1// This file is part of Eigen, a lightweight C++ template library 2// for linear algebra. 3// 4// Copyright (C) 2008-2009 Gael Guennebaud <gael.guennebaud@inria.fr> 5// Copyright (C) 2010 Konstantinos Margaritis <markos@codex.gr> 6// Heavily based on Gael's SSE version. 7// 8// This Source Code Form is subject to the terms of the Mozilla 9// Public License v. 2.0. If a copy of the MPL was not distributed 10// with this file, You can obtain one at http://mozilla.org/MPL/2.0/. 11 12#ifndef EIGEN_PACKET_MATH_NEON_H 13#define EIGEN_PACKET_MATH_NEON_H 14 15namespace Eigen { 16 17namespace internal { 18 19#ifndef EIGEN_CACHEFRIENDLY_PRODUCT_THRESHOLD 20#define EIGEN_CACHEFRIENDLY_PRODUCT_THRESHOLD 8 21#endif 22 23// FIXME NEON has 16 quad registers, but since the current register allocator 24// is so bad, it is much better to reduce it to 8 25#ifndef EIGEN_ARCH_DEFAULT_NUMBER_OF_REGISTERS 26#define EIGEN_ARCH_DEFAULT_NUMBER_OF_REGISTERS 8 27#endif 28 29typedef float32x4_t Packet4f; 30typedef int32x4_t Packet4i; 31typedef uint32x4_t Packet4ui; 32 33#define _EIGEN_DECLARE_CONST_Packet4f(NAME,X) \ 34 const Packet4f p4f_##NAME = pset1<Packet4f>(X) 35 36#define _EIGEN_DECLARE_CONST_Packet4f_FROM_INT(NAME,X) \ 37 const Packet4f p4f_##NAME = vreinterpretq_f32_u32(pset1<int>(X)) 38 39#define _EIGEN_DECLARE_CONST_Packet4i(NAME,X) \ 40 const Packet4i p4i_##NAME = pset1<Packet4i>(X) 41 42#if defined(__llvm__) && !defined(__clang__) 43 //Special treatment for Apple's llvm-gcc, its NEON packet types are unions 44 #define EIGEN_INIT_NEON_PACKET2(X, Y) {{X, Y}} 45 #define EIGEN_INIT_NEON_PACKET4(X, Y, Z, W) {{X, Y, Z, W}} 46#else 47 //Default initializer for packets 48 #define EIGEN_INIT_NEON_PACKET2(X, Y) {X, Y} 49 #define EIGEN_INIT_NEON_PACKET4(X, Y, Z, W) {X, Y, Z, W} 50#endif 51 52#ifndef __pld 53#define __pld(x) asm volatile ( " pld [%[addr]]\n" :: [addr] "r" (x) : "cc" ); 54#endif 55 56template<> struct packet_traits<float> : default_packet_traits 57{ 58 typedef Packet4f type; 59 enum { 60 Vectorizable = 1, 61 AlignedOnScalar = 1, 62 size = 4, 63 64 HasDiv = 1, 65 // FIXME check the Has* 66 HasSin = 0, 67 HasCos = 0, 68 HasLog = 0, 69 HasExp = 0, 70 HasSqrt = 0 71 }; 72}; 73template<> struct packet_traits<int> : default_packet_traits 74{ 75 typedef Packet4i type; 76 enum { 77 Vectorizable = 1, 78 AlignedOnScalar = 1, 79 size=4 80 // FIXME check the Has* 81 }; 82}; 83 84#if EIGEN_GNUC_AT_MOST(4,4) && !defined(__llvm__) 85// workaround gcc 4.2, 4.3 and 4.4 compilatin issue 86EIGEN_STRONG_INLINE float32x4_t vld1q_f32(const float* x) { return ::vld1q_f32((const float32_t*)x); } 87EIGEN_STRONG_INLINE float32x2_t vld1_f32 (const float* x) { return ::vld1_f32 ((const float32_t*)x); } 88EIGEN_STRONG_INLINE void vst1q_f32(float* to, float32x4_t from) { ::vst1q_f32((float32_t*)to,from); } 89EIGEN_STRONG_INLINE void vst1_f32 (float* to, float32x2_t from) { ::vst1_f32 ((float32_t*)to,from); } 90#endif 91 92template<> struct unpacket_traits<Packet4f> { typedef float type; enum {size=4}; }; 93template<> struct unpacket_traits<Packet4i> { typedef int type; enum {size=4}; }; 94 95template<> EIGEN_STRONG_INLINE Packet4f pset1<Packet4f>(const