Bitcoin ABC 0.33.8
P2P Digital Currency
scalar_4x64_impl.h
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1/***********************************************************************
2 * Copyright (c) 2013, 2014 Pieter Wuille *
3 * Distributed under the MIT software license, see the accompanying *
4 * file COPYING or https://www.opensource.org/licenses/mit-license.php.*
5 ***********************************************************************/
6
7#ifndef SECP256K1_SCALAR_REPR_IMPL_H
8#define SECP256K1_SCALAR_REPR_IMPL_H
9
10#include "checkmem.h"
11#include "int128.h"
12#include "modinv64_impl.h"
13#include "util.h"
14
15/* Limbs of the secp256k1 order. */
16#define SECP256K1_N_0 ((uint64_t)0xBFD25E8CD0364141ULL)
17#define SECP256K1_N_1 ((uint64_t)0xBAAEDCE6AF48A03BULL)
18#define SECP256K1_N_2 ((uint64_t)0xFFFFFFFFFFFFFFFEULL)
19#define SECP256K1_N_3 ((uint64_t)0xFFFFFFFFFFFFFFFFULL)
20
21/* Limbs of 2^256 minus the secp256k1 order. */
22#define SECP256K1_N_C_0 (~SECP256K1_N_0 + 1)
23#define SECP256K1_N_C_1 (~SECP256K1_N_1)
24#define SECP256K1_N_C_2 (1)
25
26/* Limbs of half the secp256k1 order. */
27#define SECP256K1_N_H_0 ((uint64_t)0xDFE92F46681B20A0ULL)
28#define SECP256K1_N_H_1 ((uint64_t)0x5D576E7357A4501DULL)
29#define SECP256K1_N_H_2 ((uint64_t)0xFFFFFFFFFFFFFFFFULL)
30#define SECP256K1_N_H_3 ((uint64_t)0x7FFFFFFFFFFFFFFFULL)
31
33 r->d[0] = 0;
34 r->d[1] = 0;
35 r->d[2] = 0;
36 r->d[3] = 0;
37}
38
40 r->d[0] = v;
41 r->d[1] = 0;
42 r->d[2] = 0;
43 r->d[3] = 0;
44
46}
47
48SECP256K1_INLINE static unsigned int secp256k1_scalar_get_bits(const secp256k1_scalar *a, unsigned int offset, unsigned int count) {
50 VERIFY_CHECK((offset + count - 1) >> 6 == offset >> 6);
51
52 return (a->d[offset >> 6] >> (offset & 0x3F)) & ((((uint64_t)1) << count) - 1);
53}
54
55SECP256K1_INLINE static unsigned int secp256k1_scalar_get_bits_var(const secp256k1_scalar *a, unsigned int offset, unsigned int count) {
57 VERIFY_CHECK(count < 32);
58 VERIFY_CHECK(offset + count <= 256);
59
60 if ((offset + count - 1) >> 6 == offset >> 6) {
61 return secp256k1_scalar_get_bits(a, offset, count);
62 } else {
63 VERIFY_CHECK((offset >> 6) + 1 < 4);
64 return ((a->d[offset >> 6] >> (offset & 0x3F)) | (a->d[(offset >> 6) + 1] << (64 - (offset & 0x3F)))) & ((((uint64_t)1) << count) - 1);
65 }
66}
67
69 int yes = 0;
70 int no = 0;
71 no |= (a->d[3] < SECP256K1_N_3); /* No need for a > check. */
72 no |= (a->d[2] < SECP256K1_N_2);
73 yes |= (a->d[2] > SECP256K1_N_2) & ~no;
74 no |= (a->d[1] < SECP256K1_N_1);
75 yes |= (a->d[1] > SECP256K1_N_1) & ~no;
76 yes |= (a->d[0] >= SECP256K1_N_0) & ~no;
77 return yes;
78}
79
80SECP256K1_INLINE static int secp256k1_scalar_reduce(secp256k1_scalar *r, unsigned int overflow) {
82 VERIFY_CHECK(overflow <= 1);
83
84 secp256k1_u128_from_u64(&t, r->d[0]);
87 secp256k1_u128_accum_u64(&t, r->d[1]);
90 secp256k1_u128_accum_u64(&t, r->d[2]);
93 secp256k1_u128_accum_u64(&t, r->d[3]);
94 r->d[3] = secp256k1_u128_to_u64(&t);
95
97 return overflow;
98}
99
101 int overflow;
105
106 secp256k1_u128_from_u64(&t, a->d[0]);
107 secp256k1_u128_accum_u64(&t, b->d[0]);
108 r->d[0] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
109 secp256k1_u128_accum_u64(&t, a->d[1]);
110 secp256k1_u128_accum_u64(&t, b->d[1]);
111 r->d[1] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
112 secp256k1_u128_accum_u64(&t, a->d[2]);
113 secp256k1_u128_accum_u64(&t, b->d[2]);
114 r->d[2] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
115 secp256k1_u128_accum_u64(&t, a->d[3]);
116 secp256k1_u128_accum_u64(&t, b->d[3]);
117 r->d[3] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
119 VERIFY_CHECK(overflow == 0 || overflow == 1);
120 secp256k1_scalar_reduce(r, overflow);
121
123 return overflow;
124}
125
126static void secp256k1_scalar_cadd_bit(secp256k1_scalar *r, unsigned int bit, int flag) {
