Coverage Report

Created: 2025-11-16 06:46

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/src/gmp/mpn/powm.c
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1
/* mpn_powm -- Compute R = U^E mod M.
2
3
   Contributed to the GNU project by Torbjorn Granlund.
4
5
   THE FUNCTIONS IN THIS FILE ARE INTERNAL WITH MUTABLE INTERFACES.  IT IS ONLY
6
   SAFE TO REACH THEM THROUGH DOCUMENTED INTERFACES.  IN FACT, IT IS ALMOST
7
   GUARANTEED THAT THEY WILL CHANGE OR DISAPPEAR IN A FUTURE GNU MP RELEASE.
8
9
Copyright 2007-2012, 2019-2021 Free Software Foundation, Inc.
10
11
This file is part of the GNU MP Library.
12
13
The GNU MP Library is free software; you can redistribute it and/or modify
14
it under the terms of either:
15
16
  * the GNU Lesser General Public License as published by the Free
17
    Software Foundation; either version 3 of the License, or (at your
18
    option) any later version.
19
20
or
21
22
  * the GNU General Public License as published by the Free Software
23
    Foundation; either version 2 of the License, or (at your option) any
24
    later version.
25
26
or both in parallel, as here.
27
28
The GNU MP Library is distributed in the hope that it will be useful, but
29
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
30
or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
31
for more details.
32
33
You should have received copies of the GNU General Public License and the
34
GNU Lesser General Public License along with the GNU MP Library.  If not,
35
see https://www.gnu.org/licenses/.  */
36
37
38
/*
39
  BASIC ALGORITHM, Compute U^E mod M, where M < B^n is odd.
40
41
  1. W <- U
42
43
  2. T <- (B^n * U) mod M                Convert to REDC form
44
45
  3. Compute table U^1, U^3, U^5... of E-dependent size
46
47
  4. While there are more bits in E
48
       W <- power left-to-right base-k
49
50
51
  TODO:
52
53
   * Make getbits a macro, thereby allowing it to update the index operand.
54
     That will simplify the code using getbits.  (Perhaps make getbits' sibling
55
     getbit then have similar form, for symmetry.)
56
57
   * Write an itch function.  Or perhaps get rid of tp parameter since the huge
58
     pp area is allocated locally anyway?
59
60
   * Choose window size without looping.  (Superoptimize or think(tm).)
61
62
   * Handle small bases with initial, reduction-free exponentiation.
63
64
   * Call new division functions, not mpn_tdiv_qr.
65
66
   * Consider special code for one-limb M.
67
68
   * How should we handle the redc1/redc2/redc_n choice?
69
     - redc1:  T(binvert_1limb)  + e * (n)   * (T(mullo-1x1) + n*T(addmul_1))
70
     - redc2:  T(binvert_2limbs) + e * (n/2) * (T(mullo-2x2) + n*T(addmul_2))
71
     - redc_n: T(binvert_nlimbs) + e * (T(mullo-nxn) + T(M(n)))
72
     This disregards the addmul_N constant term, but we could think of
73
     that as part of the respective mullo.
74
75
   * When U (the base) is small, we should start the exponentiation with plain
76
     operations, then convert that partial result to REDC form.
77
78
   * When U is just one limb, should it be handled without the k-ary tricks?
79
     We could keep a factor of B^n in W, but use U' = BU as base.  After
80
     multiplying by this (pseudo two-limb) number, we need to multiply by 1/B
81
     mod M.
