Coverage Report

Created: 2026-07-10 06:40

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/yara/libyara/modules/math/math.c
Line
Count
Source
1
/*
2
Copyright (c) 2014-2021. The YARA Authors. All Rights Reserved.
3
4
Redistribution and use in source and binary forms, with or without modification,
5
are permitted provided that the following conditions are met:
6
7
1. Redistributions of source code must retain the above copyright notice, this
8
list of conditions and the following disclaimer.
9
10
2. Redistributions in binary form must reproduce the above copyright notice,
11
this list of conditions and the following disclaimer in the documentation and/or
12
other materials provided with the distribution.
13
14
3. Neither the name of the copyright holder nor the names of its contributors
15
may be used to endorse or promote products derived from this software without
16
specific prior written permission.
17
18
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
19
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
20
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
21
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR
22
ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
23
(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
24
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
25
ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
26
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
27
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28
*/
29
30
#include <math.h>
31
#include <stdlib.h>
32
#include <yara/mem.h>
33
#include <yara/modules.h>
34
#include <yara/strutils.h>
35
#include <yara/utils.h>
36
37
#define MODULE_NAME math
38
39
#define PI 3.141592653589793
40
// This is more than enough space to hold the maximum signed 64bit integer as a
41
// string in decimal, hex or octal, including the sign and NULL terminator.
42
0
#define INT64_MAX_STRING 30
43
44
// log2 is not defined by math.h in VC++
45
46
#if defined(_MSC_VER) && _MSC_VER < 1800
47
static double log2(double n)
48
{
49
  return log(n) / log(2.0);
50
}
51
#endif
52
53
uint32_t* get_distribution(
54
    int64_t offset,
55
    int64_t length,
56
    YR_SCAN_CONTEXT* context)
57
8.37k
{
58
8.37k
  bool past_first_block = false;
59
60
8.37k
  size_t i;
61
62
8.37k
  uint32_t* data = (uint32_t*) yr_calloc(256, sizeof(uint32_t));
63
64
8.37k
  if (data == NULL)
65
0
    return NULL;
66
67
8.37k
  YR_MEMORY_BLOCK* block = first_memory_block(context);
68
8.37k
  YR_MEMORY_BLOCK_ITERATOR* iterator = context->iterator;
69
70
8.37k
  if (block == NULL || offset < 0 || length < 0 || offset < block->base)
71
0
  {
72
0
    yr_free(data);
73
0
    return NULL;
74
0
  }
75
76
8.37k
  foreach_memory_block(iterator, block)
77
8.37k
  {
78
8.37k
    if (offset >= block->base && offset < block->base + block->size)
79
8.37k
    {
80
8.37k
      size_t data_offset = (size_t) (offset - block->base);
81
8.37k
      size_t data_len = (size_t) yr_min(
82
8.37k
          length, (size_t) (block->size - data_offset));
83
84
8.37k
      const uint8_t* block_data = yr_fetch_block_data(block);
85
86
8.37k
      if (block_data == NULL)
87
0
      {
88
0
        yr_free(data);
89
0
        return NULL;
90
0
      }
91
92
8.37k
      offset += data_len;
93
8.37k
      length -= data_len;
94
95
12.0M
      for (i = 0; i < data_len; i++)
96
12.0M
      {
97
12.0M
        uint8_t c = *(block_data + data_offset + i);
98
12.0M
        data[c]++;
99
12.0M
      }
100
101
8.37k
      past_first_block = true;
102
8.37k
    }
103
0
    else if (past_first_block)
104
0
    {
105
      // If offset is not within current block and we already
106
      // past the first block then the we are trying to compute
107
      // the distribution over a range of non contiguous blocks. As
108
      // range contains gaps of undefined data the distribution is
109
      // undefined.
