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|
/* crc-ppc.c - POWER8 vpmsum accelerated CRC implementation
* Copyright (C) 2019-2020 Jussi Kivilinna <jussi.kivilinna@iki.fi>
*
* This file is part of Libgcrypt.
*
* Libgcrypt 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 2.1 of
* the License, or (at your option) any later version.
*
* Libgcrypt 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 program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
*
*/
#include <config.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "g10lib.h"
#include "bithelp.h"
#include "bufhelp.h"
#if defined(ENABLE_PPC_CRYPTO_SUPPORT) && \
defined(HAVE_COMPATIBLE_CC_PPC_ALTIVEC) && \
defined(HAVE_GCC_INLINE_ASM_PPC_ALTIVEC) && \
__GNUC__ >= 4
#include <altivec.h>
#include "bufhelp.h"
#define ALWAYS_INLINE inline __attribute__((always_inline))
#define NO_INLINE __attribute__((noinline))
#define NO_INSTRUMENT_FUNCTION __attribute__((no_instrument_function))
#define ASM_FUNC_ATTR NO_INSTRUMENT_FUNCTION
#define ASM_FUNC_ATTR_INLINE ASM_FUNC_ATTR ALWAYS_INLINE
#define ASM_FUNC_ATTR_NOINLINE ASM_FUNC_ATTR NO_INLINE
#define ALIGNED_64 __attribute__ ((aligned (64)))
typedef vector unsigned char vector16x_u8;
typedef vector unsigned int vector4x_u32;
typedef vector unsigned long long vector2x_u64;
/* Constants structure for generic reflected/non-reflected CRC32 PMULL
* functions. */
struct crc32_consts_s
{
/* k: { x^(32*17), x^(32*15), x^(32*5), x^(32*3), x^(32*2), 0 } mod P(x) */
unsigned long long k[6];
/* my_p: { floor(x^64 / P(x)), P(x) } */
unsigned long long my_p[2];
};
/* PMULL constants for CRC32 and CRC32RFC1510. */
static const struct crc32_consts_s crc32_consts ALIGNED_64 =
{
{ /* k[6] = reverse_33bits( x^(32*y) mod P(x) ) */
U64_C(0x154442bd4), U64_C(0x1c6e41596), /* y = { 17, 15 } */
U64_C(0x1751997d0), U64_C(0x0ccaa009e), /* y = { 5, 3 } */
U64_C(0x163cd6124), 0 /* y = 2 */
},
{ /* my_p[2] = reverse_33bits ( { floor(x^64 / P(x)), P(x) } ) */
U64_C(0x1f7011641), U64_C(0x1db710641)
}
};
/* PMULL constants for CRC24RFC2440 (polynomial multiplied with x⁸). */
static const struct crc32_consts_s crc24rfc2440_consts ALIGNED_64 =
{
{ /* k[6] = x^(32*y) mod P(x) << 32*/
U64_C(0x08289a00) << 32, U64_C(0x74b44a00) << 32, /* y = { 17, 15 } */
U64_C(0xc4b14d00) << 32, U64_C(0xfd7e0c00) << 32, /* y = { 5, 3 } */
U64_C(0xd9fe8c00) << 32, 0 /* y = 2 */
},
{ /* my_p[2] = { floor(x^64 / P(x)), P(x) } */
U64_C(0x1f845fe24), U64_C(0x1864cfb00)
}
};
static ASM_FUNC_ATTR_INLINE vector2x_u64
asm_vpmsumd(vector2x_u64 a, vector2x_u64 b)
{
__asm__("vpmsumd %0, %1, %2"
: "=v" (a)
: "v" (a), "v" (b));
