/home/docs/checkouts/readthedocs.org/user_builds/advanced-micro-devices-rocrand/checkouts/docs-6.2.0/library/include/rocrand/rocrand_normal.h Source File

/home/docs/checkouts/readthedocs.org/user_builds/advanced-micro-devices-rocrand/checkouts/docs-6.2.0/library/include/rocrand/rocrand_normal.h Source File#

API library: /home/docs/checkouts/readthedocs.org/user_builds/advanced-micro-devices-rocrand/checkouts/docs-6.2.0/library/include/rocrand/rocrand_normal.h Source File
API library
rocrand_normal.h
1 // Copyright (c) 2017-2024 Advanced Micro Devices, Inc. All rights reserved.
2 //
3 // Permission is hereby granted, free of charge, to any person obtaining a copy
4 // of this software and associated documentation files (the "Software"), to deal
5 // in the Software without restriction, including without limitation the rights
6 // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
7 // copies of the Software, and to permit persons to whom the Software is
8 // furnished to do so, subject to the following conditions:
9 //
10 // The above copyright notice and this permission notice shall be included in
11 // all copies or substantial portions of the Software.
12 //
13 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
14 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
15 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
16 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
17 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
18 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
19 // THE SOFTWARE.
20 
21 #ifndef ROCRAND_NORMAL_H_
22 #define ROCRAND_NORMAL_H_
23 
29 #include <math.h>
30 
31 #include "rocrand/rocrand_lfsr113.h"
32 #include "rocrand/rocrand_mrg31k3p.h"
33 #include "rocrand/rocrand_mrg32k3a.h"
34 #include "rocrand/rocrand_mtgp32.h"
35 #include "rocrand/rocrand_philox4x32_10.h"
36 #include "rocrand/rocrand_scrambled_sobol32.h"
37 #include "rocrand/rocrand_scrambled_sobol64.h"
38 #include "rocrand/rocrand_sobol32.h"
39 #include "rocrand/rocrand_sobol64.h"
40 #include "rocrand/rocrand_threefry2x32_20.h"
41 #include "rocrand/rocrand_threefry2x64_20.h"
42 #include "rocrand/rocrand_threefry4x32_20.h"
43 #include "rocrand/rocrand_threefry4x64_20.h"
44 #include "rocrand/rocrand_xorwow.h"
45 
46 #include "rocrand/rocrand_uniform.h"
47 
48 namespace rocrand_device {
49 namespace detail {
50 
51 __forceinline__ __device__ __host__ float2 box_muller(unsigned int x, unsigned int y)
52 {
53  float2 result;
54  float u = ROCRAND_2POW32_INV + (x * ROCRAND_2POW32_INV);
55  float v = ROCRAND_2POW32_INV_2PI + (y * ROCRAND_2POW32_INV_2PI);
56  float s = sqrtf(-2.0f * logf(u));
57  #ifdef __HIP_DEVICE_COMPILE__
58  __sincosf(v, &result.x, &result.y);
59  result.x *= s;
60  result.y *= s;
61  #else
62  result.x = sinf(v) * s;
63  result.y = cosf(v) * s;
64  #endif
65  return result;
66 }
67 
68 __forceinline__ __device__ __host__ float2 box_muller(unsigned long long v)
69 {
70  unsigned int x = static_cast<unsigned int>(v);
71  unsigned int y = static_cast<unsigned int>(v >> 32);
72 
73  return box_muller(x, y);
74 }
75 
76 __forceinline__ __device__ __host__ double2 box_muller_double(uint4 v)
77 {
78  double2 result;
79  unsigned long long int v1 = (unsigned long long int)v.x ^
80  ((unsigned long long int)v.y << (53 - 32));
81  double u = ROCRAND_2POW53_INV_DOUBLE + (v1 * ROCRAND_2POW53_INV_DOUBLE);
82  unsigned long long int v2 = (unsigned long long int)v.z ^
83  ((unsigned long long int)v.w << (53 - 32));
84  double w = (ROCRAND_2POW53_INV_DOUBLE * 2.0) +
85  (v2 * (ROCRAND_2POW53_INV_DOUBLE * 2.0));
86  double s = sqrt(-2.0 * log(u));
87  #ifdef __HIP_DEVICE_COMPILE__
88  sincospi(w, &result.x, &result.y);
89  result.x *= s;
90  result.y *= s;
91  #else
92  result.x = sin(w * ROCRAND_PI_DOUBLE) * s;
93  result.y = cos(w * ROCRAND_PI_DOUBLE) * s;
94  #endif
95  return result;
96 }
97 
98 __forceinline__ __device__ __host__ double2 box_muller_double(ulonglong2 v)
99 {
100  unsigned int x = static_cast<unsigned int>(v.x);