110
111
0
      yr_free(data);
112
0
      return NULL;
113
0
    }
114
115
8.37k
    if (block->base + block->size >= offset + length)
116
8.37k
      break;
117
8.37k
  }
118
119
8.37k
  if (!past_first_block)
120
0
  {
121
0
    yr_free(data);
122
0
    return NULL;
123
0
  }
124
8.37k
  return data;
125
8.37k
}
126
127
uint32_t* get_distribution_global(YR_SCAN_CONTEXT* context)
128
0
{
129
0
  size_t i;
130
131
0
  int64_t expected_next_offset = 0;
132
133
0
  uint32_t* data = (uint32_t*) yr_calloc(256, sizeof(uint32_t));
134
135
0
  if (data == NULL)
136
0
    return NULL;
137
138
0
  YR_MEMORY_BLOCK* block;
139
0
  YR_MEMORY_BLOCK_ITERATOR* iterator = context->iterator;
140
0
  foreach_memory_block(iterator, block)
141
0
  {
142
0
    if (expected_next_offset != block->base)
143
0
    {
144
      // If offset is not directly after the current block then
145
      // we are trying to compute the distribution over a range of non
146
      // contiguous blocks. As the range contains gaps of
147
      // undefined data the distribution is undefined.
148
0
      yr_free(data);
149
0
      return NULL;
150
0
    }
151
0
    const uint8_t* block_data = yr_fetch_block_data(block);
152
153
0
    if (block_data == NULL)
154
0
    {
155
0
      yr_free(data);
156
0
      return NULL;
157
0
    }
158
159
0
    for (i = 0; i < block->size; i++)
160
0
    {
161
0
      uint8_t c = *(block_data + i);
162
0
      data[c] += 1;
163
0
    }
164
0
    expected_next_offset = block->base + block->size;
165
0
  }
166
0
  return data;
167
0
}
168
169
define_function(string_entropy)
170
0
{
171
0
  size_t i;
172
0
  double entropy = 0.0;
173
174
0
  SIZED_STRING* s = sized_string_argument(1);
175
176
0
  uint32_t* data = (uint32_t*) yr_calloc(256, sizeof(uint32_t));
177
178
0
  if (data == NULL)
179
0
    return_float(YR_UNDEFINED);
180
181
0
  for (i = 0; i < s->length; i++)
182
0
  {
183
0
    uint8_t c = s->c_string[i];
184
0
    data[c] += 1;
185
0
  }
186
187
0
  for (i = 0; i < 256; i++)
188
0
  {
189
0
    if (data[i] != 0)
190
0
    {
191
0
      double x = (double) (data[i]) / s->length;
192
0
      entropy -= x * log2(x);
193
0
    }
194
0
  }
195
196
0
  yr_free(data);
197
0
  return_float(entropy);
198
0
}
199
200
define_function(data_entropy)
201
1.71k
{
202
1.71k
  double entropy = 0.0;
203
204
1.71k
  int64_t offset = integer_argument(1);  // offset where to start
205
1.71k
  int64_t length = integer_argument(2);  // length of bytes we want entropy on
206
207
1.71k
  YR_SCAN_CONTEXT* context = yr_scan_context();
208
209
1.71k
  size_t i;
210
211
1.71k
  size_t total_len = 0;
212
213
1.71k
  uint32_t* data = get_distribution(offset, length, context);
214
215
1.71k
  if (data == NULL)
216
1.71k
    return_float(YR_UNDEFINED);
217
218
440k
  for (i = 0; i < 256; i++)
219
438k
  {
220
438k
    total_len += data[i];
221
438k
  }
222
223
440k
  for (i = 0; i < 256; i++)
224
438k
  {
225
438k
    if (data[i] != 0)
226
47.3k
    {
227
47.3k
      double x = (double) (data[i]) / total_len;
228
47.3k
      entropy -= x * log2(x);
229
47.3k
    }
230
438k
  }
231
232
1.71k
  yr_free(data);
233
1.71k
  return_float(entropy);
234
0
}
235
236
define_function(string_deviation)
237
0
{
238
0
  SIZED_STRING* s = sized_string_argument(1);
239
240
0
  double mean = float_argument(2);
241
0
  double sum = 0.0;
242
243
0
  size_t i;
244
245
0
  for (i = 0; i < s->length; i++) sum += fabs(((double) s->c_string[i]) - mean);
246
247
0
  return_float(sum / s->length);
248
0
}
249
250
define_function(data_deviation)
251
1.71k
{
252
1.71k
  int64_t offset = integer_argument(1);
253
1.71k
  int64_t length = integer_argument(2);
254
255
1.71k
  double mean = float_argument(3);
256
1.71k
  double sum = 0.0;
257
258
1.71k
