qemu/target/arm/vec_helper.c
Richard Henderson 6b375d3546 target/arm: Vectorize integer comparison vs zero
These instructions are often used in glibc's string routines.
They were the final uses of the 32-bit at a time neon helpers.

Signed-off-by: Richard Henderson <richard.henderson@linaro.org>
Message-id: 20200418162808.4680-1-richard.henderson@linaro.org
Reviewed-by: Peter Maydell <peter.maydell@linaro.org>
Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2020-04-30 15:35:41 +01:00

1285 lines
40 KiB
C

/*
* ARM AdvSIMD / SVE Vector Operations
*
* Copyright (c) 2018 Linaro
*
* 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 "qemu/osdep.h"
#include "cpu.h"
#include "exec/helper-proto.h"
#include "tcg/tcg-gvec-desc.h"
#include "fpu/softfloat.h"
/* Note that vector data is stored in host-endian 64-bit chunks,
so addressing units smaller than that needs a host-endian fixup. */
#ifdef HOST_WORDS_BIGENDIAN
#define H1(x) ((x) ^ 7)
#define H2(x) ((x) ^ 3)
#define H4(x) ((x) ^ 1)
#else
#define H1(x) (x)
#define H2(x) (x)
#define H4(x) (x)
#endif
#define SET_QC() env->vfp.qc[0] = 1
static void clear_tail(void *vd, uintptr_t opr_sz, uintptr_t max_sz)
{
uint64_t *d = vd + opr_sz;
uintptr_t i;
for (i = opr_sz; i < max_sz; i += 8) {
*d++ = 0;
}
}
/* Signed saturating rounding doubling multiply-accumulate high half, 16-bit */
static uint16_t inl_qrdmlah_s16(CPUARMState *env, int16_t src1,
int16_t src2, int16_t src3)
{
/* Simplify:
* = ((a3 << 16) + ((e1 * e2) << 1) + (1 << 15)) >> 16
* = ((a3 << 15) + (e1 * e2) + (1 << 14)) >> 15
*/
int32_t ret = (int32_t)src1 * src2;
ret = ((int32_t)src3 << 15) + ret + (1 << 14);
ret >>= 15;
if (ret != (int16_t)ret) {
SET_QC();
ret = (ret < 0 ? -0x8000 : 0x7fff);
}
return ret;
}
uint32_t HELPER(neon_qrdmlah_s16)(CPUARMState *env, uint32_t src1,
uint32_t src2, uint32_t src3)
{
uint16_t e1 = inl_qrdmlah_s16(env, src1, src2, src3);
uint16_t e2 = inl_qrdmlah_s16(env, src1 >> 16, src2 >> 16, src3 >> 16);
return deposit32(e1, 16, 16, e2);
}
void HELPER(gvec_qrdmlah_s16)(void *vd, void *vn, void *vm,
void *ve, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
int16_t *d = vd;
int16_t *n = vn;
int16_t *m = vm;
CPUARMState *env = ve;
uintptr_t i;
for (i = 0; i < opr_sz / 2; ++i) {
d[i] = inl_qrdmlah_s16(env, n[i], m[i], d[i]);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/* Signed saturating rounding doubling multiply-subtract high half, 16-bit */
static uint16_t inl_qrdmlsh_s16(CPUARMState *env, int16_t src1,
int16_t src2, int16_t src3)
{
/* Similarly, using subtraction:
* = ((a3 << 16) - ((e1 * e2) << 1) + (1 << 15)) >> 16
* = ((a3 << 15) - (e1 * e2) + (1 << 14)) >> 15
*/
int32_t ret = (int32_t)src1 * src2;
ret = ((int32_t)src3 << 15) - ret + (1 << 14);
ret >>= 15;
if (ret != (int16_t)ret) {
SET_QC();
ret = (ret < 0 ? -0x8000 : 0x7fff);
}
return ret;
}
uint32_t HELPER(neon_qrdmlsh_s16)(CPUARMState *env, uint32_t src1,
uint32_t src2, uint32_t src3)
{
uint16_t e1 = inl_qrdmlsh_s16(env, src1, src2, src3);
uint16_t e2 = inl_qrdmlsh_s16(env, src1 >> 16, src2 >> 16, src3 >> 16);
return deposit32(e1, 16, 16, e2);
}
void HELPER(gvec_qrdmlsh_s16)(void *vd, void *vn, void *vm,
void *ve, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
int16_t *d = vd;
int16_t *n = vn;
int16_t *m = vm;
CPUARMState *env = ve;
uintptr_t i;
for (i = 0; i < opr_sz / 2; ++i) {
d[i] = inl_qrdmlsh_s16(env, n[i], m[i], d[i]);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/* Signed saturating rounding doubling multiply-accumulate high half, 32-bit */
uint32_t HELPER(neon_qrdmlah_s32)(CPUARMState *env, int32_t src1,
int32_t src2, int32_t src3)
{
/* Simplify similarly to int_qrdmlah_s16 above. */
int64_t ret = (int64_t)src1 * src2;
ret = ((int64_t)src3 << 31) + ret + (1 << 30);
ret >>= 31;
if (ret != (int32_t)ret) {
SET_QC();
ret = (ret < 0 ? INT32_MIN : INT32_MAX);
}
return ret;
}
void HELPER(gvec_qrdmlah_s32)(void *vd, void *vn, void *vm,
void *ve, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
int32_t *d = vd;
int32_t *n = vn;
int32_t *m = vm;
CPUARMState *env = ve;
uintptr_t i;
for (i = 0; i < opr_sz / 4; ++i) {
d[i] = helper_neon_qrdmlah_s32(env, n[i], m[i], d[i]);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/* Signed saturating rounding doubling multiply-subtract high half, 32-bit */
uint32_t HELPER(neon_qrdmlsh_s32)(CPUARMState *env, int32_t src1,
int32_t src2, int32_t src3)
{
/* Simplify similarly to int_qrdmlsh_s16 above. */
int64_t ret = (int64_t)src1 * src2;
ret = ((int64_t)src3 << 31) - ret + (1 << 30);
ret >>= 31;
if (ret != (int32_t)ret) {
SET_QC();
ret = (ret < 0 ? INT32_MIN : INT32_MAX);
}
return ret;
}
void HELPER(gvec_qrdmlsh_s32)(void *vd, void *vn, void *vm,
void *ve, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
int32_t *d = vd;
int32_t *n = vn;
int32_t *m = vm;
CPUARMState *env = ve;
uintptr_t i;
for (i = 0; i < opr_sz / 4; ++i) {
d[i] = helper_neon_qrdmlsh_s32(env, n[i], m[i], d[i]);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/* Integer 8 and 16-bit dot-product.