101  unsigned int y = static_cast<unsigned int>(v.x >> 32);
102  unsigned int z = static_cast<unsigned int>(v.y);
103  unsigned int w = static_cast<unsigned int>(v.y >> 32);
104 
105  return box_muller_double(make_uint4(x, y, z, w));
106 }
107 
108 __forceinline__ __device__ __host__ __half2 box_muller_half(unsigned short x, unsigned short y)
109 {
110  #if defined(ROCRAND_HALF_MATH_SUPPORTED)
111  __half u = __float2half(ROCRAND_2POW16_INV + (x * ROCRAND_2POW16_INV));
112  __half v = __float2half(ROCRAND_2POW16_INV_2PI + (y * ROCRAND_2POW16_INV_2PI));
113  __half s = hsqrt(__hmul(__float2half(-2.0f), hlog(u)));
114  return __half2 {
115  __hmul(hsin(v), s),
116  __hmul(hcos(v), s)
117  };
118  #else
119  float2 r;
120  float u = ROCRAND_2POW16_INV + (x * ROCRAND_2POW16_INV);
121  float v = ROCRAND_2POW16_INV_2PI + (y * ROCRAND_2POW16_INV_2PI);
122  float s = sqrtf(-2.0f * logf(u));
123  #ifdef __HIP_DEVICE_COMPILE__
124  __sincosf(v, &r.x, &r.y);
125  r.x *= s;
126  r.y *= s;
127  #else
128  r.x = sinf(v) * s;
129  r.y = cosf(v) * s;
130  #endif
131  return __half2 {
132  __float2half(r.x),
133  __float2half(r.y)
134  };
135  #endif
136 }
137 
138 template<typename state_type>
139 __forceinline__ __device__ __host__ float2 mrg_box_muller(unsigned int x, unsigned int y)
140 {
141  float2 result;
142  float u = rocrand_device::detail::mrg_uniform_distribution<state_type>(x);
143  float v = rocrand_device::detail::mrg_uniform_distribution<state_type>(y) * ROCRAND_2PI;
144  float s = sqrtf(-2.0f * logf(u));
145  #ifdef __HIP_DEVICE_COMPILE__
146  __sincosf(v, &result.x, &result.y);
147  result.x *= s;
148  result.y *= s;
149  #else
150  result.x = sinf(v) * s;
151  result.y = cosf(v) * s;
152  #endif
153  return result;
154 }
155 
156 template<typename state_type>
157 __forceinline__ __device__ __host__ double2 mrg_box_muller_double(unsigned int x, unsigned int y)
158 {
159  double2 result;
160  double u = rocrand_device::detail::mrg_uniform_distribution<state_type>(x);
161  double v = rocrand_device::detail::mrg_uniform_distribution<state_type>(y) * 2.0;
162  double s = sqrt(-2.0 * log(u));
163  #ifdef __HIP_DEVICE_COMPILE__
164  sincospi(v, &result.x, &result.y);
165  result.x *= s;
166  result.y *= s;
167  #else
168  result.x = sin(v * ROCRAND_PI_DOUBLE) * s;
169  result.y = cos(v * ROCRAND_PI_DOUBLE) * s;
170  #endif
171  return result;
172 }
173 
174 __forceinline__ __device__ __host__ float roc_f_erfinv(float x)
175 {
176  float tt1, tt2, lnx, sgn;
177  sgn = (x < 0.0f) ? -1.0f : 1.0f;
178 
179  x = (1.0f - x) * (1.0f + x);
180  lnx = logf(x);
181 
182  #ifdef __HIP_DEVICE_COMPILE__
183  if (isnan(lnx))
184  #else
185  if (std::isnan(lnx))
186  #endif
187  return 1.0f;
188  #ifdef __HIP_DEVICE_COMPILE__
189  else if (isinf(lnx))
190  #else
191  else if (std::isinf(lnx))
192  #endif
193  return 0.0f;
194 
195  tt1 = 2.0f / (ROCRAND_PI * 0.147f) + 0.5f * lnx;
196  tt2 = 1.0f / (0.147f) * lnx;
197 
198  return(sgn * sqrtf(-tt1 + sqrtf(tt1 * tt1 - tt2)));
199 }
200 
201 __forceinline__ __device__ __host__ double roc_d_erfinv(double x)
202 {
203  double tt1, tt2, lnx, sgn;
204  sgn = (x < 0.0) ? -1.0 : 1.0;
205 
206  x = (1.0 - x) * (1.0 + x);
207  lnx = log(x);
208 
209  #ifdef __HIP_DEVICE_COMPILE__
210  if (isnan(lnx))
211  #else
212  if (std::isnan(lnx))
213  #endif
214  return 1.0;
215  #ifdef __HIP_DEVICE_COMPILE__
216  else if (isinf(lnx))
217  #else
218  else if (std::isinf(lnx))
219  #endif
220  return 0.0;
221 
222  tt1 = 2.0 / (ROCRAND_PI_DOUBLE * 0.147) + 0.5 * lnx;
223  tt2 = 1.0 / (0.147) * lnx;
224 
225  return(sgn * sqrt(-tt1 + sqrt(tt1 * tt1 - tt2)));
226 }
227 
228 __forceinline__ __device__ __host__ float normal_distribution(unsigned int x)
229 {
230  float p = ::rocrand_device::detail::uniform_distribution(x);
231  float v = ROCRAND_SQRT2 * ::rocrand_device::detail::roc_f_erfinv(2.0f * p - 1.0f);
232  return v;
233 }
234 
235 __forceinline__ __device__ __host__ float normal_distribution(unsigned long long int x)