float& from) { return vdupq_n_f32(from); } 96template<> EIGEN_STRONG_INLINE Packet4i pset1<Packet4i>(const int& from) { return vdupq_n_s32(from); } 97 98template<> EIGEN_STRONG_INLINE Packet4f plset<float>(const float& a) 99{ 100 Packet4f countdown = EIGEN_INIT_NEON_PACKET4(0, 1, 2, 3); 101 return vaddq_f32(pset1<Packet4f>(a), countdown); 102} 103template<> EIGEN_STRONG_INLINE Packet4i plset<int>(const int& a) 104{ 105 Packet4i countdown = EIGEN_INIT_NEON_PACKET4(0, 1, 2, 3); 106 return vaddq_s32(pset1<Packet4i>(a), countdown); 107} 108 109template<> EIGEN_STRONG_INLINE Packet4f padd<Packet4f>(const Packet4f& a, const Packet4f& b) { return vaddq_f32(a,b); } 110template<> EIGEN_STRONG_INLINE Packet4i padd<Packet4i>(const Packet4i& a, const Packet4i& b) { return vaddq_s32(a,b); } 111 112template<> EIGEN_STRONG_INLINE Packet4f psub<Packet4f>(const Packet4f& a, const Packet4f& b) { return vsubq_f32(a,b); } 113template<> EIGEN_STRONG_INLINE Packet4i psub<Packet4i>(const Packet4i& a, const Packet4i& b) { return vsubq_s32(a,b); } 114 115template<> EIGEN_STRONG_INLINE Packet4f pnegate(const Packet4f& a) { return vnegq_f32(a); } 116template<> EIGEN_STRONG_INLINE Packet4i pnegate(const Packet4i& a) { return vnegq_s32(a); } 117 118template<> EIGEN_STRONG_INLINE Packet4f pconj(const Packet4f& a) { return a; } 119template<> EIGEN_STRONG_INLINE Packet4i pconj(const Packet4i& a) { return a; } 120 121template<> EIGEN_STRONG_INLINE Packet4f pmul<Packet4f>(const Packet4f& a, const Packet4f& b) { return vmulq_f32(a,b); } 122template<> EIGEN_STRONG_INLINE Packet4i pmul<Packet4i>(const Packet4i& a, const Packet4i& b) { return vmulq_s32(a,b); } 123 124template<> EIGEN_STRONG_INLINE Packet4f pdiv<Packet4f>(const Packet4f& a, const Packet4f& b) 125{ 126 Packet4f inv, restep, div; 127 128 // NEON does not offer a divide instruction, we have to do a reciprocal approximation 129 // However NEON in contrast to other SIMD engines (AltiVec/SSE), offers 130 // a reciprocal estimate AND a reciprocal step -which saves a few instructions 131 // vrecpeq_f32() returns an estimate to 1/b, which we will finetune with 132 // Newton-Raphson and vrecpsq_f32() 133 inv = vrecpeq_f32(b); 134 135 // This returns a differential, by which we will have to multiply inv to get a better 136 // approximation of 1/b. 137 restep = vrecpsq_f32(b, inv); 138 inv = vmulq_f32(restep, inv); 139 140 // Finally, multiply a by 1/b and get the wanted result of the division. 141 div = vmulq_f32(a, inv); 142 143 return div; 144} 145template<> EIGEN_STRONG_INLINE Packet4i pdiv<Packet4i>(const Packet4i& /*a*/, const Packet4i& /*b*/) 146{ eigen_assert(false && "packet integer division are not supported by NEON"); 147 return pset1<Packet4i>(0); 148} 149 150// for some weird raisons, it has to be overloaded for packet of integers 151template<> EIGEN_STRONG_INLINE Packet4f pmadd(const Packet4f& a, const Packet4f& b, const Packet4f& c) { return vmlaq_f32(c,a,b); } 152template<> EIGEN_STRONG_INLINE Packet4i pmadd(const Packet4i& a, const Packet4i& b, const Packet4i& c) { return vmlaq_s32(c,a,b); } 153 154template<> EIGEN_STRONG_INLINE Packet4f pmin<Packet4f>(const Packet4f& a, const