*
* Note that for the loops herein, host endianness does not matter
* with respect to the ordering of data within the 64-bit lanes.
* All elements are treated equally, no matter where they are.
*/
void HELPER(gvec_sdot_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
uint32_t *d = vd;
int8_t *n = vn, *m = vm;
for (i = 0; i < opr_sz / 4; ++i) {
d[i] += n[i * 4 + 0] * m[i * 4 + 0]
+ n[i * 4 + 1] * m[i * 4 + 1]
+ n[i * 4 + 2] * m[i * 4 + 2]
+ n[i * 4 + 3] * m[i * 4 + 3];
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_udot_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
uint32_t *d = vd;
uint8_t *n = vn, *m = vm;
for (i = 0; i < opr_sz / 4; ++i) {
d[i] += n[i * 4 + 0] * m[i * 4 + 0]
+ n[i * 4 + 1] * m[i * 4 + 1]
+ n[i * 4 + 2] * m[i * 4 + 2]
+ n[i * 4 + 3] * m[i * 4 + 3];
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_sdot_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
uint64_t *d = vd;
int16_t *n = vn, *m = vm;
for (i = 0; i < opr_sz / 8; ++i) {
d[i] += (int64_t)n[i * 4 + 0] * m[i * 4 + 0]
+ (int64_t)n[i * 4 + 1] * m[i * 4 + 1]
+ (int64_t)n[i * 4 + 2] * m[i * 4 + 2]
+ (int64_t)n[i * 4 + 3] * m[i * 4 + 3];
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_udot_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
uint64_t *d = vd;
uint16_t *n = vn, *m = vm;
for (i = 0; i < opr_sz / 8; ++i) {
d[i] += (uint64_t)n[i * 4 + 0] * m[i * 4 + 0]
+ (uint64_t)n[i * 4 + 1] * m[i * 4 + 1]
+ (uint64_t)n[i * 4 + 2] * m[i * 4 + 2]
+ (uint64_t)n[i * 4 + 3] * m[i * 4 + 3];
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_sdot_idx_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, segend, opr_sz = simd_oprsz(desc), opr_sz_4 = opr_sz / 4;
intptr_t index = simd_data(desc);
uint32_t *d = vd;
int8_t *n = vn;
int8_t *m_indexed = (int8_t *)vm + index * 4;
/* Notice the special case of opr_sz == 8, from aa64/aa32 advsimd.
* Otherwise opr_sz is a multiple of 16.
*/
segend = MIN(4, opr_sz_4);
i = 0;
do {
int8_t m0 = m_indexed[i * 4 + 0];
int8_t m1 = m_indexed[i * 4 + 1];
int8_t m2 = m_indexed[i * 4 + 2];
int8_t m3 = m_indexed[i * 4 + 3];
do {
d[i] += n[i * 4 + 0] * m0
+ n[i * 4 + 1] * m1
+ n[i * 4 + 2] * m2
+ n[i * 4 + 3] * m3;
} while (++i < segend);
segend = i + 4;
} while (i < opr_sz_4);
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_udot_idx_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, segend, opr_sz = simd_oprsz(desc), opr_sz_4 = opr_sz / 4;
intptr_t index = simd_data(desc);
uint32_t *d = vd;
uint8_t *n = vn;
uint8_t *m_indexed = (uint8_t *)vm + index * 4;
/* Notice the special case of opr_sz == 8, from aa64/aa32 advsimd.
* Otherwise opr_sz is a multiple of 16.
*/
segend = MIN(4, opr_sz_4);
i = 0;
do {
uint8_t m0 = m_indexed[i * 4 + 0];
uint8_t m1 = m_indexed[i * 4 + 1];
uint8_t m2 = m_indexed[i * 4 + 2];
uint8_t m3 = m_indexed[i * 4 + 3];
do {
d[i] += n[i * 4 + 0] * m0
+ n[i * 4 + 1] * m1
+ n[i * 4 + 2] * m2
+ n[i * 4 + 3] * m3;
} while (++i < segend);
segend = i + 4;
} while (i < opr_sz_4);
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_sdot_idx_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc), opr_sz_8 = opr_sz / 8;
intptr_t index = simd_data(desc);
uint64_t *d = vd;
int16_t *n = vn;
int16_t *m_indexed = (int16_t *)vm + index * 4;
/* This is supported by SVE only, so opr_sz is always a multiple of 16.