128 volatile int vflag = flag;
130 VERIFY_CHECK(bit < 256);
131
132 bit += ((uint32_t) vflag - 1) & 0x100; /* forcing (bit >> 6) > 3 makes this a noop */
133 secp256k1_u128_from_u64(&t, r->d[0]);
134 secp256k1_u128_accum_u64(&t, ((uint64_t)((bit >> 6) == 0)) << (bit & 0x3F));
135 r->d[0] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
136 secp256k1_u128_accum_u64(&t, r->d[1]);
137 secp256k1_u128_accum_u64(&t, ((uint64_t)((bit >> 6) == 1)) << (bit & 0x3F));
138 r->d[1] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
139 secp256k1_u128_accum_u64(&t, r->d[2]);
140 secp256k1_u128_accum_u64(&t, ((uint64_t)((bit >> 6) == 2)) << (bit & 0x3F));
141 r->d[2] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
142 secp256k1_u128_accum_u64(&t, r->d[3]);
143 secp256k1_u128_accum_u64(&t, ((uint64_t)((bit >> 6) == 3)) << (bit & 0x3F));
144 r->d[3] = secp256k1_u128_to_u64(&t);
145
148}
149
150static void secp256k1_scalar_set_b32(secp256k1_scalar *r, const unsigned char *b32, int *overflow) {
151 int over;
152 r->d[0] = secp256k1_read_be64(&b32[24]);
153 r->d[1] = secp256k1_read_be64(&b32[16]);
154 r->d[2] = secp256k1_read_be64(&b32[8]);
155 r->d[3] = secp256k1_read_be64(&b32[0]);
157 if (overflow) {
158 *overflow = over;
159 }
160
162}
163
164static void secp256k1_scalar_get_b32(unsigned char *bin, const secp256k1_scalar* a) {
166
167 secp256k1_write_be64(&bin[0], a->d[3]);
168 secp256k1_write_be64(&bin[8], a->d[2]);
169 secp256k1_write_be64(&bin[16], a->d[1]);
170 secp256k1_write_be64(&bin[24], a->d[0]);
171}
172
175
176 return (a->d[0] | a->d[1] | a->d[2] | a->d[3]) == 0;
177}
178
180 uint64_t nonzero = 0xFFFFFFFFFFFFFFFFULL * (secp256k1_scalar_is_zero(a) == 0);
183
184 secp256k1_u128_from_u64(&t, ~a->d[0]);
186 r->d[0] = secp256k1_u128_to_u64(&t) & nonzero; secp256k1_u128_rshift(&t, 64);
187 secp256k1_u128_accum_u64(&t, ~a->d[1]);
189 r->d[1] = secp256k1_u128_to_u64(&t) & nonzero; secp256k1_u128_rshift(&t, 64);
190 secp256k1_u128_accum_u64(&t, ~a->d[2]);
192 r->d[2] = secp256k1_u128_to_u64(&t) & nonzero; secp256k1_u128_rshift(&t, 64);
193 secp256k1_u128_accum_u64(&t, ~a->d[3]);
195 r->d[3] = secp256k1_u128_to_u64(&t) & nonzero;
196
198}
199
201 /* Writing `/` for field division and `//` for integer division, we compute
202 *
203 * a/2 = (a - (a&1))/2 + (a&1)/2
204 * = (a >> 1) + (a&1 ? 1/2 : 0)
205 * = (a >> 1) + (a&1 ? n//2+1 : 0),
206 *
207 * where n is the group order and in the last equality we have used 1/2 = n//2+1 (mod n).
208 * For n//2, we have the constants SECP256K1_N_H_0, ...
209 *
210 * This sum does not overflow. The most extreme case is a = -2, the largest odd scalar. Here:
211 * - the left summand is: a >> 1 = (a - a&1)/2 = (n-2-1)//2 = (n-3)//2
212 * - the right summand is: a&1 ? n//2+1 : 0 = n//2+1 = (n-1)//2 + 2//2 = (n+1)//2
213 * Together they sum to (n-3)//2 + (n+1)//2 = (2n-2)//2 = n - 1, which is less than n.
214 */
215 uint64_t mask = -(uint64_t)(a->d[0] & 1U);
218
219 secp256k1_u128_from_u64(&t, (a->d[0] >> 1) | (a->d[1] << 63));
220 secp256k1_u128_accum_u64(&t, (SECP256K1_N_H_0 + 1U) & mask);
221 r->d[0] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
222 secp256k1_u128_accum_u64(&t, (a->d[1] >> 1) | (a->d[2] << 63));
224 r->d[1] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
225 secp256k1_u128_accum_u64(&t, (a->d[2] >> 1) | (a->d[3] << 63));
227 r->d[2] = secp256k1_u128_to_u64(&t); secp256k1_u128_rshift(&t, 64);
228 r->d[3] = secp256k1_u128_to_u64(&t) + (a->d[3] >> 1) + (SECP256K1_N_H_3 & mask);
229#ifdef VERIFY
230 /* The line above only computed the bottom 64 bits of r->d[3]; redo the computation
231 * in full 128 bits to make sure the top 64 bits are indeed zero. */
232 secp256k1_u128_accum_u64(&t, a->d[3] >> 1);
234 secp256k1_u128_rshift(&t, 64);
236
238#endif
239}
240
243
244 return ((a->d[0] ^ 1) | a->d[1] | a->d[2] | a->d[3]) == 0;