  size_t total_len = 0;
259
1.71k
  size_t i;
260
261
1.71k
  YR_SCAN_CONTEXT* context = yr_scan_context();
262
263
1.71k
  uint32_t* data = get_distribution(offset, length, context);
264
265
1.71k
  if (data == NULL)
266
1.71k
    return_float(YR_UNDEFINED);
267
268
440k
  for (i = 0; i < 256; i++)
269
438k
  {
270
438k
    total_len += data[i];
271
438k
    sum += fabs(((double) i) - mean) * data[i];
272
438k
  }
273
274
1.71k
  yr_free(data);
275
1.71k
  return_float(sum / total_len);
276
0
}
277
278
define_function(string_mean)
279
0
{
280
0
  size_t i;
281
0
  double sum = 0.0;
282
283
0
  SIZED_STRING* s = sized_string_argument(1);
284
285
0
  for (i = 0; i < s->length; i++) sum += (double) s->c_string[i];
286
287
0
  return_float(sum / s->length);
288
0
}
289
290
define_function(data_mean)
291
1.71k
{
292
1.71k
  double sum = 0.0;
293
294
1.71k
  int64_t offset = integer_argument(1);
295
1.71k
  int64_t length = integer_argument(2);
296
297
1.71k
  YR_SCAN_CONTEXT* context = yr_scan_context();
298
299
1.71k
  size_t total_len = 0;
300
1.71k
  size_t i;
301
302
1.71k
  uint32_t* data = get_distribution(offset, length, context);
303
304
1.71k
  if (data == NULL)
305
1.71k
    return_float(YR_UNDEFINED);
306
307
440k
  for (i = 0; i < 256; i++)
308
438k
  {
309
438k
    total_len += data[i];
310
438k
    sum += ((double) i) * data[i];
311
438k
  }
312
313
1.71k
  yr_free(data);
314
1.71k
  return_float(sum / total_len);
315
0
}
316
317
define_function(data_serial_correlation)
318
1.71k
{
319
1.71k
  int past_first_block = false;
320
321
1.71k
  size_t total_len = 0;
322
1.71k
  size_t i;
323
324
1.71k
  int64_t offset = integer_argument(1);
325
1.71k
  int64_t length = integer_argument(2);
326
327
1.71k
  YR_SCAN_CONTEXT* context = yr_scan_context();
328
1.71k
  YR_MEMORY_BLOCK* block = first_memory_block(context);
329
1.71k
  YR_MEMORY_BLOCK_ITERATOR* iterator = context->iterator;
330
331
1.71k
  if (block == NULL)
332
1.71k
    return_float(YR_UNDEFINED);
333
334
1.71k
  double sccun = 0;
335
1.71k
  double sccfirst = 0;
336
1.71k
  double scclast = 0;
337
1.71k
  double scct1 = 0;
338
1.71k
  double scct2 = 0;
339
1.71k
  double scct3 = 0;
340
1.71k
  double scc = 0;
341
342
1.71k
  if (offset < 0 || length < 0 || offset < block->base)
343
1.71k
    return_float(YR_UNDEFINED);
344
345
1.71k
  foreach_memory_block(iterator, block)
346
1.71k
  {
347
1.71k
    if (offset >= block->base && offset < block->base + block->size)
348
1.71k
    {
349
1.71k
      size_t data_offset = (size_t) (offset - block->base);
350
1.71k
      size_t data_len = (size_t) yr_min(
351
1.71k
          length, (size_t) (block->size - data_offset));
352
353
1.71k
      const uint8_t* block_data = yr_fetch_block_data(block);
354
355
1.71k
      if (block_data == NULL)
356
1.71k
        return_float(YR_UNDEFINED);
357
358
1.71k
      total_len += data_len;
359
1.71k
      offset += data_len;
360
1.71k
      length -= data_len;
361
362
2.40M
      for (i = 0; i < data_len; i++)
363
2.40M
      {
364
2.40M
        sccun = (double) *(block_data + data_offset + i);
365
2.40M
        if (i == 0)
366
1.71k
        {
367
1.71k
          sccfirst = sccun;
368
1.71k
        }
369
2.40M
        scct1 += scclast * sccun;
370
2.40M
        scct2 += sccun;
371
2.40M
        scct3 += sccun * sccun;
372
2.40M
        scclast = sccun;
373
2.40M
      }
374
375
1.71k
      past_first_block = true;
376
1.71k
    }
377
0
    else if (past_first_block)
378
0
    {
379
      // If offset is not within current block and we already
380
      // past the first block then the we are trying to compute
381
      // the checksum over a range of non contiguous blocks. As
382
      // range contains gaps of undefined data the checksum is
383
      // undefined.