* Process the entire segment all at once, writing back the results
* only after we've consumed all of the inputs.
*/
for (i = 0; i < opr_sz_8 ; i += 2) {
uint64_t d0, d1;
d0 = n[i * 4 + 0] * (int64_t)m_indexed[i * 4 + 0];
d0 += n[i * 4 + 1] * (int64_t)m_indexed[i * 4 + 1];
d0 += n[i * 4 + 2] * (int64_t)m_indexed[i * 4 + 2];
d0 += n[i * 4 + 3] * (int64_t)m_indexed[i * 4 + 3];
d1 = n[i * 4 + 4] * (int64_t)m_indexed[i * 4 + 0];
d1 += n[i * 4 + 5] * (int64_t)m_indexed[i * 4 + 1];
d1 += n[i * 4 + 6] * (int64_t)m_indexed[i * 4 + 2];
d1 += n[i * 4 + 7] * (int64_t)m_indexed[i * 4 + 3];
d[i + 0] += d0;
d[i + 1] += d1;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_udot_idx_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc), opr_sz_8 = opr_sz / 8;
intptr_t index = simd_data(desc);
uint64_t *d = vd;
uint16_t *n = vn;
uint16_t *m_indexed = (uint16_t *)vm + index * 4;
/* This is supported by SVE only, so opr_sz is always a multiple of 16.
* Process the entire segment all at once, writing back the results
* only after we've consumed all of the inputs.
*/
for (i = 0; i < opr_sz_8 ; i += 2) {
uint64_t d0, d1;
d0 = n[i * 4 + 0] * (uint64_t)m_indexed[i * 4 + 0];
d0 += n[i * 4 + 1] * (uint64_t)m_indexed[i * 4 + 1];
d0 += n[i * 4 + 2] * (uint64_t)m_indexed[i * 4 + 2];
d0 += n[i * 4 + 3] * (uint64_t)m_indexed[i * 4 + 3];
d1 = n[i * 4 + 4] * (uint64_t)m_indexed[i * 4 + 0];
d1 += n[i * 4 + 5] * (uint64_t)m_indexed[i * 4 + 1];
d1 += n[i * 4 + 6] * (uint64_t)m_indexed[i * 4 + 2];
d1 += n[i * 4 + 7] * (uint64_t)m_indexed[i * 4 + 3];
d[i + 0] += d0;
d[i + 1] += d1;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcaddh)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float16 *d = vd;
float16 *n = vn;
float16 *m = vm;
float_status *fpst = vfpst;
uint32_t neg_real = extract32(desc, SIMD_DATA_SHIFT, 1);
uint32_t neg_imag = neg_real ^ 1;
uintptr_t i;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 15;
neg_imag <<= 15;
for (i = 0; i < opr_sz / 2; i += 2) {
float16 e0 = n[H2(i)];
float16 e1 = m[H2(i + 1)] ^ neg_imag;
float16 e2 = n[H2(i + 1)];
float16 e3 = m[H2(i)] ^ neg_real;
d[H2(i)] = float16_add(e0, e1, fpst);
d[H2(i + 1)] = float16_add(e2, e3, fpst);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcadds)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float32 *d = vd;
float32 *n = vn;
float32 *m = vm;
float_status *fpst = vfpst;
uint32_t neg_real = extract32(desc, SIMD_DATA_SHIFT, 1);
uint32_t neg_imag = neg_real ^ 1;
uintptr_t i;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 31;
neg_imag <<= 31;
for (i = 0; i < opr_sz / 4; i += 2) {
float32 e0 = n[H4(i)];
float32 e1 = m[H4(i + 1)] ^ neg_imag;
float32 e2 = n[H4(i + 1)];
float32 e3 = m[H4(i)] ^ neg_real;
d[H4(i)] = float32_add(e0, e1, fpst);
d[H4(i + 1)] = float32_add(e2, e3, fpst);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcaddd)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float64 *d = vd;
float64 *n = vn;
float64 *m = vm;
float_status *fpst = vfpst;
uint64_t neg_real = extract64(desc, SIMD_DATA_SHIFT, 1);
uint64_t neg_imag = neg_real ^ 1;
uintptr_t i;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 63;
neg_imag <<= 63;
for (i = 0; i < opr_sz / 8; i += 2) {
float64 e0 = n[i];
float64 e1 = m[i + 1] ^ neg_imag;
float64 e2 = n[i + 1];
float64 e3 = m[i] ^ neg_real;
d[i] = float64_add(e0, e1, fpst);
d[i + 1] = float64_add(e2, e3, fpst);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcmlah)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float16 *d = vd;
float16 *n = vn;
float16 *m = vm;
float_status *fpst = vfpst;
intptr_t flip = extract32(desc, SIMD_DATA_SHIFT, 1);
uint32_t neg_imag = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
uint32_t neg_real = flip ^ neg_imag;
uintptr_t i;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 15;
neg_imag <<= 15;
for (i = 0; i < opr_sz / 2; i += 2) {
float16 e2 = n[H2(i + flip)];
float16 e1 = m[H2(i + flip)] ^ neg_real;
float16 e4 = e2;
float16 e3 = m[H2(i + 1 - flip)] ^ neg_imag;
d[H2(i)] = float16_muladd(e2, e1, d[H2(i)], 0, fpst);
d[H2(i + 1)] = float16_muladd(e4, e3, d[H2(i + 1)], 0, fpst);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcmlah_idx)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float16 *d = vd;
