source: Daodan/MSVC/dSFMT/dSFMT.c@ 573

Last change on this file since 573 was 567, checked in by gumby, 14 years ago

Daodan MSVC

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1/**
2 * @file dSFMT.c
3 * @brief double precision SIMD-oriented Fast Mersenne Twister (dSFMT)
4 * based on IEEE 754 format.
5 *
6 * @author Mutsuo Saito (Hiroshima University)
7 * @author Makoto Matsumoto (Hiroshima University)
8 *
9 * Copyright (C) 2007,2008 Mutsuo Saito, Makoto Matsumoto and Hiroshima
10 * University. All rights reserved.
11 *
12 * The new BSD License is applied to this software, see LICENSE.txt
13 */
14#include <stdio.h>
15#include <string.h>
16#include <stdlib.h>
17#include "dSFMT-params.h"
18
19/** dsfmt internal state vector */
20dsfmt_t dsfmt_global_data;
21/** dsfmt mexp for check */
22static const int dsfmt_mexp = DSFMT_MEXP;
23
24/*----------------
25 STATIC FUNCTIONS
26 ----------------*/
27inline static uint32_t ini_func1(uint32_t x);
28inline static uint32_t ini_func2(uint32_t x);
29inline static void gen_rand_array_c1o2(dsfmt_t *dsfmt, w128_t *array,
30 int size);
31inline static void gen_rand_array_c0o1(dsfmt_t *dsfmt, w128_t *array,
32 int size);
33inline static void gen_rand_array_o0c1(dsfmt_t *dsfmt, w128_t *array,
34 int size);
35inline static void gen_rand_array_o0o1(dsfmt_t *dsfmt, w128_t *array,
36 int size);
37inline static int idxof(int i);
38static void initial_mask(dsfmt_t *dsfmt);
39static void period_certification(dsfmt_t *dsfmt);
40
41#if defined(HAVE_SSE2)
42# include <emmintrin.h>
43/** mask data for sse2 */
44static __m128i sse2_param_mask;
45/** 1 in 64bit for sse2 */
46static __m128i sse2_int_one;
47/** 2.0 double for sse2 */
48static __m128d sse2_double_two;
49/** -1.0 double for sse2 */
50static __m128d sse2_double_m_one;
51
52static void setup_const(void);
53#endif
54
55/**
56 * This function simulate a 32-bit array index overlapped to 64-bit
57 * array of LITTLE ENDIAN in BIG ENDIAN machine.
58 */
59#if defined(DSFMT_BIG_ENDIAN)
60inline static int idxof(int i) {
61 return i ^ 1;
62}
63#else
64inline static int idxof(int i) {
65 return i;
66}
67#endif
68
69/**
70 * This function represents the recursion formula.
71 * @param r output
72 * @param a a 128-bit part of the internal state array
73 * @param b a 128-bit part of the internal state array
74 * @param lung a 128-bit part of the internal state array
75 */
76#if defined(HAVE_ALTIVEC)
77inline static void do_recursion(w128_t *r, w128_t *a, w128_t * b,
78 w128_t *lung) {
79 const vector unsigned char sl1 = ALTI_SL1;
80 const vector unsigned char sl1_perm = ALTI_SL1_PERM;
81 const vector unsigned int sl1_msk = ALTI_SL1_MSK;
82 const vector unsigned char sr1 = ALTI_SR;
83 const vector unsigned char sr1_perm = ALTI_SR_PERM;
84 const vector unsigned int sr1_msk = ALTI_SR_MSK;
85 const vector unsigned char perm = ALTI_PERM;
86 const vector unsigned int msk1 = ALTI_MSK;
87 vector unsigned int w, x, y, z;
88
89 z = a->s;
90 w = lung->s;
91 x = vec_perm(w, (vector unsigned int)perm, perm);
92 y = vec_perm(z, sl1_perm, sl1_perm);
93 y = vec_sll(y, sl1);
94 y = vec_and(y, sl1_msk);
95 w = vec_xor(x, b->s);
96 w = vec_xor(w, y);
97 x = vec_perm(w, (vector unsigned int)sr1_perm, sr1_perm);
98 x = vec_srl(x, sr1);
99 x = vec_and(x, sr1_msk);
100 y = vec_and(w, msk1);
101 z = vec_xor(z, y);
102 r->s = vec_xor(z, x);
103 lung->s = w;
104}
105#elif defined(HAVE_SSE2)
106/**
107 * This function setup some constant variables for SSE2.
