT64)) {
SET_QC();
res = ((int64_t)src1 >> 63) ^ ~SIGNBIT64;
}
return res;
}
#define NEON_FN(dest, src1, src2) dest = (src1 + src2) >> 1
NEON_VOP(hadd_s8, neon_s8, 4)
NEON_VOP(hadd_u8, neon_u8, 4)
NEON_VOP(hadd_s16, neon_s16, 2)
NEON_VOP(hadd_u16, neon_u16, 2)
#undef NEON_FN
int32_t HELPER(neon_hadd_s32)(int32_t src1, int32_t src2)
{
int32_t dest;
dest = (src1 >> 1) + (src2 >> 1);
if (src1 & src2 & 1)
dest++;
return dest;
}
uint32_t HELPER(neon_hadd_u32)(uint32_t src1, uint32_t src2)
{
uint32_t dest;
dest = (src1 >> 1) + (src2 >> 1);
if (src1 & src2 & 1)
dest++;
return dest;
}
#define NEON_FN(dest, src1, src2) dest = (src1 + src2 + 1) >> 1
NEON_VOP(rhadd_s8, neon_s8, 4)
NEON_VOP(rhadd_u8, neon_u8, 4)
NEON_VOP(rhadd_s16, neon_s16, 2)
NEON_VOP(rhadd_u16, neon_u16, 2)
#undef NEON_FN
int32_t HELPER(neon_rhadd_s32)(int32_t src1, int32_t src2)
{
int32_t dest;
dest = (src1 >> 1) + (src2 >> 1);
if ((src1 | src2) & 1)
dest++;
return dest;
}
uint32_t HELPER(neon_rhadd_u32)(uint32_t src1, uint32_t src2)
{
uint32_t dest;
dest = (src1 >> 1) + (src2 >> 1);
if ((src1 | src2) & 1)
dest++;
return dest;
}
#define NEON_FN(dest, src1, src2) dest = (src1 - src2) >> 1
NEON_VOP(hsub_s8, neon_s8, 4)
NEON_VOP(hsub_u8, neon_u8, 4)
NEON_VOP(hsub_s16, neon_s16, 2)
NEON_VOP(hsub_u16, neon_u16, 2)
#undef NEON_FN
int32_t HELPER(neon_hsub_s32)(int32_t src1, int32_t src2)
{
int32_t dest;
dest = (src1 >> 1) - (src2 >> 1);
if ((~src1) & src2 & 1)
dest--;
return dest;
}
uint32_t HELPER(neon_hsub_u32)(uint32_t src1, uint32_t src2)
{
uint32_t dest;
dest = (src1 >> 1) - (src2 >> 1);
if ((~src1) & src2 & 1)
dest--;
return dest;
}
#define NEON_FN(dest, src1, src2) dest = (src1 > src2) ? ~0 : 0
NEON_VOP(cgt_s8, neon_s8, 4)
NEON_VOP(cgt_u8, neon_u8, 4)
NEON_VOP(cgt_s16, neon_s16, 2)
NEON_VOP(cgt_u16, neon_u16, 2)
NEON_VOP(cgt_s32, neon_s32, 1)
NEON_VOP(cgt_u32, neon_u32, 1)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) dest = (src1 >= src2) ? ~0 : 0
NEON_VOP(cge_s8, neon_s8, 4)
NEON_VOP(cge_u8, neon_u8, 4)
NEON_VOP(cge_s16, neon_s16, 2)
NEON_VOP(cge_u16, neon_u16, 2)
NEON_VOP(cge_s32, neon_s32, 1)
NEON_VOP(cge_u32, neon_u32, 1)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) dest = (src1 < src2) ? src1 : src2
NEON_VOP(min_s8, neon_s8, 4)
NEON_VOP(min_u8, neon_u8, 4)
NEON_VOP(min_s16, neon_s16, 2)
NEON_VOP(min_u16, neon_u16, 2)
NEON_VOP(min_s32, neon_s32, 1)
NEON_VOP(min_u32, neon_u32, 1)
NEON_POP(pmin_s8, neon_s8, 4)
NEON_POP(pmin_u8, neon_u8, 4)
NEON_POP(pmin_s16, neon_s16, 2)
NEON_POP(pmin_u16, neon_u16, 2)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) dest = (src1 > src2) ? src1 : src2
NEON_VOP(max_s8, neon_s8, 4)
NEON_VOP(max_u8, neon_u8, 4)
NEON_VOP(max_s16, neon_s16, 2)
NEON_VOP(max_u16, neon_u16, 2)
NEON_VOP(max_s32, neon_s32, 1)
NEON_VOP(max_u32, neon_u32, 1)
NEON_POP(pmax_s8, neon_s8, 4)
NEON_POP(pmax_u8, neon_u8, 4)
NEON_POP(pmax_s16, neon_s16, 2)
NEON_POP(pmax_u16, neon_u16, 2)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) \
dest = (src1 > src2) ? (src1 - src2) : (src2 - src1)
NEON_VOP(abd_s8, neon_s8, 4)
NEON_VOP(abd_u8, neon_u8, 4)
NEON_VOP(abd_s16, neon_s16, 2)
NEON_VOP(abd_u16, neon_u16, 2)
NEON_VOP(abd_s32, neon_s32, 1)
NEON_VOP(abd_u32, neon_u32, 1)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8 || \
tmp <= -(ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp < 0) { \
dest = src1 >> -tmp; \
} else { \
dest = src1 << tmp; \
}} while (0)
NEON_VOP(shl_u8, neon_u8, 4)
NEON_VOP(shl_u16, neon_u16, 2)
NEON_VOP(shl_u32, neon_u32, 1)
#undef NEON_FN
uint64_t HELPER(neon_shl_u64)(uint64_t val, uint64_t shiftop)
{
int8_t shift = (int8_t)shiftop;
if (shift >= 64 || shift <= -64) {
val = 0;
} else if (shift < 0) {
val >>= -shift;
} else {
val <<= shift;
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp <= -(ssize_t)sizeof(src1) * 8) { \
dest = src1 >> (sizeof(src1) * 8 - 1); \
} else if (tmp < 0) { \
dest = src1 >> -tmp; \
} else { \
dest = src1 << tmp; \
}} while (0)
NEON_VOP(shl_s8, neon_s8, 4)
NEON_VOP(shl_s16, neon_s16, 2)
NEON_VOP(shl_s32, neon_s32, 1)
#undef NEON_FN
uint64_t HELPER(neon_shl_s64)(uint64_t valop, uint64_t shiftop)
{
int8_t shift = (int8_t)shiftop;
int64_t val = valop;
if (shift >= 64) {
val = 0;
} else if (shift <= -64) {
val >>= 63;
} else if (shift < 0) {
val >>= -shift;
} else {
val <<= shift;
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if ((tmp >= (ssize_t)sizeof(src1) * 8) \
|| (tmp <= -(ssize_t)sizeof(src1) * 8)) { \
dest = 0; \
} else if (tmp < 0) { \
dest = (src1 + (1 << (-1 - tmp))) >> -tmp; \
} else { \
dest = src1 << tmp; \
}} while (0)
NEON_VOP(rshl_s8, neon_s8, 4)
NEON_VOP(rshl_s16, neon_s16, 2)
#undef NEON_FN
/* The addition of the rounding constant may overflow, so we use an
* intermediate 64 bit accumulator. */
uint32_t HELPER(neon_rshl_s32)(uint32_t valop, uint32_t shiftop)
{
int32_t dest;
int32_t val = (int32_t)valop;
int8_t shift = (int8_t)shiftop;
if ((shift >= 32) || (shift <= -32)) {
dest = 0;