82
*/
83
84
#include "gmp-impl.h"
85
#include "longlong.h"
86
87
#undef MPN_REDC_0
88
#define MPN_REDC_0(r0, u1, u0, m0, invm)        \
89
676k
  do {                 \
90
676k
    mp_limb_t _p1, _u1, _u0, _m0, _r0, _dummy;        \
91
676k
    _u0 = (u0);               \
92
676k
    _m0 = (m0);               \
93
676k
    umul_ppmm (_p1, _dummy, _m0, (_u0 * (invm)) & GMP_NUMB_MASK);  \
94
676k
    ASSERT (((_u0 - _dummy) & GMP_NUMB_MASK) == 0);     \
95
676k
    _u1 = (u1);               \
96
676k
    _r0 = _u1 - _p1;              \
97
676k
    _r0 = _u1 < _p1 ? _r0 + _m0 : _r0; /* _u1 < _r0 */     \
98
676k
    (r0) = _r0 & GMP_NUMB_MASK;           \
99
676k
  } while (0)
100
101
#undef MPN_REDC_1
102
#if HAVE_NATIVE_mpn_sbpi1_bdiv_r
103
#define MPN_REDC_1(rp, up, mp, n, invm)         \
104
  do {                  \
105
    mp_limb_t cy;             \
106
    cy = mpn_sbpi1_bdiv_r (up, 2 * n, mp, n, invm);     \
107
    if (cy != 0)              \
108
      mpn_sub_n (rp, up + n, mp, n);          \
109
    else                \
110
      MPN_COPY (rp, up + n, n);           \
111
  } while (0)
112
#else
113
#define MPN_REDC_1(rp, up, mp, n, invm)         \
114
13.7M
  do {                 \
115
13.7M
    mp_limb_t cy;             \
116
13.7M
    cy = mpn_redc_1 (rp, up, mp, n, invm);       \
117
13.7M
    if (cy != 0)             \
118
13.7M
      mpn_sub_n (rp, rp, mp, n);         \
119
13.7M
  } while (0)
120
#endif
121
122
#undef MPN_REDC_2
123
#define MPN_REDC_2(rp, up, mp, n, mip)          \
124
  do {                  \
125
    mp_limb_t cy;             \
126
    cy = mpn_redc_2 (rp, up, mp, n, mip);       \
127
    if (cy != 0)              \
128
      mpn_sub_n (rp, rp, mp, n);          \
129
  } while (0)
130
131
#if HAVE_NATIVE_mpn_addmul_2 || HAVE_NATIVE_mpn_redc_2
132
#define WANT_REDC_2 1
133
#endif
134
135
#define getbit(p,bi) \
136
10.4M
  ((p[(bi - 1) / GMP_LIMB_BITS] >> (bi - 1) % GMP_LIMB_BITS) & 1)
137
138
static inline mp_limb_t
139
getbits (const mp_limb_t *p, mp_bitcnt_t bi, int nbits)
140
1.31M
{
141
1.31M
  int nbits_in_r;
142
1.31M
  mp_limb_t r;
143
1.31M
  mp_size_t i;
144
145
1.31M
  if (bi <= nbits)
146
33.9k
    {
147
33.9k
      return p[0] & (((mp_limb_t) 1 << bi) - 1);
148
33.9k
    }
149
1.27M
  else
150
1.27M
    {
151
1.27M
      bi -= nbits;      /* bit index of low bit to extract */
152
1.27M
      i = bi / GMP_NUMB_BITS;   /* word index of low bit to extract */
153
1.27M
      bi %= GMP_NUMB_BITS;   /* bit index in low word */
154
1.27M
      r = p[i] >> bi;     /* extract (low) bits */
155
1.27M
      nbits_in_r = GMP_NUMB_BITS - bi;  /* number of bits now in r */
156
1.27M
      if (nbits_in_r < nbits)    /* did we get enough bits? */
157
87.4k
  r += p[i + 1] << nbits_in_r; /* prepend bits from higher word */
158
1.27M
      return r & (((mp_limb_t) 1 << nbits) - 1);
159
1.27M
    }
160
1.31M
}
161
162
static inline int
163
win_size (mp_bitcnt_t eb)
164
41.3k
{
165
41.3k
  int k;
166
41.3k
  static mp_bitcnt_t x[] = {7,25,81,241,673,1793,4609,11521,28161,~(mp_bitcnt_t)0};
167
120k
  for (k = 0; eb > x[k++]; )
168
79.3k
    ;
169
41.3k
  return k;
170
41.3k
}
171
172
/* Convert U to REDC form, U_r = B^n * U mod M */
173
static void
174
redcify (mp_ptr rp, mp_srcptr up, mp_size_t un, mp_srcptr mp, mp_size_t n)
175
48.7k
{
176
48.7k
  mp_ptr tp, qp;
177
48.7k
  TMP_DECL;
178
48.7k
  TMP_MARK;
179
180
48.7k
  TMP_ALLOC_LIMBS_2 (tp, un + n, qp, un + 1);
181
182
48.7k
  MPN_ZERO (tp, n);
183
48.7k
  MPN_COPY (tp + n, up, un);
184
48.7k
  mpn_tdiv_qr (qp, rp, 0L, tp, un + n, mp, n);
185
48.7k
  TMP_FREE;
186
48.7k
}
187
188
#if ! HAVE_NATIVE_mpn_rsblsh1_n_ip2
189
#undef mpn_rsblsh1_n_ip2
190
#if HAVE_NATIVE_mpn_rsblsh1_n
191
#define mpn_rsblsh1_n_ip2(a,b,n)  mpn_rsblsh1_n(a,b,a,n)
192
#else
193
#define mpn_rsblsh1_n_ip2(a,b,n)        \
194
1.33M
  do                \
195
1.33M
    {               \
196
1.33M
      mpn_lshift (a, a, n, 1);          \
197
1.33M
      mpn_sub_n (a, a, b, n);          \
198
1.33M
    } while (0)
199
#endif
200
#endif
201
202
#define INNERLOOP2            \
203
7.37k
  do                \
204
6.21M
    {               \
205
6.21M
      MPN_SQR (tp, rp, n);         \
206
6.21M
      MPN_REDUCE (rp, tp, mp, n, mip);        \
207
6.21M
      if (mpn_cmp (rp, mp, n) >= 0)       \
208
6.21M
  ASSERT_NOCARRY (mpn_sub_n (rp, rp, mp, n));   \
209
6.21M
      if (getbit (ep, ebi) != 0)       \
210
6.21M
  {             \
211
3.07M
    if (rp[n - 1] >> (mbi - 1) % GMP_LIMB_BITS == 0)  \
212
3.07M
      ASSERT_NOCARRY (mpn_lshift (rp, rp, n, 1));   \
213
3.07M
    else              \
214
3.07M
      mpn_rsblsh1_n_ip2 (rp, mp, n);     \
215
3.07M
  }              \
216
6.21M
    } while (--ebi != 0)
217
218
/* rp[n-1..0] = 2 ^ ep[en-1..0] mod mp[n-1..0]
219
   Requires that mp[n-1..0] is odd and > 1.