float16 *n = vn;
float16 *m = vm;
float_status *fpst = vfpst;
intptr_t flip = extract32(desc, SIMD_DATA_SHIFT, 1);
uint32_t neg_imag = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
intptr_t index = extract32(desc, SIMD_DATA_SHIFT + 2, 2);
uint32_t neg_real = flip ^ neg_imag;
intptr_t elements = opr_sz / sizeof(float16);
intptr_t eltspersegment = 16 / sizeof(float16);
intptr_t i, j;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 15;
neg_imag <<= 15;
for (i = 0; i < elements; i += eltspersegment) {
float16 mr = m[H2(i + 2 * index + 0)];
float16 mi = m[H2(i + 2 * index + 1)];
float16 e1 = neg_real ^ (flip ? mi : mr);
float16 e3 = neg_imag ^ (flip ? mr : mi);
for (j = i; j < i + eltspersegment; j += 2) {
float16 e2 = n[H2(j + flip)];
float16 e4 = e2;
d[H2(j)] = float16_muladd(e2, e1, d[H2(j)], 0, fpst);
d[H2(j + 1)] = float16_muladd(e4, e3, d[H2(j + 1)], 0, fpst);
}
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcmlas)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float32 *d = vd;
float32 *n = vn;
float32 *m = vm;
float_status *fpst = vfpst;
intptr_t flip = extract32(desc, SIMD_DATA_SHIFT, 1);
uint32_t neg_imag = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
uint32_t neg_real = flip ^ neg_imag;
uintptr_t i;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 31;
neg_imag <<= 31;
for (i = 0; i < opr_sz / 4; i += 2) {
float32 e2 = n[H4(i + flip)];
float32 e1 = m[H4(i + flip)] ^ neg_real;
float32 e4 = e2;
float32 e3 = m[H4(i + 1 - flip)] ^ neg_imag;
d[H4(i)] = float32_muladd(e2, e1, d[H4(i)], 0, fpst);
d[H4(i + 1)] = float32_muladd(e4, e3, d[H4(i + 1)], 0, fpst);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcmlas_idx)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float32 *d = vd;
float32 *n = vn;
float32 *m = vm;
float_status *fpst = vfpst;
intptr_t flip = extract32(desc, SIMD_DATA_SHIFT, 1);
uint32_t neg_imag = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
intptr_t index = extract32(desc, SIMD_DATA_SHIFT + 2, 2);
uint32_t neg_real = flip ^ neg_imag;
intptr_t elements = opr_sz / sizeof(float32);
intptr_t eltspersegment = 16 / sizeof(float32);
intptr_t i, j;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 31;
neg_imag <<= 31;
for (i = 0; i < elements; i += eltspersegment) {
float32 mr = m[H4(i + 2 * index + 0)];
float32 mi = m[H4(i + 2 * index + 1)];
float32 e1 = neg_real ^ (flip ? mi : mr);
float32 e3 = neg_imag ^ (flip ? mr : mi);
for (j = i; j < i + eltspersegment; j += 2) {
float32 e2 = n[H4(j + flip)];
float32 e4 = e2;
d[H4(j)] = float32_muladd(e2, e1, d[H4(j)], 0, fpst);
d[H4(j + 1)] = float32_muladd(e4, e3, d[H4(j + 1)], 0, fpst);
}
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_fcmlad)(void *vd, void *vn, void *vm,
void *vfpst, uint32_t desc)
{
uintptr_t opr_sz = simd_oprsz(desc);
float64 *d = vd;
float64 *n = vn;
float64 *m = vm;
float_status *fpst = vfpst;
intptr_t flip = extract32(desc, SIMD_DATA_SHIFT, 1);
uint64_t neg_imag = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
uint64_t neg_real = flip ^ neg_imag;
uintptr_t i;
/* Shift boolean to the sign bit so we can xor to negate. */
neg_real <<= 63;
neg_imag <<= 63;
for (i = 0; i < opr_sz / 8; i += 2) {
float64 e2 = n[i + flip];
float64 e1 = m[i + flip] ^ neg_real;
float64 e4 = e2;
float64 e3 = m[i + 1 - flip] ^ neg_imag;
d[i] = float64_muladd(e2, e1, d[i], 0, fpst);
d[i + 1] = float64_muladd(e4, e3, d[i + 1], 0, fpst);
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
#define DO_2OP(NAME, FUNC, TYPE) \
void HELPER(NAME)(void *vd, void *vn, void *stat, uint32_t desc) \
{ \
intptr_t i, oprsz = simd_oprsz(desc); \
TYPE *d = vd, *n = vn; \
for (i = 0; i < oprsz / sizeof(TYPE); i++) { \
d[i] = FUNC(n[i], stat); \
} \
clear_tail(d, oprsz, simd_maxsz(desc)); \
}
DO_2OP(gvec_frecpe_h, helper_recpe_f16, float16)
DO_2OP(gvec_frecpe_s, helper_recpe_f32, float32)
DO_2OP(gvec_frecpe_d, helper_recpe_f64, float64)
DO_2OP(gvec_frsqrte_h, helper_rsqrte_f16, float16)
DO_2OP(gvec_frsqrte_s, helper_rsqrte_f32, float32)
DO_2OP(gvec_frsqrte_d, helper_rsqrte_f64, float64)
#undef DO_2OP
/* Floating-point trigonometric starting value.
* See the ARM ARM pseudocode function FPTrigSMul.
