POWER7+ VSX support plus AES hardware support for POWER8 and newer. (#41)

This commit is contained in:
Judemir Ribeiro 2019-06-22 09:54:02 -04:00 committed by tevador
parent 8ff1bf027a
commit 776723dd40
2 changed files with 226 additions and 0 deletions

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@ -22,6 +22,14 @@ ifeq ($(PLATFORM),x86_64)
CXXFLAGS += -maes CXXFLAGS += -maes
endif endif
ifeq ($(PLATFORM),ppc64)
CXXFLAGS += -mcpu=native
endif
ifeq ($(PLATFORM),ppc64le)
CXXFLAGS += -mcpu=native
endif
release: CXXFLAGS += -O3 -flto release: CXXFLAGS += -O3 -flto
release: CCFLAGS += -O3 -flto release: CCFLAGS += -O3 -flto
release: LDFLAGS += -flto release: LDFLAGS += -flto

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@ -160,7 +160,225 @@ FORCE_INLINE void rx_set_rounding_mode(uint32_t mode) {
_mm_setcsr(rx_mxcsr_default | (mode << 13)); _mm_setcsr(rx_mxcsr_default | (mode << 13));
} }
#elif defined(__PPC64__) && defined(__ALTIVEC__) && defined(__VSX__) //sadly only POWER7 and newer will be able to use SIMD acceleration. Earlier processors cant use doubles or 64 bit integers with SIMD
#include <cstdint>
#include <stdexcept>
#include <cstdlib>
#include<altivec.h>
#undef vector
#undef pixel
#undef bool
typedef __vector uint8_t __m128i;
typedef __vector uint32_t __m128l;
typedef __vector int __m128li;
typedef __vector uint64_t __m128ll;
typedef __vector double __m128d;
typedef __m128i rx_vec_i128;
typedef __m128d rx_vec_f128;
typedef union{
rx_vec_i128 i;
rx_vec_f128 d;
uint64_t u64[2];
double d64[2];
uint32_t u32[4];
int i32[4];
} vec_u;
#define rx_aligned_alloc(a, b) malloc(a)
#define rx_aligned_free(a) free(a)
#define rx_prefetch_nta(x)
/* Splat 64-bit long long to 2 64-bit long longs */
FORCE_INLINE __m128i vec_splat2sd (int64_t scalar)
{ return (__m128i) vec_splats (scalar); }
FORCE_INLINE rx_vec_f128 rx_load_vec_f128(const double* pd) {
#if defined(NATIVE_LITTLE_ENDIAN)
return (rx_vec_f128)vec_vsx_ld(0,pd);
#else #else
vec_u t;
t.u64[0] = load64(pd + 0);
t.u64[1] = load64(pd + 1);
return (rx_vec_f128)t.d;
#endif
}
FORCE_INLINE void rx_store_vec_f128(double* mem_addr, rx_vec_f128 a) {
#if defined(NATIVE_LITTLE_ENDIAN)
vec_vsx_st(a,0,(rx_vec_f128*)mem_addr);
#else
vec_u _a;
_a.d = a;
store64(mem_addr + 0, _a.u64[0]);
store64(mem_addr + 1, _a.u64[1]);
#endif
}
FORCE_INLINE rx_vec_f128 rx_swap_vec_f128(rx_vec_f128 a) {
return (rx_vec_f128)vec_perm((__m128i)a,(__m128i)a,(__m128i){8,9,10,11,12,13,14,15,0,1,2,3,4,5,6,7});
}
FORCE_INLINE rx_vec_f128 rx_add_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_add(a,b);
}
FORCE_INLINE rx_vec_f128 rx_sub_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_sub(a,b);
}
FORCE_INLINE rx_vec_f128 rx_mul_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_mul(a,b);
}
FORCE_INLINE rx_vec_f128 rx_div_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_div(a,b);
}
FORCE_INLINE rx_vec_f128 rx_sqrt_vec_f128(rx_vec_f128 a) {
return (rx_vec_f128)vec_sqrt(a);
}
FORCE_INLINE rx_vec_i128 rx_set1_long_vec_i128(uint64_t a) {
return (rx_vec_i128)vec_splat2sd(a);
}
FORCE_INLINE rx_vec_f128 rx_vec_i128_vec_f128(rx_vec_i128 a) {
return (rx_vec_f128)a;
}
FORCE_INLINE rx_vec_f128 rx_set_vec_f128(uint64_t x1, uint64_t x0) {