220
   Requires that ep[en-1..0] is > 1.
221
   Uses scratch space at tp of MAX(mpn_binvert_itch(n),2n) limbs.  */
222
static void
223
mpn_2powm (mp_ptr rp, mp_srcptr ep, mp_size_t en,
224
    mp_srcptr mp, mp_size_t n, mp_ptr tp)
225
8.37k
{
226
8.37k
  mp_limb_t ip[2], *mip;
227
8.37k
  mp_bitcnt_t ebi, mbi, tbi;
228
8.37k
  mp_size_t tn;
229
8.37k
  int count;
230
8.37k
  TMP_DECL;
231
232
8.37k
  ASSERT (en > 1 || (en == 1 && ep[0] > 1));
233
8.37k
  ASSERT (n > 0 && (mp[0] & 1) != 0);
234
235
8.37k
  MPN_SIZEINBASE_2EXP(ebi, ep, en, 1);
236
8.37k
  MPN_SIZEINBASE_2EXP(mbi, mp, n, 1);
237
238
8.37k
  if (LIKELY (mbi <= GMP_NUMB_MAX))
239
8.37k
    {
240
8.37k
      count_leading_zeros(count, (mp_limb_t) mbi);
241
8.37k
      count = GMP_NUMB_BITS - (count - GMP_NAIL_BITS);
242
8.37k
    }
243
0
  else
244
0
    {
245
0
      mp_bitcnt_t tc = mbi;
246
247
0
      count = 0;
248
0
      do { ++count; } while ((tc >>= 1) != 0);
249
0
    }
250
251
8.37k
  tbi = getbits (ep, ebi, count);
252
8.37k
  if (tbi >= mbi)
253
6.39k
    {
254
6.39k
      --count;
255
6.39k
      ASSERT ((tbi >> count) == 1);
256
6.39k
      tbi >>= 1;
257
6.39k
      ASSERT (tbi < mbi);
258
6.39k
      ASSERT (ebi > count);
259
6.39k
    }
260
1.98k
  else if (ebi <= count)
261
16
    {
262
16
      MPN_FILL (rp, n, 0);
263
16
      rp[tbi / GMP_LIMB_BITS] = CNST_LIMB (1) << (tbi % GMP_LIMB_BITS);
264
16
      return;
265
16
    }
266
8.36k
  ebi -= count;
267
268
8.36k
  if (n == 1)
269
987
    {
270
987
      mp_limb_t r0, m0, invm;
271
987
      m0 = *mp;
272
273
      /* redcify (rp, tp, tn + 1, mp, n); */
274
      /* TODO: test direct use of udiv_qrnnd */
275
987
      ASSERT (tbi < GMP_LIMB_BITS);
276
987
      tp[1] = CNST_LIMB (1) << tbi;
277
987
      tp[0] = CNST_LIMB (0);
278
987
      r0 = mpn_mod_1 (tp, 2, m0);
279
280
987
      binvert_limb (invm, m0);
281
987
      do
282
154k
  {
283
154k
    mp_limb_t t0, t1, t2;
284
    /* MPN_SQR (tp, rp, n);     */
285
154k
    umul_ppmm (t1, t0, r0, r0);
286
    /* MPN_REDUCE (rp, tp, mp, n, mip);   */
287
154k
    MPN_REDC_0(r0, t1, t0, m0, invm);
288
289
154k
    t2 = r0 << 1;
290
154k
    t2 = r0 > (m0 >> 1) ? t2 - m0 : t2;
291
154k
    r0 = getbit (ep, ebi) != 0 ? t2 : r0;
292
154k
  } while (--ebi != 0);
293
294
      /* tp[1] = 0; tp[0] = r0; */
295
      /* MPN_REDUCE (rp, tp, mp, n, mip); */
296
987
      MPN_REDC_0(*rp, 0, r0, m0, invm);
297
298
987
      return;
299
987
    }
300
301
7.37k
  TMP_MARK;
302
303
#if WANT_REDC_2
304
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
305
    {
306
      mip = ip;
307
      binvert_limb (ip[0], mp[0]);
308
      ip[0] = -ip[0];
309
    }
310
  else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
311
    {
312
      mip = ip;
313
      mpn_binvert (ip, mp, 2, tp);
314
      ip[0] = -ip[0]; ip[1] = ~ip[1];
315
    }
316
#else
317
7.37k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
318
6.63k
    {
319
6.63k
      mip = ip;
320
6.63k
      binvert_limb (ip[0], mp[0]);
321
6.63k
      ip[0] = -ip[0];
322
6.63k
    }
323
735
#endif
324
735
  else
325
735
    {
326
735
      mip = TMP_ALLOC_LIMBS (n);
327
735
      mpn_binvert (mip, mp, n, tp);
328
735
    }
329
330
7.37k
  tn = tbi / GMP_LIMB_BITS;
331
7.37k
  MPN_ZERO (tp, tn);
332
7.37k
  tp[tn] = CNST_LIMB (1) << (tbi % GMP_LIMB_BITS);
333
334
7.37k
  redcify (rp, tp, tn + 1, mp, n);
335
336
#if WANT_REDC_2
337
  if (REDC_1_TO_REDC_2_THRESHOLD < MUL_TOOM22_THRESHOLD)
338
    {
339
      if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
340
  {
341
    if (REDC_1_TO_REDC_2_THRESHOLD < SQR_BASECASE_THRESHOLD
342
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
343
      {
344
#undef MPN_SQR
345
#undef MPN_REDUCE
346
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
347
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
348
        INNERLOOP2;
349
      }
350
    else
351
      {
352
#undef MPN_SQR
353
#undef MPN_REDUCE
354
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
355
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
356
        INNERLOOP2;
357
      }
358
  }
359
      else if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