} else if (shift < 0) {
int64_t big_dest = ((int64_t)val + (1 << (-1 - shift)));
dest = big_dest >> -shift;
} else {
dest = val << shift;
}
return dest;
}
/* Handling addition overflow with 64 bit input values is more
* tricky than with 32 bit values. */
uint64_t HELPER(neon_rshl_s64)(uint64_t valop, uint64_t shiftop)
{
int8_t shift = (int8_t)shiftop;
int64_t val = valop;
if ((shift >= 64) || (shift <= -64)) {
val = 0;
} else if (shift < 0) {
val >>= (-shift - 1);
if (val == INT64_MAX) {
/* In this case, it means that the rounding constant is 1,
* and the addition would overflow. Return the actual
* result directly. */
val = 0x4000000000000000LL;
} else {
val++;
val >>= 1;
}
} else {
val <<= shift;
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8 || \
tmp < -(ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp == -(ssize_t)sizeof(src1) * 8) { \
dest = src1 >> (-tmp - 1); \
} else if (tmp < 0) { \
dest = (src1 + (1 << (-1 - tmp))) >> -tmp; \
} else { \
dest = src1 << tmp; \
}} while (0)
NEON_VOP(rshl_u8, neon_u8, 4)
NEON_VOP(rshl_u16, neon_u16, 2)
#undef NEON_FN
/* The addition of the rounding constant may overflow, so we use an
* intermediate 64 bit accumulator. */
uint32_t HELPER(neon_rshl_u32)(uint32_t val, uint32_t shiftop)
{
uint32_t dest;
int8_t shift = (int8_t)shiftop;
if (shift >= 32 || shift < -32) {
dest = 0;
} else if (shift == -32) {
dest = val >> 31;
} else if (shift < 0) {
uint64_t big_dest = ((uint64_t)val + (1 << (-1 - shift)));
dest = big_dest >> -shift;
} else {
dest = val << shift;
}
return dest;
}
/* Handling addition overflow with 64 bit input values is more
* tricky than with 32 bit values. */
uint64_t HELPER(neon_rshl_u64)(uint64_t val, uint64_t shiftop)
{
int8_t shift = (uint8_t)shiftop;
if (shift >= 64 || shift < -64) {
val = 0;
} else if (shift == -64) {
/* Rounding a 1-bit result just preserves that bit. */
val >>= 63;
} else if (shift < 0) {
val >>= (-shift - 1);
if (val == UINT64_MAX) {
/* In this case, it means that the rounding constant is 1,
* and the addition would overflow. Return the actual
* result directly. */
val = 0x8000000000000000ULL;
} else {
val++;
val >>= 1;
}
} else {
val <<= shift;
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8) { \
if (src1) { \
SET_QC(); \
dest = ~0; \
} else { \
dest = 0; \
} \
} else if (tmp <= -(ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp < 0) { \
dest = src1 >> -tmp; \
} else { \
dest = src1 << tmp; \
if ((dest >> tmp) != src1) { \
SET_QC(); \
dest = ~0; \
} \
}} while (0)
NEON_VOP_ENV(qshl_u8, neon_u8, 4)
NEON_VOP_ENV(qshl_u16, neon_u16, 2)
NEON_VOP_ENV(qshl_u32, neon_u32, 1)
#undef NEON_FN
uint64_t HELPER(neon_qshl_u64)(CPUARMState *env, uint64_t val, uint64_t shiftop)
{
int8_t shift = (int8_t)shiftop;
if (shift >= 64) {
if (val) {
val = ~(uint64_t)0;
SET_QC();
}
} else if (shift <= -64) {
val = 0;
} else if (shift < 0) {
val >>= -shift;
} else {
uint64_t tmp = val;
val <<= shift;
if ((val >> shift) != tmp) {
SET_QC();
val = ~(uint64_t)0;
}
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8) { \
if (src1) { \
SET_QC(); \
dest = (uint32_t)(1 << (sizeof(src1) * 8 - 1)); \
if (src1 > 0) { \
dest--; \
} \
} else { \
dest = src1; \
} \
} else if (tmp <= -(ssize_t)sizeof(src1) * 8) { \
dest = src1 >> 31; \
} else if (tmp < 0) { \
dest = src1 >> -tmp; \
} else { \
dest = src1 << tmp; \
if ((dest >> tmp) != src1) { \
SET_QC(); \
dest = (uint32_t)(1 << (sizeof(src1) * 8 - 1)); \
if (src1 > 0) { \
dest--; \
} \
} \
}} while (0)
NEON_VOP_ENV(qshl_s8, neon_s8, 4)
NEON_VOP_ENV(qshl_s16, neon_s16, 2)
NEON_VOP_ENV(qshl_s32, neon_s32, 1)
#undef NEON_FN
uint64_t HELPER(neon_qshl_s64)(CPUARMState *env, uint64_t valop, uint64_t shiftop)
{
int8_t shift = (uint8_t)shiftop;
int64_t val = valop;
if (shift >= 64) {
if (val) {
SET_QC();
val = (val >> 63) ^ ~SIGNBIT64;
}
} else if (shift <= -64) {
val >>= 63;
} else if (shift < 0) {
val >>= -shift;
} else {
int64_t tmp = val;
val <<= shift;
if ((val >> shift) != tmp) {
SET_QC();
val = (tmp >> 63) ^ ~SIGNBIT64;
}
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
if (src1 & (1 << (sizeof(src1) * 8 - 1))) { \
SET_QC(); \
dest = 0; \
} else { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8) { \
if (src1) { \
SET_QC(); \
dest = ~0; \
} else { \
dest = 0; \
} \
} else if (tmp <= -(ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp < 0) { \
dest = src1 >> -tmp; \
} else { \
dest = src1 << tmp; \
if ((dest >> tmp) != src1) { \
SET_QC(); \
dest = ~0; \
} \
} \
}} while (0)
NEON_VOP_ENV(qshlu_s8, neon_u8, 4)
NEON_VOP_ENV(qshlu_s16, neon_u16, 2)
#undef NEON_FN
uint32_t HELPER(neon_qshlu_s32)(CPUARMState *env, uint32_t valop, uint32_t shiftop)
{
if ((int32_t)valop < 0) {
SET_QC();
return 0;
}
return helper_neon_qshl_u32(env, valop, shiftop);
}
uint64_t HELPER(neon_qshlu_s64)(CPUARMState *env, uint64_t valop, uint64_t shiftop)
{
if ((int64_t)valop < 0) {
SET_QC();
return 0;
}
return helper_neon_qshl_u64(env, valop, shiftop);
