-
Notifications
You must be signed in to change notification settings - Fork 14
/
mpint.h
458 lines (422 loc) · 17.9 KB
/
mpint.h
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
#ifndef PUTTY_MPINT_H
#define PUTTY_MPINT_H
/*
* PuTTY's multiprecision integer library.
*
* This library is written with the aim of avoiding leaking the input
* numbers via timing and cache side channels. This means avoiding
* making any control flow change, or deciding the address of any
* memory access, based on the value of potentially secret input data.
*
* But in a library that has to handle numbers of arbitrary size, you
* can't avoid your control flow depending on the _size_ of the input!
* So the rule is that an mp_int has a nominal size that need not be
* its mathematical size: i.e. if you call (say) mp_from_bytes_be to
* turn an array of 256 bytes into an integer, and all but the last of
* those bytes is zero, then you get an mp_int which has space for 256
* bytes of data but just happens to store the value 1. So the
* _nominal_ sizes of input data - e.g. the size in bits of some
* public-key modulus - are not considered secret, and control flow is
* allowed to do what it likes based on those sizes. But the same
* function, called with the same _nominally sized_ arguments
* containing different values, should run in the same length of time.
*
* When a function returns an 'mp_int *', it is newly allocated to an
* appropriate nominal size (which, again, depends only on the nominal
* sizes of the inputs). Other functions have 'into' in their name,
* and they instead overwrite the contents of an existing mp_int.
*
* Functions in this API which return values that are logically
* boolean return them as 'unsigned' rather than the C99 bool type.
* That's because C99 bool does an implicit test for non-zero-ness
* when converting any other integer type to it, which compilers might
* well implement using data-dependent control flow.
*/
/*
* Create and destroy mp_ints. A newly created one is initialised to
* zero. mp_clear also resets an existing number to zero.
*/
mp_int *mp_new(size_t maxbits);
void mp_free(mp_int *);
void mp_clear(mp_int *x);
/*
* Resize the physical size of existing mp_int, e.g. so that you have
* room to transform it in place to a larger value. Destroys the old
* mp_int in the process.
*/
mp_int *mp_resize(mp_int *, size_t newmaxbits);
/*
* Create mp_ints from various sources: little- and big-endian binary
* data, an ordinary C unsigned integer type, a decimal or hex string
* (given either as a ptrlen or a C NUL-terminated string), and
* another mp_int.
*
* The decimal and hex conversion functions have running time
* dependent on the length of the input data, of course.
*/
mp_int *mp_from_bytes_le(ptrlen bytes);
mp_int *mp_from_bytes_be(ptrlen bytes);
mp_int *mp_from_integer(uintmax_t n);
mp_int *mp_from_decimal_pl(ptrlen decimal);
mp_int *mp_from_decimal(const char *decimal);
mp_int *mp_from_hex_pl(ptrlen hex);
mp_int *mp_from_hex(const char *hex);
mp_int *mp_copy(mp_int *x);
/*
* A macro for declaring large fixed numbers in source code (such as
* elliptic curve parameters, or standard Diffie-Hellman moduli). The
* idea is that you just write something like
*
* mp_int *value = MP_LITERAL(0x19284376283754638745693467245);
*
* and it newly allocates you an mp_int containing that number.
*
* Internally, the macro argument is stringified and passed to
* mp_from_hex. That's not as fast as it could be if I had instead set
* up some kind of mp_from_array_of_uint64_t() function, but I think
* this system is valuable for the fact that the literal integers
* appear in a very natural syntax that can be pasted directly out
* into, say, Python if you want to cross-check a calculation.
*/
static inline mp_int *mp__from_string_literal(const char *lit)
{
/* Don't call this directly; it's not equipped to deal with
* hostile data. Use only via the MP_LITERAL macro. */
if (lit[0] && (lit[1] == 'x' || lit[1] == 'X'))
return mp_from_hex(lit+2);
else
return mp_from_decimal(lit);
}
#define MP_LITERAL(number) mp__from_string_literal(#number)
/*
* Create an mp_int with the value 2^power.