360
  {
361
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
362
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
363
      {
364
#undef MPN_SQR
365
#undef MPN_REDUCE
366
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
367
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
368
        INNERLOOP2;
369
      }
370
    else
371
      {
372
#undef MPN_SQR
373
#undef MPN_REDUCE
374
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
375
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
376
        INNERLOOP2;
377
      }
378
  }
379
      else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
380
  {
381
#undef MPN_SQR
382
#undef MPN_REDUCE
383
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
384
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
385
    INNERLOOP2;
386
  }
387
      else
388
  {
389
#undef MPN_SQR
390
#undef MPN_REDUCE
391
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
392
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
393
    INNERLOOP2;
394
  }
395
    }
396
  else
397
    {
398
      if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
399
  {
400
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
401
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
402
      {
403
#undef MPN_SQR
404
#undef MPN_REDUCE
405
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
406
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
407
        INNERLOOP2;
408
      }
409
    else
410
      {
411
#undef MPN_SQR
412
#undef MPN_REDUCE
413
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
414
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
415
        INNERLOOP2;
416
      }
417
  }
418
      else if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
419
  {
420
#undef MPN_SQR
421
#undef MPN_REDUCE
422
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
423
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
424
    INNERLOOP2;
425
  }
426
      else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
427
  {
428
#undef MPN_SQR
429
#undef MPN_REDUCE
430
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
431
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
432
    INNERLOOP2;
433
  }
434
      else
435
  {
436
#undef MPN_SQR
437
#undef MPN_REDUCE
438
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
439
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
440
    INNERLOOP2;
441
  }
442
    }
443
444
#else  /* WANT_REDC_2 */
445
446
7.37k
  if (REDC_1_TO_REDC_N_THRESHOLD < MUL_TOOM22_THRESHOLD)
447
0
    {
448
0
      if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
449
0
  {
450
0
    if (REDC_1_TO_REDC_N_THRESHOLD < SQR_BASECASE_THRESHOLD
451
0
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
452
0
      {
453
0
#undef MPN_SQR
454
0
#undef MPN_REDUCE
455
0
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
456
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
457
0
        INNERLOOP2;
458
0
      }
459
0
    else
460
0
      {
461
0
#undef MPN_SQR
462
0
#undef MPN_REDUCE
463
0
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
464
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
465
0
        INNERLOOP2;
466
0
      }
467
0
  }
468
0
      else if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
469
0
  {
470
0
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
471
0
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
472
0
      {
473
0
#undef MPN_SQR
474
0
#undef MPN_REDUCE
475
0
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
476
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
477
0
        INNERLOOP2;
478
0
      }
479
0
    else
480
0
      {
481
0
#undef MPN_SQR
482
0
#undef MPN_REDUCE
483
0
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
484
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
485
0
        INNERLOOP2;
486
0
      }
487
0
  }
488
0
      else
489
0
  {
490
0
#undef MPN_SQR
491
0
#undef MPN_REDUCE
492
0
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
493
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
494
0
    INNERLOOP2;
495
0
  }
496
0
    }
497
7.37k
  else
498
7.37k
    {
499