Packet4f& b) { return vminq_f32(a,b); } 155template<> EIGEN_STRONG_INLINE Packet4i pmin<Packet4i>(const Packet4i& a, const Packet4i& b) { return vminq_s32(a,b); } 156 157template<> EIGEN_STRONG_INLINE Packet4f pmax<Packet4f>(const Packet4f& a, const Packet4f& b) { return vmaxq_f32(a,b); } 158template<> EIGEN_STRONG_INLINE Packet4i pmax<Packet4i>(const Packet4i& a, const Packet4i& b) { return vmaxq_s32(a,b); } 159 160// Logical Operations are not supported for float, so we have to reinterpret casts using NEON intrinsics 161template<> EIGEN_STRONG_INLINE Packet4f pand<Packet4f>(const Packet4f& a, const Packet4f& b) 162{ 163 return vreinterpretq_f32_u32(vandq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b))); 164} 165template<> EIGEN_STRONG_INLINE Packet4i pand<Packet4i>(const Packet4i& a, const Packet4i& b) { return vandq_s32(a,b); } 166 167template<> EIGEN_STRONG_INLINE Packet4f por<Packet4f>(const Packet4f& a, const Packet4f& b) 168{ 169 return vreinterpretq_f32_u32(vorrq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b))); 170} 171template<> EIGEN_STRONG_INLINE Packet4i por<Packet4i>(const Packet4i& a, const Packet4i& b) { return vorrq_s32(a,b); } 172 173template<> EIGEN_STRONG_INLINE Packet4f pxor<Packet4f>(const Packet4f& a, const Packet4f& b) 174{ 175 return vreinterpretq_f32_u32(veorq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b))); 176} 177template<> EIGEN_STRONG_INLINE Packet4i pxor<Packet4i>(const Packet4i& a, const Packet4i& b) { return veorq_s32(a,b); } 178 179template<> EIGEN_STRONG_INLINE Packet4f pandnot<Packet4f>(const Packet4f& a, const Packet4f& b) 180{ 181 return vreinterpretq_f32_u32(vbicq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b))); 182} 183template<> EIGEN_STRONG_INLINE Packet4i pandnot<Packet4i>(const Packet4i& a, const Packet4i& b) { return vbicq_s32(a,b); } 184 185template<> EIGEN_STRONG_INLINE Packet4f pload<Packet4f>(const float* from) { EIGEN_DEBUG_ALIGNED_LOAD return vld1q_f32(from); } 186template<> EIGEN_STRONG_INLINE Packet4i pload<Packet4i>(const int* from) { EIGEN_DEBUG_ALIGNED_LOAD return vld1q_s32(from); } 187 188template<> EIGEN_STRONG_INLINE Packet4f ploadu<Packet4f>(const float* from) { EIGEN_DEBUG_UNALIGNED_LOAD return vld1q_f32(from); } 189template<> EIGEN_STRONG_INLINE Packet4i ploadu<Packet4i>(const int* from) { EIGEN_DEBUG_UNALIGNED_LOAD return vld1q_s32(from); } 190 191template<> EIGEN_STRONG_INLINE Packet4f ploaddup<Packet4f>(const float* from) 192{ 193 float32x2_t lo, hi; 194 lo = vld1_dup_f32(from); 195 hi = vld1_dup_f32(from+1); 196 return vcombine_f32(lo, hi); 197} 198template<> EIGEN_STRONG_INLINE Packet4i ploaddup<Packet4i>(const int* from) 199{ 200 int32x2_t lo, hi; 201 lo = vld1_dup_s32(from); 202 hi = vld1_dup_s32(from+1); 203 return vcombine_s32(lo, hi); 204} 205 206template<> EIGEN_STRONG_INLINE void pstore<float>(float* to, const Packet4f& from) { EIGEN_DEBUG_ALIGNED_STORE vst1q_f32(to, from); } 207template<> EIGEN_STRONG_INLINE void pstore<int>(int* to, const Packet4i& from) { EIGEN_DEBUG_ALIGNED_STORE vst1q_s32(to, from); } 208 209template<> EIGEN_STRONG_INLINE void pstoreu<float>(float* to, const Packet4f& from) { EIGEN_DEBUG_UNALIGNED_STORE vst1q_f32(to, from); } 210template<> EIGEN_STRONG_INLINE void pstoreu<int>(int* to, const Packet4i& from) { EIGEN_DEBUG_UNALIGNED_STORE vst1q_s32(to, from); } 211 212template<> EIGEN_STRONG_INLINE void prefetch<float>(const float* addr) { __pld(addr); } 213template<> EIGEN_STRONG_INLINE void prefetch<int>(const int* addr) { __pld(addr); } 214 215// FIXME only store the 2 first elements ? 