236 {
237  float p = ::rocrand_device::detail::uniform_distribution(x);
238  float v = ROCRAND_SQRT2 * ::rocrand_device::detail::roc_f_erfinv(2.0f * p - 1.0f);
239  return v;
240 }
241 
242 __forceinline__ __device__ __host__ float2 normal_distribution2(unsigned int v1, unsigned int v2)
243 {
244  return ::rocrand_device::detail::box_muller(v1, v2);
245 }
246 
247 __forceinline__ __device__ __host__ float2 normal_distribution2(uint2 v)
248 {
249  return ::rocrand_device::detail::box_muller(v.x, v.y);
250 }
251 
252 __forceinline__ __device__ __host__ float2 normal_distribution2(unsigned long long v)
253 {
254  return ::rocrand_device::detail::box_muller(v);
255 }
256 
257 __forceinline__ __device__ __host__ float4 normal_distribution4(uint4 v)
258 {
259  float2 r1 = ::rocrand_device::detail::box_muller(v.x, v.y);
260  float2 r2 = ::rocrand_device::detail::box_muller(v.z, v.w);
261  return float4{
262  r1.x,
263  r1.y,
264  r2.x,
265  r2.y
266  };
267 }
268 
269 __forceinline__ __device__ __host__ float4 normal_distribution4(longlong2 v)
270 {
271  float2 r1 = ::rocrand_device::detail::box_muller(v.x);
272  float2 r2 = ::rocrand_device::detail::box_muller(v.y);
273  return float4{r1.x, r1.y, r2.x, r2.y};
274 }
275 
276 __forceinline__ __device__ __host__ float4 normal_distribution4(unsigned long long v1,
277  unsigned long long v2)
278 {
279  float2 r1 = ::rocrand_device::detail::box_muller(v1);
280  float2 r2 = ::rocrand_device::detail::box_muller(v2);
281  return float4{r1.x, r1.y, r2.x, r2.y};
282 }
283 
284 __forceinline__ __device__ __host__ double normal_distribution_double(unsigned int x)
285 {
286  double p = ::rocrand_device::detail::uniform_distribution_double(x);
287  double v = ROCRAND_SQRT2 * ::rocrand_device::detail::roc_d_erfinv(2.0 * p - 1.0);
288  return v;
289 }
290 
291 __forceinline__ __device__ __host__ double normal_distribution_double(unsigned long long int x)
292 {
293  double p = ::rocrand_device::detail::uniform_distribution_double(x);
294  double v = ROCRAND_SQRT2 * ::rocrand_device::detail::roc_d_erfinv(2.0 * p - 1.0);
295  return v;
296 }
297 
298 __forceinline__ __device__ __host__ double2 normal_distribution_double2(uint4 v)
299 {
300  return ::rocrand_device::detail::box_muller_double(v);
301 }
302 
303 __forceinline__ __device__ __host__ double2 normal_distribution_double2(ulonglong2 v)
304 {
305  return ::rocrand_device::detail::box_muller_double(v);
306 }
307 
308 __forceinline__ __device__ __host__ __half2 normal_distribution_half2(unsigned int v)
309 {
310  return ::rocrand_device::detail::box_muller_half(
311  static_cast<unsigned short>(v),
312  static_cast<unsigned short>(v >> 16)
313  );
314 }
315 
316 __forceinline__ __device__ __host__ __half2 normal_distribution_half2(unsigned long long v)
317 {
318  return ::rocrand_device::detail::box_muller_half(static_cast<unsigned short>(v),
319  static_cast<unsigned short>(v >> 32));
320 }
321 
322 template<typename state_type>
323 __forceinline__ __device__ __host__ float2 mrg_normal_distribution2(unsigned int v1,
324  unsigned int v2)
325 {
326  return ::rocrand_device::detail::mrg_box_muller<state_type>(v1, v2);
327 }
328 
329 template<typename state_type>
330 __forceinline__ __device__ __host__ double2 mrg_normal_distribution_double2(unsigned int v1,
331  unsigned int v2)
332 {
333  return ::rocrand_device::detail::mrg_box_muller_double<state_type>(v1, v2);
334 }
335 
336 template<typename state_type>
337 __forceinline__ __device__ __host__ __half2 mrg_normal_distribution_half2(unsigned int v)
338 {
339  v = rocrand_device::detail::mrg_uniform_distribution_uint<state_type>(v);
340  return ::rocrand_device::detail::box_muller_half(
341  static_cast<unsigned short>(v),
342  static_cast<unsigned short>(v >> 16)
343  );
344 }
345 
346 } // end namespace detail
347 } // end namespace rocrand_device
348 
363 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
364 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_philox4x32_10* state)