*/
mp_int *mp_power_2(size_t power);
/*
* Retrieve the value of a particular bit or byte of an mp_int. The
* byte / bit index is not considered to be secret data. Out-of-range
* byte/bit indices are handled cleanly and return zero.
*/
uint8_t mp_get_byte(mp_int *x, size_t byte);
unsigned mp_get_bit(mp_int *x, size_t bit);
/*
* Retrieve the value of an mp_int as a uintmax_t, assuming it's small
* enough to fit.
*/
uintmax_t mp_get_integer(mp_int *x);
/*
* Set an mp_int bit. Again, the bit index is not considered secret.
* Do not pass an out-of-range index, on pain of assertion failure.
*/
void mp_set_bit(mp_int *x, size_t bit, unsigned val);
/*
* Return the nominal size of an mp_int, in terms of the maximum
* number of bytes or bits that can fit in it.
*/
size_t mp_max_bytes(mp_int *x);
size_t mp_max_bits(mp_int *x);
/*
* Return the _mathematical_ bit count of an mp_int (not its nominal
* size), i.e. a value n such that 2^{n-1} <= x < 2^n.
*
* This function is supposed to run in constant time for a given
* nominal input size. Of course it's likely that clients of this
* function will promptly need to use the result as the limit of some
* loop (e.g. marshalling an mp_int into an SSH packet, which doesn't
* permit extra prefix zero bytes). But that's up to the caller to
* decide the safety of.
*/
size_t mp_get_nbits(mp_int *x);
/*
* Return the value of an mp_int as a decimal or hex string. The
* result is dynamically allocated, and the caller is responsible for
* freeing it.
*
* These functions should run in constant time for a given nominal
* input size, even though the exact number of digits returned is
* variable. They always allocate enough space for the largest output
* that might be needed, but they don't always fill it.
*/
char *mp_get_decimal(mp_int *x);
char *mp_get_hex(mp_int *x);
char *mp_get_hex_uppercase(mp_int *x);
/*
* Compare two mp_ints, or compare one mp_int against a C integer. The
* 'eq' functions return 1 if the two inputs are equal, or 0
* otherwise; the 'hs' functions return 1 if the first input is >= the
* second, and 0 otherwise.
*/
unsigned mp_cmp_hs(mp_int *a, mp_int *b);
unsigned mp_cmp_eq(mp_int *a, mp_int *b);
unsigned mp_hs_integer(mp_int *x, uintmax_t n);
unsigned mp_eq_integer(mp_int *x, uintmax_t n);
/*
* Take the minimum or maximum of two mp_ints, without using a
* conditional branch.
*/
void mp_min_into(mp_int *r, mp_int *x, mp_int *y);
void mp_max_into(mp_int *r, mp_int *x, mp_int *y);
mp_int *mp_min(mp_int *x, mp_int *y);
mp_int *mp_max(mp_int *x, mp_int *y);
/*
* Diagnostic function. Writes out x in hex to the supplied stdio
* stream, preceded by the string 'prefix' and followed by 'suffix'.
*
* This is useful to put temporarily into code, but it's also
* potentially useful to call from a debugger.
*/
void mp_dump(FILE *fp, const char *prefix, mp_int *x, const char *suffix);
/*
* Overwrite one mp_int with another, or with a plain integer.
*/
void mp_copy_into(mp_int *dest, mp_int *src);
void mp_copy_integer_into(mp_int *dest, uintmax_t n);
/*
* Conditional selection. Overwrites dest with either src0 or src1,
* according to the value of 'choose_src1'. choose_src1 should be 0 or
* 1; if it's 1, then dest is set to src1, otherwise src0.
*
* The value of choose_src1 is considered to be secret data, so
* control flow and memory access should not depend on it.
