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/*
* Lightweight wrappers for SIMD operations
* (C) 2009,2011,2016 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#ifndef BOTAN_SIMD_32_H__
#define BOTAN_SIMD_32_H__
#include <botan/types.h>
#include <botan/loadstor.h>
#include <botan/bswap.h>
#if defined(BOTAN_TARGET_SUPPORTS_SSE2) && 0
#include <emmintrin.h>
#define BOTAN_SIMD_USE_SSE2
#elif defined(BOTAN_TARGET_SUPPORTS_ALTIVEC)
#include <altivec.h>
#undef vector
#undef bool
#define BOTAN_SIMD_USE_ALTIVEC
#endif
// TODO: NEON support
namespace Botan {
/**
* This class is not a general purpose SIMD type, and only offers
* instructions needed for evaluation of specific crypto primitives.
* For example it does not currently have equality operators of any
* kind.
*/
class SIMD_4x32
{
public:
SIMD_4x32() // zero initialized
{
#if defined(BOTAN_SIMD_USE_SSE2) || defined(BOTAN_SIMD_USE_ALTIVEC)
::memset(&m_reg, 0, sizeof(m_reg));
#else
::memset(m_reg, 0, sizeof(m_reg));
#endif
}
explicit SIMD_4x32(const u32bit B[4])
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_loadu_si128(reinterpret_cast<const __m128i*>(B));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = (__vector unsigned int){B[0], B[1], B[2], B[3]};
#else
m_reg[0] = B[0];
m_reg[1] = B[1];
m_reg[2] = B[2];
m_reg[3] = B[3];
#endif
}
SIMD_4x32(u32bit B0, u32bit B1, u32bit B2, u32bit B3)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_set_epi32(B0, B1, B2, B3);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = (__vector unsigned int){B0, B1, B2, B3};
#else
m_reg[0] = B0;
m_reg[1] = B1;
m_reg[2] = B2;
m_reg[3] = B3;
#endif
}
explicit SIMD_4x32(u32bit B)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_set1_epi32(B);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = (__vector unsigned int){B, B, B, B};
#else
m_reg[0] = B;
m_reg[1] = B;
m_reg[2] = B;
m_reg[3] = B;
#endif
}
static SIMD_4x32 load_le(const void* in)
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_loadu_si128(reinterpret_cast<const __m128i*>(in)));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
const u32bit* in_32 = static_cast<const u32bit*>(in);
__vector unsigned int R0 = vec_ld(0, in_32);
__vector unsigned int R1 = vec_ld(12, in_32);
__vector unsigned char perm = vec_lvsl(0, in_32);
perm = vec_xor(perm, vec_splat_u8(3));
R0 = vec_perm(R0, R1, perm);
return SIMD_4x32(R0);
#else
SIMD_4x32 out;
Botan::load_le(out.m_reg, static_cast<const uint8_t*>(in), 4);
return out;
#endif
}
static SIMD_4x32 load_be(const void* in)
{
#if defined(BOTAN_SIMD_USE_SSE2)
return load_le(in).bswap();
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
const u32bit* in_32 = static_cast<const u32bit*>(in);
__vector unsigned int R0 = vec_ld(0, in_32);
__vector unsigned int R1 = vec_ld(12, in_32);
__vector unsigned char perm = vec_lvsl(0, in_32);
R0 = vec_perm(R0, R1, perm);
return SIMD_4x32(R0);
#else
SIMD_4x32 out;
Botan::load_be(out.m_reg, static_cast<const uint8_t*>(in), 4);
return out;
#endif
}
void store_le(uint8_t out[]) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
_mm_storeu_si128(reinterpret_cast<__m128i*>(out), m_reg);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
__vector unsigned char perm = vec_lvsl(0, static_cast<u32bit*>(nullptr));
perm = vec_xor(perm, vec_splat_u8(3)); // bswap vector
union {
__vector unsigned int V;
u32bit R[4];
} vec;
vec.V = vec_perm(m_reg, m_reg, perm);
Botan::store_be(out, vec.R[0], vec.R[1], vec.R[2], vec.R[3]);
#else
Botan::store_le(out, m_reg[0], m_reg[1], m_reg[2], m_reg[3]);
#endif
}
void store_be(uint8_t out[]) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
bswap().store_le(out);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
union {
__vector unsigned int V;
u32bit R[4];
} vec;
vec.V = m_reg;
Botan::store_be(out, vec.R[0], vec.R[1], vec.R[2], vec.R[3]);