*/
static float16 float16_ftsmul(float16 op1, uint16_t op2, float_status *stat)
{
float16 result = float16_mul(op1, op1, stat);
if (!float16_is_any_nan(result)) {
result = float16_set_sign(result, op2 & 1);
}
return result;
}
static float32 float32_ftsmul(float32 op1, uint32_t op2, float_status *stat)
{
float32 result = float32_mul(op1, op1, stat);
if (!float32_is_any_nan(result)) {
result = float32_set_sign(result, op2 & 1);
}
return result;
}
static float64 float64_ftsmul(float64 op1, uint64_t op2, float_status *stat)
{
float64 result = float64_mul(op1, op1, stat);
if (!float64_is_any_nan(result)) {
result = float64_set_sign(result, op2 & 1);
}
return result;
}
#define DO_3OP(NAME, FUNC, TYPE) \
void HELPER(NAME)(void *vd, void *vn, void *vm, void *stat, uint32_t desc) \
{ \
intptr_t i, oprsz = simd_oprsz(desc); \
TYPE *d = vd, *n = vn, *m = vm; \
for (i = 0; i < oprsz / sizeof(TYPE); i++) { \
d[i] = FUNC(n[i], m[i], stat); \
} \
clear_tail(d, oprsz, simd_maxsz(desc)); \
}
DO_3OP(gvec_fadd_h, float16_add, float16)
DO_3OP(gvec_fadd_s, float32_add, float32)
DO_3OP(gvec_fadd_d, float64_add, float64)
DO_3OP(gvec_fsub_h, float16_sub, float16)
DO_3OP(gvec_fsub_s, float32_sub, float32)
DO_3OP(gvec_fsub_d, float64_sub, float64)
DO_3OP(gvec_fmul_h, float16_mul, float16)
DO_3OP(gvec_fmul_s, float32_mul, float32)
DO_3OP(gvec_fmul_d, float64_mul, float64)
DO_3OP(gvec_ftsmul_h, float16_ftsmul, float16)
DO_3OP(gvec_ftsmul_s, float32_ftsmul, float32)
DO_3OP(gvec_ftsmul_d, float64_ftsmul, float64)
#ifdef TARGET_AARCH64
DO_3OP(gvec_recps_h, helper_recpsf_f16, float16)
DO_3OP(gvec_recps_s, helper_recpsf_f32, float32)
DO_3OP(gvec_recps_d, helper_recpsf_f64, float64)
DO_3OP(gvec_rsqrts_h, helper_rsqrtsf_f16, float16)
DO_3OP(gvec_rsqrts_s, helper_rsqrtsf_f32, float32)
DO_3OP(gvec_rsqrts_d, helper_rsqrtsf_f64, float64)
#endif
#undef DO_3OP
/* For the indexed ops, SVE applies the index per 128-bit vector segment.
* For AdvSIMD, there is of course only one such vector segment.
*/
#define DO_MUL_IDX(NAME, TYPE, H) \
void HELPER(NAME)(void *vd, void *vn, void *vm, void *stat, uint32_t desc) \
{ \
intptr_t i, j, oprsz = simd_oprsz(desc), segment = 16 / sizeof(TYPE); \
intptr_t idx = simd_data(desc); \
TYPE *d = vd, *n = vn, *m = vm; \
for (i = 0; i < oprsz / sizeof(TYPE); i += segment) { \
TYPE mm = m[H(i + idx)]; \
for (j = 0; j < segment; j++) { \
d[i + j] = TYPE##_mul(n[i + j], mm, stat); \
} \
} \
}
DO_MUL_IDX(gvec_fmul_idx_h, float16, H2)
DO_MUL_IDX(gvec_fmul_idx_s, float32, H4)
DO_MUL_IDX(gvec_fmul_idx_d, float64, )
#undef DO_MUL_IDX
#define DO_FMLA_IDX(NAME, TYPE, H) \
void HELPER(NAME)(void *vd, void *vn, void *vm, void *va, \
void *stat, uint32_t desc) \
{ \
intptr_t i, j, oprsz = simd_oprsz(desc), segment = 16 / sizeof(TYPE); \
TYPE op1_neg = extract32(desc, SIMD_DATA_SHIFT, 1); \
intptr_t idx = desc >> (SIMD_DATA_SHIFT + 1); \
TYPE *d = vd, *n = vn, *m = vm, *a = va; \
op1_neg <<= (8 * sizeof(TYPE) - 1); \
for (i = 0; i < oprsz / sizeof(TYPE); i += segment) { \
TYPE mm = m[H(i + idx)]; \
for (j = 0; j < segment; j++) { \
d[i + j] = TYPE##_muladd(n[i + j] ^ op1_neg, \
mm, a[i + j], 0, stat); \
} \
} \
}
DO_FMLA_IDX(gvec_fmla_idx_h, float16, H2)
DO_FMLA_IDX(gvec_fmla_idx_s, float32, H4)
DO_FMLA_IDX(gvec_fmla_idx_d, float64, )
#undef DO_FMLA_IDX
#define DO_SAT(NAME, WTYPE, TYPEN, TYPEM, OP, MIN, MAX) \
void HELPER(NAME)(void *vd, void *vq, void *vn, void *vm, uint32_t desc) \
{ \
intptr_t i, oprsz = simd_oprsz(desc); \
TYPEN *d = vd, *n = vn; TYPEM *m = vm; \
bool q = false; \