384
0
      return_float(YR_UNDEFINED);
385
0
    }
386
387
1.71k
    if (block->base + block->size >= offset + length)
388
1.71k
      break;
389
1.71k
  }
390
391
1.71k
  if (!past_first_block)
392
1.71k
    return_float(YR_UNDEFINED);
393
394
1.71k
  scct1 += scclast * sccfirst;
395
1.71k
  scct2 *= scct2;
396
397
1.71k
  scc = total_len * scct3 - scct2;
398
399
1.71k
  if (scc == 0)
400
18
    scc = -100000;
401
1.69k
  else
402
1.69k
    scc = (total_len * scct1 - scct2) / scc;
403
404
1.71k
  return_float(scc);
405
0
}
406
407
define_function(string_serial_correlation)
408
0
{
409
0
  SIZED_STRING* s = sized_string_argument(1);
410
411
0
  double sccun = 0;
412
0
  double scclast = 0;
413
0
  double scct1 = 0;
414
0
  double scct2 = 0;
415
0
  double scct3 = 0;
416
0
  double scc = 0;
417
418
0
  size_t i;
419
420
0
  for (i = 0; i < s->length; i++)
421
0
  {
422
0
    sccun = (double) s->c_string[i];
423
0
    scct1 += scclast * sccun;
424
0
    scct2 += sccun;
425
0
    scct3 += sccun * sccun;
426
0
    scclast = sccun;
427
0
  }
428
429
0
  if (s->length > 0)
430
0
  {
431
0
    scct1 += scclast * (double) s->c_string[0];
432
0
  }
433
0
  scct2 *= scct2;
434
435
0
  scc = s->length * scct3 - scct2;
436
437
0
  if (scc == 0)
438
0
    scc = -100000;
439
0
  else
440
0
    scc = (s->length * scct1 - scct2) / scc;
441
442
0
  return_float(scc);
443
0
}
444
445
define_function(data_monte_carlo_pi)
446
1.62k
{
447
1.62k
  int past_first_block = false;
448
1.62k
  int mcount = 0;
449
1.62k
  int inmont = 0;
450
451
1.62k
  double INCIRC = pow(pow(256.0, 3.0) - 1, 2.0);
452
1.62k
  double mpi = 0;
453
454
1.62k
  size_t i;
455
456
1.62k
  int64_t offset = integer_argument(1);
457
1.62k
  int64_t length = integer_argument(2);
458
459
1.62k
  YR_SCAN_CONTEXT* context = yr_scan_context();
460
1.62k
  YR_MEMORY_BLOCK* block = first_memory_block(context);
461
1.62k
  YR_MEMORY_BLOCK_ITERATOR* iterator = context->iterator;
462
463
1.62k
  if (block == NULL)
464
1.62k
    return_float(YR_UNDEFINED);
465
466
1.62k
  if (offset < 0 || length < 0 || offset < block->base)
467
1.62k
    return_float(YR_UNDEFINED);
468
469
1.62k
  foreach_memory_block(iterator, block)
470
1.62k
  {
471
1.62k
    if (offset >= block->base && offset < block->base + block->size)
472
1.62k
    {
473
1.62k
      unsigned int monte[6];
474
475
1.62k
      size_t data_offset = (size_t) (offset - block->base);
476
1.62k
      size_t data_len = (size_t) yr_min(
477
1.62k
          length, (size_t) (block->size - data_offset));
478
479
1.62k
      const uint8_t* block_data = yr_fetch_block_data(block);
480
481
1.62k
      if (block_data == NULL)
482
1.62k
        return_float(YR_UNDEFINED);
483
484
1.62k
      offset += data_len;
485
1.62k
      length -= data_len;
486
487
2.40M
      for (i = 0; i < data_len; i++)
488
2.40M
      {
489
2.40M
        monte[i % 6] = (unsigned int) *(block_data + data_offset + i);
490
491
2.40M
        if (i % 6 == 5)
492
399k
        {
493
399k
          double mx = 0;
494
399k
          double my = 0;
495
399k
          int j;
496
497
399k
          mcount++;
498
499
1.59M
          for (j = 0; j < 3; j++)
500
1.19M
          {
501
1.19M
            mx = (mx * 256.0) + monte[j];
502
1.19M
            my = (my * 256.0) + monte[j + 3];
503
1.19M
          }
504
505
399k
          if ((mx * mx + my * my) <= INCIRC)
506
304k
            inmont++;
507
399k
        }
508
2.40M
      }
509
510
1.62k
      past_first_block = true;
511
1.62k
    }
512
0
    else if (past_first_block)
513
0
    {
514
      // If offset is not within current block and we already
515
      // past the first block then the we are trying to compute
516
      // the checksum over a range of non contiguous blocks. As
517
      // range contains gaps of undefined data the checksum is
518
      // undefined.
