Coverage Report

Created: 2026-06-30 06:42

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/src/gmp/mpn/sec_powm.c
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Source
1
/* mpn_sec_powm -- Compute R = U^E mod M.  Secure variant, side-channel silent
2
   under the assumption that the multiply instruction is side channel silent.
3
4
   Contributed to the GNU project by Torbjörn Granlund.
5
6
Copyright 2007-2009, 2011-2014, 2018-2019, 2021 Free Software Foundation, Inc.
7
8
This file is part of the GNU MP Library.
9
10
The GNU MP Library is free software; you can redistribute it and/or modify
11
it under the terms of either:
12
13
  * the GNU Lesser General Public License as published by the Free
14
    Software Foundation; either version 3 of the License, or (at your
15
    option) any later version.
16
17
or
18
19
  * the GNU General Public License as published by the Free Software
20
    Foundation; either version 2 of the License, or (at your option) any
21
    later version.
22
23
or both in parallel, as here.
24
25
The GNU MP Library is distributed in the hope that it will be useful, but
26
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
27
or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
28
for more details.
29
30
You should have received copies of the GNU General Public License and the
31
GNU Lesser General Public License along with the GNU MP Library.  If not,
32
see https://www.gnu.org/licenses/.  */
33
34
35
/*
36
  BASIC ALGORITHM, Compute U^E mod M, where M < B^n is odd.
37
38
  1. T <- (B^n * U) mod M; convert to REDC form
39
40
  2. Compute table U^0, U^1, U^2... of floor(log(E))-dependent size
41
42
  3. While there are more bits in E
43
       W <- power left-to-right base-k
44
45
  The article "Defeating modexp side-channel attacks with data-independent
46
  execution traces", https://gmplib.org/~tege/modexp-silent.pdf, has details.
47
48
49
  TODO:
50
51
   * Make getbits a macro, thereby allowing it to update the index operand.
52
     That will simplify the code using getbits.  (Perhaps make getbits' sibling
53
     getbit then have similar form, for symmetry.)
54
55
   * Choose window size without looping.  (Superoptimize or think(tm).)
56
57
   * REDC_1_TO_REDC_2_THRESHOLD might actually represent the cutoff between
58
     redc_1 and redc_n.  On such systems, we will switch to redc_2 causing
59
     slowdown.
60
*/
61
62
#include "gmp-impl.h"
63
#include "longlong.h"
64
65
#undef MPN_REDC_1_SEC
66
#if HAVE_NATIVE_mpn_sbpi1_bdiv_r
67
#define MPN_REDC_1_SEC(rp, up, mp, n, invm)       \
68
  do {                  \
69
    mp_limb_t cy;             \
70
    cy = mpn_sbpi1_bdiv_r (up, 2 * n, mp, n, invm);     \
71
    mpn_cnd_sub_n (cy, rp, up + n, mp, n);        \
72
  } while (0)
73
#else
74
#define MPN_REDC_1_SEC(rp, up, mp, n, invm)       \
75
49.8M
  do {                 \
76
49.8M
    mp_limb_t cy;             \
77
49.8M
    cy = mpn_redc_1 (rp, up, mp, n, invm);       \
78
49.8M
    mpn_cnd_sub_n (cy, rp, rp, mp, n);         \
79
49.8M
  } while (0)
80
#endif
81
82
#if HAVE_NATIVE_mpn_addmul_2 || HAVE_NATIVE_mpn_redc_2
83
#undef MPN_REDC_2_SEC
84
#define MPN_REDC_2_SEC(rp, up, mp, n, mip)        \
85
  do {                  \
86
    mp_limb_t cy;             \
87
    cy = mpn_redc_2 (rp, up, mp, n, mip);       \
88
    mpn_cnd_sub_n (cy, rp, rp, mp, n);          \
89
  } while (0)
90
#else
91
#define MPN_REDC_2_SEC(rp, up, mp, n, mip) /* empty */
92
#undef REDC_1_TO_REDC_2_THRESHOLD