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8) { \
if (src1) { \
SET_QC(); \
dest = ~0; \
} else { \
dest = 0; \
} \
} else if (tmp < -(ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp == -(ssize_t)sizeof(src1) * 8) { \
dest = src1 >> (sizeof(src1) * 8 - 1); \
} else if (tmp < 0) { \
dest = (src1 + (1 << (-1 - tmp))) >> -tmp; \
} else { \
dest = src1 << tmp; \
if ((dest >> tmp) != src1) { \
SET_QC(); \
dest = ~0; \
} \
}} while (0)
NEON_VOP_ENV(qrshl_u8, neon_u8, 4)
NEON_VOP_ENV(qrshl_u16, neon_u16, 2)
#undef NEON_FN
/* The addition of the rounding constant may overflow, so we use an
* intermediate 64 bit accumulator. */
uint32_t HELPER(neon_qrshl_u32)(CPUARMState *env, uint32_t val, uint32_t shiftop)
{
uint32_t dest;
int8_t shift = (int8_t)shiftop;
if (shift >= 32) {
if (val) {
SET_QC();
dest = ~0;
} else {
dest = 0;
}
} else if (shift < -32) {
dest = 0;
} else if (shift == -32) {
dest = val >> 31;
} else if (shift < 0) {
uint64_t big_dest = ((uint64_t)val + (1 << (-1 - shift)));
dest = big_dest >> -shift;
} else {
dest = val << shift;
if ((dest >> shift) != val) {
SET_QC();
dest = ~0;
}
}
return dest;
}
/* Handling addition overflow with 64 bit input values is more
* tricky than with 32 bit values. */
uint64_t HELPER(neon_qrshl_u64)(CPUARMState *env, uint64_t val, uint64_t shiftop)
{
int8_t shift = (int8_t)shiftop;
if (shift >= 64) {
if (val) {
SET_QC();
val = ~0;
}
} else if (shift < -64) {
val = 0;
} else if (shift == -64) {
val >>= 63;
} else if (shift < 0) {
val >>= (-shift - 1);
if (val == UINT64_MAX) {
/* In this case, it means that the rounding constant is 1,
* and the addition would overflow. Return the actual
* result directly. */
val = 0x8000000000000000ULL;
} else {
val++;
val >>= 1;
}
} else { \
uint64_t tmp = val;
val <<= shift;
if ((val >> shift) != tmp) {
SET_QC();
val = ~0;
}
}
return val;
}
#define NEON_FN(dest, src1, src2) do { \
int8_t tmp; \
tmp = (int8_t)src2; \
if (tmp >= (ssize_t)sizeof(src1) * 8) { \
if (src1) { \
SET_QC(); \
dest = (typeof(dest))(1 << (sizeof(src1) * 8 - 1)); \
if (src1 > 0) { \
dest--; \
} \
} else { \
dest = 0; \
} \
} else if (tmp <= -(ssize_t)sizeof(src1) * 8) { \
dest = 0; \
} else if (tmp < 0) { \
dest = (src1 + (1 << (-1 - tmp))) >> -tmp; \
} else { \
dest = src1 << tmp; \
if ((dest >> tmp) != src1) { \
SET_QC(); \
dest = (uint32_t)(1 << (sizeof(src1) * 8 - 1)); \
if (src1 > 0) { \
dest--; \
} \
} \
}} while (0)
NEON_VOP_ENV(qrshl_s8, neon_s8, 4)
NEON_VOP_ENV(qrshl_s16, neon_s16, 2)
#undef NEON_FN
/* The addition of the rounding constant may overflow, so we use an
* intermediate 64 bit accumulator. */
uint32_t HELPER(neon_qrshl_s32)(CPUARMState *env, uint32_t valop, uint32_t shiftop)
{
int32_t dest;
int32_t val = (int32_t)valop;
int8_t shift = (int8_t)shiftop;
if (shift >= 32) {
if (val) {
SET_QC();
dest = (val >> 31) ^ ~SIGNBIT;
} else {
dest = 0;
}
} else if (shift <= -32) {
dest = 0;
} else if (shift < 0) {
int64_t big_dest = ((int64_t)val + (1 << (-1 - shift)));
dest = big_dest >> -shift;
} else {
dest = val << shift;
if ((dest >> shift) != val) {
SET_QC();
dest = (val >> 31) ^ ~SIGNBIT;
}
}
return dest;
}
/* Handling addition overflow with 64 bit input values is more
* tricky than with 32 bit values. */
uint64_t HELPER(neon_qrshl_s64)(CPUARMState *env, uint64_t valop, uint64_t shiftop)
{
int8_t shift = (uint8_t)shiftop;
int64_t val = valop;
if (shift >= 64) {
if (val) {
SET_QC();
val = (val >> 63) ^ ~SIGNBIT64;
}
} else if (shift <= -64) {
val = 0;
} else if (shift < 0) {
val >>= (-shift - 1);
if (val == INT64_MAX) {
/* In this case, it means that the rounding constant is 1,
* and the addition would overflow. Return the actual
* result directly. */
val = 0x4000000000000000ULL;
} else {
val++;
val >>= 1;
}
} else {
int64_t tmp = val;
val <<= shift;
if ((val >> shift) != tmp) {
SET_QC();
val = (tmp >> 63) ^ ~SIGNBIT64;
}
}
return val;
}
uint32_t HELPER(neon_add_u8)(uint32_t a, uint32_t b)
{
uint32_t mask;
mask = (a ^ b) & 0x80808080u;
a &= ~0x80808080u;
b &= ~0x80808080u;
return (a + b) ^ mask;
}
uint32_t HELPER(neon_add_u16)(uint32_t a, uint32_t b)
{
uint32_t mask;
mask = (a ^ b) & 0x80008000u;
a &= ~0x80008000u;
b &= ~0x80008000u;
return (a + b) ^ mask;
}
#define NEON_FN(dest, src1, src2) dest = src1 + src2
NEON_POP(padd_u8, neon_u8, 4)
NEON_POP(padd_u16, neon_u16, 2)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) dest = src1 - src2
NEON_VOP(sub_u8, neon_u8, 4)
NEON_VOP(sub_u16, neon_u16, 2)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) dest = src1 * src2
NEON_VOP(mul_u8, neon_u8, 4)
NEON_VOP(mul_u16, neon_u16, 2)
#undef NEON_FN
/* Polynomial multiplication is like integer multiplication except the
partial products are XORed, not added. */
uint32_t HELPER(neon_mul_p8)(uint32_t op1, uint32_t op2)
{
uint32_t mask;
uint32_t result;
result = 0;
while (op1) {
mask = 0;
if (op1 & 1)
mask |= 0xff;
if (op1 & (1 << 8))
mask |= (0xff << 8);
if (op1 & (1 << 16))
mask |= (0xff << 16);
if (op1 & (1 << 24))