245}
246
248 int yes = 0;
249 int no = 0;
251
252 no |= (a->d[3] < SECP256K1_N_H_3);
253 yes |= (a->d[3] > SECP256K1_N_H_3) & ~no;
254 no |= (a->d[2] < SECP256K1_N_H_2) & ~yes; /* No need for a > check. */
255 no |= (a->d[1] < SECP256K1_N_H_1) & ~yes;
256 yes |= (a->d[1] > SECP256K1_N_H_1) & ~no;
257 yes |= (a->d[0] > SECP256K1_N_H_0) & ~no;
258 return yes;
259}
260
262 /* If we are flag = 0, mask = 00...00 and this is a no-op;
263 * if we are flag = 1, mask = 11...11 and this is identical to secp256k1_scalar_negate */
264 volatile int vflag = flag;
265 uint64_t mask = -vflag;
266 uint64_t nonzero = (secp256k1_scalar_is_zero(r) != 0) - 1;
269
270 secp256k1_u128_from_u64(&t, r->d[0] ^ mask);
271 secp256k1_u128_accum_u64(&t, (SECP256K1_N_0 + 1) & mask);
272 r->d[0] = secp256k1_u128_to_u64(&t) & nonzero; secp256k1_u128_rshift(&t, 64);
273 secp256k1_u128_accum_u64(&t, r->d[1] ^ mask);
275 r->d[1] = secp256k1_u128_to_u64(&t) & nonzero; secp256k1_u128_rshift(&t, 64);
276 secp256k1_u128_accum_u64(&t, r->d[2] ^ mask);
278 r->d[2] = secp256k1_u128_to_u64(&t) & nonzero; secp256k1_u128_rshift(&t, 64);
279 secp256k1_u128_accum_u64(&t, r->d[3] ^ mask);
281 r->d[3] = secp256k1_u128_to_u64(&t) & nonzero;
282
284 return 2 * (mask == 0) - 1;
285}
286
287/* Inspired by the macros in OpenSSL's crypto/bn/asm/x86_64-gcc.c. */
288
290#define muladd(a,b) { \
291 uint64_t tl, th; \
292 { \
293 secp256k1_uint128 t; \
294 secp256k1_u128_mul(&t, a, b); \
295 th = secp256k1_u128_hi_u64(&t); /* at most 0xFFFFFFFFFFFFFFFE */ \
296 tl = secp256k1_u128_to_u64(&t); \
297 } \
298 c0 += tl; /* overflow is handled on the next line */ \
299 th += (c0 < tl); /* at most 0xFFFFFFFFFFFFFFFF */ \
300 c1 += th; /* overflow is handled on the next line */ \
301 c2 += (c1 < th); /* never overflows by contract (verified in the next line) */ \
302 VERIFY_CHECK((c1 >= th) || (c2 != 0)); \
303}
304
306#define muladd_fast(a,b) { \
307 uint64_t tl, th; \
308 { \
309 secp256k1_uint128 t; \
310 secp256k1_u128_mul(&t, a, b); \
311 th = secp256k1_u128_hi_u64(&t); /* at most 0xFFFFFFFFFFFFFFFE */ \
312 tl = secp256k1_u128_to_u64(&t); \
313 } \
314 c0 += tl; /* overflow is handled on the next line */ \
315 th += (c0 < tl); /* at most 0xFFFFFFFFFFFFFFFF */ \
316 c1 += th; /* never overflows by contract (verified in the next line) */ \
317 VERIFY_CHECK(c1 >= th); \
318}
319
321#define sumadd(a) { \
322 unsigned int over; \
323 c0 += (a); /* overflow is handled on the next line */ \
324 over = (c0 < (a)); \
325 c1 += over; /* overflow is handled on the next line */ \
326 c2 += (c1 < over); /* never overflows by contract */ \
327}
328
330#define sumadd_fast(a) { \
331 c0 += (a); /* overflow is handled on the next line */ \
332 c1 += (c0 < (a)); /* never overflows by contract (verified the next line) */ \
333 VERIFY_CHECK((c1 != 0) | (c0 >= (a))); \
334 VERIFY_CHECK(c2 == 0); \
335}
336
338#define extract(n) { \
339 (n) = c0; \
340 c0 = c1; \
341 c1 = c2; \
342 c2 = 0; \
343}
344
346#define extract_fast(n) { \
347 (n) = c0; \
348 c0 = c1; \
349 c1 = 0; \
350 VERIFY_CHECK(c2 == 0); \
351}
352
353static void secp256k1_scalar_reduce_512(secp256k1_scalar *r, const uint64_t *l) {
354#ifdef USE_ASM_X86_64
355 /* Reduce 512 bits into 385. */
356 uint64_t m0, m1, m2, m3, m4, m5, m6;
357 uint64_t p0, p1, p2, p3, p4;
358 uint64_t c;
359
360 __asm__ __volatile__(
361 /* Preload. */
362 "movq 32(%%rsi), %%r11\n"
363 "movq 40(%%rsi), %%r12\n"
364 "movq 48(%%rsi), %%r13\n"
365 "movq 56(%%rsi), %%r14\n"
366 /* Initialize r8,r9,r10 */
367 "movq 0(%%rsi), %%r8\n"
368 "xorq %%r9, %%r9\n"
369 "xorq %%r10, %%r10\n"
370 /* (r8,r9) += n0 * c0 */
371 "movq %8, %%rax\n"
372 "mulq %%r11\n"
373 "addq %%rax, %%r8\n"
374 "adcq %%rdx, %%r9\n"
375 /* extract m0 */
376 "movq %%r8, %q0\n"
377 "xorq %%r8, %%r8\n"
378 /* (r9,r10) += l1 */