108 */
109static void setup_const(void) {
110 static int first = 1;
111 if (!first) {
112 return;
113 }
114 sse2_param_mask = _mm_set_epi32(DSFMT_MSK32_3, DSFMT_MSK32_4,
115 DSFMT_MSK32_1, DSFMT_MSK32_2);
116 sse2_int_one = _mm_set_epi32(0, 1, 0, 1);
117 sse2_double_two = _mm_set_pd(2.0, 2.0);
118 sse2_double_m_one = _mm_set_pd(-1.0, -1.0);
119 first = 0;
120}
121
122/**
123 * This function represents the recursion formula.
124 * @param r output 128-bit
125 * @param a a 128-bit part of the internal state array
126 * @param b a 128-bit part of the internal state array
127 * @param d a 128-bit part of the internal state array (I/O)
128 */
129inline static void do_recursion(w128_t *r, w128_t *a, w128_t *b, w128_t *u) {
130 __m128i v, w, x, y, z;
131
132 x = a->si;
133 z = _mm_slli_epi64(x, DSFMT_SL1);
134 y = _mm_shuffle_epi32(u->si, SSE2_SHUFF);
135 z = _mm_xor_si128(z, b->si);
136 y = _mm_xor_si128(y, z);
137
138 v = _mm_srli_epi64(y, DSFMT_SR);
139 w = _mm_and_si128(y, sse2_param_mask);
140 v = _mm_xor_si128(v, x);
141 v = _mm_xor_si128(v, w);
142 r->si = v;
143 u->si = y;
144}
145#else /* standard C */
146/**
147 * This function represents the recursion formula.
148 * @param r output 128-bit
149 * @param a a 128-bit part of the internal state array
150 * @param b a 128-bit part of the internal state array
151 * @param lung a 128-bit part of the internal state array (I/O)
152 */
153inline static void do_recursion(w128_t *r, w128_t *a, w128_t * b,
154 w128_t *lung) {
155 uint64_t t0, t1, L0, L1;
156
157 t0 = a->u[0];
158 t1 = a->u[1];
159 L0 = lung->u[0];
160 L1 = lung->u[1];
161 lung->u[0] = (t0 << DSFMT_SL1) ^ (L1 >> 32) ^ (L1 << 32) ^ b->u[0];
162 lung->u[1] = (t1 << DSFMT_SL1) ^ (L0 >> 32) ^ (L0 << 32) ^ b->u[1];
163 r->u[0] = (lung->u[0] >> DSFMT_SR) ^ (lung->u[0] & DSFMT_MSK1) ^ t0;
164 r->u[1] = (lung->u[1] >> DSFMT_SR) ^ (lung->u[1] & DSFMT_MSK2) ^ t1;
165}
166#endif
167
168#if defined(HAVE_SSE2)
169/**
170 * This function converts the double precision floating point numbers which
171 * distribute uniformly in the range [1, 2) to those which distribute uniformly
172 * in the range [0, 1).
173 * @param w 128bit stracture of double precision floating point numbers (I/O)
174 */
175inline static void convert_c0o1(w128_t *w) {
176 w->sd = _mm_add_pd(w->sd, sse2_double_m_one);
177}
178
179/**
180 * This function converts the double precision floating point numbers which
181 * distribute uniformly in the range [1, 2) to those which distribute uniformly
182 * in the range (0, 1].
183 * @param w 128bit stracture of double precision floating point numbers (I/O)
184 */
185inline static void convert_o0c1(w128_t *w) {
186 w->sd = _mm_sub_pd(sse2_double_two, w->sd);
187}
188
189/**
190 * This function converts the double precision floating point numbers which
191 * distribute uniformly in the range [1, 2) to those which distribute uniformly
192 * in the range (0, 1).
193 * @param w 128bit stracture of double precision floating point numbers (I/O)
194 */
195inline static void convert_o0o1(w128_t *w) {
196 w->si = _mm_or_si128(w->si, sse2_int_one);
197 w->sd = _mm_add_pd(w->sd, sse2_double_m_one);
198}
199#else /* standard C and altivec */
200/**
201 * This function converts the double precision floating point numbers which
202 * distribute uniformly in the range [1, 2) to those which distribute uniformly
203 * in the range [0, 1).