mask |= (0xff << 24);
result ^= op2 & mask;
op1 = (op1 >> 1) & 0x7f7f7f7f;
op2 = (op2 << 1) & 0xfefefefe;
}
return result;
}
uint64_t HELPER(neon_mull_p8)(uint32_t op1, uint32_t op2)
{
uint64_t result = 0;
uint64_t mask;
uint64_t op2ex = op2;
op2ex = (op2ex & 0xff) |
((op2ex & 0xff00) << 8) |
((op2ex & 0xff0000) << 16) |
((op2ex & 0xff000000) << 24);
while (op1) {
mask = 0;
if (op1 & 1) {
mask |= 0xffff;
}
if (op1 & (1 << 8)) {
mask |= (0xffffU << 16);
}
if (op1 & (1 << 16)) {
mask |= (0xffffULL << 32);
}
if (op1 & (1 << 24)) {
mask |= (0xffffULL << 48);
}
result ^= op2ex & mask;
op1 = (op1 >> 1) & 0x7f7f7f7f;
op2ex <<= 1;
}
return result;
}
#define NEON_FN(dest, src1, src2) dest = (src1 & src2) ? -1 : 0
NEON_VOP(tst_u8, neon_u8, 4)
NEON_VOP(tst_u16, neon_u16, 2)
NEON_VOP(tst_u32, neon_u32, 1)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) dest = (src1 == src2) ? -1 : 0
NEON_VOP(ceq_u8, neon_u8, 4)
NEON_VOP(ceq_u16, neon_u16, 2)
NEON_VOP(ceq_u32, neon_u32, 1)
#undef NEON_FN
#define NEON_FN(dest, src, dummy) dest = (src < 0) ? -src : src
NEON_VOP1(abs_s8, neon_s8, 4)
NEON_VOP1(abs_s16, neon_s16, 2)
#undef NEON_FN
/* Count Leading Sign/Zero Bits. */
static inline int do_clz8(uint8_t x)
{
int n;
for (n = 8; x; n--)
x >>= 1;
return n;
}
static inline int do_clz16(uint16_t x)
{
int n;
for (n = 16; x; n--)
x >>= 1;
return n;
}
#define NEON_FN(dest, src, dummy) dest = do_clz8(src)
NEON_VOP1(clz_u8, neon_u8, 4)
#undef NEON_FN
#define NEON_FN(dest, src, dummy) dest = do_clz16(src)
NEON_VOP1(clz_u16, neon_u16, 2)
#undef NEON_FN
#define NEON_FN(dest, src, dummy) dest = do_clz8((src < 0) ? ~src : src) - 1
NEON_VOP1(cls_s8, neon_s8, 4)
#undef NEON_FN
#define NEON_FN(dest, src, dummy) dest = do_clz16((src < 0) ? ~src : src) - 1
NEON_VOP1(cls_s16, neon_s16, 2)
#undef NEON_FN
uint32_t HELPER(neon_cls_s32)(uint32_t x)
{
int count;
if ((int32_t)x < 0)
x = ~x;
for (count = 32; x; count--)
x = x >> 1;
return count - 1;
}
/* Bit count. */
uint32_t HELPER(neon_cnt_u8)(uint32_t x)
{
x = (x & 0x55555555) + ((x >> 1) & 0x55555555);
x = (x & 0x33333333) + ((x >> 2) & 0x33333333);
x = (x & 0x0f0f0f0f) + ((x >> 4) & 0x0f0f0f0f);
return x;
}
/* Reverse bits in each 8 bit word */
uint32_t HELPER(neon_rbit_u8)(uint32_t x)
{
x = ((x & 0xf0f0f0f0) >> 4)
| ((x & 0x0f0f0f0f) << 4);
x = ((x & 0x88888888) >> 3)
| ((x & 0x44444444) >> 1)
| ((x & 0x22222222) << 1)
| ((x & 0x11111111) << 3);
return x;
}
#define NEON_QDMULH16(dest, src1, src2, round) do { \
uint32_t tmp = (int32_t)(int16_t) src1 * (int16_t) src2; \
if ((tmp ^ (tmp << 1)) & SIGNBIT) { \
SET_QC(); \
tmp = (tmp >> 31) ^ ~SIGNBIT; \
} else { \
tmp <<= 1; \
} \
if (round) { \
int32_t old = tmp; \
tmp += 1 << 15; \
if ((int32_t)tmp < old) { \
SET_QC(); \
tmp = SIGNBIT - 1; \
} \
} \
dest = tmp >> 16; \
} while(0)
#define NEON_FN(dest, src1, src2) NEON_QDMULH16(dest, src1, src2, 0)
NEON_VOP_ENV(qdmulh_s16, neon_s16, 2)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) NEON_QDMULH16(dest, src1, src2, 1)
NEON_VOP_ENV(qrdmulh_s16, neon_s16, 2)
#undef NEON_FN
#undef NEON_QDMULH16
#define NEON_QDMULH32(dest, src1, src2, round) do { \
uint64_t tmp = (int64_t)(int32_t) src1 * (int32_t) src2; \
if ((tmp ^ (tmp << 1)) & SIGNBIT64) { \
SET_QC(); \
tmp = (tmp >> 63) ^ ~SIGNBIT64; \
} else { \
tmp <<= 1; \
} \
if (round) { \
int64_t old = tmp; \
tmp += (int64_t)1 << 31; \
if ((int64_t)tmp < old) { \
SET_QC(); \
tmp = SIGNBIT64 - 1; \
} \
} \
dest = tmp >> 32; \
} while(0)
#define NEON_FN(dest, src1, src2) NEON_QDMULH32(dest, src1, src2, 0)
NEON_VOP_ENV(qdmulh_s32, neon_s32, 1)
#undef NEON_FN
#define NEON_FN(dest, src1, src2) NEON_QDMULH32(dest, src1, src2, 1)
NEON_VOP_ENV(qrdmulh_s32, neon_s32, 1)
#undef NEON_FN
#undef NEON_QDMULH32
uint32_t HELPER(neon_narrow_u8)(uint64_t x)
{
return (x & 0xffu) | ((x >> 8) & 0xff00u) | ((x >> 16) & 0xff0000u)
| ((x >> 24) & 0xff000000u);
}
uint32_t HELPER(neon_narrow_u16)(uint64_t x)
{
return (x & 0xffffu) | ((x >> 16) & 0xffff0000u);
}
uint32_t HELPER(neon_narrow_high_u8)(uint64_t x)
{
return ((x >> 8) & 0xff) | ((x >> 16) & 0xff00)
| ((x >> 24) & 0xff0000) | ((x >> 32) & 0xff000000);
}
uint32_t HELPER(neon_narrow_high_u16)(uint64_t x)
{
return ((x >> 16) & 0xffff) | ((x >> 32) & 0xffff0000);
}
uint32_t HELPER(neon_narrow_round_high_u8)(uint64_t x)
{
x &= 0xff80ff80ff80ff80ull;
x += 0x0080008000800080ull;
return ((x >> 8) & 0xff) | ((x >> 16) & 0xff00)
| ((x >> 24) & 0xff0000) | ((x >> 32) & 0xff000000);
}
uint32_t HELPER(neon_narrow_round_high_u16)(uint64_t x)
{
x &= 0xffff8000ffff8000ull;
x += 0x0000800000008000ull;
return ((x >> 16) & 0xffff) | ((x >> 32) & 0xffff0000);
}
uint32_t HELPER(neon_unarrow_sat8)(CPUARMState *env, uint64_t x)
{
uint16_t s;
uint8_t d;
uint32_t res = 0;
#define SAT8(n) \
s = x >> n; \
if (s & 0x8000) { \
SET_QC(); \
} else { \
if (s > 0xff) { \
d = 0xff; \
SET_QC(); \
} else { \
d = s; \
} \
res |= (uint32_t)d << (n / 2); \
}
SAT8(0);
SAT8(16);
SAT8(32);
SAT8(48);