#else
Botan::store_be(out, m_reg[0], m_reg[1], m_reg[2], m_reg[3]);
#endif
}
void rotate_left(size_t rot)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_or_si128(_mm_slli_epi32(m_reg, static_cast<int>(rot)),
_mm_srli_epi32(m_reg, static_cast<int>(32-rot)));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
const unsigned int r = static_cast<unsigned int>(rot);
m_reg = vec_rl(m_reg, (__vector unsigned int){r, r, r, r});
#else
m_reg[0] = Botan::rotate_left(m_reg[0], rot);
m_reg[1] = Botan::rotate_left(m_reg[1], rot);
m_reg[2] = Botan::rotate_left(m_reg[2], rot);
m_reg[3] = Botan::rotate_left(m_reg[3], rot);
#endif
}
void rotate_right(size_t rot)
{
rotate_left(32 - rot);
}
void operator+=(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_add_epi32(m_reg, other.m_reg);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = vec_add(m_reg, other.m_reg);
#else
m_reg[0] += other.m_reg[0];
m_reg[1] += other.m_reg[1];
m_reg[2] += other.m_reg[2];
m_reg[3] += other.m_reg[3];
#endif
}
SIMD_4x32 operator+(const SIMD_4x32& other) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_add_epi32(m_reg, other.m_reg));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
return SIMD_4x32(vec_add(m_reg, other.m_reg));
#else
return SIMD_4x32(m_reg[0] + other.m_reg[0],
m_reg[1] + other.m_reg[1],
m_reg[2] + other.m_reg[2],
m_reg[3] + other.m_reg[3]);
#endif
}
void operator-=(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_sub_epi32(m_reg, other.m_reg);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = vec_sub(m_reg, other.m_reg);
#else
m_reg[0] -= other.m_reg[0];
m_reg[1] -= other.m_reg[1];
m_reg[2] -= other.m_reg[2];
m_reg[3] -= other.m_reg[3];
#endif
}
SIMD_4x32 operator-(const SIMD_4x32& other) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_sub_epi32(m_reg, other.m_reg));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
return SIMD_4x32(vec_sub(m_reg, other.m_reg));
#else
return SIMD_4x32(m_reg[0] - other.m_reg[0],
m_reg[1] - other.m_reg[1],
m_reg[2] - other.m_reg[2],
m_reg[3] - other.m_reg[3]);
#endif
}
void operator^=(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_xor_si128(m_reg, other.m_reg);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = vec_xor(m_reg, other.m_reg);
#else
m_reg[0] ^= other.m_reg[0];
m_reg[1] ^= other.m_reg[1];
m_reg[2] ^= other.m_reg[2];
m_reg[3] ^= other.m_reg[3];
#endif
}
SIMD_4x32 operator^(const SIMD_4x32& other) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_xor_si128(m_reg, other.m_reg));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
return SIMD_4x32(vec_xor(m_reg, other.m_reg));
#else
return SIMD_4x32(m_reg[0] ^ other.m_reg[0],
m_reg[1] ^ other.m_reg[1],
m_reg[2] ^ other.m_reg[2],
m_reg[3] ^ other.m_reg[3]);
#endif
}
void operator|=(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_or_si128(m_reg, other.m_reg);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = vec_or(m_reg, other.m_reg);
#else
m_reg[0] |= other.m_reg[0];
m_reg[1] |= other.m_reg[1];
m_reg[2] |= other.m_reg[2];
m_reg[3] |= other.m_reg[3];
#endif
}
SIMD_4x32 operator&(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_and_si128(m_reg, other.m_reg));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
return SIMD_4x32(vec_and(m_reg, other.m_reg));
#else
return SIMD_4x32(m_reg[0] & other.m_reg[0],
m_reg[1] & other.m_reg[1],
m_reg[2] & other.m_reg[2],
m_reg[3] & other.m_reg[3]);
#endif
}
void operator&=(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
m_reg = _mm_and_si128(m_reg, other.m_reg);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
m_reg = vec_and(m_reg, other.m_reg);
#else
m_reg[0] &= other.m_reg[0];
m_reg[1] &= other.m_reg[1];
m_reg[2] &= other.m_reg[2];
m_reg[3] &= other.m_reg[3];
#endif
}
SIMD_4x32 operator<<(size_t shift) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_slli_epi32(m_reg, static_cast<int>(shift)));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