204 * @param w 128bit stracture of double precision floating point numbers (I/O)
205 */
206inline static void convert_c0o1(w128_t *w) {
207 w->d[0] -= 1.0;
208 w->d[1] -= 1.0;
209}
210
211/**
212 * This function converts the double precision floating point numbers which
213 * distribute uniformly in the range [1, 2) to those which distribute uniformly
214 * in the range (0, 1].
215 * @param w 128bit stracture of double precision floating point numbers (I/O)
216 */
217inline static void convert_o0c1(w128_t *w) {
218 w->d[0] = 2.0 - w->d[0];
219 w->d[1] = 2.0 - w->d[1];
220}
221
222/**
223 * This function converts the double precision floating point numbers which
224 * distribute uniformly in the range [1, 2) to those which distribute uniformly
225 * in the range (0, 1).
226 * @param w 128bit stracture of double precision floating point numbers (I/O)
227 */
228inline static void convert_o0o1(w128_t *w) {
229 w->u[0] |= 1;
230 w->u[1] |= 1;
231 w->d[0] -= 1.0;
232 w->d[1] -= 1.0;
233}
234#endif
235
236/**
237 * This function fills the user-specified array with double precision
238 * floating point pseudorandom numbers of the IEEE 754 format.
239 * @param dsfmt dsfmt state vector.
240 * @param array an 128-bit array to be filled by pseudorandom numbers.
241 * @param size number of 128-bit pseudorandom numbers to be generated.
242 */
243inline static void gen_rand_array_c1o2(dsfmt_t *dsfmt, w128_t *array,
244 int size) {
245 int i, j;
246 w128_t lung;
247
248 lung = dsfmt->status[DSFMT_N];
249 do_recursion(&array[0], &dsfmt->status[0], &dsfmt->status[DSFMT_POS1],
250 &lung);
251 for (i = 1; i < DSFMT_N - DSFMT_POS1; i++) {
252 do_recursion(&array[i], &dsfmt->status[i],
253 &dsfmt->status[i + DSFMT_POS1], &lung);
254 }
255 for (; i < DSFMT_N; i++) {
256 do_recursion(&array[i], &dsfmt->status[i],
257 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
258 }
259 for (; i < size - DSFMT_N; i++) {
260 do_recursion(&array[i], &array[i - DSFMT_N],
261 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
262 }
263 for (j = 0; j < 2 * DSFMT_N - size; j++) {
264 dsfmt->status[j] = array[j + size - DSFMT_N];
265 }
266 for (; i < size; i++, j++) {
267 do_recursion(&array[i], &array[i - DSFMT_N],
268 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
269 dsfmt->status[j] = array[i];
270 }
271 dsfmt->status[DSFMT_N] = lung;
272}
273
274/**
275 * This function fills the user-specified array with double precision
276 * floating point pseudorandom numbers of the IEEE 754 format.
277 * @param dsfmt dsfmt state vector.
278 * @param array an 128-bit array to be filled by pseudorandom numbers.
279 * @param size number of 128-bit pseudorandom numbers to be generated.
280 */
281inline static void gen_rand_array_c0o1(dsfmt_t *dsfmt, w128_t *array,
282 int size) {
283 int i, j;
284 w128_t lung;
285
286 lung = dsfmt->status[DSFMT_N];
287 do_recursion(&array[0], &dsfmt->status[0], &dsfmt->status[DSFMT_POS1],
288 &lung);
289 for (i = 1; i < DSFMT_N - DSFMT_POS1; i++) {
290 do_recursion(&array[i], &dsfmt->status[i],
291 &dsfmt->status[i + DSFMT_POS1], &lung);
292 }
293 for (; i < DSFMT_N; i++) {
294 do_recursion(&array[i], &dsfmt->status[i],
295 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
296 }
297 for (; i < size - DSFMT_N; i++) {
298 do_recursion(&array[i], &array[i - DSFMT_N],
299 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
300 convert_c0o1(&array[i - DSFMT_N]);
301 }
302 for (j = 0; j < 2 * DSFMT_N - size; j++) {
303 dsfmt->status[j] = array[j + size - DSFMT_N];
304 }
305 for (; i < size; i++, j++) {
306 do_recursion(&array[i], &array[i - DSFMT_N],
307 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
308 dsfmt->status[j] = array[i];
309 convert_c0o1(&array[i - DSFMT_N]);
310 }
311 for (i = size - DSFMT_N; i < size; i++) {
312 convert_c0o1(&array[i]);
313 }
314 dsfmt->status[DSFMT_N] = lung;
315}
316
317/**
318 * This function fills the user-specified array with double precision
319 * floating point pseudorandom numbers of the IEEE 754 format.