#undef SAT8
return res;
}
uint32_t HELPER(neon_narrow_sat_u8)(CPUARMState *env, uint64_t x)
{
uint16_t s;
uint8_t d;
uint32_t res = 0;
#define SAT8(n) \
s = x >> n; \
if (s > 0xff) { \
d = 0xff; \
SET_QC(); \
} else { \
d = s; \
} \
res |= (uint32_t)d << (n / 2);
SAT8(0);
SAT8(16);
SAT8(32);
SAT8(48);
#undef SAT8
return res;
}
uint32_t HELPER(neon_narrow_sat_s8)(CPUARMState *env, uint64_t x)
{
int16_t s;
uint8_t d;
uint32_t res = 0;
#define SAT8(n) \
s = x >> n; \
if (s != (int8_t)s) { \
d = (s >> 15) ^ 0x7f; \
SET_QC(); \
} else { \
d = s; \
} \
res |= (uint32_t)d << (n / 2);
SAT8(0);
SAT8(16);
SAT8(32);
SAT8(48);
#undef SAT8
return res;
}
uint32_t HELPER(neon_unarrow_sat16)(CPUARMState *env, uint64_t x)
{
uint32_t high;
uint32_t low;
low = x;
if (low & 0x80000000) {
low = 0;
SET_QC();
} else if (low > 0xffff) {
low = 0xffff;
SET_QC();
}
high = x >> 32;
if (high & 0x80000000) {
high = 0;
SET_QC();
} else if (high > 0xffff) {
high = 0xffff;
SET_QC();
}
return low | (high << 16);
}
uint32_t HELPER(neon_narrow_sat_u16)(CPUARMState *env, uint64_t x)
{
uint32_t high;
uint32_t low;
low = x;
if (low > 0xffff) {
low = 0xffff;
SET_QC();
}
high = x >> 32;
if (high > 0xffff) {
high = 0xffff;
SET_QC();
}
return low | (high << 16);
}
uint32_t HELPER(neon_narrow_sat_s16)(CPUARMState *env, uint64_t x)
{
int32_t low;
int32_t high;
low = x;
if (low != (int16_t)low) {
low = (low >> 31) ^ 0x7fff;
SET_QC();
}
high = x >> 32;
if (high != (int16_t)high) {
high = (high >> 31) ^ 0x7fff;
SET_QC();
}
return (uint16_t)low | (high << 16);
}
uint32_t HELPER(neon_unarrow_sat32)(CPUARMState *env, uint64_t x)
{
if (x & 0x8000000000000000ull) {
SET_QC();
return 0;
}
if (x > 0xffffffffu) {
SET_QC();
return 0xffffffffu;
}
return x;
}
uint32_t HELPER(neon_narrow_sat_u32)(CPUARMState *env, uint64_t x)
{
if (x > 0xffffffffu) {
SET_QC();
return 0xffffffffu;
}
return x;
}
uint32_t HELPER(neon_narrow_sat_s32)(CPUARMState *env, uint64_t x)
{
if ((int64_t)x != (int32_t)x) {
SET_QC();
return ((int64_t)x >> 63) ^ 0x7fffffff;
}
return x;
}
uint64_t HELPER(neon_widen_u8)(uint32_t x)
{
uint64_t tmp;
uint64_t ret;
ret = (uint8_t)x;
tmp = (uint8_t)(x >> 8);
ret |= tmp << 16;
tmp = (uint8_t)(x >> 16);
ret |= tmp << 32;
tmp = (uint8_t)(x >> 24);
ret |= tmp << 48;
return ret;
}
uint64_t HELPER(neon_widen_s8)(uint32_t x)
{
uint64_t tmp;
uint64_t ret;
ret = (uint16_t)(int8_t)x;
tmp = (uint16_t)(int8_t)(x >> 8);
ret |= tmp << 16;
tmp = (uint16_t)(int8_t)(x >> 16);
ret |= tmp << 32;
tmp = (uint16_t)(int8_t)(x >> 24);
ret |= tmp << 48;
return ret;
}
uint64_t HELPER(neon_widen_u16)(uint32_t x)
{
uint64_t high = (uint16_t)(x >> 16);
return ((uint16_t)x) | (high << 32);
}
uint64_t HELPER(neon_widen_s16)(uint32_t x)
{
uint64_t high = (int16_t)(x >> 16);
return ((uint32_t)(int16_t)x) | (high << 32);
}
uint64_t HELPER(neon_addl_u16)(uint64_t a, uint64_t b)
{
uint64_t mask;
mask = (a ^ b) & 0x8000800080008000ull;
a &= ~0x8000800080008000ull;
b &= ~0x8000800080008000ull;
return (a + b) ^ mask;
}
uint64_t HELPER(neon_addl_u32)(uint64_t a, uint64_t b)
{
uint64_t mask;
mask = (a ^ b) & 0x8000000080000000ull;
a &= ~0x8000000080000000ull;
b &= ~0x8000000080000000ull;
return (a + b) ^ mask;
}
uint64_t HELPER(neon_paddl_u16)(uint64_t a, uint64_t b)
{
uint64_t tmp;
uint64_t tmp2;
tmp = a & 0x0000ffff0000ffffull;
tmp += (a >> 16) & 0x0000ffff0000ffffull;
tmp2 = b & 0xffff0000ffff0000ull;
tmp2 += (b << 16) & 0xffff0000ffff0000ull;
return ( tmp & 0xffff)
| ((tmp >> 16) & 0xffff0000ull)
| ((tmp2 << 16) & 0xffff00000000ull)
| ( tmp2 & 0xffff000000000000ull);
}
uint64_t HELPER(neon_paddl_u32)(uint64_t a, uint64_t b)
{
uint32_t low = a + (a >> 32);
uint32_t high = b + (b >> 32);
return low + ((uint64_t)high << 32);
}
uint64_t HELPER(neon_subl_u16)(uint64_t a, uint64_t b)
{
uint64_t mask;
mask = (a ^ ~b) & 0x8000800080008000ull;
a |= 0x8000800080008000ull;
b &= ~0x8000800080008000ull;
return (a - b) ^ mask;
}
uint64_t HELPER(neon_subl_u32)(uint64_t a, uint64_t b)
{
uint64_t mask;
mask = (a ^ ~b) & 0x8000000080000000ull;
a |= 0x8000000080000000ull;
b &= ~0x8000000080000000ull;
return (a - b) ^ mask;
}
uint64_t HELPER(neon_addl_saturate_s32)(CPUARMState *env, uint64_t a, uint64_t b)
{
uint32_t x, y;
uint32_t low, high;
x = a;
y = b;
low = x + y;
if (((low ^ x) & SIGNBIT) && !((x ^ y) & SIGNBIT)) {
SET_QC();
low = ((int32_t)x >> 31) ^ ~SIGNBIT;
}
x = a >> 32;
y = b >> 32;
high = x + y;
if (((high ^ x) & SIGNBIT) && !((x ^ y) & SIGNBIT)) {
SET_QC();
high = ((int32_t)x >> 31) ^ ~SIGNBIT;
}
return low | ((uint64_t)high << 32);
}
uint64_t HELPER(neon_addl_saturate_s64)(CPUARMState *env, uint64_t a, uint64_t b)
{
uint64_t result;
result = a + b;
if (((result ^ a) & SIGNBIT64) && !((a ^ b) & SIGNBIT64)) {
SET_QC();
result = ((int64_t)a >> 63) ^ ~SIGNBIT64;
}
return result;
}
/* We have to do the arithmetic in a larger type than
* the input type, because for example with a signed 32 bit
* op the absolute difference can overflow a signed 32 bit value.