216template<> EIGEN_STRONG_INLINE float pfirst<Packet4f>(const Packet4f& a) { float EIGEN_ALIGN16 x[4]; vst1q_f32(x, a); return x[0]; } 217template<> EIGEN_STRONG_INLINE int pfirst<Packet4i>(const Packet4i& a) { int EIGEN_ALIGN16 x[4]; vst1q_s32(x, a); return x[0]; } 218 219template<> EIGEN_STRONG_INLINE Packet4f preverse(const Packet4f& a) { 220 float32x2_t a_lo, a_hi; 221 Packet4f a_r64; 222 223 a_r64 = vrev64q_f32(a); 224 a_lo = vget_low_f32(a_r64); 225 a_hi = vget_high_f32(a_r64); 226 return vcombine_f32(a_hi, a_lo); 227} 228template<> EIGEN_STRONG_INLINE Packet4i preverse(const Packet4i& a) { 229 int32x2_t a_lo, a_hi; 230 Packet4i a_r64; 231 232 a_r64 = vrev64q_s32(a); 233 a_lo = vget_low_s32(a_r64); 234 a_hi = vget_high_s32(a_r64); 235 return vcombine_s32(a_hi, a_lo); 236} 237template<> EIGEN_STRONG_INLINE Packet4f pabs(const Packet4f& a) { return vabsq_f32(a); } 238template<> EIGEN_STRONG_INLINE Packet4i pabs(const Packet4i& a) { return vabsq_s32(a); } 239 240template<> EIGEN_STRONG_INLINE float predux<Packet4f>(const Packet4f& a) 241{ 242 float32x2_t a_lo, a_hi, sum; 243 244 a_lo = vget_low_f32(a); 245 a_hi = vget_high_f32(a); 246 sum = vpadd_f32(a_lo, a_hi); 247 sum = vpadd_f32(sum, sum); 248 return vget_lane_f32(sum, 0); 249} 250 251template<> EIGEN_STRONG_INLINE Packet4f preduxp<Packet4f>(const Packet4f* vecs) 252{ 253 float32x4x2_t vtrn1, vtrn2, res1, res2; 254 Packet4f sum1, sum2, sum; 255 256 // NEON zip performs interleaving of the supplied vectors. 257 // We perform two interleaves in a row to acquire the transposed vector 258 vtrn1 = vzipq_f32(vecs[0], vecs[2]); 259 vtrn2 = vzipq_f32(vecs[1], vecs[3]); 260 res1 = vzipq_f32(vtrn1.val[0], vtrn2.val[0]); 261 res2 = vzipq_f32(vtrn1.val[1], vtrn2.val[1]); 262 263 // Do the addition of the resulting vectors 264 sum1 = vaddq_f32(res1.val[0], res1.val[1]); 265 sum2 = vaddq_f32(res2.val[0], res2.val[1]); 266 sum = vaddq_f32(sum1, sum2); 267 268 return sum; 269} 270 271template<> EIGEN_STRONG_INLINE int predux<Packet4i>(const Packet4i& a) 272{ 273 int32x2_t a_lo, a_hi, sum; 274 275 a_lo = vget_low_s32(a); 276 a_hi = vget_high_s32(a); 277 sum = vpadd_s32(a_lo, a_hi); 278 sum = vpadd_s32(sum, sum); 279 return vget_lane_s32(sum, 0); 280} 281 282template<> EIGEN_STRONG_INLINE Packet4i preduxp<Packet4i>(const Packet4i* vecs) 283{ 284 int32x4x2_t vtrn1, vtrn2, res1, res2; 285 Packet4i sum1, sum2, sum; 286 287 // NEON zip performs interleaving of the supplied vectors. 