320 * @param dsfmt dsfmt state vector.
321 * @param array an 128-bit array to be filled by pseudorandom numbers.
322 * @param size number of 128-bit pseudorandom numbers to be generated.
323 */
324inline static void gen_rand_array_o0o1(dsfmt_t *dsfmt, w128_t *array,
325 int size) {
326 int i, j;
327 w128_t lung;
328
329 lung = dsfmt->status[DSFMT_N];
330 do_recursion(&array[0], &dsfmt->status[0], &dsfmt->status[DSFMT_POS1],
331 &lung);
332 for (i = 1; i < DSFMT_N - DSFMT_POS1; i++) {
333 do_recursion(&array[i], &dsfmt->status[i],
334 &dsfmt->status[i + DSFMT_POS1], &lung);
335 }
336 for (; i < DSFMT_N; i++) {
337 do_recursion(&array[i], &dsfmt->status[i],
338 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
339 }
340 for (; i < size - DSFMT_N; i++) {
341 do_recursion(&array[i], &array[i - DSFMT_N],
342 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
343 convert_o0o1(&array[i - DSFMT_N]);
344 }
345 for (j = 0; j < 2 * DSFMT_N - size; j++) {
346 dsfmt->status[j] = array[j + size - DSFMT_N];
347 }
348 for (; i < size; i++, j++) {
349 do_recursion(&array[i], &array[i - DSFMT_N],
350 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
351 dsfmt->status[j] = array[i];
352 convert_o0o1(&array[i - DSFMT_N]);
353 }
354 for (i = size - DSFMT_N; i < size; i++) {
355 convert_o0o1(&array[i]);
356 }
357 dsfmt->status[DSFMT_N] = lung;
358}
359
360/**
361 * This function fills the user-specified array with double precision
362 * floating point pseudorandom numbers of the IEEE 754 format.
363 * @param dsfmt dsfmt state vector.
364 * @param array an 128-bit array to be filled by pseudorandom numbers.
365 * @param size number of 128-bit pseudorandom numbers to be generated.
366 */
367inline static void gen_rand_array_o0c1(dsfmt_t *dsfmt, w128_t *array,
368 int size) {
369 int i, j;
370 w128_t lung;
371
372 lung = dsfmt->status[DSFMT_N];
373 do_recursion(&array[0], &dsfmt->status[0], &dsfmt->status[DSFMT_POS1],
374 &lung);
375 for (i = 1; i < DSFMT_N - DSFMT_POS1; i++) {
376 do_recursion(&array[i], &dsfmt->status[i],
377 &dsfmt->status[i + DSFMT_POS1], &lung);
378 }
379 for (; i < DSFMT_N; i++) {
380 do_recursion(&array[i], &dsfmt->status[i],
381 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
382 }
383 for (; i < size - DSFMT_N; i++) {
384 do_recursion(&array[i], &array[i - DSFMT_N],
385 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
386 convert_o0c1(&array[i - DSFMT_N]);
387 }
388 for (j = 0; j < 2 * DSFMT_N - size; j++) {
389 dsfmt->status[j] = array[j + size - DSFMT_N];
390 }
391 for (; i < size; i++, j++) {
392 do_recursion(&array[i], &array[i - DSFMT_N],
393 &array[i + DSFMT_POS1 - DSFMT_N], &lung);
394 dsfmt->status[j] = array[i];
395 convert_o0c1(&array[i - DSFMT_N]);
396 }
397 for (i = size - DSFMT_N; i < size; i++) {
398 convert_o0c1(&array[i]);
399 }
400 dsfmt->status[DSFMT_N] = lung;
401}
402
403/**
404 * This function represents a function used in the initialization
405 * by init_by_array
406 * @param x 32-bit integer
407 * @return 32-bit integer
408 */
409static uint32_t ini_func1(uint32_t x) {
410 return (x ^ (x >> 27)) * (uint32_t)1664525UL;
411}
412
413/**
414 * This function represents a function used in the initialization
415 * by init_by_array
416 * @param x 32-bit integer
417 * @return 32-bit integer
418 */
419static uint32_t ini_func2(uint32_t x) {
420 return (x ^ (x >> 27)) * (uint32_t)1566083941UL;
421}
422
423/**
424 * This function initializes the internal state array to fit the IEEE
425 * 754 format.