*/
void mp_select_into(mp_int *dest, mp_int *src0, mp_int *src1,
unsigned choose_src1);
/*
* Addition, subtraction and multiplication, either targeting an
* existing mp_int or making a new one large enough to hold whatever
* the output might be..
*/
void mp_add_into(mp_int *r, mp_int *a, mp_int *b);
void mp_sub_into(mp_int *r, mp_int *a, mp_int *b);
void mp_mul_into(mp_int *r, mp_int *a, mp_int *b);
mp_int *mp_add(mp_int *x, mp_int *y);
mp_int *mp_sub(mp_int *x, mp_int *y);
mp_int *mp_mul(mp_int *x, mp_int *y);
/*
* Bitwise operations.
*/
void mp_and_into(mp_int *r, mp_int *a, mp_int *b);
void mp_or_into(mp_int *r, mp_int *a, mp_int *b);
void mp_xor_into(mp_int *r, mp_int *a, mp_int *b);
void mp_bic_into(mp_int *r, mp_int *a, mp_int *b);
/*
* Addition, subtraction and multiplication with one argument small
* enough to fit in a C integer. For mp_mul_integer_into, it has to be
* even smaller than that.
*/
void mp_add_integer_into(mp_int *r, mp_int *a, uintmax_t n);
void mp_sub_integer_into(mp_int *r, mp_int *a, uintmax_t n);
void mp_mul_integer_into(mp_int *r, mp_int *a, uint16_t n);
/*
* Conditional addition/subtraction. If yes == 1, sets r to a+b or a-b
* (respectively). If yes == 0, sets r to just a. 'yes' is considered
* secret data.
*/
void mp_cond_add_into(mp_int *r, mp_int *a, mp_int *b, unsigned yes);
void mp_cond_sub_into(mp_int *r, mp_int *a, mp_int *b, unsigned yes);
/*
* Swap x0 and x1 if swap == 1, and not if swap == 0. 'swap' is
* considered secret.
*/
void mp_cond_swap(mp_int *x0, mp_int *x1, unsigned swap);
/*
* Set x to 0 if clear == 1, and otherwise leave it unchanged. 'clear'
* is considered secret.
*/
void mp_cond_clear(mp_int *x, unsigned clear);
/*
* Division. mp_divmod_into divides n by d, and writes the quotient
* into q and the remainder into r. You can pass either of q and r as
* NULL if you don't need one of the outputs.
*
* mp_div and mp_mod are wrappers that return one or other of those
* outputs as a freshly allocated mp_int of the appropriate size.
*
* Division by zero gives no error, and returns a quotient of 0 and a
* remainder of n (so as to still satisfy the division identity that
* n=qd+r).
*/
void mp_divmod_into(mp_int *n, mp_int *d, mp_int *q, mp_int *r);
mp_int *mp_div(mp_int *n, mp_int *d);
mp_int *mp_mod(mp_int *x, mp_int *modulus);
/*
* Compute the residue of x mod m, where m is a small integer. x is
* kept secret, but m is not.
*/
uint32_t mp_mod_known_integer(mp_int *x, uint32_t m);
/*
* Integer nth root. mp_nthroot returns the largest integer x such
* that x^n <= y, and if 'remainder' is non-NULL then it fills it with
* the residue (y - x^n).
*
* Currently, n has to be small enough that the largest binomial
* coefficient (n choose k) fits in 16 bits, which works out to at
* most 18.
*/
mp_int *mp_nthroot(mp_int *y, unsigned n, mp_int *remainder);
/*
* Trivially easy special case of mp_mod: reduce a number mod a power
* of two.
*/
void mp_reduce_mod_2to(mp_int *x, size_t p);
/*
* Modular inverses. mp_invert computes the inverse of x mod modulus
* (and will expect the two to be coprime). mp_invert_mod_2to computes
* the inverse of x mod 2^p, and is a great deal faster.
*/
mp_int *mp_invert_mod_2to(mp_int *x, size_t p);
mp_int *mp_invert(mp_int *x, mp_int *modulus);
/*
* Greatest common divisor.