93
#define REDC_1_TO_REDC_2_THRESHOLD MP_SIZE_T_MAX
94
#endif
95
96
/* Define our own mpn squaring function.  We do this since we cannot use a
97
   native mpn_sqr_basecase over TUNE_SQR_TOOM2_MAX, or a non-native one over
98
   SQR_TOOM2_THRESHOLD.  This is so because of fixed size stack allocations
99
   made inside mpn_sqr_basecase.  */
100
101
#if ! HAVE_NATIVE_mpn_sqr_basecase
102
/* The limit of the generic code is SQR_TOOM2_THRESHOLD.  */
103
#define SQR_BASECASE_LIM  SQR_TOOM2_THRESHOLD
104
#endif
105
106
#if HAVE_NATIVE_mpn_sqr_basecase
107
#ifdef TUNE_SQR_TOOM2_MAX
108
/* We slightly abuse TUNE_SQR_TOOM2_MAX here.  If it is set for an assembly
109
   mpn_sqr_basecase, it comes from SQR_TOOM2_THRESHOLD_MAX in the assembly
110
   file.  An assembly mpn_sqr_basecase that does not define it should allow
111
   any size.  */
112
#define SQR_BASECASE_LIM  SQR_TOOM2_THRESHOLD
113
#endif
114
#endif
115
116
#ifdef WANT_FAT_BINARY
117
/* For fat builds, we use SQR_TOOM2_THRESHOLD which will expand to a read from
118
   __gmpn_cpuvec.  Perhaps any possible sqr_basecase.asm allow any size, and we
119
   limit the use unnecessarily.  We cannot tell, so play it safe.  FIXME.  */
120
#define SQR_BASECASE_LIM  SQR_TOOM2_THRESHOLD
121
#endif
122
123
#ifndef SQR_BASECASE_LIM
124
/* If SQR_BASECASE_LIM is now not defined, use mpn_sqr_basecase for any operand
125
   size.  */
126
#define SQR_BASECASE_LIM  MP_SIZE_T_MAX
127
#endif
128
129
#define mpn_local_sqr(rp,up,n)            \
130
39.6M
  do {                 \
131
39.6M
    if (ABOVE_THRESHOLD (n, SQR_BASECASE_THRESHOLD)      \
132
39.6M
  && BELOW_THRESHOLD (n, SQR_BASECASE_LIM))     \
133
39.6M
      mpn_sqr_basecase (rp, up, n);         \
134
39.6M
    else                \
135
39.6M
      mpn_mul_basecase(rp, up, n, up, n);       \
136
39.6M
  } while (0)
137
138
#define getbit(p,bi) \
139
  ((p[(bi - 1) / GMP_NUMB_BITS] >> (bi - 1) % GMP_NUMB_BITS) & 1)
140
141
/* FIXME: Maybe some things would get simpler if all callers ensure
142
   that bi >= nbits. As far as I understand, with the current code bi
143
   < nbits can happen only for the final iteration. */
144
static inline mp_limb_t
145
getbits (const mp_limb_t *p, mp_bitcnt_t bi, int nbits)
146
10.0M
{
147
10.0M
  int nbits_in_r;
148
10.0M
  mp_limb_t r;
149
10.0M
  mp_size_t i;
150
151
10.0M
  if (bi < nbits)
152
27.1k
    {
153
27.1k
      return p[0] & (((mp_limb_t) 1 << bi) - 1);
154
27.1k
    }
155
9.99M
  else
156
9.99M
    {
157
9.99M
      bi -= nbits;      /* bit index of low bit to extract */
158
9.99M
      i = bi / GMP_NUMB_BITS;   /* word index of low bit to extract */
159
9.99M
      bi %= GMP_NUMB_BITS;   /* bit index in low word */
160
9.99M
      r = p[i] >> bi;     /* extract (low) bits */
161
9.99M
      nbits_in_r = GMP_NUMB_BITS - bi;  /* number of bits now in r */
162
9.99M
      if (nbits_in_r < nbits)    /* did we get enough bits? */
163
0
  r += p[i + 1] << nbits_in_r; /* prepend bits from higher word */
164
9.99M
      return r & (((mp_limb_t ) 1 << nbits) - 1);
165
9.99M
    }
166
10.0M
}
167
168
#ifndef POWM_SEC_TABLE
169
#if GMP_NUMB_BITS < 50
170
#define POWM_SEC_TABLE  2,33,96,780,2741
171
#else
172
135k
#define POWM_SEC_TABLE  2,130,524,2578
173
#endif
174
#endif
175
176
#if TUNE_PROGRAM_BUILD
177
extern int win_size (mp_bitcnt_t);
178
#else
179
static inline int
180
win_size (mp_bitcnt_t enb)
181
135k
{
182
135k
  int k;
183
  /* Find k, such that x[k-1] < enb <= x[k].