7.37k
      if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
500
1.73k
  {
501
1.73k
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
502
0
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
503
0
      {
504
0
#undef MPN_SQR
505
0
#undef MPN_REDUCE
506
0
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
507
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
508
0
        INNERLOOP2;
509
0
      }
510
1.73k
    else
511
1.73k
      {
512
1.73k
#undef MPN_SQR
513
1.73k
#undef MPN_REDUCE
514
240k
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
515
240k
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
516
1.73k
        INNERLOOP2;
517
1.73k
      }
518
1.73k
  }
519
5.64k
      else if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
520
4.90k
  {
521
4.90k
#undef MPN_SQR
522
4.90k
#undef MPN_REDUCE
523
4.94M
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
524
4.94M
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
525
4.90k
    INNERLOOP2;
526
4.90k
  }
527
735
      else
528
735
  {
529
735
#undef MPN_SQR
530
735
#undef MPN_REDUCE
531
1.02M
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
532
1.02M
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
533
735
    INNERLOOP2;
534
735
  }
535
7.37k
    }
536
7.37k
#endif  /* WANT_REDC_2 */
537
538
7.37k
  MPN_COPY (tp, rp, n);
539
7.37k
  MPN_FILL (tp + n, n, 0);
540
541
#if WANT_REDC_2
542
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
543
    MPN_REDC_1 (rp, tp, mp, n, ip[0]);
544
  else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
545
    MPN_REDC_2 (rp, tp, mp, n, mip);
546
#else
547
7.37k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
548
6.63k
    MPN_REDC_1 (rp, tp, mp, n, ip[0]);
549
735
#endif
550
735
  else
551
735
    mpn_redc_n (rp, tp, mp, n, mip);
552
553
7.37k
  if (mpn_cmp (rp, mp, n) >= 0)
554
0
    mpn_sub_n (rp, rp, mp, n);
555
556
7.37k
  TMP_FREE;
557
7.37k
}
558
559
/* rp[n-1..0] = bp[bn-1..0] ^ ep[en-1..0] mod mp[n-1..0]
560
   Requires that mp[n-1..0] is odd.
561
   Requires that ep[en-1..0] is > 1.
562
   Uses scratch space at tp of MAX(mpn_binvert_itch(n),2n) limbs.  */
563
void
564
mpn_powm (mp_ptr rp, mp_srcptr bp, mp_size_t bn,
565
    mp_srcptr ep, mp_size_t en,
566
    mp_srcptr mp, mp_size_t n, mp_ptr tp)
567
49.7k
{
568
49.7k
  mp_limb_t ip[2], *mip;
569
49.7k
  int cnt;
570
49.7k
  mp_bitcnt_t ebi;
571
49.7k
  int windowsize, this_windowsize;
572
49.7k
  mp_limb_t expbits;
573
49.7k
  mp_ptr pp, this_pp;
574
49.7k
  long i;
575
49.7k
  TMP_DECL;
576
577
49.7k
  ASSERT (en > 1 || (en == 1 && ep[0] > 1));
578
49.7k
  ASSERT (n >= 1 && ((mp[0] & 1) != 0));
579
580
49.7k
  if (bn == 1 && bp[0] == 2)
581
8.37k
    {
582
8.37k
      mpn_2powm (rp, ep, en, mp, n, tp);
583
8.37k
      return;
584
8.37k
    }
585
586
41.3k
  TMP_MARK;
587
588
41.3k
  MPN_SIZEINBASE_2EXP(ebi, ep, en, 1);
589
590
#if 0
591
  if (bn < n)
592
    {
593
      /* Do the first few exponent bits without mod reductions,
594
   until the result is greater than the mod argument.  */
595
      for (;;)
596
  {
597
    mpn_sqr (tp, this_pp, tn);
598
    tn = tn * 2 - 1,  tn += tp[tn] != 0;
599
    if (getbit (ep, ebi) != 0)
600
      mpn_mul (..., tp, tn, bp, bn);
601
    ebi--;
602
  }
603
    }
604
#endif
605
606
41.3k
  windowsize = win_size (ebi);
607
608
#if WANT_REDC_2
609
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
610
    {
611
      mip = ip;
612
      binvert_limb (mip[0], mp[0]);
613
      mip[0] = -mip[0];
614
    }
615
  else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
616
    {
617
      mip = ip;
618
      mpn_binvert (mip, mp, 2, tp);
619
      mip[0] = -mip[0]; mip[1] = ~mip[1];
620
    }
621
#else
622
41.3k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
623
39.8k
    {
624
39.8k
      mip = ip;
625
39.8k
      binvert_limb (mip[0], mp[0]);
626
39.8k
      mip[0] = -mip[0];
627
39.8k
    }
628
1.55k
#endif
629
1.55k
  else
630
1.55k
    {
631
1.55k
      mip = TMP_ALLOC_LIMBS (n);
632
1.55k
      mpn_binvert (mip, mp, n, tp);
633
1.55k
    }
634
635
41.3k
  pp = TMP_ALLOC_LIMBS (n << (windowsize - 1));
636
637
41.3k
  this_pp = pp;