379 "addq 8(%%rsi), %%r9\n"
380 "adcq $0, %%r10\n"
381 /* (r9,r10,r8) += n1 * c0 */
382 "movq %8, %%rax\n"
383 "mulq %%r12\n"
384 "addq %%rax, %%r9\n"
385 "adcq %%rdx, %%r10\n"
386 "adcq $0, %%r8\n"
387 /* (r9,r10,r8) += n0 * c1 */
388 "movq %9, %%rax\n"
389 "mulq %%r11\n"
390 "addq %%rax, %%r9\n"
391 "adcq %%rdx, %%r10\n"
392 "adcq $0, %%r8\n"
393 /* extract m1 */
394 "movq %%r9, %q1\n"
395 "xorq %%r9, %%r9\n"
396 /* (r10,r8,r9) += l2 */
397 "addq 16(%%rsi), %%r10\n"
398 "adcq $0, %%r8\n"
399 "adcq $0, %%r9\n"
400 /* (r10,r8,r9) += n2 * c0 */
401 "movq %8, %%rax\n"
402 "mulq %%r13\n"
403 "addq %%rax, %%r10\n"
404 "adcq %%rdx, %%r8\n"
405 "adcq $0, %%r9\n"
406 /* (r10,r8,r9) += n1 * c1 */
407 "movq %9, %%rax\n"
408 "mulq %%r12\n"
409 "addq %%rax, %%r10\n"
410 "adcq %%rdx, %%r8\n"
411 "adcq $0, %%r9\n"
412 /* (r10,r8,r9) += n0 */
413 "addq %%r11, %%r10\n"
414 "adcq $0, %%r8\n"
415 "adcq $0, %%r9\n"
416 /* extract m2 */
417 "movq %%r10, %q2\n"
418 "xorq %%r10, %%r10\n"
419 /* (r8,r9,r10) += l3 */
420 "addq 24(%%rsi), %%r8\n"
421 "adcq $0, %%r9\n"
422 "adcq $0, %%r10\n"
423 /* (r8,r9,r10) += n3 * c0 */
424 "movq %8, %%rax\n"
425 "mulq %%r14\n"
426 "addq %%rax, %%r8\n"
427 "adcq %%rdx, %%r9\n"
428 "adcq $0, %%r10\n"
429 /* (r8,r9,r10) += n2 * c1 */
430 "movq %9, %%rax\n"
431 "mulq %%r13\n"
432 "addq %%rax, %%r8\n"
433 "adcq %%rdx, %%r9\n"
434 "adcq $0, %%r10\n"
435 /* (r8,r9,r10) += n1 */
436 "addq %%r12, %%r8\n"
437 "adcq $0, %%r9\n"
438 "adcq $0, %%r10\n"
439 /* extract m3 */
440 "movq %%r8, %q3\n"
441 "xorq %%r8, %%r8\n"
442 /* (r9,r10,r8) += n3 * c1 */
443 "movq %9, %%rax\n"
444 "mulq %%r14\n"
445 "addq %%rax, %%r9\n"
446 "adcq %%rdx, %%r10\n"
447 "adcq $0, %%r8\n"
448 /* (r9,r10,r8) += n2 */
449 "addq %%r13, %%r9\n"
450 "adcq $0, %%r10\n"
451 "adcq $0, %%r8\n"
452 /* extract m4 */
453 "movq %%r9, %q4\n"
454 /* (r10,r8) += n3 */
455 "addq %%r14, %%r10\n"
456 "adcq $0, %%r8\n"
457 /* extract m5 */
458 "movq %%r10, %q5\n"
459 /* extract m6 */
460 "movq %%r8, %q6\n"
461 : "=&g"(m0), "=&g"(m1), "=&g"(m2), "=g"(m3), "=g"(m4), "=g"(m5), "=g"(m6)
462 : "S"(l), "i"(SECP256K1_N_C_0), "i"(SECP256K1_N_C_1)
463 : "rax", "rdx", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "cc");
464
465 /* Reduce 385 bits into 258. */
466 __asm__ __volatile__(
467 /* Preload */
468 "movq %q9, %%r11\n"
469 "movq %q10, %%r12\n"
470 "movq %q11, %%r13\n"
471 /* Initialize (r8,r9,r10) */
472 "movq %q5, %%r8\n"
473 "xorq %%r9, %%r9\n"
474 "xorq %%r10, %%r10\n"
475 /* (r8,r9) += m4 * c0 */
476 "movq %12, %%rax\n"
477 "mulq %%r11\n"
478 "addq %%rax, %%r8\n"
479 "adcq %%rdx, %%r9\n"
480 /* extract p0 */
481 "movq %%r8, %q0\n"
482 "xorq %%r8, %%r8\n"
483 /* (r9,r10) += m1 */
484 "addq %q6, %%r9\n"
485 "adcq $0, %%r10\n"
486 /* (r9,r10,r8) += m5 * c0 */
487 "movq %12, %%rax\n"
488 "mulq %%r12\n"
489 "addq %%rax, %%r9\n"
490 "adcq %%rdx, %%r10\n"
491 "adcq $0, %%r8\n"
492 /* (r9,r10,r8) += m4 * c1 */
493 "movq %13, %%rax\n"
494 "mulq %%r11\n"
495 "addq %%rax, %%r9\n"
496 "adcq %%rdx, %%r10\n"
497 "adcq $0, %%r8\n"
498 /* extract p1 */
499 "movq %%r9, %q1\n"
500 "xorq %%r9, %%r9\n"
501 /* (r10,r8,r9) += m2 */
502 "addq %q7, %%r10\n"
503 "adcq $0, %%r8\n"
504 "adcq $0, %%r9\n"
505 /* (r10,r8,r9) += m6 * c0 */
506 "movq %12, %%rax\n"
507 "mulq %%r13\n"
508 "addq %%rax, %%r10\n"
509 "adcq %%rdx, %%r8\n"
510 "adcq $0, %%r9\n"
511 /* (r10,r8,r9) += m5 * c1 */
512 "movq %13, %%rax\n"
513 "mulq %%r12\n"
514 "addq %%rax, %%r10\n"
515 "adcq %%rdx, %%r8\n"
516 "adcq $0, %%r9\n"
517 /* (r10,r8,r9) += m4 */
518 "addq %%r11, %%r10\n"
519 "adcq $0, %%r8\n"
520 "adcq $0, %%r9\n"
521 /* extract p2 */
522 "movq %%r10, %q2\n"
523 /* (r8,r9) += m3 */
524 "addq %q8, %%r8\n"
525 "adcq $0, %%r9\n"
526 /* (r8,r9) += m6 * c1 */
527 "movq %13, %%rax\n"
528 "mulq %%r13\n"
529 "addq %%rax, %%r8\n"
530 "adcq %%rdx, %%r9\n"