426 * @param dsfmt dsfmt state vector.
427 */
428static void initial_mask(dsfmt_t *dsfmt) {
429 int i;
430 uint64_t *psfmt;
431
432 psfmt = &dsfmt->status[0].u[0];
433 for (i = 0; i < DSFMT_N * 2; i++) {
434 psfmt[i] = (psfmt[i] & DSFMT_LOW_MASK) | DSFMT_HIGH_CONST;
435 }
436}
437
438/**
439 * This function certificate the period of 2^{SFMT_MEXP}-1.
440 * @param dsfmt dsfmt state vector.
441 */
442static void period_certification(dsfmt_t *dsfmt) {
443 uint64_t pcv[2] = {DSFMT_PCV1, DSFMT_PCV2};
444 uint64_t tmp[2];
445 uint64_t inner;
446 int i;
447#if (DSFMT_PCV2 & 1) != 1
448 int j;
449 uint64_t work;
450#endif
451
452 tmp[0] = (dsfmt->status[DSFMT_N].u[0] ^ DSFMT_FIX1);
453 tmp[1] = (dsfmt->status[DSFMT_N].u[1] ^ DSFMT_FIX2);
454
455 inner = tmp[0] & pcv[0];
456 inner ^= tmp[1] & pcv[1];
457 for (i = 32; i > 0; i >>= 1) {
458 inner ^= inner >> i;
459 }
460 inner &= 1;
461 /* check OK */
462 if (inner == 1) {
463 return;
464 }
465 /* check NG, and modification */
466#if (DSFMT_PCV2 & 1) == 1
467 dsfmt->status[DSFMT_N].u[1] ^= 1;
468#else
469 for (i = 1; i >= 0; i--) {
470 work = 1;
471 for (j = 0; j < 64; j++) {
472 if ((work & pcv[i]) != 0) {
473 dsfmt->status[DSFMT_N].u[i] ^= work;
474 return;
475 }
476 work = work << 1;
477 }
478 }
479#endif
480 return;
481}
482
483/*----------------
484 PUBLIC FUNCTIONS
485 ----------------*/
486/**
487 * This function returns the identification string. The string shows
488 * the Mersenne exponent, and all parameters of this generator.
489 * @return id string.
490 */
491const char *dsfmt_get_idstring(void) {
492 return DSFMT_IDSTR;
493}
494
495/**
496 * This function returns the minimum size of array used for \b
497 * fill_array functions.
498 * @return minimum size of array used for fill_array functions.
499 */
500int dsfmt_get_min_array_size(void) {
501 return DSFMT_N64;
502}
503
504/**
505 * This function fills the internal state array with double precision
506 * floating point pseudorandom numbers of the IEEE 754 format.
507 * @param dsfmt dsfmt state vector.
508 */
509void dsfmt_gen_rand_all(dsfmt_t *dsfmt) {
510 int i;
511 w128_t lung;
512
513 lung = dsfmt->status[DSFMT_N];
514 do_recursion(&dsfmt->status[0], &dsfmt->status[0],
515 &dsfmt->status[DSFMT_POS1], &lung);
516 for (i = 1; i < DSFMT_N - DSFMT_POS1; i++) {
517 do_recursion(&dsfmt->status[i], &dsfmt->status[i],
518 &dsfmt->status[i + DSFMT_POS1], &lung);
519 }
520 for (; i < DSFMT_N; i++) {
521 do_recursion(&dsfmt->status[i], &dsfmt->status[i],
522 &dsfmt->status[i + DSFMT_POS1 - DSFMT_N], &lung);
523 }
524 dsfmt->status[DSFMT_N] = lung;
525}
526
527/**
528 * This function generates double precision floating point
529 * pseudorandom numbers which distribute in the range [1, 2) to the
530 * specified array[] by one call. The number of pseudorandom numbers
531 * is specified by the argument \b size, which must be at least (SFMT_MEXP
532 * / 128) * 2 and a multiple of two. The function
533 * get_min_array_size() returns this minimum size. The generation by
534 * this function is much faster than the following fill_array_xxx functions.