638
41.3k
  redcify (this_pp, bp, bn, mp, n);
639
640
  /* Store b^2 at rp.  */
641
41.3k
  mpn_sqr (tp, this_pp, n);
642
#if 0
643
  if (n == 1) {
644
    MPN_REDC_0 (rp[0], tp[1], tp[0], mp[0], -mip[0]);
645
  } else
646
#endif
647
#if WANT_REDC_2
648
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
649
    MPN_REDC_1 (rp, tp, mp, n, mip[0]);
650
  else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
651
    MPN_REDC_2 (rp, tp, mp, n, mip);
652
#else
653
41.3k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
654
39.8k
    MPN_REDC_1 (rp, tp, mp, n, mip[0]);
655
1.55k
#endif
656
1.55k
  else
657
1.55k
    mpn_redc_n (rp, tp, mp, n, mip);
658
659
  /* Precompute odd powers of b and put them in the temporary area at pp.  */
660
335k
  for (i = (1 << (windowsize - 1)) - 1; i > 0; i--)
661
294k
#if 1
662
294k
    if (n == 1) {
663
17.3k
      umul_ppmm((tp)[1], *(tp), *(this_pp), *(rp));
664
17.3k
      ++this_pp ;
665
17.3k
      MPN_REDC_0 (*this_pp, tp[1], tp[0], *mp, -mip[0]);
666
17.3k
    } else
667
277k
#endif
668
277k
    {
669
277k
      mpn_mul_n (tp, this_pp, rp, n);
670
277k
      this_pp += n;
671
#if WANT_REDC_2
672
      if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
673
  MPN_REDC_1 (this_pp, tp, mp, n, mip[0]);
674
      else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
675
  MPN_REDC_2 (this_pp, tp, mp, n, mip);
676
#else
677
277k
      if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
678
228k
  MPN_REDC_1 (this_pp, tp, mp, n, mip[0]);
679
48.7k
#endif
680
48.7k
      else
681
48.7k
  mpn_redc_n (this_pp, tp, mp, n, mip);
682
277k
    }
683
684
41.3k
  expbits = getbits (ep, ebi, windowsize);
685
41.3k
  ebi -= windowsize;
686
687
  /* THINK: Should we initialise the case expbits % 4 == 0 with a mul? */
688
41.3k
  count_trailing_zeros (cnt, expbits);
689
41.3k
  ebi += cnt;
690
41.3k
  expbits >>= cnt;
691
692
41.3k
  MPN_COPY (rp, pp + n * (expbits >> 1), n);
693
694
41.3k
#define INNERLOOP             \
695
1.30M
  while (ebi != 0)             \
696
1.27M
    {                 \
697
4.07M
      while (getbit (ep, ebi) == 0)         \
698
2.81M
  {               \
699
2.81M
    MPN_SQR (tp, rp, n);           \
700
2.81M
    MPN_REDUCE (rp, tp, mp, n, mip);        \
701
2.81M
    if (--ebi == 0)           \
702
2.81M
      goto done;             \
703
2.81M
  }                \
704
1.27M
                  \
705
      /* The next bit of the exponent is 1.  Now extract the largest  \
706
   block of bits <= windowsize, and such that the least   \
707
   significant bit is 1.  */          \
708
1.27M
                  \
709
1.27M
      expbits = getbits (ep, ebi, windowsize);        \
710
1.26M
      this_windowsize = MIN (ebi, windowsize);       \
711
1.26M
                  \
712
1.26M
      count_trailing_zeros (cnt, expbits);        \
713
1.26M
      this_windowsize -= cnt;           \
714
1.26M
      ebi -= this_windowsize;           \
715
1.26M
      expbits >>= cnt;              \
716
1.26M
                  \
717
1.26M
      do                \
718
6.34M
  {               \
719
6.34M
    MPN_SQR (tp, rp, n);           \
720
6.34M
    MPN_REDUCE (rp, tp, mp, n, mip);        \
721
6.34M
  }                \
722
6.34M
      while (--this_windowsize != 0);          \
723
1.26M
                  \
724
1.26M
      MPN_MUL_N (tp, rp, pp + n * (expbits >> 1), n);      \
725
1.26M
      MPN_REDUCE (rp, tp, mp, n, mip);          \
726
1.26M
    }
727
728
729
41.3k
  if (n == 1)
730
1.73k
    {
731
1.73k
#undef MPN_MUL_N
732
1.73k
#undef MPN_SQR
733
1.73k
#undef MPN_REDUCE
734
72.2k
#define MPN_MUL_N(r,a,b,n)    umul_ppmm((r)[1], *(r), *(a), *(b))
735
430k
#define MPN_SQR(r,a,n)      umul_ppmm((r)[1], *(r), *(a), *(a))
736
503k
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_0(*(rp), (tp)[1], (tp)[0], *(mp), - *(mip))
737
1.73k
      INNERLOOP;
738
393
    }
739
39.6k
  else
740
#if WANT_REDC_2
741
  if (REDC_1_TO_REDC_2_THRESHOLD < MUL_TOOM22_THRESHOLD)
742
    {
743
      if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
744
  {
745
    if (REDC_1_TO_REDC_2_THRESHOLD < SQR_BASECASE_THRESHOLD
746