184
185
     We require that x[k] >= k, then it follows that enb > x[k-1] >=
186
     k-1, which implies k <= enb.
187
  */
188
135k
  static const mp_bitcnt_t x[] = {POWM_SEC_TABLE,~(mp_bitcnt_t)0};
189
434k
  for (k = 0; enb > x[k++]; )
190
298k
    ;
191
135k
  ASSERT (k <= enb);
192
135k
  return k;
193
135k
}
194
#endif
195
196
/* Convert U to REDC form, U_r = B^n * U mod M.
197
   Uses scratch space at tp of size 2un + n + 1.  */
198
static void
199
redcify (mp_ptr rp, mp_srcptr up, mp_size_t un, mp_srcptr mp, mp_size_t n, mp_ptr tp)
200
108k
{
201
108k
  MPN_ZERO (tp, n);
202
108k
  MPN_COPY (tp + n, up, un);
203
204
108k
  mpn_sec_div_r (tp, un + n, mp, n, tp + un + n);
205
108k
  MPN_COPY (rp, tp, n);
206
108k
}
207
208
static mp_limb_t
209
sec_binvert_limb (mp_limb_t n)
210
54.3k
{
211
54.3k
  mp_limb_t inv, t;
212
54.3k
  ASSERT ((n & 1) == 1);
213
  /* 3 + 2 -> 5 */
214
54.3k
  inv = n + (((n + 1) << 1) & 0x18);
215
216
54.3k
  t = n * inv;
217
#if GMP_NUMB_BITS <= 10
218
  /* 5 x 2 -> 10 */
219
  inv = 2 * inv - inv * t;
220
#else /* GMP_NUMB_BITS > 10 */
221
  /* 5 x 2 + 2 -> 12 */
222
54.3k
  inv = 2 * inv - inv * t + ((inv<<10)&-(t&(1<<5)));
223
54.3k
#endif /* GMP_NUMB_BITS <= 10 */
224
225
54.3k
  if (GMP_NUMB_BITS > 12)
226
54.3k
    {
227
54.3k
      t = n * inv - 1;
228
54.3k
      if (GMP_NUMB_BITS <= 36)
229
0
  {
230
    /* 12 x 3 -> 36 */
231
0
    inv += inv * t * (t - 1);
232
0
  }
233
54.3k
      else /* GMP_NUMB_BITS > 36 */
234
54.3k
  {
235
54.3k
    mp_limb_t t2 = t * t;
236
#if GMP_NUMB_BITS <= 60
237
    /* 12 x 5 -> 60 */
238
    inv += inv * (t2 + 1) * (t2 - t);
239
#else /* GMP_NUMB_BITS > 60 */
240
    /* 12 x 5 + 4 -> 64 */
241
54.3k
    inv *= (t2 + 1) * (t2 - t) + 1 - ((t<<48)&-(t&(1<<12)));
242
243
    /* 64 -> 128 -> 256 -> ... */
244
54.3k
    for (int todo = (GMP_NUMB_BITS - 1) >> 6; todo != 0; todo >>= 1)
245
0
      inv = 2 * inv - inv * inv * n;
246
54.3k
#endif /* GMP_NUMB_BITS <= 60 */
247
54.3k
  }
248
54.3k
    }
249
250
54.3k
  ASSERT ((inv * n & GMP_NUMB_MASK) == 1);
251
54.3k
  return inv & GMP_NUMB_MASK;
252
54.3k
}
253
254
/* {rp, n} <-- {bp, bn} ^ {ep, en} mod {mp, n},
255
   where en = ceil (enb / GMP_NUMB_BITS)
256
   Requires that {mp, n} is odd (and hence also mp[0] odd).