535 *
536 * For initialization, init_gen_rand() or init_by_array() must be called
537 * before the first call of this function. This function can not be
538 * used after calling genrand_xxx functions, without initialization.
539 *
540 * @param dsfmt dsfmt state vector.
541 * @param array an array where pseudorandom numbers are filled
542 * by this function. The pointer to the array must be "aligned"
543 * (namely, must be a multiple of 16) in the SIMD version, since it
544 * refers to the address of a 128-bit integer. In the standard C
545 * version, the pointer is arbitrary.
546 *
547 * @param size the number of 64-bit pseudorandom integers to be
548 * generated. size must be a multiple of 2, and greater than or equal
549 * to (SFMT_MEXP / 128) * 2.
550 *
551 * @note \b memalign or \b posix_memalign is available to get aligned
552 * memory. Mac OSX doesn't have these functions, but \b malloc of OSX
553 * returns the pointer to the aligned memory block.
554 */
555void dsfmt_fill_array_close1_open2(dsfmt_t *dsfmt, double array[], int size) {
556 assert(size % 2 == 0);
557 assert(size >= DSFMT_N64);
558 gen_rand_array_c1o2(dsfmt, (w128_t *)array, size / 2);
559}
560
561/**
562 * This function generates double precision floating point
563 * pseudorandom numbers which distribute in the range (0, 1] to the
564 * specified array[] by one call. This function is the same as
565 * fill_array_close1_open2() except the distribution range.
566 *
567 * @param dsfmt dsfmt state vector.
568 * @param array an array where pseudorandom numbers are filled
569 * by this function.
570 * @param size the number of pseudorandom numbers to be generated.
571 * see also \sa fill_array_close1_open2()
572 */
573void dsfmt_fill_array_open_close(dsfmt_t *dsfmt, double array[], int size) {
574 assert(size % 2 == 0);
575 assert(size >= DSFMT_N64);
576 gen_rand_array_o0c1(dsfmt, (w128_t *)array, size / 2);
577}
578
579/**
580 * This function generates double precision floating point
581 * pseudorandom numbers which distribute in the range [0, 1) to the
582 * specified array[] by one call. This function is the same as
583 * fill_array_close1_open2() except the distribution range.
584 *
585 * @param array an array where pseudorandom numbers are filled
586 * by this function.
587 * @param dsfmt dsfmt state vector.
588 * @param size the number of pseudorandom numbers to be generated.
589 * see also \sa fill_array_close1_open2()
590 */
591void dsfmt_fill_array_close_open(dsfmt_t *dsfmt, double array[], int size) {
592 assert(size % 2 == 0);
593 assert(size >= DSFMT_N64);
594 gen_rand_array_c0o1(dsfmt, (w128_t *)array, size / 2);
595}
596
597/**
598 * This function generates double precision floating point
599 * pseudorandom numbers which distribute in the range (0, 1) to the
600 * specified array[] by one call. This function is the same as
601 * fill_array_close1_open2() except the distribution range.
602 *
603 * @param dsfmt dsfmt state vector.
604 * @param array an array where pseudorandom numbers are filled
605 * by this function.
606 * @param size the number of pseudorandom numbers to be generated.
607 * see also \sa fill_array_close1_open2()
608 */
609void dsfmt_fill_array_open_open(dsfmt_t *dsfmt, double array[], int size) {
610 assert(size % 2 == 0);
611 assert(size >= DSFMT_N64);
612 gen_rand_array_o0o1(dsfmt, (w128_t *)array, size / 2);
613}
614
615#if defined(__INTEL_COMPILER)
616# pragma warning(disable:981)
617#endif
618/**
619 * This function initializes the internal state array with a 32-bit
620 * integer seed.
621 * @param dsfmt dsfmt state vector.
622 * @param seed a 32-bit integer used as the seed.