for (i = 0; i < oprsz / sizeof(TYPEN); i++) { \
WTYPE dd = (WTYPE)n[i] OP m[i]; \
if (dd < MIN) { \
dd = MIN; \
q = true; \
} else if (dd > MAX) { \
dd = MAX; \
q = true; \
} \
d[i] = dd; \
} \
if (q) { \
uint32_t *qc = vq; \
qc[0] = 1; \
} \
clear_tail(d, oprsz, simd_maxsz(desc)); \
}
DO_SAT(gvec_uqadd_b, int, uint8_t, uint8_t, +, 0, UINT8_MAX)
DO_SAT(gvec_uqadd_h, int, uint16_t, uint16_t, +, 0, UINT16_MAX)
DO_SAT(gvec_uqadd_s, int64_t, uint32_t, uint32_t, +, 0, UINT32_MAX)
DO_SAT(gvec_sqadd_b, int, int8_t, int8_t, +, INT8_MIN, INT8_MAX)
DO_SAT(gvec_sqadd_h, int, int16_t, int16_t, +, INT16_MIN, INT16_MAX)
DO_SAT(gvec_sqadd_s, int64_t, int32_t, int32_t, +, INT32_MIN, INT32_MAX)
DO_SAT(gvec_uqsub_b, int, uint8_t, uint8_t, -, 0, UINT8_MAX)
DO_SAT(gvec_uqsub_h, int, uint16_t, uint16_t, -, 0, UINT16_MAX)
DO_SAT(gvec_uqsub_s, int64_t, uint32_t, uint32_t, -, 0, UINT32_MAX)
DO_SAT(gvec_sqsub_b, int, int8_t, int8_t, -, INT8_MIN, INT8_MAX)
DO_SAT(gvec_sqsub_h, int, int16_t, int16_t, -, INT16_MIN, INT16_MAX)
DO_SAT(gvec_sqsub_s, int64_t, int32_t, int32_t, -, INT32_MIN, INT32_MAX)
#undef DO_SAT
void HELPER(gvec_uqadd_d)(void *vd, void *vq, void *vn,
void *vm, uint32_t desc)
{
intptr_t i, oprsz = simd_oprsz(desc);
uint64_t *d = vd, *n = vn, *m = vm;
bool q = false;
for (i = 0; i < oprsz / 8; i++) {
uint64_t nn = n[i], mm = m[i], dd = nn + mm;
if (dd < nn) {
dd = UINT64_MAX;
q = true;
}
d[i] = dd;
}
if (q) {
uint32_t *qc = vq;
qc[0] = 1;
}
clear_tail(d, oprsz, simd_maxsz(desc));
}
void HELPER(gvec_uqsub_d)(void *vd, void *vq, void *vn,
void *vm, uint32_t desc)
{
intptr_t i, oprsz = simd_oprsz(desc);
uint64_t *d = vd, *n = vn, *m = vm;
bool q = false;
for (i = 0; i < oprsz / 8; i++) {
uint64_t nn = n[i], mm = m[i], dd = nn - mm;
if (nn < mm) {
dd = 0;
q = true;
}
d[i] = dd;
}
if (q) {
uint32_t *qc = vq;
qc[0] = 1;
}
clear_tail(d, oprsz, simd_maxsz(desc));
}
void HELPER(gvec_sqadd_d)(void *vd, void *vq, void *vn,
void *vm, uint32_t desc)
{
intptr_t i, oprsz = simd_oprsz(desc);
int64_t *d = vd, *n = vn, *m = vm;
bool q = false;
for (i = 0; i < oprsz / 8; i++) {
int64_t nn = n[i], mm = m[i], dd = nn + mm;
if (((dd ^ nn) & ~(nn ^ mm)) & INT64_MIN) {
dd = (nn >> 63) ^ ~INT64_MIN;
q = true;
}
d[i] = dd;
}
if (q) {
uint32_t *qc = vq;
qc[0] = 1;
}
clear_tail(d, oprsz, simd_maxsz(desc));
}
void HELPER(gvec_sqsub_d)(void *vd, void *vq, void *vn,
void *vm, uint32_t desc)
{
intptr_t i, oprsz = simd_oprsz(desc);
int64_t *d = vd, *n = vn, *m = vm;
bool q = false;
for (i = 0; i < oprsz / 8; i++) {
int64_t nn = n[i], mm = m[i], dd = nn - mm;
if (((dd ^ nn) & (nn ^ mm)) & INT64_MIN) {
dd = (nn >> 63) ^ ~INT64_MIN;
q = true;
}
d[i] = dd;
}
if (q) {
uint32_t *qc = vq;
qc[0] = 1;
}
clear_tail(d, oprsz, simd_maxsz(desc));
}
/*
* Convert float16 to float32, raising no exceptions and
* preserving exceptional values, including SNaN.
* This is effectively an unpack+repack operation.
*/
static float32 float16_to_float32_by_bits(uint32_t f16, bool fz16)
{
const int f16_bias = 15;
const int f32_bias = 127;
uint32_t sign = extract32(f16, 15, 1);
uint32_t exp = extract32(f16, 10, 5);
uint32_t frac = extract32(f16, 0, 10);
if (exp == 0x1f) {
/* Inf or NaN */
exp = 0xff;
} else if (exp == 0) {
/* Zero or denormal. */
if (frac != 0) {
if (fz16) {
frac = 0;
} else {
/*
* Denormal; these are all normal float32.
* Shift the fraction so that the msb is at bit 11,
* then remove bit 11 as the implicit bit of the
* normalized float32. Note that we still go through
* the shift for normal numbers below, to put the
* float32 fraction at the right place.