365 {
366  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_philox4x32_10> bm_helper;
367 
368  if(bm_helper::has_float(state))
369  {
370  return bm_helper::get_float(state);
371  }
372 
373  auto state1 = rocrand(state);
374  auto state2 = rocrand(state);
375 
376  float2 r = rocrand_device::detail::normal_distribution2(state1, state2);
377  bm_helper::save_float(state, r.y);
378  return r.x;
379 }
380 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
381 
396 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_philox4x32_10* state)
397 {
398  auto state1 = rocrand(state);
399  auto state2 = rocrand(state);
400 
401  return rocrand_device::detail::normal_distribution2(state1, state2);
402 }
403 
418 __forceinline__ __device__ __host__ float4 rocrand_normal4(rocrand_state_philox4x32_10* state)
419 {
420  return rocrand_device::detail::normal_distribution4(rocrand4(state));
421 }
422 
437 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
438 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_philox4x32_10* state)
439 {
440  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_philox4x32_10> bm_helper;
441 
442  if(bm_helper::has_double(state))
443  {
444  return bm_helper::get_double(state);
445  }
446  double2 r = rocrand_device::detail::normal_distribution_double2(rocrand4(state));
447  bm_helper::save_double(state, r.y);
448  return r.x;
449 }
450 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
451 
466 __forceinline__ __device__ __host__ double2
467  rocrand_normal_double2(rocrand_state_philox4x32_10* state)
468 {
469  return rocrand_device::detail::normal_distribution_double2(rocrand4(state));
470 }
471 
486 __forceinline__ __device__ __host__ double4
487  rocrand_normal_double4(rocrand_state_philox4x32_10* state)
488 {
489  double2 r1, r2;
490  r1 = rocrand_device::detail::normal_distribution_double2(rocrand4(state));
491  r2 = rocrand_device::detail::normal_distribution_double2(rocrand4(state));
492  return double4 {
493  r1.x, r1.y, r2.x, r2.y
494  };
495 }
496 
511 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
512 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_mrg31k3p* state)
513 {
514  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_mrg31k3p> bm_helper;
515 
516  if(bm_helper::has_float(state))
517  {
518  return bm_helper::get_float(state);
519  }
520 
521  auto state1 = state->next();
522  auto state2 = state->next();
523 
524  float2 r
525  = rocrand_device::detail::mrg_normal_distribution2<rocrand_state_mrg31k3p>(state1, state2);
526  bm_helper::save_float(state, r.y);
527  return r.x;
528 }
529 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
530 
545 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_mrg31k3p* state)
546 {
547  auto state1 = state->next();
548  auto state2 = state->next();
549 
550  return rocrand_device::detail::mrg_normal_distribution2<rocrand_state_mrg31k3p>(state1, state2);
551 }
552 
567 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
568 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_mrg31k3p* state)
569 {
570  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_mrg31k3p> bm_helper;
571 
572  if(bm_helper::has_double(state))
573  {
574  return bm_helper::get_double(state);
575  }
576 
577  auto state1 = state->next();
578  auto state2 = state->next();
579 
580  double2 r
581  = rocrand_device::detail::mrg_normal_distribution_double2<rocrand_state_mrg31k3p>(state1,
582  state2);
583  bm_helper::save_double(state, r.y);
584  return r.x;
585 }
586 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
587 
602 __forceinline__ __device__ __host__ double2 rocrand_normal_double2(rocrand_state_mrg31k3p* state)
603 {
604  auto state1 = state->next();
605  auto state2 = state->next();
606 
607  return rocrand_device::detail::mrg_normal_distribution_double2<rocrand_state_mrg31k3p>(state1,
608  state2);
609 }
610 
625 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
626 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_mrg32k3a* state)