623 * @param mexp caller's mersenne expornent
624 */
625void dsfmt_chk_init_gen_rand(dsfmt_t *dsfmt, uint32_t seed, int mexp) {
626 int i;
627 uint32_t *psfmt;
628
629 /* make sure caller program is compiled with the same MEXP */
630 if (mexp != dsfmt_mexp) {
631 fprintf(stderr, "DSFMT_MEXP doesn't match with dSFMT.c\n");
632 exit(1);
633 }
634 psfmt = &dsfmt->status[0].u32[0];
635 psfmt[idxof(0)] = seed;
636 for (i = 1; i < (DSFMT_N + 1) * 4; i++) {
637 psfmt[idxof(i)] = 1812433253UL
638 * (psfmt[idxof(i - 1)] ^ (psfmt[idxof(i - 1)] >> 30)) + i;
639 }
640 initial_mask(dsfmt);
641 period_certification(dsfmt);
642 dsfmt->idx = DSFMT_N64;
643#if defined(HAVE_SSE2)
644 setup_const();
645#endif
646}
647
648/**
649 * This function initializes the internal state array,
650 * with an array of 32-bit integers used as the seeds
651 * @param dsfmt dsfmt state vector.
652 * @param init_key the array of 32-bit integers, used as a seed.
653 * @param key_length the length of init_key.
654 * @param mexp caller's mersenne expornent
655 */
656void dsfmt_chk_init_by_array(dsfmt_t *dsfmt, uint32_t init_key[],
657 int key_length, int mexp) {
658 int i, j, count;
659 uint32_t r;
660 uint32_t *psfmt32;
661 int lag;
662 int mid;
663 int size = (DSFMT_N + 1) * 4; /* pulmonary */
664
665 /* make sure caller program is compiled with the same MEXP */
666 if (mexp != dsfmt_mexp) {
667 fprintf(stderr, "DSFMT_MEXP doesn't match with dSFMT.c\n");
668 exit(1);
669 }
670 if (size >= 623) {
671 lag = 11;
672 } else if (size >= 68) {
673 lag = 7;
674 } else if (size >= 39) {
675 lag = 5;
676 } else {
677 lag = 3;
678 }
679 mid = (size - lag) / 2;
680
681 psfmt32 = &dsfmt->status[0].u32[0];
682 memset(dsfmt->status, 0x8b, sizeof(dsfmt->status));
683 if (key_length + 1 > size) {
684 count = key_length + 1;
685 } else {
686 count = size;
687 }
688 r = ini_func1(psfmt32[idxof(0)] ^ psfmt32[idxof(mid % size)]
689 ^ psfmt32[idxof((size - 1) % size)]);
690 psfmt32[idxof(mid % size)] += r;
691 r += key_length;
692 psfmt32[idxof((mid + lag) % size)] += r;
693 psfmt32[idxof(0)] = r;
694 count--;
695 for (i = 1, j = 0; (j < count) && (j < key_length); j++) {
696 r = ini_func1(psfmt32[idxof(i)]
697 ^ psfmt32[idxof((i + mid) % size)]
698 ^ psfmt32[idxof((i + size - 1) % size)]);
699 psfmt32[idxof((i + mid) % size)] += r;
700 r += init_key[j] + i;
701 psfmt32[idxof((i + mid + lag) % size)] += r;
702 psfmt32[idxof(i)] = r;
703 i = (i + 1) % size;
704 }
705 for (; j < count; j++) {
706 r = ini_func1(psfmt32[idxof(i)]
707 ^ psfmt32[idxof((i + mid) % size)]
708 ^ psfmt32[idxof((i + size - 1) % size)]);
709 psfmt32[idxof((i + mid) % size)] += r;
710 r += i;
711 psfmt32[idxof((i + mid + lag) % size)] += r;
712 psfmt32[idxof(i)] = r;
713 i = (i + 1) % size;
714 }
715 for (j = 0; j < size; j++) {
716 r = ini_func2(psfmt32[idxof(i)]
717 + psfmt32[idxof((i + mid) % size)]
718 + psfmt32[idxof((i + size - 1) % size)]);
719 psfmt32[idxof((i + mid) % size)] ^= r;
720 r -= i;
721 psfmt32[idxof((i + mid + lag) % size)] ^= r;
722 psfmt32[idxof(i)] = r;
723 i = (i + 1) % size;
724 }
725 initial_mask(dsfmt);
726 period_certification(dsfmt);
727 dsfmt->idx = DSFMT_N64;
728#if defined(HAVE_SSE2)
729 setup_const();
730#endif
731}
732#if defined(__INTEL_COMPILER)
733# pragma warning(default:981)
734#endif
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