*/
int shift = clz32(frac) - 21;
frac = (frac << shift) & 0x3ff;
exp = f32_bias - f16_bias - shift + 1;
}
}
} else {
/* Normal number; adjust the bias. */
exp += f32_bias - f16_bias;
}
sign <<= 31;
exp <<= 23;
frac <<= 23 - 10;
return sign | exp | frac;
}
static uint64_t load4_f16(uint64_t *ptr, int is_q, int is_2)
{
/*
* Branchless load of u32[0], u64[0], u32[1], or u64[1].
* Load the 2nd qword iff is_q & is_2.
* Shift to the 2nd dword iff !is_q & is_2.
* For !is_q & !is_2, the upper bits of the result are garbage.
*/
return ptr[is_q & is_2] >> ((is_2 & ~is_q) << 5);
}
/*
* Note that FMLAL requires oprsz == 8 or oprsz == 16,
* as there is not yet SVE versions that might use blocking.
*/
static void do_fmlal(float32 *d, void *vn, void *vm, float_status *fpst,
uint32_t desc, bool fz16)
{
intptr_t i, oprsz = simd_oprsz(desc);
int is_s = extract32(desc, SIMD_DATA_SHIFT, 1);
int is_2 = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
int is_q = oprsz == 16;
uint64_t n_4, m_4;
/* Pre-load all of the f16 data, avoiding overlap issues. */
n_4 = load4_f16(vn, is_q, is_2);
m_4 = load4_f16(vm, is_q, is_2);
/* Negate all inputs for FMLSL at once. */
if (is_s) {
n_4 ^= 0x8000800080008000ull;
}
for (i = 0; i < oprsz / 4; i++) {
float32 n_1 = float16_to_float32_by_bits(n_4 >> (i * 16), fz16);
float32 m_1 = float16_to_float32_by_bits(m_4 >> (i * 16), fz16);
d[H4(i)] = float32_muladd(n_1, m_1, d[H4(i)], 0, fpst);
}
clear_tail(d, oprsz, simd_maxsz(desc));
}
void HELPER(gvec_fmlal_a32)(void *vd, void *vn, void *vm,
void *venv, uint32_t desc)
{
CPUARMState *env = venv;
do_fmlal(vd, vn, vm, &env->vfp.standard_fp_status, desc,
get_flush_inputs_to_zero(&env->vfp.fp_status_f16));
}
void HELPER(gvec_fmlal_a64)(void *vd, void *vn, void *vm,
void *venv, uint32_t desc)
{
CPUARMState *env = venv;
do_fmlal(vd, vn, vm, &env->vfp.fp_status, desc,
get_flush_inputs_to_zero(&env->vfp.fp_status_f16));
}
static void do_fmlal_idx(float32 *d, void *vn, void *vm, float_status *fpst,
uint32_t desc, bool fz16)
{
intptr_t i, oprsz = simd_oprsz(desc);
int is_s = extract32(desc, SIMD_DATA_SHIFT, 1);
int is_2 = extract32(desc, SIMD_DATA_SHIFT + 1, 1);
int index = extract32(desc, SIMD_DATA_SHIFT + 2, 3);
int is_q = oprsz == 16;
uint64_t n_4;
float32 m_1;
/* Pre-load all of the f16 data, avoiding overlap issues. */
n_4 = load4_f16(vn, is_q, is_2);
/* Negate all inputs for FMLSL at once. */
if (is_s) {
n_4 ^= 0x8000800080008000ull;
}
m_1 = float16_to_float32_by_bits(((float16 *)vm)[H2(index)], fz16);
for (i = 0; i < oprsz / 4; i++) {
float32 n_1 = float16_to_float32_by_bits(n_4 >> (i * 16), fz16);
d[H4(i)] = float32_muladd(n_1, m_1, d[H4(i)], 0, fpst);
}
clear_tail(d, oprsz, simd_maxsz(desc));
}
void HELPER(gvec_fmlal_idx_a32)(void *vd, void *vn, void *vm,
void *venv, uint32_t desc)
{
CPUARMState *env = venv;
do_fmlal_idx(vd, vn, vm, &env->vfp.standard_fp_status, desc,
get_flush_inputs_to_zero(&env->vfp.fp_status_f16));
}
void HELPER(gvec_fmlal_idx_a64)(void *vd, void *vn, void *vm,
void *venv, uint32_t desc)
{
CPUARMState *env = venv;
do_fmlal_idx(vd, vn, vm, &env->vfp.fp_status, desc,
get_flush_inputs_to_zero(&env->vfp.fp_status_f16));
}
void HELPER(gvec_sshl_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
int8_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz; ++i) {
int8_t mm = m[i];
int8_t nn = n[i];
int8_t res = 0;
if (mm >= 0) {
if (mm < 8) {
res = nn << mm;
}
} else {
res = nn >> (mm > -8 ? -mm : 7);
}
d[i] = res;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_sshl_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
int16_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz / 2; ++i) {
int8_t mm = m[i]; /* only 8 bits of shift are significant */
int16_t nn = n[i];
int16_t res = 0;
if (mm >= 0) {
if (mm < 16) {
res = nn << mm;
}
} else {
res = nn >> (mm > -16 ? -mm : 15);
}
d[i] = res;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_ushl_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
uint8_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz; ++i) {
int8_t mm = m[i];
uint8_t nn = n[i];
uint8_t res = 0;
if (mm >= 0) {
if (mm < 8) {
res = nn << mm;
}
} else {
if (mm > -8) {
res = nn >> -mm;
}
}
d[i] = res;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
void HELPER(gvec_ushl_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, opr_sz = simd_oprsz(desc);
uint16_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz / 2; ++i) {
int8_t mm = m[i]; /* only 8 bits of shift are significant */
uint16_t nn = n[i];
uint16_t res = 0;
if (mm >= 0) {
if (mm < 16) {
res = nn << mm;
}
} else {
if (mm > -16) {
res = nn >> -mm;
}
}
d[i] = res;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/*
* 8x8->8 polynomial multiply.