531 /* (r8,r9) += m5 */
532 "addq %%r12, %%r8\n"
533 "adcq $0, %%r9\n"
534 /* extract p3 */
535 "movq %%r8, %q3\n"
536 /* (r9) += m6 */
537 "addq %%r13, %%r9\n"
538 /* extract p4 */
539 "movq %%r9, %q4\n"
540 : "=&g"(p0), "=&g"(p1), "=&g"(p2), "=g"(p3), "=g"(p4)
541 : "g"(m0), "g"(m1), "g"(m2), "g"(m3), "g"(m4), "g"(m5), "g"(m6), "i"(SECP256K1_N_C_0), "i"(SECP256K1_N_C_1)
542 : "rax", "rdx", "r8", "r9", "r10", "r11", "r12", "r13", "cc");
543
544 /* Reduce 258 bits into 256. */
545 __asm__ __volatile__(
546 /* Preload */
547 "movq %q5, %%r10\n"
548 /* (rax,rdx) = p4 * c0 */
549 "movq %7, %%rax\n"
550 "mulq %%r10\n"
551 /* (rax,rdx) += p0 */
552 "addq %q1, %%rax\n"
553 "adcq $0, %%rdx\n"
554 /* extract r0 */
555 "movq %%rax, 0(%q6)\n"
556 /* Move to (r8,r9) */
557 "movq %%rdx, %%r8\n"
558 "xorq %%r9, %%r9\n"
559 /* (r8,r9) += p1 */
560 "addq %q2, %%r8\n"
561 "adcq $0, %%r9\n"
562 /* (r8,r9) += p4 * c1 */
563 "movq %8, %%rax\n"
564 "mulq %%r10\n"
565 "addq %%rax, %%r8\n"
566 "adcq %%rdx, %%r9\n"
567 /* Extract r1 */
568 "movq %%r8, 8(%q6)\n"
569 "xorq %%r8, %%r8\n"
570 /* (r9,r8) += p4 */
571 "addq %%r10, %%r9\n"
572 "adcq $0, %%r8\n"
573 /* (r9,r8) += p2 */
574 "addq %q3, %%r9\n"
575 "adcq $0, %%r8\n"
576 /* Extract r2 */
577 "movq %%r9, 16(%q6)\n"
578 "xorq %%r9, %%r9\n"
579 /* (r8,r9) += p3 */
580 "addq %q4, %%r8\n"
581 "adcq $0, %%r9\n"
582 /* Extract r3 */
583 "movq %%r8, 24(%q6)\n"
584 /* Extract c */
585 "movq %%r9, %q0\n"
586 : "=g"(c)
587 : "g"(p0), "g"(p1), "g"(p2), "g"(p3), "g"(p4), "D"(r), "i"(SECP256K1_N_C_0), "i"(SECP256K1_N_C_1)
588 : "rax", "rdx", "r8", "r9", "r10", "cc", "memory");
589#else
591 uint64_t c, c0, c1, c2;
592 uint64_t n0 = l[4], n1 = l[5], n2 = l[6], n3 = l[7];
593 uint64_t m0, m1, m2, m3, m4, m5;
594 uint32_t m6;
595 uint64_t p0, p1, p2, p3;
596 uint32_t p4;
597
598 /* Reduce 512 bits into 385. */
599 /* m[0..6] = l[0..3] + n[0..3] * SECP256K1_N_C. */
600 c0 = l[0]; c1 = 0; c2 = 0;
602 extract_fast(m0);
603 sumadd_fast(l[1]);
606 extract(m1);
607 sumadd(l[2]);
610 sumadd(n0);
611 extract(m2);
612 sumadd(l[3]);
615 sumadd(n1);
616 extract(m3);
618 sumadd(n2);
619 extract(m4);
620 sumadd_fast(n3);
621 extract_fast(m5);
622 VERIFY_CHECK(c0 <= 1);
623 m6 = c0;
624
625 /* Reduce 385 bits into 258. */
626 /* p[0..4] = m[0..3] + m[4..6] * SECP256K1_N_C. */
627 c0 = m0; c1 = 0; c2 = 0;
629 extract_fast(p0);
630 sumadd_fast(m1);
633 extract(p1);
634 sumadd(m2);
637 sumadd(m4);
638 extract(p2);
639 sumadd_fast(m3);
641 sumadd_fast(m5);
642 extract_fast(p3);
643 p4 = c0 + m6;
644 VERIFY_CHECK(p4 <= 2);
645
646 /* Reduce 258 bits into 256. */
647 /* r[0..3] = p[0..3] + p[4] * SECP256K1_N_C. */
648 secp256k1_u128_from_u64(&c128, p0);
650 r->d[0] = secp256k1_u128_to_u64(&c128); secp256k1_u128_rshift(&c128, 64);
651 secp256k1_u128_accum_u64(&c128, p1);
653 r->d[1] = secp256k1_u128_to_u64(&c128); secp256k1_u128_rshift(&c128, 64);
654 secp256k1_u128_accum_u64(&c128, p2);
655 secp256k1_u128_accum_u64(&c128, p4);
656 r->d[2] = secp256k1_u128_to_u64(&c128); secp256k1_u128_rshift(&c128, 64);
657 secp256k1_u128_accum_u64(&c128, p3);
658 r->d[3] = secp256k1_u128_to_u64(&c128);
659 c = secp256k1_u128_hi_u64(&c128);
660#endif
661
662 /* Final reduction of r. */
664}
665
666static void secp256k1_scalar_mul_512(uint64_t l[8], const secp256k1_scalar *a, const secp256k1_scalar *b) {
667#ifdef USE_ASM_X86_64
668 const uint64_t *pb = b->d;
669 __asm__ __volatile__(
670 /* Preload */
671 "movq 0(%%rdi), %%r15\n"
672 "movq 8(%%rdi), %%rbx\n"
673 "movq 16(%%rdi), %%rcx\n"
674 "movq 0(%%rdx), %%r11\n"
675 "movq 8(%%rdx), %%r12\n"
676 "movq 16(%%rdx), %%r13\n"
677 "movq 24(%%rdx), %%r14\n"
678 /* (rax,rdx) = a0 * b0 */
679 "movq %%r15, %%rax\n"
680 "mulq %%r11\n"
681 /* Extract l0 */
682 "movq %%rax, 0(%%rsi)\n"
683 /* (r8,r9,r10) = (rdx) */
684 "movq %%rdx, %%r8\n"