627 {
628  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_mrg32k3a> bm_helper;
629 
630  if(bm_helper::has_float(state))
631  {
632  return bm_helper::get_float(state);
633  }
634 
635  auto state1 = state->next();
636  auto state2 = state->next();
637 
638  float2 r
639  = rocrand_device::detail::mrg_normal_distribution2<rocrand_state_mrg32k3a>(state1, state2);
640  bm_helper::save_float(state, r.y);
641  return r.x;
642 }
643 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
644 
659 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_mrg32k3a* state)
660 {
661  auto state1 = state->next();
662  auto state2 = state->next();
663 
664  return rocrand_device::detail::mrg_normal_distribution2<rocrand_state_mrg32k3a>(state1, state2);
665 }
666 
681 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
682 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_mrg32k3a* state)
683 {
684  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_mrg32k3a> bm_helper;
685 
686  if(bm_helper::has_double(state))
687  {
688  return bm_helper::get_double(state);
689  }
690 
691  auto state1 = state->next();
692  auto state2 = state->next();
693 
694  double2 r
695  = rocrand_device::detail::mrg_normal_distribution_double2<rocrand_state_mrg32k3a>(state1,
696  state2);
697  bm_helper::save_double(state, r.y);
698  return r.x;
699 }
700 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
701 
716 __forceinline__ __device__ __host__ double2 rocrand_normal_double2(rocrand_state_mrg32k3a* state)
717 {
718  auto state1 = state->next();
719  auto state2 = state->next();
720 
721  return rocrand_device::detail::mrg_normal_distribution_double2<rocrand_state_mrg32k3a>(state1,
722  state2);
723 }
724 
739 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
740 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_xorwow* state)
741 {
742  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_xorwow> bm_helper;
743 
744  if(bm_helper::has_float(state))
745  {
746  return bm_helper::get_float(state);
747  }
748  auto state1 = rocrand(state);
749  auto state2 = rocrand(state);
750  float2 r = rocrand_device::detail::normal_distribution2(state1, state2);
751  bm_helper::save_float(state, r.y);
752  return r.x;
753 }
754 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
755 
770 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_xorwow* state)
771 {
772  auto state1 = rocrand(state);
773  auto state2 = rocrand(state);
774  return rocrand_device::detail::normal_distribution2(state1, state2);
775 }
776 
791 #ifndef ROCRAND_DETAIL_BM_NOT_IN_STATE
792 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_xorwow* state)
793 {
794  typedef rocrand_device::detail::engine_boxmuller_helper<rocrand_state_xorwow> bm_helper;
795 
796  if(bm_helper::has_double(state))
797  {
798  return bm_helper::get_double(state);
799  }
800 
801  auto state1 = rocrand(state);
802  auto state2 = rocrand(state);
803  auto state3 = rocrand(state);
804  auto state4 = rocrand(state);
805 
806  double2 r = rocrand_device::detail::normal_distribution_double2(
807  uint4 { state1, state2, state3, state4 }
808  );
809  bm_helper::save_double(state, r.y);
810  return r.x;
811 }
812 #endif // ROCRAND_DETAIL_BM_NOT_IN_STATE
813 
828 __forceinline__ __device__ __host__ double2 rocrand_normal_double2(rocrand_state_xorwow* state)
829 {
830  auto state1 = rocrand(state);
831  auto state2 = rocrand(state);
832  auto state3 = rocrand(state);
833  auto state4 = rocrand(state);
834 
835  return rocrand_device::detail::normal_distribution_double2(
836  uint4 { state1, state2, state3, state4 }
837  );
838 }
839 
852 __forceinline__ __device__ float rocrand_normal(rocrand_state_mtgp32* state)
853 {
854  return rocrand_device::detail::normal_distribution(rocrand(state));
855 }
856 
871 __forceinline__ __device__ float2 rocrand_normal2(rocrand_state_mtgp32* state)
872 {
873  auto state1 = rocrand(state);
874  auto state2 = rocrand(state);