288 // We perform two interleaves in a row to acquire the transposed vector 289 vtrn1 = vzipq_s32(vecs[0], vecs[2]); 290 vtrn2 = vzipq_s32(vecs[1], vecs[3]); 291 res1 = vzipq_s32(vtrn1.val[0], vtrn2.val[0]); 292 res2 = vzipq_s32(vtrn1.val[1], vtrn2.val[1]); 293 294 // Do the addition of the resulting vectors 295 sum1 = vaddq_s32(res1.val[0], res1.val[1]); 296 sum2 = vaddq_s32(res2.val[0], res2.val[1]); 297 sum = vaddq_s32(sum1, sum2); 298 299 return sum; 300} 301 302// Other reduction functions: 303// mul 304template<> EIGEN_STRONG_INLINE float predux_mul<Packet4f>(const Packet4f& a) 305{ 306 float32x2_t a_lo, a_hi, prod; 307 308 // Get a_lo = |a1|a2| and a_hi = |a3|a4| 309 a_lo = vget_low_f32(a); 310 a_hi = vget_high_f32(a); 311 // Get the product of a_lo * a_hi -> |a1*a3|a2*a4| 312 prod = vmul_f32(a_lo, a_hi); 313 // Multiply prod with its swapped value |a2*a4|a1*a3| 314 prod = vmul_f32(prod, vrev64_f32(prod)); 315 316 return vget_lane_f32(prod, 0); 317} 318template<> EIGEN_STRONG_INLINE int predux_mul<Packet4i>(const Packet4i& a) 319{ 320 int32x2_t a_lo, a_hi, prod; 321 322 // Get a_lo = |a1|a2| and a_hi = |a3|a4| 323 a_lo = vget_low_s32(a); 324 a_hi = vget_high_s32(a); 325 // Get the product of a_lo * a_hi -> |a1*a3|a2*a4| 326 prod = vmul_s32(a_lo, a_hi); 327 // Multiply prod with its swapped value |a2*a4|a1*a3| 328 prod = vmul_s32(prod, vrev64_s32(prod)); 329 330 return vget_lane_s32(prod, 0); 331} 332 333// min 334template<> EIGEN_STRONG_INLINE float predux_min<Packet4f>(const Packet4f& a) 335{ 336 float32x2_t a_lo, a_hi, min; 337 338 a_lo = vget_low_f32(a); 339 a_hi = vget_high_f32(a); 340 min = vpmin_f32(a_lo, a_hi); 341 min = vpmin_f32(min, min); 342 343 return vget_lane_f32(min, 0); 344} 345 346template<> EIGEN_STRONG_INLINE int predux_min<Packet4i>(const Packet4i& a) 347{ 348 int32x2_t a_lo, a_hi, min; 349 350 a_lo = vget_low_s32(a); 351 a_hi = vget_high_s32(a); 352 min = vpmin_s32(a_lo, a_hi); 353 min = vpmin_s32(min, min); 354 355 return vget_lane_s32(min, 0); 356} 357 358// max 359template<> EIGEN_STRONG_INLINE float predux_max<Packet4f>(const Packet4f& a) 360{ 361 float32x2_t a_lo, a_hi, max; 362 363 a_lo = vget_low_f32(a); 364 a_hi = vget_high_f32(a); 365 max = vpmax_f32(a_lo, a_hi); 366 max = vpmax_f32(max, max); 367 368 return vget_lane_f32(max, 0); 369} 370 371template<> EIGEN_STRONG_INLINE int predux_max<Packet4i>(const Packet4i& a) 372{ 373 int32x2_t a_lo, a_hi, max; 374 375 a_lo = vget_low_s32(a); 376 a_hi = vget_high_s32(a); 377 max = vpmax_s32(a_lo, a_hi); 378 379 return vget_lane_s32(max, 0); 380} 381 382// this PALIGN_NEON business is to work around a bug in LLVM Clang 3.0 causing incorrect compilation errors, 383// see bug 347 and this LLVM bug: http://llvm.org/bugs/show_bug.cgi?id=11074 384#define PALIGN_NEON(Offset,Type,Command) \ 385template<>\ 386struct palign_impl<Offset,Type>\ 387{\ 388 EIGEN_STRONG_INLINE static void run(Type& first, const Type& second)\ 389 {\ 390 if (Offset!=0)\ 391 first = Command(first, second, Offset);\ 392 }\ 393};\ 394 395PALIGN_NEON(0,Packet4f,vextq_f32) 396PALIGN_NEON(1,Packet4f,vextq_f32) 397PALIGN_NEON(2,Packet4f,vextq_f32) 398PALIGN_NEON(3,Packet4f,vextq_f32) 399PALIGN_NEON(0,Packet4i,vextq_s32) 400PALIGN_NEON(1,Packet4i,vextq_s32) 401PALIGN_NEON(2,Packet4i,vextq_s32) 402PALIGN_NEON(3,Packet4i,vextq_s32) 403 404#undef PALIGN_NEON 405 406} // end namespace internal 407 408} // end namespace Eigen 409 410#endif // EIGEN_PACKET_MATH_NEON_H 411