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
747
      {
748
#undef MPN_MUL_N
749
#undef MPN_SQR
750
#undef MPN_REDUCE
751
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
752
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
753
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
754
        INNERLOOP;
755
      }
756
    else
757
      {
758
#undef MPN_MUL_N
759
#undef MPN_SQR
760
#undef MPN_REDUCE
761
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
762
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
763
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
764
        INNERLOOP;
765
      }
766
  }
767
      else if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
768
  {
769
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
770
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
771
      {
772
#undef MPN_MUL_N
773
#undef MPN_SQR
774
#undef MPN_REDUCE
775
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
776
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
777
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
778
        INNERLOOP;
779
      }
780
    else
781
      {
782
#undef MPN_MUL_N
783
#undef MPN_SQR
784
#undef MPN_REDUCE
785
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
786
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
787
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
788
        INNERLOOP;
789
      }
790
  }
791
      else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
792
  {
793
#undef MPN_MUL_N
794
#undef MPN_SQR
795
#undef MPN_REDUCE
796
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
797
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
798
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
799
    INNERLOOP;
800
  }
801
      else
802
  {
803
#undef MPN_MUL_N
804
#undef MPN_SQR
805
#undef MPN_REDUCE
806
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
807
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
808
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
809
    INNERLOOP;
810
  }
811
    }
812
  else
813
    {
814
      if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
815
  {
816
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
817
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
818
      {
819
#undef MPN_MUL_N
820
#undef MPN_SQR
821
#undef MPN_REDUCE
822
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
823
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
824
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
825
        INNERLOOP;
826
      }
827
    else
828
      {
829
#undef MPN_MUL_N
830
#undef MPN_SQR
831
#undef MPN_REDUCE
832
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
833
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
834
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
835
        INNERLOOP;
836
      }
837
  }
838
      else if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
839
  {
840
#undef MPN_MUL_N
841
#undef MPN_SQR
842
#undef MPN_REDUCE
843
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
844
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
845
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
846
    INNERLOOP;
847
  }
848
      else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
849
  {
850
#undef MPN_MUL_N
851
#undef MPN_SQR
852
#undef MPN_REDUCE
853
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
854
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
855
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2 (rp, tp, mp, n, mip)
856
    INNERLOOP;
857
  }
858
      else
859
  {
860
#undef MPN_MUL_N
861
#undef MPN_SQR
862
#undef MPN_REDUCE
863
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
864
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
865
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
866
    INNERLOOP;
867
  }
868
    }
869
870
#else  /* WANT_REDC_2 */
871
872
39.6k
  if (REDC_1_TO_REDC_N_THRESHOLD < MUL_TOOM22_THRESHOLD)
873
0
    {
874
0
      if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
875
0
  {
876
0
    if (REDC_1_TO_REDC_N_THRESHOLD < SQR_BASECASE_THRESHOLD
877
0
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
878