519
0
      return_float(YR_UNDEFINED);
520
0
    }
521
522
1.62k
    if (block->base + block->size >= offset + length)
523
1.62k
      break;
524
1.62k
  }
525
526
1.62k
  if (!past_first_block || mcount == 0)
527
1.61k
    return_float(YR_UNDEFINED);
528
529
1.61k
  mpi = 4.0 * ((double) inmont / mcount);
530
531
1.61k
  return_float(fabs((mpi - PI) / PI));
532
0
}
533
534
define_function(string_monte_carlo_pi)
535
0
{
536
0
  SIZED_STRING* s = sized_string_argument(1);
537
538
0
  double INCIRC = pow(pow(256.0, 3.0) - 1, 2.0);
539
0
  double mpi = 0;
540
541
0
  unsigned int monte[6];
542
543
0
  int mcount = 0;
544
0
  int inmont = 0;
545
546
0
  size_t i;
547
548
0
  for (i = 0; i < s->length; i++)
549
0
  {
550
0
    monte[i % 6] = (unsigned int) s->c_string[i];
551
552
0
    if (i % 6 == 5)
553
0
    {
554
0
      double mx = 0;
555
0
      double my = 0;
556
557
0
      int j;
558
559
0
      mcount++;
560
561
0
      for (j = 0; j < 3; j++)
562
0
      {
563
0
        mx = (mx * 256.0) + monte[j];
564
0
        my = (my * 256.0) + monte[j + 3];
565
0
      }
566
567
0
      if ((mx * mx + my * my) <= INCIRC)
568
0
        inmont++;
569
0
    }
570
0
  }
571
572
0
  if (mcount == 0)
573
0
    return_float(YR_UNDEFINED);
574
575
0
  mpi = 4.0 * ((double) inmont / mcount);
576
0
  return_float(fabs((mpi - PI) / PI));
577
0
}
578
579
define_function(in_range)
580
0
{
581
0
  double test = float_argument(1);
582
0
  double lower = float_argument(2);
583
0
  double upper = float_argument(3);
584
585
0
  return_integer((lower <= test && test <= upper) ? 1 : 0);
586
0
}
587
588
// Undefine existing "min" and "max" macros in order to avoid conflicts with
589
// function names.