257
   Uses scratch space at tp as defined by mpn_sec_powm_itch.  */
258
void
259
mpn_sec_powm (mp_ptr rp, mp_srcptr bp, mp_size_t bn,
260
        mp_srcptr ep, mp_bitcnt_t enb,
261
        mp_srcptr mp, mp_size_t n, mp_ptr tp)
262
54.3k
{
263
54.3k
  mp_limb_t ip[2], *mip;
264
54.3k
  int windowsize, this_windowsize;
265
54.3k
  mp_limb_t expbits;
266
54.3k
  mp_ptr pp, this_pp, ps;
267
54.3k
  long i;
268
54.3k
  int cnd;
269
270
54.3k
  ASSERT (enb > 0);
271
54.3k
  ASSERT (n > 0);
272
  /* The code works for bn = 0, but the defined scratch space is 2 limbs
273
     greater than we supply, when converting 1 to redc form .  */
274
54.3k
  ASSERT (bn > 0);
275
54.3k
  ASSERT ((mp[0] & 1) != 0);
276
277
54.3k
  windowsize = win_size (enb);
278
279
54.3k
  mip = ip;
280
54.3k
  mip[0] = sec_binvert_limb (mp[0]);
281
54.3k
  if (ABOVE_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
282
0
    {
283
0
      mp_limb_t t, dummy, mip0 = mip[0];
284
285
0
      umul_ppmm (t, dummy, mip0, mp[0]);
286
0
      ASSERT (dummy == 1);
287
0
      t += mip0 * mp[1]; /* t = (mp * mip0)[1] */
288
289
0
      mip[1] = t * mip0 - 1; /* ~( - t * mip0) */
290
0
    }
291
54.3k
  mip[0] = -mip[0];
292
293
54.3k
  pp = tp;
294
54.3k
  tp += (n << windowsize);  /* put tp after power table */
295
296
  /* Compute pp[0] table entry */
297
  /* scratch: |   n   | 1 |   n+2    |  */
298
  /*          | pp[0] | 1 | redcify  |  */
299
54.3k
  this_pp = pp;
300
54.3k
  this_pp[n] = 1;
301
54.3k
  redcify (this_pp, this_pp + n, 1, mp, n, this_pp + n + 1);
302
54.3k
  this_pp += n;
303
304
  /* Compute pp[1] table entry.  To avoid excessive scratch usage in the
305
     degenerate situation where B >> M, we let redcify use scratch space which
306
     will later be used by the pp table (element 2 and up).  */
307
  /* scratch: |   n   |   n   |  bn + n + 1  |  */
308
  /*          | pp[0] | pp[1] |   redcify    |  */
309
54.3k
  redcify (this_pp, bp, bn, mp, n, this_pp + n);
310
311
  /* Precompute powers of b and put them in the temporary area at pp.  */
312
  /* scratch: |   n   |   n   | ...  |                    |   2n      |  */
313
  /*          | pp[0] | pp[1] | ...  | pp[2^windowsize-1] |  product  |  */
314
54.3k
  ps = pp + n;    /* initially B^1 */
315
54.3k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
316
54.3k
    {
317
271k
      for (i = (1 << windowsize) - 2; i > 0; i -= 2)
318
217k
  {
319
217k
    mpn_local_sqr (tp, ps, n);
320
217k
    ps += n;
321
217k
    this_pp += n;
322
217k
    MPN_REDC_1_SEC (this_pp, tp, mp, n, mip[0]);
323
324
217k
    mpn_mul_basecase (tp, this_pp, n, pp + n, n);
325
217k
    this_pp += n;
326
217k
    MPN_REDC_1_SEC (this_pp, tp, mp, n, mip[0]);
327
217k
  }
328
54.3k
    }
329
0
  else
330
0
    {
331
0
      for (i = (1 << windowsize) - 2; i > 0; i -= 2)
332
0
  {
333
0
    mpn_local_sqr (tp, ps, n);
334
0
    ps += n;
335
0
    this_pp += n;
336
0
    MPN_REDC_2_SEC (this_pp, tp, mp, n, mip);
337
338
0
    mpn_mul_basecase (tp, this_pp, n, pp + n, n);
339
0
    this_pp += n;
340
0
    MPN_REDC_2_SEC (this_pp, tp, mp, n, mip);
341
0
  }
342
0
    }
343
344
54.3k
  expbits = getbits (ep, enb, windowsize);
345
54.3k
  ASSERT_ALWAYS (enb >= windowsize);
346
54.3k
  enb -= windowsize;
347
348
54.3k
  mpn_sec_tabselect (rp, pp, n, 1 << windowsize, expbits);