685 "xorq %%r9, %%r9\n"
686 "xorq %%r10, %%r10\n"
687 /* (r8,r9,r10) += a0 * b1 */
688 "movq %%r15, %%rax\n"
689 "mulq %%r12\n"
690 "addq %%rax, %%r8\n"
691 "adcq %%rdx, %%r9\n"
692 "adcq $0, %%r10\n"
693 /* (r8,r9,r10) += a1 * b0 */
694 "movq %%rbx, %%rax\n"
695 "mulq %%r11\n"
696 "addq %%rax, %%r8\n"
697 "adcq %%rdx, %%r9\n"
698 "adcq $0, %%r10\n"
699 /* Extract l1 */
700 "movq %%r8, 8(%%rsi)\n"
701 "xorq %%r8, %%r8\n"
702 /* (r9,r10,r8) += a0 * b2 */
703 "movq %%r15, %%rax\n"
704 "mulq %%r13\n"
705 "addq %%rax, %%r9\n"
706 "adcq %%rdx, %%r10\n"
707 "adcq $0, %%r8\n"
708 /* (r9,r10,r8) += a1 * b1 */
709 "movq %%rbx, %%rax\n"
710 "mulq %%r12\n"
711 "addq %%rax, %%r9\n"
712 "adcq %%rdx, %%r10\n"
713 "adcq $0, %%r8\n"
714 /* (r9,r10,r8) += a2 * b0 */
715 "movq %%rcx, %%rax\n"
716 "mulq %%r11\n"
717 "addq %%rax, %%r9\n"
718 "adcq %%rdx, %%r10\n"
719 "adcq $0, %%r8\n"
720 /* Extract l2 */
721 "movq %%r9, 16(%%rsi)\n"
722 "xorq %%r9, %%r9\n"
723 /* (r10,r8,r9) += a0 * b3 */
724 "movq %%r15, %%rax\n"
725 "mulq %%r14\n"
726 "addq %%rax, %%r10\n"
727 "adcq %%rdx, %%r8\n"
728 "adcq $0, %%r9\n"
729 /* Preload a3 */
730 "movq 24(%%rdi), %%r15\n"
731 /* (r10,r8,r9) += a1 * b2 */
732 "movq %%rbx, %%rax\n"
733 "mulq %%r13\n"
734 "addq %%rax, %%r10\n"
735 "adcq %%rdx, %%r8\n"
736 "adcq $0, %%r9\n"
737 /* (r10,r8,r9) += a2 * b1 */
738 "movq %%rcx, %%rax\n"
739 "mulq %%r12\n"
740 "addq %%rax, %%r10\n"
741 "adcq %%rdx, %%r8\n"
742 "adcq $0, %%r9\n"
743 /* (r10,r8,r9) += a3 * b0 */
744 "movq %%r15, %%rax\n"
745 "mulq %%r11\n"
746 "addq %%rax, %%r10\n"
747 "adcq %%rdx, %%r8\n"
748 "adcq $0, %%r9\n"
749 /* Extract l3 */
750 "movq %%r10, 24(%%rsi)\n"
751 "xorq %%r10, %%r10\n"
752 /* (r8,r9,r10) += a1 * b3 */
753 "movq %%rbx, %%rax\n"
754 "mulq %%r14\n"
755 "addq %%rax, %%r8\n"
756 "adcq %%rdx, %%r9\n"
757 "adcq $0, %%r10\n"
758 /* (r8,r9,r10) += a2 * b2 */
759 "movq %%rcx, %%rax\n"
760 "mulq %%r13\n"
761 "addq %%rax, %%r8\n"
762 "adcq %%rdx, %%r9\n"
763 "adcq $0, %%r10\n"
764 /* (r8,r9,r10) += a3 * b1 */
765 "movq %%r15, %%rax\n"
766 "mulq %%r12\n"
767 "addq %%rax, %%r8\n"
768 "adcq %%rdx, %%r9\n"
769 "adcq $0, %%r10\n"
770 /* Extract l4 */
771 "movq %%r8, 32(%%rsi)\n"
772 "xorq %%r8, %%r8\n"
773 /* (r9,r10,r8) += a2 * b3 */
774 "movq %%rcx, %%rax\n"
775 "mulq %%r14\n"
776 "addq %%rax, %%r9\n"
777 "adcq %%rdx, %%r10\n"
778 "adcq $0, %%r8\n"
779 /* (r9,r10,r8) += a3 * b2 */
780 "movq %%r15, %%rax\n"
781 "mulq %%r13\n"
782 "addq %%rax, %%r9\n"
783 "adcq %%rdx, %%r10\n"
784 "adcq $0, %%r8\n"
785 /* Extract l5 */
786 "movq %%r9, 40(%%rsi)\n"
787 /* (r10,r8) += a3 * b3 */
788 "movq %%r15, %%rax\n"
789 "mulq %%r14\n"
790 "addq %%rax, %%r10\n"
791 "adcq %%rdx, %%r8\n"
792 /* Extract l6 */
793 "movq %%r10, 48(%%rsi)\n"
794 /* Extract l7 */
795 "movq %%r8, 56(%%rsi)\n"
796 : "+d"(pb)
797 : "S"(l), "D"(a->d)
798 : "rax", "rbx", "rcx", "r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15", "cc", "memory");
799#else
800 /* 160 bit accumulator. */
801 uint64_t c0 = 0, c1 = 0;
802 uint32_t c2 = 0;
803
804 /* l[0..7] = a[0..3] * b[0..3]. */
805 muladd_fast(a->d[0], b->d[0]);
806 extract_fast(l[0]);
807 muladd(a->d[0], b->d[1]);
808 muladd(a->d[1], b->d[0]);
809 extract(l[1]);
810 muladd(a->d[0], b->d[2]);
811 muladd(a->d[1], b->d[1]);
812 muladd(a->d[2], b->d[0]);
813 extract(l[2]);
814 muladd(a->d[0], b->d[3]);
815 muladd(a->d[1], b->d[2]);
816 muladd(a->d[2], b->d[1]);
817 muladd(a->d[3], b->d[0]);
818 extract(l[3]);
819 muladd(a->d[1], b->d[3]);
820 muladd(a->d[2], b->d[2]);
821 muladd(a->d[3], b->d[1]);
822 extract(l[4]);
823 muladd(a->d[2], b->d[3]);
824 muladd(a->d[3], b->d[2]);
825 extract(l[5]);
826 muladd_fast(a->d[3], b->d[3]);
827 extract_fast(l[6]);
828 VERIFY_CHECK(c1 == 0);
829 l[7] = c0;
830#endif
831}
832
833#undef sumadd
834#undef sumadd_fast
835#undef muladd