return a;
}
static ASM_FUNC_ATTR_INLINE vector2x_u64
asm_swap_u64(vector2x_u64 a)
{
__asm__("xxswapd %x0, %x1"
: "=wa" (a)
: "wa" (a));
return a;
}
static ASM_FUNC_ATTR_INLINE vector4x_u32
vec_sld_u32(vector4x_u32 a, vector4x_u32 b, unsigned int idx)
{
return vec_sld (a, b, (4 * idx) & 15);
}
static const byte crc32_partial_fold_input_mask[16 + 16] ALIGNED_64 =
{
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
};
static const byte crc32_shuf_shift[3 * 16] ALIGNED_64 =
{
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
0x0f, 0x0e, 0x0d, 0x0c, 0x0b, 0x0a, 0x09, 0x08,
0x07, 0x06, 0x05, 0x04, 0x03, 0x02, 0x01, 0x00,
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
};
static const byte crc32_refl_shuf_shift[3 * 16] ALIGNED_64 =
{
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f,
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f, 0x1f,
};
static const vector16x_u8 bswap_const ALIGNED_64 =
{ 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0 };
#define CRC_VEC_SWAP(v) ({ vector2x_u64 __vecu64 = (v); \
vec_perm(__vecu64, __vecu64, bswap_const); })
#ifdef WORDS_BIGENDIAN
# define CRC_VEC_U64_DEF(lo, hi) { (hi), (lo) }
# define CRC_VEC_U64_LOAD(offs, ptr) \
asm_swap_u64(asm_vec_u64_load(offs, ptr))
# define CRC_VEC_U64_LOAD_LE(offs, ptr) \
CRC_VEC_SWAP(asm_vec_u64_load(offs, ptr))
# define CRC_VEC_U64_LOAD_BE(offs, ptr) \
asm_vec_u64_load(offs, ptr)
# define CRC_VEC_SWAP_TO_LE(v) CRC_VEC_SWAP(v)
# define CRC_VEC_SWAP_TO_BE(v) (v)
# define VEC_U64_LO 1
# define VEC_U64_HI 0
static ASM_FUNC_ATTR_INLINE vector2x_u64
asm_vec_u64_load(unsigned long offset, const void *ptr)
{
vector2x_u64 vecu64;
#if __GNUC__ >= 4
if (__builtin_constant_p (offset) && offset == 0)
__asm__ volatile ("lxvd2x %x0,0,%1\n\t"
: "=wa" (vecu64)
: "r" ((uintptr_t)ptr)
: "memory");
else
#endif
__asm__ volatile ("lxvd2x %x0,%1,%2\n\t"
: "=wa" (vecu64)
: "r" (offset), "r" ((uintptr_t)ptr)
: "memory", "r0");
return vecu64;
}
#else
# define CRC_VEC_U64_DEF(lo, hi) { (lo), (hi) }
# define CRC_VEC_U64_LOAD(offs, ptr) asm_vec_u64_load_le(offs, ptr)
# define CRC_VEC_U64_LOAD_LE(offs, ptr) asm_vec_u64_load_le(offs, ptr)
# define CRC_VEC_U64_LOAD_BE(offs, ptr) asm_vec_u64_load_be(offs, ptr)
# define CRC_VEC_SWAP_TO_LE(v) (v)
# define CRC_VEC_SWAP_TO_BE(v) CRC_VEC_SWAP(v)
# define VEC_U64_LO 0
# define VEC_U64_HI 1
static ASM_FUNC_ATTR_INLINE vector2x_u64
asm_vec_u64_load_le(unsigned long offset, const void *ptr)
{
vector2x_u64 vecu64;
#if __GNUC__ >= 4
if (__builtin_constant_p (offset) && offset == 0)
__asm__ volatile ("lxvd2x %x0,0,%1\n\t"
: "=wa" (vecu64)
: "r" ((uintptr_t)ptr)
