xref: /freebsd/contrib/bearssl/src/ec/ec_c25519_m64.c (revision c66ec88fed842fbaad62c30d510644ceb7bd2d71)
1 /*
2  * Copyright (c) 2018 Thomas Pornin <pornin@bolet.org>
3  *
4  * Permission is hereby granted, free of charge, to any person obtaining
5  * a copy of this software and associated documentation files (the
6  * "Software"), to deal in the Software without restriction, including
7  * without limitation the rights to use, copy, modify, merge, publish,
8  * distribute, sublicense, and/or sell copies of the Software, and to
9  * permit persons to whom the Software is furnished to do so, subject to
10  * the following conditions:
11  *
12  * The above copyright notice and this permission notice shall be
13  * included in all copies or substantial portions of the Software.
14  *
15  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
16  * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
17  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
18  * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
19  * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
20  * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
21  * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
22  * SOFTWARE.
23  */
24 
25 #include "inner.h"
26 
27 #if BR_INT128 || BR_UMUL128
28 
29 #if BR_UMUL128
30 #include <intrin.h>
31 #endif
32 
33 static const unsigned char GEN[] = {
34 	0x09, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
35 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
36 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
37 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00
38 };
39 
40 static const unsigned char ORDER[] = {
41 	0x7F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
42 	0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
43 	0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
44 	0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF
45 };
46 
47 static const unsigned char *
48 api_generator(int curve, size_t *len)
49 {
50 	(void)curve;
51 	*len = 32;
52 	return GEN;
53 }
54 
55 static const unsigned char *
56 api_order(int curve, size_t *len)
57 {
58 	(void)curve;
59 	*len = 32;
60 	return ORDER;
61 }
62 
63 static size_t
64 api_xoff(int curve, size_t *len)
65 {
66 	(void)curve;
67 	*len = 32;
68 	return 0;
69 }
70 
71 /*
72  * A field element is encoded as four 64-bit integers, in basis 2^63.
73  * Operations return partially reduced values, which may range up to
74  * 2^255+37.
75  */
76 
77 #define MASK63   (((uint64_t)1 << 63) - (uint64_t)1)
78 
79 /*
80  * Swap two field elements, conditionally on a flag.
81  */
82 static inline void
83 f255_cswap(uint64_t *a, uint64_t *b, uint32_t ctl)
84 {
85 	uint64_t m, w;
86 
87 	m = -(uint64_t)ctl;
88 	w = m & (a[0] ^ b[0]); a[0] ^= w; b[0] ^= w;
89 	w = m & (a[1] ^ b[1]); a[1] ^= w; b[1] ^= w;
90 	w = m & (a[2] ^ b[2]); a[2] ^= w; b[2] ^= w;
91 	w = m & (a[3] ^ b[3]); a[3] ^= w; b[3] ^= w;
92 }
93 
94 /*
95  * Addition in the field.
96  */
97 static inline void
98 f255_add(uint64_t *d, const uint64_t *a, const uint64_t *b)
99 {
100 #if BR_INT128
101 
102 	uint64_t t0, t1, t2, t3, cc;
103 	unsigned __int128 z;
104 
105 	z = (unsigned __int128)a[0] + (unsigned __int128)b[0];
106 	t0 = (uint64_t)z;
107 	z = (unsigned __int128)a[1] + (unsigned __int128)b[1] + (z >> 64);
108 	t1 = (uint64_t)z;
109 	z = (unsigned __int128)a[2] + (unsigned __int128)b[2] + (z >> 64);
110 	t2 = (uint64_t)z;
111 	z = (unsigned __int128)a[3] + (unsigned __int128)b[3] + (z >> 64);
112 	t3 = (uint64_t)z & MASK63;
113 	cc = (uint64_t)(z >> 63);
114 
115 	/*
116 	 * Since operands are at most 2^255+37, the sum is at most
117 	 * 2^256+74; thus, the carry cc is equal to 0, 1 or 2.
118 	 *
119 	 * We use: 2^255 = 19 mod p.
120 	 * Since we add 0, 19 or 38 to a value that fits on 255 bits,
121 	 * the result is at most 2^255+37.
122 	 */
123 	z = (unsigned __int128)t0 + (unsigned __int128)(19 * cc);
124 	d[0] = (uint64_t)z;
125 	z = (unsigned __int128)t1 + (z >> 64);
126 	d[1] = (uint64_t)z;
127 	z = (unsigned __int128)t2 + (z >> 64);
128 	d[2] = (uint64_t)z;
129 	d[3] = t3 + (uint64_t)(z >> 64);
130 
131 #elif BR_UMUL128
132 
133 	uint64_t t0, t1, t2, t3, cc;
134 	unsigned char k;
135 
136 	k = _addcarry_u64(0, a[0], b[0], &t0);
137 	k = _addcarry_u64(k, a[1], b[1], &t1);
138 	k = _addcarry_u64(k, a[2], b[2], &t2);
139 	k = _addcarry_u64(k, a[3], b[3], &t3);
140 	cc = (k << 1) + (t3 >> 63);
141 	t3 &= MASK63;
142 
143 	/*
144 	 * Since operands are at most 2^255+37, the sum is at most
145 	 * 2^256+74; thus, the carry cc is equal to 0, 1 or 2.