590
#undef min
591
#undef max
592
593
define_function(min)
594
1.61k
{
595
1.61k
  uint64_t i = integer_argument(1);
596
1.61k
  uint64_t j = integer_argument(2);
597
598
1.61k
  return_integer(i < j ? i : j);
599
0
}
600
601
define_function(max)
602
1.61k
{
603
1.61k
  uint64_t i = integer_argument(1);
604
1.61k
  uint64_t j = integer_argument(2);
605
606
1.61k
  return_integer(i > j ? i : j);
607
0
}
608
609
define_function(to_number)
610
0
{
611
0
  return_integer(integer_argument(1) ? 1 : 0);
612
0
}
613
614
define_function(yr_math_abs)
615
0
{
616
0
  return_integer(llabs(integer_argument(1)));
617
0
}
618
619
define_function(count_range)
620
1.61k
{
621
1.61k
  int64_t byte = integer_argument(1);
622
1.61k
  int64_t offset = integer_argument(2);
623
1.61k
  int64_t length = integer_argument(3);
624
625
1.61k
  if (byte < 0 || byte > 255)
626
1.61k
    return_integer(YR_UNDEFINED);
627
628
1.61k
  YR_SCAN_CONTEXT* context = yr_scan_context();
629
630
1.61k
  uint32_t* distribution = get_distribution(offset, length, context);
631
632
1.61k
  if (distribution == NULL)
633
1.61k
    return_integer(YR_UNDEFINED);
634
635
1.61k
  int64_t count = (int64_t) distribution[byte];
636
1.61k
  yr_free(distribution);
637
1.61k
  return_integer(count);
638
0
}
639
640
define_function(count_global)
641
0
{
642
0
  int64_t byte = integer_argument(1);
643
644
0
  if (byte < 0 || byte > 255)
645
0
    return_integer(YR_UNDEFINED);
646
647
0
  YR_SCAN_CONTEXT* context = yr_scan_context();
648
649
0
  uint32_t* distribution = get_distribution_global(context);
650
651
0
  if (distribution == NULL)
652
0
    return_integer(YR_UNDEFINED);
653
654
0
  int64_t count = (int64_t) distribution[byte];
655
0
  yr_free(distribution);
656
0
  return_integer(count);
657
0
}
658
659
define_function(percentage_range)
660
1.61k
{
661
1.61k
  int64_t byte = integer_argument(1);
662
1.61k
  int64_t offset = integer_argument(2);
663
1.61k
  int64_t length = integer_argument(3);
664
665
1.61k
  if (byte < 0 || byte > 255)
666
1.61k
    return_float(YR_UNDEFINED);
667
668
1.61k
  YR_SCAN_CONTEXT* context = yr_scan_context();
669
670
1.61k
  uint32_t* distribution = get_distribution(offset, length, context);
671
672
1.61k
  if (distribution == NULL)
673
1.61k
    return_float(YR_UNDEFINED);
674
675
1.61k
  int64_t count = (int64_t) distribution[byte];
676
1.61k
  int64_t total_count = 0;
677
1.61k
  int64_t i;
678
679
415k
  for (i = 0; i < 256; i++) total_count += distribution[i];
680
681
1.61k
  yr_free(distribution);
682
1.61k
  return_float(((float) count) / ((float) total_count));
683
0
}
684
685
define_function(percentage_global)
686
0
{
687
0
  int64_t byte = integer_argument(1);
688
689
0
  if (byte < 0 || byte > 255)
690
0
    return_float(YR_UNDEFINED);
691
692
0
  YR_SCAN_CONTEXT* context = yr_scan_context();
693
694
0
  uint32_t* distribution = get_distribution_global(context);
695
696
0
  if (distribution == NULL)
697
0
    return_float(YR_UNDEFINED);
698
699
0
  int64_t count = (int64_t) distribution[byte];
700
0
  int64_t total_count = 0;
701
0
  int64_t i;
702
703
0
  for (i = 0; i < 256; i++) total_count += distribution[i];
704
705
0
  yr_free(distribution);
706
0
  return_float(((float) count) / ((float) total_count));
707
0
}
708
709
define_function(mode_range)
710
0
{
711
0
  int64_t offset = integer_argument(1);
712
0
  int64_t length = integer_argument(2);
713
714
0
  YR_SCAN_CONTEXT* context = yr_scan_context();
715
716
0
  uint32_t* distribution = get_distribution(offset, length, context);
717
718
0
  if (distribution == NULL)
719
0
    return_integer(YR_UNDEFINED);
720
721
0
  int64_t most_common = 0;
722
0
  size_t i;
723
724
0
  for (i = 0; i < 256; i++)
725
0
  {