: "memory");
else
#endif
__asm__ volatile ("lxvd2x %x0,%1,%2\n\t"
: "=wa" (vecu64)
: "r" (offset), "r" ((uintptr_t)ptr)
: "memory", "r0");
return asm_swap_u64(vecu64);
}
static ASM_FUNC_ATTR_INLINE vector2x_u64
asm_vec_u64_load_be(unsigned int offset, const void *ptr)
{
static const vector16x_u8 vec_load_le_const =
{ ~7, ~6, ~5, ~4, ~3, ~2, ~1, ~0, ~15, ~14, ~13, ~12, ~11, ~10, ~9, ~8 };
vector2x_u64 vecu64;
#if __GNUC__ >= 4
if (__builtin_constant_p (offset) && offset == 0)
__asm__ ("lxvd2x %%vs32,0,%1\n\t"
"vperm %0,%%v0,%%v0,%2\n\t"
: "=v" (vecu64)
: "r" ((uintptr_t)(ptr)), "v" (vec_load_le_const)
: "memory", "v0");
#endif
else
__asm__ ("lxvd2x %%vs32,%1,%2\n\t"
"vperm %0,%%v0,%%v0,%3\n\t"
: "=v" (vecu64)
: "r" (offset), "r" ((uintptr_t)(ptr)),
"v" (vec_load_le_const)
: "memory", "r0", "v0");
return vecu64;
}
#endif
static ASM_FUNC_ATTR_INLINE void
crc32r_ppc8_ce_bulk (u32 *pcrc, const byte *inbuf, size_t inlen,
const struct crc32_consts_s *consts)
{
vector4x_u32 zero = { 0, 0, 0, 0 };
vector2x_u64 low_64bit_mask = CRC_VEC_U64_DEF((u64)-1, 0);
vector2x_u64 low_32bit_mask = CRC_VEC_U64_DEF((u32)-1, 0);
vector2x_u64 my_p = CRC_VEC_U64_LOAD(0, &consts->my_p[0]);
vector2x_u64 k1k2 = CRC_VEC_U64_LOAD(0, &consts->k[1 - 1]);
vector2x_u64 k3k4 = CRC_VEC_U64_LOAD(0, &consts->k[3 - 1]);
vector2x_u64 k4lo = CRC_VEC_U64_DEF(k3k4[VEC_U64_HI], 0);
vector2x_u64 k5lo = CRC_VEC_U64_LOAD(0, &consts->k[5 - 1]);
vector2x_u64 crc = CRC_VEC_U64_DEF(*pcrc, 0);
vector2x_u64 crc0, crc1, crc2, crc3;
vector2x_u64 v0;
if (inlen >= 8 * 16)
{
crc0 = CRC_VEC_U64_LOAD_LE(0 * 16, inbuf);
crc0 ^= crc;
crc1 = CRC_VEC_U64_LOAD_LE(1 * 16, inbuf);
crc2 = CRC_VEC_U64_LOAD_LE(2 * 16, inbuf);
crc3 = CRC_VEC_U64_LOAD_LE(3 * 16, inbuf);
inbuf += 4 * 16;
inlen -= 4 * 16;
/* Fold by 4. */
while (inlen >= 4 * 16)
{
v0 = CRC_VEC_U64_LOAD_LE(0 * 16, inbuf);
crc0 = asm_vpmsumd(crc0, k1k2) ^ v0;
v0 = CRC_VEC_U64_LOAD_LE(1 * 16, inbuf);
crc1 = asm_vpmsumd(crc1, k1k2) ^ v0;
v0 = CRC_VEC_U64_LOAD_LE(2 * 16, inbuf);
crc2 = asm_vpmsumd(crc2, k1k2) ^ v0;
v0 = CRC_VEC_U64_LOAD_LE(3 * 16, inbuf);
crc3 = asm_vpmsumd(crc3, k1k2) ^ v0;
inbuf += 4 * 16;
inlen -= 4 * 16;
}
/* Fold 4 to 1. */
crc1 ^= asm_vpmsumd(crc0, k3k4);
crc2 ^= asm_vpmsumd(crc1, k3k4);
crc3 ^= asm_vpmsumd(crc2, k3k4);
crc = crc3;
}
else
{
v0 = CRC_VEC_U64_LOAD_LE(0, inbuf);
crc ^= v0;
inbuf += 16;
inlen -= 16;
}
/* Fold by 1. */
while (inlen >= 16)
{
v0 = CRC_VEC_U64_LOAD_LE(0, inbuf);
crc = asm_vpmsumd(k3k4, crc);
crc ^= v0;
inbuf += 16;
inlen -= 16;
}
/* Partial fold. */
if (inlen)
{
/* Load last input and add padding zeros. */