return (rx_vec_f128)(__m128ll){x0,x1};
}
FORCE_INLINE rx_vec_f128 rx_set1_vec_f128(uint64_t x) {
return (rx_vec_f128)vec_splat2sd(x);
}
FORCE_INLINE rx_vec_f128 rx_xor_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_xor(a,b);
}
FORCE_INLINE rx_vec_f128 rx_and_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_and(a,b);
}
FORCE_INLINE rx_vec_f128 rx_or_vec_f128(rx_vec_f128 a, rx_vec_f128 b) {
return (rx_vec_f128)vec_or(a,b);
}
#if defined(__CRYPTO__)
FORCE_INLINE __m128ll vrev(__m128i v){
#if defined(NATIVE_LITTLE_ENDIAN)
return (__m128ll)vec_perm((__m128i)v,(__m128i){0},(__m128i){15,14,13,12,11,10,9,8,7,6,5,4,3,2,1,0});
#else
return (__m128ll)vec_perm((__m128i)v,(__m128i){0},(__m128i){3,2,1,0, 7,6,5,4, 11,10,9,8, 15,14,13,12});
#endif
}
FORCE_INLINE rx_vec_i128 rx_aesenc_vec_i128(rx_vec_i128 v, rx_vec_i128 rkey) {
__m128ll _v = vrev(v);
__m128ll _rkey = vrev(rkey);
__m128ll result = vrev((__m128i)__builtin_crypto_vcipher(_v,_rkey));
return (rx_vec_i128)result;
}
FORCE_INLINE rx_vec_i128 rx_aesdec_vec_i128(rx_vec_i128 v, rx_vec_i128 rkey) {
__m128ll _v = vrev(v);
__m128ll zero = (__m128ll){0};
__m128ll out = vrev((__m128i)__builtin_crypto_vncipher(_v,zero));
return (rx_vec_i128)vec_xor((__m128i)out,rkey);
}
#else
static const char* platformError = "Platform doesn't support hardware AES";
FORCE_INLINE rx_vec_i128 rx_aesenc_vec_i128(rx_vec_i128 v, rx_vec_i128 rkey) {
throw std::runtime_error(platformError);
}
FORCE_INLINE rx_vec_i128 rx_aesdec_vec_i128(rx_vec_i128 v, rx_vec_i128 rkey) {
throw std::runtime_error(platformError);
}
#endif
FORCE_INLINE int rx_vec_i128_x(rx_vec_i128 a) {
vec_u _a;
_a.i = a;
return _a.i32[0];
}
FORCE_INLINE int rx_vec_i128_y(rx_vec_i128 a) {
vec_u _a;
_a.i = a;
return _a.i32[1];
}
FORCE_INLINE int rx_vec_i128_z(rx_vec_i128 a) {
vec_u _a;
_a.i = a;
return _a.i32[2];
}
FORCE_INLINE int rx_vec_i128_w(rx_vec_i128 a) {
vec_u _a;
_a.i = a;
return _a.i32[3];
}
FORCE_INLINE rx_vec_i128 rx_set_int_vec_i128(int _I3, int _I2, int _I1, int _I0) {
return (rx_vec_i128)((__m128li){_I0,_I1,_I2,_I3});
};
FORCE_INLINE rx_vec_i128 rx_xor_vec_i128(rx_vec_i128 _A, rx_vec_i128 _B) {
return (rx_vec_i128)vec_xor(_A,_B);
}
FORCE_INLINE rx_vec_i128 rx_load_vec_i128(rx_vec_i128 const *_P) {
#if defined(NATIVE_LITTLE_ENDIAN)
return *_P;
#else
uint32_t* ptr = (uint32_t*)_P;
vec_u c;
c.u32[0] = load32(ptr + 0);
c.u32[1] = load32(ptr + 1);
c.u32[2] = load32(ptr + 2);
c.u32[3] = load32(ptr + 3);
return (rx_vec_i128)c.i;
#endif
}
FORCE_INLINE void rx_store_vec_i128(rx_vec_i128 *_P, rx_vec_i128 _B) {
#if defined(NATIVE_LITTLE_ENDIAN)
*_P = _B;
#else
uint32_t* ptr = (uint32_t*)_P;
vec_u B;
B.i = _B;
store32(ptr + 0, B.u32[0]);
store32(ptr + 1, B.u32[1]);
store32(ptr + 2, B.u32[2]);
store32(ptr + 3, B.u32[3]);
#endif
}
FORCE_INLINE rx_vec_f128 rx_cvt_packed_int_vec_f128(const void* addr) {
vec_u x;
x.d64[0] = (double)unsigned32ToSigned2sCompl(load32((uint8_t*)addr + 0));
x.d64[1] = (double)unsigned32ToSigned2sCompl(load32((uint8_t*)addr + 4));
return (rx_vec_f128)x.d;
}
#define RANDOMX_DEFAULT_FENV
void rx_reset_float_state();
void rx_set_rounding_mode(uint32_t mode);
#else //end altivec
#include <cstdint> #include <cstdint>
#include <stdexcept> #include <stdexcept>
#include <cstdlib> #include <cstdlib>