349
350
  /* Main exponentiation loop.  */
351
  /* scratch: |   n   |   n   | ...  |                    |     3n-4n     |  */
352
  /*          | pp[0] | pp[1] | ...  | pp[2^windowsize-1] |  loop scratch |  */
353
354
54.3k
#define INNERLOOP             \
355
10.0M
  while (enb != 0)             \
356
9.97M
    {                 \
357
9.97M
      expbits = getbits (ep, enb, windowsize);        \
358
9.97M
      this_windowsize = windowsize;         \
359
9.97M
      if (enb < windowsize)           \
360
9.97M
  {               \
361
27.1k
    this_windowsize -= windowsize - enb;        \
362
27.1k
    enb = 0;              \
363
27.1k
  }                \
364
9.97M
      else                \
365
9.97M
  enb -= windowsize;           \
366
9.97M
                  \
367
9.97M
      do                \
368
39.4M
  {               \
369
39.4M
    mpn_local_sqr (tp, rp, n);         \
370
39.4M
    MPN_REDUCE (rp, tp, mp, n, mip);        \
371
39.4M
    this_windowsize--;            \
372
39.4M
  }                \
373
39.4M
      while (this_windowsize != 0);          \
374
9.97M
                  \
375
9.97M
      mpn_sec_tabselect (tp + 2*n, pp, n, 1 << windowsize, expbits); \
376
9.97M
      mpn_mul_basecase (tp, rp, n, tp + 2*n, n);      \
377
9.97M
                  \
378
9.97M
      MPN_REDUCE (rp, tp, mp, n, mip);          \
379
9.97M
    }
380
381
54.3k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
382
54.3k
    {
383
54.3k
#undef MPN_REDUCE
384
49.3M
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_1_SEC (rp, tp, mp, n, mip[0])
385
54.3k
      INNERLOOP;
386
54.3k
    }
387
0
  else
388
0
    {
389
0
#undef MPN_REDUCE
390
0
#define MPN_REDUCE(rp,tp,mp,n,mip)  MPN_REDC_2_SEC (rp, tp, mp, n, mip)
391
0
      INNERLOOP;
392
0
    }
393
394
54.3k
  MPN_COPY (tp, rp, n);
395
54.3k
  MPN_ZERO (tp + n, n);
396
397
54.3k
  if (BELOW_THRESHOLD (n, REDC_1_TO_REDC_2_THRESHOLD))
398
54.3k
    MPN_REDC_1_SEC (rp, tp, mp, n, mip[0]);
399
0
  else
400
0
    MPN_REDC_2_SEC (rp, tp, mp, n, mip);
401
402
54.3k
  cnd = mpn_sub_n (tp, rp, mp, n); /* we need just retval */
403
54.3k
  mpn_cnd_sub_n (!cnd, rp, rp, mp, n);
404
54.3k
}
405
406
mp_size_t
407
mpn_sec_powm_itch (mp_size_t bn, mp_bitcnt_t enb, mp_size_t n)
408
81.5k
{
409
81.5k
  int windowsize;
410
81.5k
  mp_size_t redcify_itch, itch;
411
412
  /* FIXME: no more _local/_basecase difference. */
413
  /* The top scratch usage will either be when reducing B in the 2nd redcify
414
     call, or more typically n*2^windowsize + 3n or 4n, in the main loop.  (It
415
     is 3n or 4n depending on if we use mpn_local_sqr or a native
416
     mpn_sqr_basecase.  We assume 4n always for now.) */
417
418
81.5k
  windowsize = win_size (enb);
419
420
  /* The 2n term is due to pp[0] and pp[1] at the time of the 2nd redcify call,
421
     the (bn + n) term is due to redcify's own usage, and the rest is due to
422
     mpn_sec_div_r's usage when called from redcify.  */
423
81.5k
  redcify_itch = (2 * n) + (bn + n) + ((bn + n) + 2 * n + 2);
424
425
  /* The n * 2^windowsize term is due to the power table, the 4n term is due to
426
     scratch needs of squaring/multiplication in the exponentiation loop.  */
427
81.5k
  itch = (n << windowsize) + (4 * n);
428
429
81.5k
  return MAX (itch, redcify_itch);
430
81.5k
}