vector2x_u64 mask = CRC_VEC_U64_LOAD_LE(inlen, crc32_partial_fold_input_mask);
vector2x_u64 shl_shuf = CRC_VEC_U64_LOAD_LE(inlen, crc32_refl_shuf_shift);
vector2x_u64 shr_shuf = CRC_VEC_U64_LOAD_LE(inlen + 16, crc32_refl_shuf_shift);
v0 = CRC_VEC_U64_LOAD_LE(inlen - 16, inbuf);
v0 &= mask;
crc = CRC_VEC_SWAP_TO_LE(crc);
v0 |= (vector2x_u64)vec_perm((vector16x_u8)crc, (vector16x_u8)zero,
(vector16x_u8)shr_shuf);
crc = (vector2x_u64)vec_perm((vector16x_u8)crc, (vector16x_u8)zero,
(vector16x_u8)shl_shuf);
crc = asm_vpmsumd(k3k4, crc);
crc ^= v0;
inbuf += inlen;
inlen -= inlen;
}
/* Final fold. */
/* reduce 128-bits to 96-bits */
v0 = asm_swap_u64(crc);
v0 &= low_64bit_mask;
crc = asm_vpmsumd(k4lo, crc);
crc ^= v0;
/* reduce 96-bits to 64-bits */
v0 = (vector2x_u64)vec_sld_u32((vector4x_u32)crc,
(vector4x_u32)crc, 3); /* [x0][x3][x2][x1] */
v0 &= low_64bit_mask; /* [00][00][x2][x1] */
crc = crc & low_32bit_mask; /* [00][00][00][x0] */
crc = v0 ^ asm_vpmsumd(k5lo, crc); /* [00][00][xx][xx] */
/* barrett reduction */
v0 = crc << 32; /* [00][00][x0][00] */
v0 = asm_vpmsumd(my_p, v0);
v0 = asm_swap_u64(v0);
v0 = asm_vpmsumd(my_p, v0);
crc = (vector2x_u64)vec_sld_u32((vector4x_u32)crc,
zero, 1); /* [00][x1][x0][00] */
crc ^= v0;
*pcrc = (u32)crc[VEC_U64_HI];
}
static ASM_FUNC_ATTR_INLINE u32
crc32r_ppc8_ce_reduction_4 (u32 data, u32 crc,
const struct crc32_consts_s *consts)
{
vector4x_u32 zero = { 0, 0, 0, 0 };
vector2x_u64 my_p = CRC_VEC_U64_LOAD(0, &consts->my_p[0]);
vector2x_u64 v0 = CRC_VEC_U64_DEF((u64)data, 0);
v0 = asm_vpmsumd(v0, my_p); /* [00][00][xx][xx] */
v0 = (vector2x_u64)vec_sld_u32((vector4x_u32)v0,
zero, 3); /* [x0][00][00][00] */
v0 = (vector2x_u64)vec_sld_u32((vector4x_u32)v0,
(vector4x_u32)v0, 3); /* [00][x0][00][00] */
v0 = asm_vpmsumd(v0, my_p); /* [00][00][xx][xx] */
return (v0[VEC_U64_LO] >> 32) ^ crc;
}
static ASM_FUNC_ATTR_INLINE void
crc32r_less_than_16 (u32 *pcrc, const byte *inbuf, size_t inlen,
const struct crc32_consts_s *consts)
{
u32 crc = *pcrc;
u32 data;
while (inlen >= 4)
{
data = buf_get_le32(inbuf);
data ^= crc;
inlen -= 4;
inbuf += 4;
crc = crc32r_ppc8_ce_reduction_4 (data, 0, consts);
}
switch (inlen)
{
case 0:
break;
case 1:
data = inbuf[0];
data ^= crc;
data <<= 24;
crc >>= 8;
crc = crc32r_ppc8_ce_reduction_4 (data, crc, consts);
break;
case 2:
data = inbuf[0] << 0;
data |= inbuf[1] << 8;
data ^= crc;
data <<= 16;
crc >>= 16;
crc = crc32r_ppc8_ce_reduction_4 (data, crc, consts);
break;
case 3:
data = inbuf[0] << 0;
data |= inbuf[1] << 8;
data |= inbuf[2] << 16;
data ^= crc;
data <<= 8;
crc >>= 24;
crc = crc32r_ppc8_ce_reduction_4 (data, crc, consts);
break;
}
*pcrc = crc;