*
* mp_gcd_into also returns a pair of Bezout coefficients, namely A,B
* such that a*A - b*B = gcd. (The minus sign is so that both returned
* coefficients can be positive.)
*
* You can pass any of mp_gcd_into's output pointers as NULL if you
* don't need that output value.
*
* mp_gcd is a wrapper with a less cumbersome API, for the case where
* the only output value you need is the gcd itself. mp_coprime is
* even easier, if all you care about is whether or not that gcd is 1.
*/
mp_int *mp_gcd(mp_int *a, mp_int *b);
void mp_gcd_into(mp_int *a, mp_int *b,
mp_int *gcd_out, mp_int *A_out, mp_int *B_out);
unsigned mp_coprime(mp_int *a, mp_int *b);
/*
* System for taking square roots modulo an odd prime.
*
* In order to do this efficiently, you need to provide an extra piece
* of information at setup time, namely a number which is not
* congruent mod p to any square. Given p and that non-square, you can
* use modsqrt_new to make a context containing all the necessary
* equipment for actually calculating the square roots, and then you
* can call mp_modsqrt as many times as you like on that context
* before freeing it.
*
* The output parameter '*success' will be filled in with 1 if the
* operation was successful, or 0 if the input number doesn't have a
* square root mod p at all. In the latter case, the returned mp_int
* will be nonsense and you shouldn't depend on it.
*
* ==== WARNING ====
*
* This function DOES NOT TREAT THE PRIME MODULUS AS SECRET DATA! It
* will protect the number you're taking the square root _of_, but not
* the number you're taking the root of it _mod_.
*
* (This is because the algorithm requires a number of loop iterations
* equal to the number of factors of 2 in p-1. And the expected use of
* this function is for elliptic-curve point decompression, in which
* the modulus is always a well-known one written down in standards
* documents.)
*/
typedef struct ModsqrtContext ModsqrtContext;
ModsqrtContext *modsqrt_new(mp_int *p, mp_int *any_nonsquare_mod_p);
void modsqrt_free(ModsqrtContext *);
mp_int *mp_modsqrt(ModsqrtContext *sc, mp_int *x, unsigned *success);
/*
* Functions for Montgomery multiplication, a fast technique for doing
* a long series of modular multiplications all with the same modulus
* (which has to be odd).
*
* You start by calling monty_new to set up a context structure
* containing all the precomputed bits and pieces needed by the
* algorithm. Then, any numbers you want to work with must first be
* transformed into the internal Montgomery representation using
* monty_import; having done that, you can use monty_mul and monty_pow
* to operate on them efficiently; and finally, monty_export will
* convert numbers back out of Montgomery representation to give their
* ordinary values.
*
* Addition and subtraction are not optimised by the Montgomery trick,
* but monty_add and monty_sub are provided anyway for convenience.
*
* There are also monty_invert and monty_modsqrt, which are analogues
* of mp_invert and mp_modsqrt which take their inputs in Montgomery
* representation. For mp_modsqrt, the prime modulus of the
* ModsqrtContext must be the same as the modulus of the MontyContext.
*
* The query functions monty_modulus and monty_identity return numbers
* stored inside the MontyContext, without copying them. The returned
* pointers are still owned by the MontyContext, so don't free them!