875  return rocrand_device::detail::normal_distribution2(state1, state2);
876 }
877 
890 __forceinline__ __device__ double rocrand_normal_double(rocrand_state_mtgp32* state)
891 {
892  return rocrand_device::detail::normal_distribution_double(rocrand(state));
893 }
894 
909 __forceinline__ __device__ double2 rocrand_normal_double2(rocrand_state_mtgp32* state)
910 {
911  auto state1 = rocrand(state);
912  auto state2 = rocrand(state);
913  auto state3 = rocrand(state);
914  auto state4 = rocrand(state);
915 
916  return rocrand_device::detail::normal_distribution_double2(
917  uint4{state1, state2, state3, state4});
918 }
919 
932 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_sobol32* state)
933 {
934  return rocrand_device::detail::normal_distribution(rocrand(state));
935 }
936 
949 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_sobol32* state)
950 {
951  return rocrand_device::detail::normal_distribution_double(rocrand(state));
952 }
953 
966 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_scrambled_sobol32* state)
967 {
968  return rocrand_device::detail::normal_distribution(rocrand(state));
969 }
970 
983 __forceinline__ __device__ __host__ double
984  rocrand_normal_double(rocrand_state_scrambled_sobol32* state)
985 {
986  return rocrand_device::detail::normal_distribution_double(rocrand(state));
987 }
988 
1001 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_sobol64* state)
1002 {
1003  return rocrand_device::detail::normal_distribution(rocrand(state));
1004 }
1005 
1018 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_sobol64* state)
1019 {
1020  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1021 }
1022 
1035 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_scrambled_sobol64* state)
1036 {
1037  return rocrand_device::detail::normal_distribution(rocrand(state));
1038 }
1039 
1052 __forceinline__ __device__ __host__ double
1053  rocrand_normal_double(rocrand_state_scrambled_sobol64* state)
1054 {
1055  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1056 }
1057 
1070 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_lfsr113* state)
1071 {
1072  return rocrand_device::detail::normal_distribution(rocrand(state));
1073 }
1074 
1089 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_lfsr113* state)
1090 {
1091  auto state1 = rocrand(state);
1092  auto state2 = rocrand(state);
1093 
1094  return rocrand_device::detail::normal_distribution2(state1, state2);
1095 }
1096 
1109 __forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_lfsr113* state)
1110 {
1111  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1112 }
1113 
1128 __forceinline__ __device__ __host__ double2 rocrand_normal_double2(rocrand_state_lfsr113* state)
1129 {
1130  auto state1 = rocrand(state);
1131  auto state2 = rocrand(state);
1132  auto state3 = rocrand(state);
1133  auto state4 = rocrand(state);
1134 
1135  return rocrand_device::detail::normal_distribution_double2(
1136  uint4{state1, state2, state3, state4});
1137 }
1138 
1151 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_threefry2x32_20* state)
1152 {
1153  return rocrand_device::detail::normal_distribution(rocrand(state));
1154 }
1155 
1170 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_threefry2x32_20* state)
1171 {
1172  return rocrand_device::detail::normal_distribution2(rocrand2(state));
1173 }
1174 
1187 __forceinline__ __device__ __host__ double
1188  rocrand_normal_double(rocrand_state_threefry2x32_20* state)
1189 {
1190  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1191 }
1192 
1207 __forceinline__ __device__ __host__ double2
1208  rocrand_normal_double2(rocrand_state_threefry2x32_20* state)
1209 {
1210  auto state1 = rocrand2(state);
1211  auto state2 = rocrand2(state);
1212 
1213  return rocrand_device::detail::normal_distribution_double2(
1214  uint4{state1.x, state1.y, state2.x, state2.y});
1215 }
1216 
1229 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_threefry2x64_20* state)
1230 {
1231  return rocrand_device::detail::normal_distribution(rocrand(state));