}
static ASM_FUNC_ATTR_INLINE void
crc32_ppc8_ce_bulk (u32 *pcrc, const byte *inbuf, size_t inlen,
const struct crc32_consts_s *consts)
{
vector4x_u32 zero = { 0, 0, 0, 0 };
vector2x_u64 low_96bit_mask = CRC_VEC_U64_DEF(~0, ~((u64)(u32)-1 << 32));
vector2x_u64 p_my = asm_swap_u64(CRC_VEC_U64_LOAD(0, &consts->my_p[0]));
vector2x_u64 p_my_lo, p_my_hi;
vector2x_u64 k2k1 = asm_swap_u64(CRC_VEC_U64_LOAD(0, &consts->k[1 - 1]));
vector2x_u64 k4k3 = asm_swap_u64(CRC_VEC_U64_LOAD(0, &consts->k[3 - 1]));
vector2x_u64 k4hi = CRC_VEC_U64_DEF(0, consts->k[4 - 1]);
vector2x_u64 k5hi = CRC_VEC_U64_DEF(0, consts->k[5 - 1]);
vector2x_u64 crc = CRC_VEC_U64_DEF(0, _gcry_bswap64(*pcrc));
vector2x_u64 crc0, crc1, crc2, crc3;
vector2x_u64 v0;
if (inlen >= 8 * 16)
{
crc0 = CRC_VEC_U64_LOAD_BE(0 * 16, inbuf);
crc0 ^= crc;
crc1 = CRC_VEC_U64_LOAD_BE(1 * 16, inbuf);
crc2 = CRC_VEC_U64_LOAD_BE(2 * 16, inbuf);
crc3 = CRC_VEC_U64_LOAD_BE(3 * 16, inbuf);
inbuf += 4 * 16;
inlen -= 4 * 16;
/* Fold by 4. */
while (inlen >= 4 * 16)
{
v0 = CRC_VEC_U64_LOAD_BE(0 * 16, inbuf);
crc0 = asm_vpmsumd(crc0, k2k1) ^ v0;
v0 = CRC_VEC_U64_LOAD_BE(1 * 16, inbuf);
crc1 = asm_vpmsumd(crc1, k2k1) ^ v0;
v0 = CRC_VEC_U64_LOAD_BE(2 * 16, inbuf);
crc2 = asm_vpmsumd(crc2, k2k1) ^ v0;
v0 = CRC_VEC_U64_LOAD_BE(3 * 16, inbuf);
crc3 = asm_vpmsumd(crc3, k2k1) ^ v0;
inbuf += 4 * 16;
inlen -= 4 * 16;
}
/* Fold 4 to 1. */
crc1 ^= asm_vpmsumd(crc0, k4k3);
crc2 ^= asm_vpmsumd(crc1, k4k3);
crc3 ^= asm_vpmsumd(crc2, k4k3);
crc = crc3;
}
else
{
v0 = CRC_VEC_U64_LOAD_BE(0, inbuf);
crc ^= v0;
inbuf += 16;
inlen -= 16;
}
/* Fold by 1. */
while (inlen >= 16)
{
v0 = CRC_VEC_U64_LOAD_BE(0, inbuf);
crc = asm_vpmsumd(k4k3, crc);
crc ^= v0;
inbuf += 16;
inlen -= 16;
}
/* Partial fold. */
if (inlen)
{
/* Load last input and add padding zeros. */
vector2x_u64 mask = CRC_VEC_U64_LOAD_LE(inlen, crc32_partial_fold_input_mask);
vector2x_u64 shl_shuf = CRC_VEC_U64_LOAD_LE(32 - inlen, crc32_refl_shuf_shift);
vector2x_u64 shr_shuf = CRC_VEC_U64_LOAD_LE(inlen + 16, crc32_shuf_shift);
v0 = CRC_VEC_U64_LOAD_LE(inlen - 16, inbuf);
v0 &= mask;
crc = CRC_VEC_SWAP_TO_LE(crc);
crc2 = (vector2x_u64)vec_perm((vector16x_u8)crc, (vector16x_u8)zero,
(vector16x_u8)shr_shuf);
v0 |= crc2;
v0 = CRC_VEC_SWAP(v0);
crc = (vector2x_u64)vec_perm((vector16x_u8)crc, (vector16x_u8)zero,
(vector16x_u8)shl_shuf);
crc = asm_vpmsumd(k4k3, crc);
crc ^= v0;
inbuf += inlen;
inlen -= inlen;
}
/* Final fold. */
/* reduce 128-bits to 96-bits */
v0 = (vector2x_u64)vec_sld_u32((vector4x_u32)crc,
(vector4x_u32)zero, 2);
crc = asm_vpmsumd(k4hi, crc);
crc ^= v0; /* bottom 32-bit are zero */