*/
#define DO_ABD(dest, x, y, intype, arithtype) do { \
arithtype tmp_x = (intype)(x); \
arithtype tmp_y = (intype)(y); \
dest = ((tmp_x > tmp_y) ? tmp_x - tmp_y : tmp_y - tmp_x); \
} while(0)
uint64_t HELPER(neon_abdl_u16)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_ABD(result, a, b, uint8_t, uint32_t);
DO_ABD(tmp, a >> 8, b >> 8, uint8_t, uint32_t);
result |= tmp << 16;
DO_ABD(tmp, a >> 16, b >> 16, uint8_t, uint32_t);
result |= tmp << 32;
DO_ABD(tmp, a >> 24, b >> 24, uint8_t, uint32_t);
result |= tmp << 48;
return result;
}
uint64_t HELPER(neon_abdl_s16)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_ABD(result, a, b, int8_t, int32_t);
DO_ABD(tmp, a >> 8, b >> 8, int8_t, int32_t);
result |= tmp << 16;
DO_ABD(tmp, a >> 16, b >> 16, int8_t, int32_t);
result |= tmp << 32;
DO_ABD(tmp, a >> 24, b >> 24, int8_t, int32_t);
result |= tmp << 48;
return result;
}
uint64_t HELPER(neon_abdl_u32)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_ABD(result, a, b, uint16_t, uint32_t);
DO_ABD(tmp, a >> 16, b >> 16, uint16_t, uint32_t);
return result | (tmp << 32);
}
uint64_t HELPER(neon_abdl_s32)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_ABD(result, a, b, int16_t, int32_t);
DO_ABD(tmp, a >> 16, b >> 16, int16_t, int32_t);
return result | (tmp << 32);
}
uint64_t HELPER(neon_abdl_u64)(uint32_t a, uint32_t b)
{
uint64_t result;
DO_ABD(result, a, b, uint32_t, uint64_t);
return result;
}
uint64_t HELPER(neon_abdl_s64)(uint32_t a, uint32_t b)
{
uint64_t result;
DO_ABD(result, a, b, int32_t, int64_t);
return result;
}
#undef DO_ABD
/* Widening multiply. Named type is the source type. */
#define DO_MULL(dest, x, y, type1, type2) do { \
type1 tmp_x = x; \
type1 tmp_y = y; \
dest = (type2)((type2)tmp_x * (type2)tmp_y); \
} while(0)
uint64_t HELPER(neon_mull_u8)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_MULL(result, a, b, uint8_t, uint16_t);
DO_MULL(tmp, a >> 8, b >> 8, uint8_t, uint16_t);
result |= tmp << 16;
DO_MULL(tmp, a >> 16, b >> 16, uint8_t, uint16_t);
result |= tmp << 32;
DO_MULL(tmp, a >> 24, b >> 24, uint8_t, uint16_t);
result |= tmp << 48;
return result;
}
uint64_t HELPER(neon_mull_s8)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_MULL(result, a, b, int8_t, uint16_t);
DO_MULL(tmp, a >> 8, b >> 8, int8_t, uint16_t);
result |= tmp << 16;
DO_MULL(tmp, a >> 16, b >> 16, int8_t, uint16_t);
result |= tmp << 32;
DO_MULL(tmp, a >> 24, b >> 24, int8_t, uint16_t);
result |= tmp << 48;
return result;
}
uint64_t HELPER(neon_mull_u16)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_MULL(result, a, b, uint16_t, uint32_t);
DO_MULL(tmp, a >> 16, b >> 16, uint16_t, uint32_t);
return result | (tmp << 32);
}
uint64_t HELPER(neon_mull_s16)(uint32_t a, uint32_t b)
{
uint64_t tmp;
uint64_t result;
DO_MULL(result, a, b, int16_t, uint32_t);
DO_MULL(tmp, a >> 16, b >> 16, int16_t, uint32_t);
return result | (tmp << 32);
}
uint64_t HELPER(neon_negl_u16)(uint64_t x)
{
uint16_t tmp;
uint64_t result;
result = (uint16_t)-x;
tmp = -(x >> 16);
result |= (uint64_t)tmp << 16;
tmp = -(x >> 32);
result |= (uint64_t)tmp << 32;
tmp = -(x >> 48);
result |= (uint64_t)tmp << 48;
return result;
}
uint64_t HELPER(neon_negl_u32)(uint64_t x)
{
uint32_t low = -x;
uint32_t high = -(x >> 32);
return low | ((uint64_t)high << 32);
}
/* Saturating sign manipulation. */
/* ??? Make these use NEON_VOP1 */
#define DO_QABS8(x) do { \
if (x == (int8_t)0x80) { \
x = 0x7f; \
SET_QC(); \
} else if (x < 0) { \
x = -x; \
}} while (0)
uint32_t HELPER(neon_qabs_s8)(CPUARMState *env, uint32_t x)
{
neon_s8 vec;
NEON_UNPACK(neon_s8, vec, x);
DO_QABS8(vec.v1);
DO_QABS8(vec.v2);
DO_QABS8(vec.v3);
DO_QABS8(vec.v4);
NEON_PACK(neon_s8, x, vec);
return x;
}
#undef DO_QABS8
#define DO_QNEG8(x) do { \
if (x == (int8_t)0x80) { \
x = 0x7f; \
SET_QC(); \
} else { \
x = -x; \
}} while (0)
uint32_t HELPER(neon_qneg_s8)(CPUARMState *env, uint32_t x)
{
neon_s8 vec;
NEON_UNPACK(neon_s8, vec, x);
DO_QNEG8(vec.v1);
DO_QNEG8(vec.v2);
DO_QNEG8(vec.v3);
DO_QNEG8(vec.v4);
NEON_PACK(neon_s8, x, vec);
return x;
}
#undef DO_QNEG8
#define DO_QABS16(x) do { \
if (x == (int16_t)0x8000) { \
x = 0x7fff; \
SET_QC(); \
} else if (x < 0) { \
x = -x; \
}} while (0)
uint32_t HELPER(neon_qabs_s16)(CPUARMState *env, uint32_t x)
{
neon_s16 vec;
NEON_UNPACK(neon_s16, vec, x);
DO_QABS16(vec.v1);
DO_QABS16(vec.v2);
NEON_PACK(neon_s16, x, vec);
return x;
}
#undef DO_QABS16
#define DO_QNEG16(x) do { \
if (x == (int16_t)0x8000) { \
x = 0x7fff; \
SET_QC(); \
} else { \
x = -x; \
}} while (0)
uint32_t HELPER(neon_qneg_s16)(CPUARMState *env, uint32_t x)
{
neon_s16 vec;
NEON_UNPACK(neon_s16, vec, x);
DO_QNEG16(vec.v1);
DO_QNEG16(vec.v2);
NEON_PACK(neon_s16, x, vec);
return x;
}
#undef DO_QNEG16
uint32_t HELPER(neon_qabs_s32)(CPUARMState *env, uint32_t x)
{
if (x == SIGNBIT) {
SET_QC();
x = ~SIGNBIT;
} else if ((int32_t)x < 0) {
x = -x;
}
return x;
}
uint32_t HELPER(neon_qneg_s32)(CPUARMState *env, uint32_t x)
{
if (x == SIGNBIT) {
SET_QC();
x = ~SIGNBIT;
} else {
x = -x;
}
return x;
}
uint64_t HELPER(neon_qabs_s64)(CPUARMState *env, uint64_t x)
{
if (x == SIGNBIT64) {
SET_QC();
x = ~SIGNBIT64;
} else if ((int64_t)x < 0) {
x = -x;
}
return x;
}
uint64_t HELPER(neon_qneg_s64)(CPUARMState *env, uint64_t x)
{
if (x == SIGNBIT64) {
SET_QC();
x = ~SIGNBIT64;
} else {
x = -x;
}
return x;
}
/* NEON Float helpers. */
uint32_t HELPER(neon_abd_f32)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
float32 f0 = make_float32(a);
float32 f1 = make_float32(b);
return float32_val(float32_abs(float32_sub(f0, f1, fpst)));
}
/* Floating point comparisons produce an integer result.