1232 }
1233 
1248 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_threefry2x64_20* state)
1249 {
1250  return rocrand_device::detail::normal_distribution2(rocrand(state));
1251 }
1252 
1265 __forceinline__ __device__ __host__ double
1266  rocrand_normal_double(rocrand_state_threefry2x64_20* state)
1267 {
1268  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1269 }
1270 
1285 __forceinline__ __device__ __host__ double2
1286  rocrand_normal_double2(rocrand_state_threefry2x64_20* state)
1287 {
1288  return rocrand_device::detail::normal_distribution_double2(rocrand2(state));
1289 }
1290 
1303 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_threefry4x32_20* state)
1304 {
1305  return rocrand_device::detail::normal_distribution(rocrand(state));
1306 }
1307 
1322 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_threefry4x32_20* state)
1323 {
1324  auto state1 = rocrand(state);
1325  auto state2 = rocrand(state);
1326 
1327  return rocrand_device::detail::normal_distribution2(state1, state2);
1328 }
1329 
1342 __forceinline__ __device__ __host__ double
1343  rocrand_normal_double(rocrand_state_threefry4x32_20* state)
1344 {
1345  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1346 }
1347 
1362 __forceinline__ __device__ __host__ double2
1363  rocrand_normal_double2(rocrand_state_threefry4x32_20* state)
1364 {
1365  return rocrand_device::detail::normal_distribution_double2(rocrand4(state));
1366 }
1367 
1380 __forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_threefry4x64_20* state)
1381 {
1382  return rocrand_device::detail::normal_distribution(rocrand(state));
1383 }
1384 
1399 __forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_threefry4x64_20* state)
1400 {
1401  auto state1 = rocrand(state);
1402  auto state2 = rocrand(state);
1403 
1404  return rocrand_device::detail::normal_distribution2(state1, state2);
1405 }
1406 
1419 __forceinline__ __device__ __host__ double
1420  rocrand_normal_double(rocrand_state_threefry4x64_20* state)
1421 {
1422  return rocrand_device::detail::normal_distribution_double(rocrand(state));
1423 }
1424 
1439 __forceinline__ __device__ __host__ double2
1440  rocrand_normal_double2(rocrand_state_threefry4x64_20* state)
1441 {
1442  auto state1 = rocrand(state);
1443  auto state2 = rocrand(state);
1444 
1445  return rocrand_device::detail::normal_distribution_double2(ulonglong2{state1, state2});
1446 }
1447  // end of group rocranddevice
1449 
1450 #endif // ROCRAND_NORMAL_H_
__forceinline__ __device__ __host__ double4 rocrand_normal_double4(rocrand_state_philox4x32_10 *state)
Returns four normally distributed double values.
Definition: rocrand_normal.h:487
__forceinline__ __device__ __host__ double2 rocrand_normal_double2(rocrand_state_philox4x32_10 *state)
Returns two normally distributed double values.
Definition: rocrand_normal.h:467
__forceinline__ __device__ __host__ float rocrand_normal(rocrand_state_philox4x32_10 *state)
Returns a normally distributed float value.
Definition: rocrand_normal.h:364
__forceinline__ __device__ __host__ uint4 rocrand4(rocrand_state_philox4x32_10 *state)
Returns four uniformly distributed random unsigned int values from [0; 2^32 - 1] range.
Definition: rocrand_philox4x32_10.h:386
__forceinline__ __device__ __host__ double rocrand_normal_double(rocrand_state_philox4x32_10 *state)
Returns a normally distributed double value.
Definition: rocrand_normal.h:438
__forceinline__ __device__ __host__ float4 rocrand_normal4(rocrand_state_philox4x32_10 *state)
Returns four normally distributed float values.
Definition: rocrand_normal.h:418
__forceinline__ __device__ __host__ unsigned int rocrand(rocrand_state_lfsr113 *state)
Returns uniformly distributed random unsigned int value from [0; 2^32 - 1] range.
Definition: rocrand_lfsr113.h:274
__forceinline__ __device__ __host__ float2 rocrand_normal2(rocrand_state_philox4x32_10 *state)
Returns two normally distributed float values.
Definition: rocrand_normal.h:396