/* reduce 96-bits to 64-bits */
v0 = crc & low_96bit_mask; /* [00][x2][x1][00] */
crc >>= 32; /* [00][x3][00][x0] */
crc = asm_vpmsumd(k5hi, crc); /* [00][xx][xx][00] */
crc ^= v0; /* top and bottom 32-bit are zero */
/* barrett reduction */
p_my_hi = p_my;
p_my_lo = p_my;
p_my_hi[VEC_U64_LO] = 0;
p_my_lo[VEC_U64_HI] = 0;
v0 = crc >> 32; /* [00][00][00][x1] */
crc = asm_vpmsumd(p_my_hi, crc); /* [00][xx][xx][xx] */
crc = (vector2x_u64)vec_sld_u32((vector4x_u32)crc,
(vector4x_u32)crc, 3); /* [x0][00][x2][x1] */
crc = asm_vpmsumd(p_my_lo, crc); /* [00][xx][xx][xx] */
crc ^= v0;
*pcrc = _gcry_bswap32(crc[VEC_U64_LO]);
}
static ASM_FUNC_ATTR_INLINE u32
crc32_ppc8_ce_reduction_4 (u32 data, u32 crc,
const struct crc32_consts_s *consts)
{
vector2x_u64 my_p = CRC_VEC_U64_LOAD(0, &consts->my_p[0]);
vector2x_u64 v0 = CRC_VEC_U64_DEF((u64)data << 32, 0);
v0 = asm_vpmsumd(v0, my_p); /* [00][x1][x0][00] */
v0[VEC_U64_LO] = 0; /* [00][x1][00][00] */
v0 = asm_vpmsumd(v0, my_p); /* [00][00][xx][xx] */
return _gcry_bswap32(v0[VEC_U64_LO]) ^ crc;
}
static ASM_FUNC_ATTR_INLINE void
crc32_less_than_16 (u32 *pcrc, const byte *inbuf, size_t inlen,
const struct crc32_consts_s *consts)
{
u32 crc = *pcrc;
u32 data;
while (inlen >= 4)
{
data = buf_get_le32(inbuf);
data ^= crc;
data = _gcry_bswap32(data);
inlen -= 4;
inbuf += 4;
crc = crc32_ppc8_ce_reduction_4 (data, 0, consts);
}
switch (inlen)
{
case 0:
break;
case 1:
data = inbuf[0];
data ^= crc;
data = data & 0xffU;
crc = crc >> 8;
crc = crc32_ppc8_ce_reduction_4 (data, crc, consts);
break;
case 2:
data = inbuf[0] << 0;
data |= inbuf[1] << 8;
data ^= crc;
data = _gcry_bswap32(data << 16);
crc = crc >> 16;
crc = crc32_ppc8_ce_reduction_4 (data, crc, consts);
break;
case 3:
data = inbuf[0] << 0;
data |= inbuf[1] << 8;
data |= inbuf[2] << 16;
data ^= crc;
data = _gcry_bswap32(data << 8);
crc = crc >> 24;
crc = crc32_ppc8_ce_reduction_4 (data, crc, consts);
break;
}
*pcrc = crc;
}
void ASM_FUNC_ATTR
_gcry_crc32_ppc8_vpmsum (u32 *pcrc, const byte *inbuf, size_t inlen)
{
const struct crc32_consts_s *consts = &crc32_consts;
if (!inlen)
return;
if (inlen >= 16)
crc32r_ppc8_ce_bulk (pcrc, inbuf, inlen, consts);
else
crc32r_less_than_16 (pcrc, inbuf, inlen, consts);
}
void ASM_FUNC_ATTR
_gcry_crc24rfc2440_ppc8_vpmsum (u32 *pcrc, const byte *inbuf, size_t inlen)
{
const struct crc32_consts_s *consts = &crc24rfc2440_consts;
if (!inlen)
return;
/* Note: *pcrc in input endian. */
if (inlen >= 16)
crc32_ppc8_ce_bulk (pcrc, inbuf, inlen, consts);
else
crc32_less_than_16 (pcrc, inbuf, inlen, consts);
}
#endif
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