const unsigned int s = static_cast<unsigned int>(shift);
return SIMD_4x32(vec_sl(m_reg, (__vector unsigned int){s, s, s, s}));
#else
return SIMD_4x32(m_reg[0] << shift,
m_reg[1] << shift,
m_reg[2] << shift,
m_reg[3] << shift);
#endif
}
SIMD_4x32 operator>>(size_t shift) const
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_srli_epi32(m_reg, static_cast<int>(shift)));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
const unsigned int s = static_cast<unsigned int>(shift);
return SIMD_4x32(vec_sr(m_reg, (__vector unsigned int){s, s, s, s}));
#else
return SIMD_4x32(m_reg[0] >> shift,
m_reg[1] >> shift,
m_reg[2] >> shift,
m_reg[3] >> shift);
#endif
}
SIMD_4x32 operator~() const
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_xor_si128(m_reg, _mm_set1_epi32(0xFFFFFFFF)));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
return SIMD_4x32(vec_nor(m_reg, m_reg));
#else
return SIMD_4x32(~m_reg[0],
~m_reg[1],
~m_reg[2],
~m_reg[3]);
#endif
}
// (~reg) & other
SIMD_4x32 andc(const SIMD_4x32& other)
{
#if defined(BOTAN_SIMD_USE_SSE2)
return SIMD_4x32(_mm_andnot_si128(m_reg, other.m_reg));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
/*
AltiVec does arg1 & ~arg2 rather than SSE's ~arg1 & arg2
so swap the arguments
*/
return SIMD_4x32(vec_andc(other.m_reg, m_reg));
#else
return SIMD_4x32((~m_reg[0]) & other.m_reg[0],
(~m_reg[1]) & other.m_reg[1],
(~m_reg[2]) & other.m_reg[2],
(~m_reg[3]) & other.m_reg[3]);
#endif
}
SIMD_4x32 bswap() const
{
#if defined(BOTAN_SIMD_USE_SSE2)
__m128i T = m_reg;
T = _mm_shufflehi_epi16(T, _MM_SHUFFLE(2, 3, 0, 1));
T = _mm_shufflelo_epi16(T, _MM_SHUFFLE(2, 3, 0, 1));
return SIMD_4x32(_mm_or_si128(_mm_srli_epi16(T, 8),
_mm_slli_epi16(T, 8)));
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
__vector unsigned char perm = vec_lvsl(0, static_cast<u32bit*>(nullptr));
perm = vec_xor(perm, vec_splat_u8(3));
return SIMD_4x32(vec_perm(m_reg, m_reg, perm));
#else
return SIMD_4x32(reverse_bytes(m_reg[0]),
reverse_bytes(m_reg[1]),
reverse_bytes(m_reg[2]),
reverse_bytes(m_reg[3]));
#endif
}
static void transpose(SIMD_4x32& B0, SIMD_4x32& B1,
SIMD_4x32& B2, SIMD_4x32& B3)
{
#if defined(BOTAN_SIMD_USE_SSE2)
__m128i T0 = _mm_unpacklo_epi32(B0.m_reg, B1.m_reg);
__m128i T1 = _mm_unpacklo_epi32(B2.m_reg, B3.m_reg);
__m128i T2 = _mm_unpackhi_epi32(B0.m_reg, B1.m_reg);
__m128i T3 = _mm_unpackhi_epi32(B2.m_reg, B3.m_reg);
B0.m_reg = _mm_unpacklo_epi64(T0, T1);
B1.m_reg = _mm_unpackhi_epi64(T0, T1);
B2.m_reg = _mm_unpacklo_epi64(T2, T3);
B3.m_reg = _mm_unpackhi_epi64(T2, T3);
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
__vector unsigned int T0 = vec_mergeh(B0.m_reg, B2.m_reg);
__vector unsigned int T1 = vec_mergel(B0.m_reg, B2.m_reg);
__vector unsigned int T2 = vec_mergeh(B1.m_reg, B3.m_reg);
__vector unsigned int T3 = vec_mergel(B1.m_reg, B3.m_reg);
B0.m_reg = vec_mergeh(T0, T2);
B1.m_reg = vec_mergel(T0, T2);
B2.m_reg = vec_mergeh(T1, T3);
B3.m_reg = vec_mergel(T1, T3);
#else
SIMD_4x32 T0(B0.m_reg[0], B1.m_reg[0], B2.m_reg[0], B3.m_reg[0]);
SIMD_4x32 T1(B0.m_reg[1], B1.m_reg[1], B2.m_reg[1], B3.m_reg[1]);
SIMD_4x32 T2(B0.m_reg[2], B1.m_reg[2], B2.m_reg[2], B3.m_reg[2]);
SIMD_4x32 T3(B0.m_reg[3], B1.m_reg[3], B2.m_reg[3], B3.m_reg[3]);
B0 = T0;
B1 = T1;
B2 = T2;
B3 = T3;
#endif
}
private:
#if defined(BOTAN_SIMD_USE_SSE2)
explicit SIMD_4x32(__m128i in) { m_reg = in; }
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
explicit SIMD_4x32(__vector unsigned int input) { m_reg = input; }
#endif
#if defined(BOTAN_SIMD_USE_SSE2)
__m128i m_reg;
#elif defined(BOTAN_SIMD_USE_ALTIVEC)
__vector unsigned int m_reg;
#else
uint32_t m_reg[4];
#endif
};
typedef SIMD_4x32 SIMD_32;
}
#endif
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