836#undef muladd_fast
837#undef extract
838#undef extract_fast
839
841 uint64_t l[8];
844
847
849}
850
853
854 r1->d[0] = k->d[0];
855 r1->d[1] = k->d[1];
856 r1->d[2] = 0;
857 r1->d[3] = 0;
858 r2->d[0] = k->d[2];
859 r2->d[1] = k->d[3];
860 r2->d[2] = 0;
861 r2->d[3] = 0;
862
865}
866
870
871 return ((a->d[0] ^ b->d[0]) | (a->d[1] ^ b->d[1]) | (a->d[2] ^ b->d[2]) | (a->d[3] ^ b->d[3])) == 0;
872}
873
875 uint64_t l[8];
876 unsigned int shiftlimbs;
877 unsigned int shiftlow;
878 unsigned int shifthigh;
881 VERIFY_CHECK(shift >= 256);
882
884 shiftlimbs = shift >> 6;
885 shiftlow = shift & 0x3F;
886 shifthigh = 64 - shiftlow;
887 r->d[0] = shift < 512 ? (l[0 + shiftlimbs] >> shiftlow | (shift < 448 && shiftlow ? (l[1 + shiftlimbs] << shifthigh) : 0)) : 0;
888 r->d[1] = shift < 448 ? (l[1 + shiftlimbs] >> shiftlow | (shift < 384 && shiftlow ? (l[2 + shiftlimbs] << shifthigh) : 0)) : 0;
889 r->d[2] = shift < 384 ? (l[2 + shiftlimbs] >> shiftlow | (shift < 320 && shiftlow ? (l[3 + shiftlimbs] << shifthigh) : 0)) : 0;
890 r->d[3] = shift < 320 ? (l[3 + shiftlimbs] >> shiftlow) : 0;
891 secp256k1_scalar_cadd_bit(r, 0, (l[(shift - 1) >> 6] >> ((shift - 1) & 0x3f)) & 1);
892
894}
895
897 uint64_t mask0, mask1;
898 volatile int vflag = flag;
900 SECP256K1_CHECKMEM_CHECK_VERIFY(r->d, sizeof(r->d));
901
902 mask0 = vflag + ~((uint64_t)0);
903 mask1 = ~mask0;
904 r->d[0] = (r->d[0] & mask0) | (a->d[0] & mask1);
905 r->d[1] = (r->d[1] & mask0) | (a->d[1] & mask1);
906 r->d[2] = (r->d[2] & mask0) | (a->d[2] & mask1);
907 r->d[3] = (r->d[3] & mask0) | (a->d[3] & mask1);
908
910}
911
913 const uint64_t a0 = a->v[0], a1 = a->v[1], a2 = a->v[2], a3 = a->v[3], a4 = a->v[4];
914
915 /* The output from secp256k1_modinv64{_var} should be normalized to range [0,modulus), and
916 * have limbs in [0,2^62). The modulus is < 2^256, so the top limb must be below 2^(256-62*4).
917 */
918 VERIFY_CHECK(a0 >> 62 == 0);
919 VERIFY_CHECK(a1 >> 62 == 0);
920 VERIFY_CHECK(a2 >> 62 == 0);
921 VERIFY_CHECK(a3 >> 62 == 0);
922 VERIFY_CHECK(a4 >> 8 == 0);
923
924 r->d[0] = a0 | a1 << 62;
925 r->d[1] = a1 >> 2 | a2 << 60;
926 r->d[2] = a2 >> 4 | a3 << 58;
927 r->d[3] = a3 >> 6 | a4 << 56;
928
930}
931
933 const uint64_t M62 = UINT64_MAX >> 2;
934 const uint64_t a0 = a->d[0], a1 = a->d[1], a2 = a->d[2], a3 = a->d[3];
936
937 r->v[0] = a0 & M62;
938 r->v[1] = (a0 >> 62 | a1 << 2) & M62;
939 r->v[2] = (a1 >> 60 | a2 << 4) & M62;
940 r->v[3] = (a2 >> 58 | a3 << 6) & M62;
941 r->v[4] = a3 >> 56;
942}
943
945 {{0x3FD25E8CD0364141LL, 0x2ABB739ABD2280EELL, -0x15LL, 0, 256}},
946 0x34F20099AA774EC1LL
947};
948
951#ifdef VERIFY
952 int zero_in = secp256k1_scalar_is_zero(x);
953#endif
955
959
962}
963
966#ifdef VERIFY
967 int zero_in = secp256k1_scalar_is_zero(x);
968#endif
970
974
977}
978
981
982 return !(a->d[0] & 1);
983}
984
985#endif /* SECP256K1_SCALAR_REPR_IMPL_H */
#define SECP256K1_CHECKMEM_CHECK_VERIFY(p, len)
Definition: checkmem.h:85
static SECP256K1_INLINE uint64_t secp256k1_u128_hi_u64(const secp256k1_uint128 *a)
static SECP256K1_INLINE void secp256k1_u128_from_u64(secp256k1_uint128 *r, uint64_t a)
static SECP256K1_INLINE void secp256k1_u128_rshift(secp256k1_uint128 *r, unsigned int n)
static SECP256K1_INLINE void secp256k1_u128_accum_u64(secp256k1_uint128 *r, uint64_t a)
static SECP256K1_INLINE void secp256k1_u128_accum_mul(secp256k1_uint128 *r, uint64_t a, uint64_t b)
static SECP256K1_INLINE uint64_t secp256k1_u128_to_u64(const secp256k1_uint128 *a)
static void secp256k1_modinv64(secp256k1_modinv64_signed62 *x, const secp256k1_modinv64_modinfo *modinfo)
static void secp256k1_modinv64_var(secp256k1_modinv64_signed62 *x, const secp256k1_modinv64_modinfo *modinfo)
#define SECP256K1_SCALAR_VERIFY(r)
Definition: scalar.h:103
static SECP256K1_INLINE int secp256k1_scalar_is_even(const secp256k1_scalar *a)