* Note that EQ doesn't signal InvalidOp for QNaNs but GE and GT do.
* Softfloat routines return 0/1, which we convert to the 0/-1 Neon requires.
*/
uint32_t HELPER(neon_ceq_f32)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
return -float32_eq_quiet(make_float32(a), make_float32(b), fpst);
}
uint32_t HELPER(neon_cge_f32)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
return -float32_le(make_float32(b), make_float32(a), fpst);
}
uint32_t HELPER(neon_cgt_f32)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
return -float32_lt(make_float32(b), make_float32(a), fpst);
}
uint32_t HELPER(neon_acge_f32)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
float32 f0 = float32_abs(make_float32(a));
float32 f1 = float32_abs(make_float32(b));
return -float32_le(f1, f0, fpst);
}
uint32_t HELPER(neon_acgt_f32)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
float32 f0 = float32_abs(make_float32(a));
float32 f1 = float32_abs(make_float32(b));
return -float32_lt(f1, f0, fpst);
}
uint64_t HELPER(neon_acge_f64)(uint64_t a, uint64_t b, void *fpstp)
{
float_status *fpst = fpstp;
float64 f0 = float64_abs(make_float64(a));
float64 f1 = float64_abs(make_float64(b));
return -float64_le(f1, f0, fpst);
}
uint64_t HELPER(neon_acgt_f64)(uint64_t a, uint64_t b, void *fpstp)
{
float_status *fpst = fpstp;
float64 f0 = float64_abs(make_float64(a));
float64 f1 = float64_abs(make_float64(b));
return -float64_lt(f1, f0, fpst);
}
#define ELEM(V, N, SIZE) (((V) >> ((N) * (SIZE))) & ((1ull << (SIZE)) - 1))
void HELPER(neon_qunzip8)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd0 = rd[0], zd1 = rd[1];
uint64_t zm0 = rm[0], zm1 = rm[1];
uint64_t d0 = ELEM(zd0, 0, 8) | (ELEM(zd0, 2, 8) << 8)
| (ELEM(zd0, 4, 8) << 16) | (ELEM(zd0, 6, 8) << 24)
| (ELEM(zd1, 0, 8) << 32) | (ELEM(zd1, 2, 8) << 40)
| (ELEM(zd1, 4, 8) << 48) | (ELEM(zd1, 6, 8) << 56);
uint64_t d1 = ELEM(zm0, 0, 8) | (ELEM(zm0, 2, 8) << 8)
| (ELEM(zm0, 4, 8) << 16) | (ELEM(zm0, 6, 8) << 24)
| (ELEM(zm1, 0, 8) << 32) | (ELEM(zm1, 2, 8) << 40)
| (ELEM(zm1, 4, 8) << 48) | (ELEM(zm1, 6, 8) << 56);
uint64_t m0 = ELEM(zd0, 1, 8) | (ELEM(zd0, 3, 8) << 8)
| (ELEM(zd0, 5, 8) << 16) | (ELEM(zd0, 7, 8) << 24)
| (ELEM(zd1, 1, 8) << 32) | (ELEM(zd1, 3, 8) << 40)
| (ELEM(zd1, 5, 8) << 48) | (ELEM(zd1, 7, 8) << 56);
uint64_t m1 = ELEM(zm0, 1, 8) | (ELEM(zm0, 3, 8) << 8)
| (ELEM(zm0, 5, 8) << 16) | (ELEM(zm0, 7, 8) << 24)
| (ELEM(zm1, 1, 8) << 32) | (ELEM(zm1, 3, 8) << 40)
| (ELEM(zm1, 5, 8) << 48) | (ELEM(zm1, 7, 8) << 56);
rm[0] = m0;
rm[1] = m1;
rd[0] = d0;
rd[1] = d1;
}
void HELPER(neon_qunzip16)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd0 = rd[0], zd1 = rd[1];
uint64_t zm0 = rm[0], zm1 = rm[1];
uint64_t d0 = ELEM(zd0, 0, 16) | (ELEM(zd0, 2, 16) << 16)
| (ELEM(zd1, 0, 16) << 32) | (ELEM(zd1, 2, 16) << 48);
uint64_t d1 = ELEM(zm0, 0, 16) | (ELEM(zm0, 2, 16) << 16)
| (ELEM(zm1, 0, 16) << 32) | (ELEM(zm1, 2, 16) << 48);
uint64_t m0 = ELEM(zd0, 1, 16) | (ELEM(zd0, 3, 16) << 16)
| (ELEM(zd1, 1, 16) << 32) | (ELEM(zd1, 3, 16) << 48);
uint64_t m1 = ELEM(zm0, 1, 16) | (ELEM(zm0, 3, 16) << 16)
| (ELEM(zm1, 1, 16) << 32) | (ELEM(zm1, 3, 16) << 48);
rm[0] = m0;
rm[1] = m1;
rd[0] = d0;
rd[1] = d1;
}
void HELPER(neon_qunzip32)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd0 = rd[0], zd1 = rd[1];
uint64_t zm0 = rm[0], zm1 = rm[1];
uint64_t d0 = ELEM(zd0, 0, 32) | (ELEM(zd1, 0, 32) << 32);
uint64_t d1 = ELEM(zm0, 0, 32) | (ELEM(zm1, 0, 32) << 32);
uint64_t m0 = ELEM(zd0, 1, 32) | (ELEM(zd1, 1, 32) << 32);
uint64_t m1 = ELEM(zm0, 1, 32) | (ELEM(zm1, 1, 32) << 32);
rm[0] = m0;
rm[1] = m1;
rd[0] = d0;
rd[1] = d1;
}
void HELPER(neon_unzip8)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd = rd[0], zm = rm[0];
uint64_t d0 = ELEM(zd, 0, 8) | (ELEM(zd, 2, 8) << 8)
| (ELEM(zd, 4, 8) << 16) | (ELEM(zd, 6, 8) << 24)
| (ELEM(zm, 0, 8) << 32) | (ELEM(zm, 2, 8) << 40)
| (ELEM(zm, 4, 8) << 48) | (ELEM(zm, 6, 8) << 56);
uint64_t m0 = ELEM(zd, 1, 8) | (ELEM(zd, 3, 8) << 8)
| (ELEM(zd, 5, 8) << 16) | (ELEM(zd, 7, 8) << 24)
| (ELEM(zm, 1, 8) << 32) | (ELEM(zm, 3, 8) << 40)