0
      {
879
0
#undef MPN_MUL_N
880
0
#undef MPN_SQR
881
0
#undef MPN_REDUCE
882
0
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
883
0
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
884
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
885
0
        INNERLOOP;
886
0
      }
887
0
    else
888
0
      {
889
0
#undef MPN_MUL_N
890
0
#undef MPN_SQR
891
0
#undef MPN_REDUCE
892
0
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
893
0
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
894
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
895
0
        INNERLOOP;
896
0
      }
897
0
  }
898
0
      else if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
899
0
  {
900
0
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
901
0
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
902
0
      {
903
0
#undef MPN_MUL_N
904
0
#undef MPN_SQR
905
0
#undef MPN_REDUCE
906
0
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
907
0
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
908
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
909
0
        INNERLOOP;
910
0
      }
911
0
    else
912
0
      {
913
0
#undef MPN_MUL_N
914
0
#undef MPN_SQR
915
0
#undef MPN_REDUCE
916
0
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
917
0
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
918
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
919
0
        INNERLOOP;
920
0
      }
921
0
  }
922
0
      else
923
0
  {
924
0
#undef MPN_MUL_N
925
0
#undef MPN_SQR
926
0
#undef MPN_REDUCE
927
0
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
928
0
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
929
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
930
0
    INNERLOOP;
931
0
  }
932
0
    }
933
39.6k
  else
934
39.6k
    {
935
39.6k
      if (BELOW_THRESHOLD (n, MUL_TOOM22_THRESHOLD))
936
8.57k
  {
937
8.57k
    if (MUL_TOOM22_THRESHOLD < SQR_BASECASE_THRESHOLD
938
0
        || BELOW_THRESHOLD (n, SQR_BASECASE_THRESHOLD))
939
0
      {
940
0
#undef MPN_MUL_N
941
0
#undef MPN_SQR
942
0
#undef MPN_REDUCE
943
0
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
944
0
#define MPN_SQR(r,a,n)      mpn_mul_basecase (r,a,n,a,n)
945
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
946
0
        INNERLOOP;
947
0
      }
948
8.57k
    else
949
8.57k
      {
950
8.57k
#undef MPN_MUL_N
951
8.57k
#undef MPN_SQR
952
8.57k
#undef MPN_REDUCE
953
217k
#define MPN_MUL_N(r,a,b,n)    mpn_mul_basecase (r,a,n,b,n)
954
1.25M
#define MPN_SQR(r,a,n)      mpn_sqr_basecase (r,a,n)
955
1.47M
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
956
8.57k
        INNERLOOP;
957
1.66k
      }
958
8.57k
  }
959
31.0k
      else if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
960
29.5k
  {
961
29.5k
#undef MPN_MUL_N
962
29.5k
#undef MPN_SQR
963
29.5k
#undef MPN_REDUCE
964
768k
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
965
6.04M
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
966
6.81M
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1 (rp, tp, mp, n, mip[0])
967
29.5k
    INNERLOOP;
968
28.0k
  }
969
1.55k
      else
970
1.55k
  {
971
1.55k
#undef MPN_MUL_N
972
1.55k
#undef MPN_SQR
973
1.55k
#undef MPN_REDUCE
974
203k
#define MPN_MUL_N(r,a,b,n)    mpn_mul_n (r,a,b,n)
975
1.43M
#define MPN_SQR(r,a,n)      mpn_sqr (r,a,n)
976
1.64M
#define MPN_REDUCE(rp,tp,mp,n,mip)  mpn_redc_n (rp, tp, mp, n, mip)
977
1.55k
    INNERLOOP;
978
674
  }
979
39.6k
    }
980
30.7k
#endif  /* WANT_REDC_2 */
981
982
41.3k
 done:
983
984
41.3k
  MPN_COPY (tp, rp, n);
985
41.3k
  MPN_ZERO (tp + n, n);
986
987
#if WANT_REDC_2
988
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
989
    MPN_REDC_1 (rp, tp, mp, n, mip[0]);
990
  else if (BELOW_THRESHOLD (n, REDC_2_TO_REDC_N_THRESHOLD))
991
    MPN_REDC_2 (rp, tp, mp, n, mip);
992
#else
993
41.3k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_N_THRESHOLD))
994
39.8k
    MPN_REDC_1 (rp, tp, mp, n, mip[0]);
995
1.55k
#endif
996
1.55k
  else
997
1.55k
    mpn_redc_n (rp, tp, mp, n, mip);
998
999
41.3k
  if (mpn_cmp (rp, mp, n) >= 0)
1000
1
    mpn_sub_n (rp, rp, mp, n);
1001
1002
41.3k
  TMP_FREE;
1003
41.3k
}