static SECP256K1_INLINE int secp256k1_scalar_check_overflow(const secp256k1_scalar *a)
static SECP256K1_INLINE void secp256k1_scalar_mul_shift_var(secp256k1_scalar *r, const secp256k1_scalar *a, const secp256k1_scalar *b, unsigned int shift)
static void secp256k1_scalar_half(secp256k1_scalar *r, const secp256k1_scalar *a)
#define SECP256K1_N_3
static void secp256k1_scalar_split_128(secp256k1_scalar *r1, secp256k1_scalar *r2, const secp256k1_scalar *k)
static SECP256K1_INLINE unsigned int secp256k1_scalar_get_bits_var(const secp256k1_scalar *a, unsigned int offset, unsigned int count)
static SECP256K1_INLINE void secp256k1_scalar_clear(secp256k1_scalar *r)
#define extract(n)
Extract the lowest 64 bits of (c0,c1,c2) into n, and left shift the number 64 bits.
#define SECP256K1_N_C_2
static void secp256k1_scalar_set_b32(secp256k1_scalar *r, const unsigned char *b32, int *overflow)
#define SECP256K1_N_C_1
static void secp256k1_scalar_inverse_var(secp256k1_scalar *r, const secp256k1_scalar *x)
static const secp256k1_modinv64_modinfo secp256k1_const_modinfo_scalar
#define sumadd_fast(a)
Add a to the number defined by (c0,c1).
static void secp256k1_scalar_get_b32(unsigned char *bin, const secp256k1_scalar *a)
#define SECP256K1_N_1
static void secp256k1_scalar_reduce_512(secp256k1_scalar *r, const uint64_t *l)
#define SECP256K1_N_2
#define SECP256K1_N_H_2
static void secp256k1_scalar_from_signed62(secp256k1_scalar *r, const secp256k1_modinv64_signed62 *a)
static SECP256K1_INLINE void secp256k1_scalar_set_int(secp256k1_scalar *r, unsigned int v)
static void secp256k1_scalar_mul_512(uint64_t l[8], const secp256k1_scalar *a, const secp256k1_scalar *b)
static void secp256k1_scalar_inverse(secp256k1_scalar *r, const secp256k1_scalar *x)
#define SECP256K1_N_C_0
static SECP256K1_INLINE void secp256k1_scalar_cmov(secp256k1_scalar *r, const secp256k1_scalar *a, int flag)
#define extract_fast(n)
Extract the lowest 64 bits of (c0,c1,c2) into n, and left shift the number 64 bits.
#define muladd(a, b)
Add a*b to the number defined by (c0,c1,c2).
static void secp256k1_scalar_to_signed62(secp256k1_modinv64_signed62 *r, const secp256k1_scalar *a)
#define SECP256K1_N_H_0
static SECP256K1_INLINE int secp256k1_scalar_eq(const secp256k1_scalar *a, const secp256k1_scalar *b)
static int secp256k1_scalar_add(secp256k1_scalar *r, const secp256k1_scalar *a, const secp256k1_scalar *b)
#define sumadd(a)
Add a to the number defined by (c0,c1,c2).
static int secp256k1_scalar_cond_negate(secp256k1_scalar *r, int flag)
static void secp256k1_scalar_mul(secp256k1_scalar *r, const secp256k1_scalar *a, const secp256k1_scalar *b)
#define SECP256K1_N_H_1
static SECP256K1_INLINE int secp256k1_scalar_reduce(secp256k1_scalar *r, unsigned int overflow)
#define SECP256K1_N_0
static void secp256k1_scalar_negate(secp256k1_scalar *r, const secp256k1_scalar *a)
static SECP256K1_INLINE int secp256k1_scalar_is_zero(const secp256k1_scalar *a)
static int secp256k1_scalar_is_high(const secp256k1_scalar *a)
static SECP256K1_INLINE unsigned int secp256k1_scalar_get_bits(const secp256k1_scalar *a, unsigned int offset, unsigned int count)
#define SECP256K1_N_H_3
static void secp256k1_scalar_cadd_bit(secp256k1_scalar *r, unsigned int bit, int flag)
#define muladd_fast(a, b)
Add a*b to the number defined by (c0,c1).
static SECP256K1_INLINE int secp256k1_scalar_is_one(const secp256k1_scalar *a)
#define SECP256K1_INLINE
Definition: util.h:48
static SECP256K1_INLINE void secp256k1_write_be64(unsigned char *p, uint64_t x)
Definition: util.h:383
#define VERIFY_CHECK(cond)
Definition: util.h:153
static SECP256K1_INLINE uint64_t secp256k1_read_be64(const unsigned char *p)
Definition: util.h:371
A scalar modulo the group order of the secp256k1 curve.
Definition: scalar_4x64.h:13
uint64_t d[4]
Definition: scalar_4x64.h:14
static int count