| (ELEM(zm, 5, 8) << 48) | (ELEM(zm, 7, 8) << 56);
rm[0] = m0;
rd[0] = d0;
}
void HELPER(neon_unzip16)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd = rd[0], zm = rm[0];
uint64_t d0 = ELEM(zd, 0, 16) | (ELEM(zd, 2, 16) << 16)
| (ELEM(zm, 0, 16) << 32) | (ELEM(zm, 2, 16) << 48);
uint64_t m0 = ELEM(zd, 1, 16) | (ELEM(zd, 3, 16) << 16)
| (ELEM(zm, 1, 16) << 32) | (ELEM(zm, 3, 16) << 48);
rm[0] = m0;
rd[0] = d0;
}
void HELPER(neon_qzip8)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd0 = rd[0], zd1 = rd[1];
uint64_t zm0 = rm[0], zm1 = rm[1];
uint64_t d0 = ELEM(zd0, 0, 8) | (ELEM(zm0, 0, 8) << 8)
| (ELEM(zd0, 1, 8) << 16) | (ELEM(zm0, 1, 8) << 24)
| (ELEM(zd0, 2, 8) << 32) | (ELEM(zm0, 2, 8) << 40)
| (ELEM(zd0, 3, 8) << 48) | (ELEM(zm0, 3, 8) << 56);
uint64_t d1 = ELEM(zd0, 4, 8) | (ELEM(zm0, 4, 8) << 8)
| (ELEM(zd0, 5, 8) << 16) | (ELEM(zm0, 5, 8) << 24)
| (ELEM(zd0, 6, 8) << 32) | (ELEM(zm0, 6, 8) << 40)
| (ELEM(zd0, 7, 8) << 48) | (ELEM(zm0, 7, 8) << 56);
uint64_t m0 = ELEM(zd1, 0, 8) | (ELEM(zm1, 0, 8) << 8)
| (ELEM(zd1, 1, 8) << 16) | (ELEM(zm1, 1, 8) << 24)
| (ELEM(zd1, 2, 8) << 32) | (ELEM(zm1, 2, 8) << 40)
| (ELEM(zd1, 3, 8) << 48) | (ELEM(zm1, 3, 8) << 56);
uint64_t m1 = ELEM(zd1, 4, 8) | (ELEM(zm1, 4, 8) << 8)
| (ELEM(zd1, 5, 8) << 16) | (ELEM(zm1, 5, 8) << 24)
| (ELEM(zd1, 6, 8) << 32) | (ELEM(zm1, 6, 8) << 40)
| (ELEM(zd1, 7, 8) << 48) | (ELEM(zm1, 7, 8) << 56);
rm[0] = m0;
rm[1] = m1;
rd[0] = d0;
rd[1] = d1;
}
void HELPER(neon_qzip16)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd0 = rd[0], zd1 = rd[1];
uint64_t zm0 = rm[0], zm1 = rm[1];
uint64_t d0 = ELEM(zd0, 0, 16) | (ELEM(zm0, 0, 16) << 16)
| (ELEM(zd0, 1, 16) << 32) | (ELEM(zm0, 1, 16) << 48);
uint64_t d1 = ELEM(zd0, 2, 16) | (ELEM(zm0, 2, 16) << 16)
| (ELEM(zd0, 3, 16) << 32) | (ELEM(zm0, 3, 16) << 48);
uint64_t m0 = ELEM(zd1, 0, 16) | (ELEM(zm1, 0, 16) << 16)
| (ELEM(zd1, 1, 16) << 32) | (ELEM(zm1, 1, 16) << 48);
uint64_t m1 = ELEM(zd1, 2, 16) | (ELEM(zm1, 2, 16) << 16)
| (ELEM(zd1, 3, 16) << 32) | (ELEM(zm1, 3, 16) << 48);
rm[0] = m0;
rm[1] = m1;
rd[0] = d0;
rd[1] = d1;
}
void HELPER(neon_qzip32)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd0 = rd[0], zd1 = rd[1];
uint64_t zm0 = rm[0], zm1 = rm[1];
uint64_t d0 = ELEM(zd0, 0, 32) | (ELEM(zm0, 0, 32) << 32);
uint64_t d1 = ELEM(zd0, 1, 32) | (ELEM(zm0, 1, 32) << 32);
uint64_t m0 = ELEM(zd1, 0, 32) | (ELEM(zm1, 0, 32) << 32);
uint64_t m1 = ELEM(zd1, 1, 32) | (ELEM(zm1, 1, 32) << 32);
rm[0] = m0;
rm[1] = m1;
rd[0] = d0;
rd[1] = d1;
}
void HELPER(neon_zip8)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd = rd[0], zm = rm[0];
uint64_t d0 = ELEM(zd, 0, 8) | (ELEM(zm, 0, 8) << 8)
| (ELEM(zd, 1, 8) << 16) | (ELEM(zm, 1, 8) << 24)
| (ELEM(zd, 2, 8) << 32) | (ELEM(zm, 2, 8) << 40)
| (ELEM(zd, 3, 8) << 48) | (ELEM(zm, 3, 8) << 56);
uint64_t m0 = ELEM(zd, 4, 8) | (ELEM(zm, 4, 8) << 8)
| (ELEM(zd, 5, 8) << 16) | (ELEM(zm, 5, 8) << 24)
| (ELEM(zd, 6, 8) << 32) | (ELEM(zm, 6, 8) << 40)
| (ELEM(zd, 7, 8) << 48) | (ELEM(zm, 7, 8) << 56);
rm[0] = m0;
rd[0] = d0;
}
void HELPER(neon_zip16)(void *vd, void *vm)
{
uint64_t *rd = vd, *rm = vm;
uint64_t zd = rd[0], zm = rm[0];
uint64_t d0 = ELEM(zd, 0, 16) | (ELEM(zm, 0, 16) << 16)
| (ELEM(zd, 1, 16) << 32) | (ELEM(zm, 1, 16) << 48);
uint64_t m0 = ELEM(zd, 2, 16) | (ELEM(zm, 2, 16) << 16)
| (ELEM(zd, 3, 16) << 32) | (ELEM(zm, 3, 16) << 48);
rm[0] = m0;
rd[0] = d0;
}
/* Helper function for 64 bit polynomial multiply case:
* perform PolynomialMult(op1, op2) and return either the top or
* bottom half of the 128 bit result.
*/
uint64_t HELPER(neon_pmull_64_lo)(uint64_t op1, uint64_t op2)
{
int bitnum;
uint64_t res = 0;
for (bitnum = 0; bitnum < 64; bitnum++) {
if (op1 & (1ULL << bitnum)) {
res ^= op2 << bitnum;
}
}
return res;
}
uint64_t HELPER(neon_pmull_64_hi)(uint64_t op1, uint64_t op2)
{
int bitnum;
uint64_t res = 0;
/* bit 0 of op1 can't influence the high 64 bits at all */
for (bitnum = 1; bitnum < 64; bitnum++) {
if (op1 & (1ULL << bitnum)) {
res ^= op2 >> (64 - bitnum);
}
}
return res;
}