*/
MontyContext *monty_new(mp_int *modulus);
void monty_free(MontyContext *mc);
mp_int *monty_modulus(MontyContext *mc); /* doesn't transfer ownership */
mp_int *monty_identity(MontyContext *mc); /* doesn't transfer ownership */
void monty_import_into(MontyContext *mc, mp_int *r, mp_int *x);
mp_int *monty_import(MontyContext *mc, mp_int *x);
void monty_export_into(MontyContext *mc, mp_int *r, mp_int *x);
mp_int *monty_export(MontyContext *mc, mp_int *x);
void monty_mul_into(MontyContext *, mp_int *r, mp_int *, mp_int *);
mp_int *monty_add(MontyContext *, mp_int *, mp_int *);
mp_int *monty_sub(MontyContext *, mp_int *, mp_int *);
mp_int *monty_mul(MontyContext *, mp_int *, mp_int *);
mp_int *monty_pow(MontyContext *, mp_int *base, mp_int *exponent);
mp_int *monty_invert(MontyContext *, mp_int *);
mp_int *monty_modsqrt(ModsqrtContext *sc, mp_int *mx, unsigned *success);
/*
* Modular arithmetic functions which don't use an explicit
* MontyContext. mp_modpow will use one internally (on the assumption
* that the exponent is likely to be large enough to make it
* worthwhile); the other three will just do ordinary non-Montgomery-
* optimised modular reduction. Use mp_modmul if you only have one
* product to compute; if you have a lot, consider using a
* MontyContext in the client code.
*/
mp_int *mp_modpow(mp_int *base, mp_int *exponent, mp_int *modulus);
mp_int *mp_modmul(mp_int *x, mp_int *y, mp_int *modulus);
mp_int *mp_modadd(mp_int *x, mp_int *y, mp_int *modulus);
mp_int *mp_modsub(mp_int *x, mp_int *y, mp_int *modulus);
/*
* Shift an mp_int by a given number of bits. The shift count is
* considered to be secret data, and as a result, the algorithm takes
* O(n log n) time instead of the obvious O(n).
*
* There's no mp_lshift_safe, because the size of mp_int to allocate
* would not be able to avoid depending on the shift count. So if you
* need to behave independently of the size of a left shift, you have
* to know a bound on the space you'll need by some other means.
*/
void mp_lshift_safe_into(mp_int *r, mp_int *x, size_t shift);
void mp_rshift_safe_into(mp_int *r, mp_int *x, size_t shift);
mp_int *mp_rshift_safe(mp_int *x, size_t shift);
/*
* Shift an mp_int left or right by a fixed number of bits. The shift
* count is NOT considered to be secret data! Use this if you're
* always dividing by 2, for example, but don't use it to shift by a
* variable amount derived from another secret number.
*
* The upside is that these functions run in sensible linear time.
*/
void mp_lshift_fixed_into(mp_int *r, mp_int *a, size_t shift);
void mp_rshift_fixed_into(mp_int *r, mp_int *x, size_t shift);
mp_int *mp_lshift_fixed(mp_int *x, size_t shift);
mp_int *mp_rshift_fixed(mp_int *x, size_t shift);
/*
* Generate a random mp_int.
*
* The _function_ definitions here will expect to be given a gen_data
* function that provides random data. Normally you'd use this using
* random_read() from sshrand.c, and the macro wrappers automate that.
*
* (This is a bit of a dodge to avoid mpint.c having a link-time
* dependency on sshrand.c, so that programs can link against one but
* not the other: if a client of this header uses one of these macros
* then _they_ have link-time dependencies on both modules.)
*
* mp_random_bits[_fn] returns an integer 0 <= n < 2^bits.
* mp_random_upto[_fn](limit) returns an integer 0 <= n < limit.
* mp_random_in_range[_fn](lo,hi) returns an integer lo <= n < hi.
*/
typedef void (*random_read_fn_t)(void *, size_t);
mp_int *mp_random_bits_fn(size_t bits, random_read_fn_t randfn);
mp_int *mp_random_upto_fn(mp_int *limit, random_read_fn_t randfn);
mp_int *mp_random_in_range_fn(
mp_int *lo_inclusive, mp_int *hi_exclusive, random_read_fn_t randfn);
#define mp_random_bits(bits) mp_random_bits_fn(bits, random_read)
#define mp_random_upto(limit) mp_random_upto_fn(limit, random_read)
#define mp_random_in_range(lo, hi) mp_random_in_range_fn(lo, hi, random_read)
#endif /* PUTTY_MPINT_H */