*
* Polynomial multiplication is like integer multiplication except the
* partial products are XORed, not added.
*
* TODO: expose this as a generic vector operation, as it is a common
* crypto building block.
*/
void HELPER(gvec_pmul_b)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, j, opr_sz = simd_oprsz(desc);
uint64_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz / 8; ++i) {
uint64_t nn = n[i];
uint64_t mm = m[i];
uint64_t rr = 0;
for (j = 0; j < 8; ++j) {
uint64_t mask = (nn & 0x0101010101010101ull) * 0xff;
rr ^= mm & mask;
mm = (mm << 1) & 0xfefefefefefefefeull;
nn >>= 1;
}
d[i] = rr;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/*
* 64x64->128 polynomial multiply.
* Because of the lanes are not accessed in strict columns,
* this probably cannot be turned into a generic helper.
*/
void HELPER(gvec_pmull_q)(void *vd, void *vn, void *vm, uint32_t desc)
{
intptr_t i, j, opr_sz = simd_oprsz(desc);
intptr_t hi = simd_data(desc);
uint64_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz / 8; i += 2) {
uint64_t nn = n[i + hi];
uint64_t mm = m[i + hi];
uint64_t rhi = 0;
uint64_t rlo = 0;
/* Bit 0 can only influence the low 64-bit result. */
if (nn & 1) {
rlo = mm;
}
for (j = 1; j < 64; ++j) {
uint64_t mask = -((nn >> j) & 1);
rlo ^= (mm << j) & mask;
rhi ^= (mm >> (64 - j)) & mask;
}
d[i] = rlo;
d[i + 1] = rhi;
}
clear_tail(d, opr_sz, simd_maxsz(desc));
}
/*
* 8x8->16 polynomial multiply.
*
* The byte inputs are expanded to (or extracted from) half-words.
* Note that neon and sve2 get the inputs from different positions.
* This allows 4 bytes to be processed in parallel with uint64_t.
*/
static uint64_t expand_byte_to_half(uint64_t x)
{
return (x & 0x000000ff)
| ((x & 0x0000ff00) << 8)
| ((x & 0x00ff0000) << 16)
| ((x & 0xff000000) << 24);
}
static uint64_t pmull_h(uint64_t op1, uint64_t op2)
{
uint64_t result = 0;
int i;
for (i = 0; i < 8; ++i) {
uint64_t mask = (op1 & 0x0001000100010001ull) * 0xffff;
result ^= op2 & mask;
op1 >>= 1;
op2 <<= 1;
}
return result;
}
void HELPER(neon_pmull_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
int hi = simd_data(desc);
uint64_t *d = vd, *n = vn, *m = vm;
uint64_t nn = n[hi], mm = m[hi];
d[0] = pmull_h(expand_byte_to_half(nn), expand_byte_to_half(mm));
nn >>= 32;
mm >>= 32;
d[1] = pmull_h(expand_byte_to_half(nn), expand_byte_to_half(mm));
clear_tail(d, 16, simd_maxsz(desc));
}
#ifdef TARGET_AARCH64
void HELPER(sve2_pmull_h)(void *vd, void *vn, void *vm, uint32_t desc)
{
int shift = simd_data(desc) * 8;
intptr_t i, opr_sz = simd_oprsz(desc);
uint64_t *d = vd, *n = vn, *m = vm;
for (i = 0; i < opr_sz / 8; ++i) {
uint64_t nn = (n[i] >> shift) & 0x00ff00ff00ff00ffull;
uint64_t mm = (m[i] >> shift) & 0x00ff00ff00ff00ffull;
d[i] = pmull_h(nn, mm);
}
}
#endif
#define DO_CMP0(NAME, TYPE, OP) \
void HELPER(NAME)(void *vd, void *vn, uint32_t desc) \
{ \
intptr_t i, opr_sz = simd_oprsz(desc); \
for (i = 0; i < opr_sz; i += sizeof(TYPE)) { \
TYPE nn = *(TYPE *)(vn + i); \
*(TYPE *)(vd + i) = -(nn OP 0); \
} \
clear_tail(vd, opr_sz, simd_maxsz(desc)); \
}
DO_CMP0(gvec_ceq0_b, int8_t, ==)
DO_CMP0(gvec_clt0_b, int8_t, <)
DO_CMP0(gvec_cle0_b, int8_t, <=)
DO_CMP0(gvec_cgt0_b, int8_t, >)
DO_CMP0(gvec_cge0_b, int8_t, >=)
DO_CMP0(gvec_ceq0_h, int16_t, ==)
DO_CMP0(gvec_clt0_h, int16_t, <)
DO_CMP0(gvec_cle0_h, int16_t, <=)
DO_CMP0(gvec_cgt0_h, int16_t, >)
DO_CMP0(gvec_cge0_h, int16_t, >=)
#undef DO_CMP0