726
0
    if (distribution[i] > distribution[most_common])
727
0
      most_common = (int64_t) i;
728
0
  }
729
730
0
  yr_free(distribution);
731
0
  return_integer(most_common);
732
0
}
733
734
define_function(mode_global)
735
0
{
736
0
  YR_SCAN_CONTEXT* context = yr_scan_context();
737
738
0
  uint32_t* distribution = get_distribution_global(context);
739
740
0
  if (distribution == NULL)
741
0
    return_integer(YR_UNDEFINED);
742
743
0
  int64_t most_common = 0;
744
0
  size_t i;
745
746
0
  for (i = 0; i < 256; i++)
747
0
  {
748
0
    if (distribution[i] > distribution[most_common])
749
0
      most_common = (int64_t) i;
750
0
  }
751
752
0
  yr_free(distribution);
753
0
  return_integer(most_common);
754
0
}
755
756
define_function(to_string)
757
0
{
758
0
  int64_t i = integer_argument(1);
759
0
  char str[INT64_MAX_STRING];
760
0
  snprintf(str, INT64_MAX_STRING, "%" PRId64, i);
761
0
  return_string(&str);
762
0
}
763
764
define_function(to_string_base)
765
0
{
766
0
  int64_t i = integer_argument(1);
767
0
  int64_t base = integer_argument(2);
768
0
  char str[INT64_MAX_STRING];
769
0
  char* fmt;
770
0
  switch (base)
771
0
  {
772
0
  case 10:
773
0
    fmt = "%" PRId64;
774
0
    break;
775
0
  case 8:
776
0
    fmt = "%" PRIo64;
777
0
    break;
778
0
  case 16:
779
0
    fmt = "%" PRIx64;
780
0
    break;
781
0
  default:
782
0
    return_string(YR_UNDEFINED);
783
0
  }
784
0
  snprintf(str, INT64_MAX_STRING, fmt, i);
785
0
  return_string(&str);
786
0
}
787
788
1.71k
begin_declarations
789
1.71k
  declare_float("MEAN_BYTES");
790
1.71k
  declare_function("in_range", "fff", "i", in_range);
791
1.71k
  declare_function("deviation", "iif", "f", data_deviation);
792
1.71k
  declare_function("deviation", "sf", "f", string_deviation);
793
1.71k
  declare_function("mean", "ii", "f", data_mean);
794
1.71k
  declare_function("mean", "s", "f", string_mean);
795
1.71k
  declare_function("serial_correlation", "ii", "f", data_serial_correlation);
796
1.71k
  declare_function("serial_correlation", "s", "f", string_serial_correlation);
797
1.71k
  declare_function("monte_carlo_pi", "ii", "f", data_monte_carlo_pi);
798
1.71k
  declare_function("monte_carlo_pi", "s", "f", string_monte_carlo_pi);
799
1.71k
  declare_function("entropy", "ii", "f", data_entropy);
800
1.71k
  declare_function("entropy", "s", "f", string_entropy);
801
1.71k
  declare_function("min", "ii", "i", min);
802
1.71k
  declare_function("max", "ii", "i", max);
803
1.71k
  declare_function("to_number", "b", "i", to_number);
804
1.71k
  declare_function("abs", "i", "i", yr_math_abs);
805
1.71k
  declare_function("count", "iii", "i", count_range);
806
1.71k
  declare_function("count", "i", "i", count_global);
807
1.71k
  declare_function("percentage", "iii", "f", percentage_range);
808
1.71k
  declare_function("percentage", "i", "f", percentage_global);
809
1.71k
  declare_function("mode", "ii", "i", mode_range);
810
1.71k
  declare_function("mode", "", "i", mode_global);
811
1.71k
  declare_function("to_string", "i", "s", to_string);
812
1.71k
  declare_function("to_string", "ii", "s", to_string_base);
813
1.71k
end_declarations
814
815
int module_initialize(YR_MODULE* module)
816
2
{
817
2
  return ERROR_SUCCESS;
818
2
}
819
820
int module_finalize(YR_MODULE* module)
821
0
{
822
0
  return ERROR_SUCCESS;
823
0
}
824
825
int module_load(
826
    YR_SCAN_CONTEXT* context,
827
    YR_OBJECT* module_object,
828
    void* module_data,
829
    size_t module_data_size)
830
1.71k
{
831
1.71k
  yr_set_float(127.5, module_object, "MEAN_BYTES");
832
1.71k
  return ERROR_SUCCESS;
833
1.71k
}
834
835
int module_unload(YR_OBJECT* module_object)
836
1.71k
{
837
1.71k
  return ERROR_SUCCESS;
838
1.71k
}