146 	 *
147 	 * We use: 2^255 = 19 mod p.
148 	 * Since we add 0, 19 or 38 to a value that fits on 255 bits,
149 	 * the result is at most 2^255+37.
150 	 */
151 	k = _addcarry_u64(0, t0, 19 * cc, &d[0]);
152 	k = _addcarry_u64(k, t1, 0, &d[1]);
153 	k = _addcarry_u64(k, t2, 0, &d[2]);
154 	(void)_addcarry_u64(k, t3, 0, &d[3]);
155 
156 #endif
157 }
158 
159 /*
160  * Subtraction.
161  * On input, limbs must fit on 60 bits each. On output, result is
162  * partially reduced, with max value 2^255+19456; moreover, all
163  * limbs will fit on 51 bits, except the low limb, which may have
164  * value up to 2^51+19455.
165  */
166 static inline void
167 f255_sub(uint64_t *d, const uint64_t *a, const uint64_t *b)
168 {
169 #if BR_INT128
170 
171 	/*
172 	 * We compute t = 2^256 - 38 + a - b, which is necessarily
173 	 * positive but lower than 2^256 + 2^255, since a <= 2^255 + 37
174 	 * and b <= 2^255 + 37. We then subtract 0, p or 2*p, depending
175 	 * on the two upper bits of t (bits 255 and 256).
176 	 */
177 
178 	uint64_t t0, t1, t2, t3, t4, cc;
179 	unsigned __int128 z;
180 
181 	z = (unsigned __int128)a[0] - (unsigned __int128)b[0] - 38;
182 	t0 = (uint64_t)z;
183 	cc = -(uint64_t)(z >> 64);
184 	z = (unsigned __int128)a[1] - (unsigned __int128)b[1]
185 		- (unsigned __int128)cc;
186 	t1 = (uint64_t)z;
187 	cc = -(uint64_t)(z >> 64);
188 	z = (unsigned __int128)a[2] - (unsigned __int128)b[2]
189 		- (unsigned __int128)cc;
190 	t2 = (uint64_t)z;
191 	cc = -(uint64_t)(z >> 64);
192 	z = (unsigned __int128)a[3] - (unsigned __int128)b[3]
193 		- (unsigned __int128)cc;
194 	t3 = (uint64_t)z;
195 	t4 = 1 + (uint64_t)(z >> 64);
196 
197 	/*
198 	 * We have a 257-bit result. The two top bits can be 00, 01 or 10,
199 	 * but not 11 (value t <= 2^256 - 38 + 2^255 + 37 = 2^256 + 2^255 - 1).
200 	 * Therefore, we can truncate to 255 bits, and add 0, 19 or 38.
201 	 * This guarantees that the result is at most 2^255+37.
202 	 */
203 	cc = (38 & -t4) + (19 & -(t3 >> 63));
204 	t3 &= MASK63;
205 	z = (unsigned __int128)t0 + (unsigned __int128)cc;
206 	d[0] = (uint64_t)z;
207 	z = (unsigned __int128)t1 + (z >> 64);
208 	d[1] = (uint64_t)z;
209 	z = (unsigned __int128)t2 + (z >> 64);
210 	d[2] = (uint64_t)z;
211 	d[3] = t3 + (uint64_t)(z >> 64);
212 
213 #elif BR_UMUL128
214 
215 	/*
216 	 * We compute t = 2^256 - 38 + a - b, which is necessarily
217 	 * positive but lower than 2^256 + 2^255, since a <= 2^255 + 37
218 	 * and b <= 2^255 + 37. We then subtract 0, p or 2*p, depending
219 	 * on the two upper bits of t (bits 255 and 256).
220 	 */
221 
222 	uint64_t t0, t1, t2, t3, t4;
223 	unsigned char k;
224 
225 	k = _subborrow_u64(0, a[0], b[0], &t0);
226 	k = _subborrow_u64(k, a[1], b[1], &t1);
227 	k = _subborrow_u64(k, a[2], b[2], &t2);
228 	k = _subborrow_u64(k, a[3], b[3], &t3);
229 	(void)_subborrow_u64(k, 1, 0, &t4);
230 
231 	k = _subborrow_u64(0, t0, 38, &t0);
232 	k = _subborrow_u64(k, t1, 0, &t1);
233 	k = _subborrow_u64(k, t2, 0, &t2);
234 	k = _subborrow_u64(k, t3, 0, &t3);
235 	(void)_subborrow_u64(k, t4, 0, &t4);
236 
237 	/*
238 	 * We have a 257-bit result. The two top bits can be 00, 01 or 10,
239 	 * but not 11 (value t <= 2^256 - 38 + 2^255 + 37 = 2^256 + 2^255 - 1).
240 	 * Therefore, we can truncate to 255 bits, and add 0, 19 or 38.
241 	 * This guarantees that the result is at most 2^255+37.
242 	 */
243 	t4 = (38 & -t4) + (19 & -(t3 >> 63));
244 	t3 &= MASK63;
245 	k = _addcarry_u64(0, t0, t4, &d[0]);
246 	k = _addcarry_u64(k, t1, 0, &d[1]);
247 	k = _addcarry_u64(k, t2, 0, &d[2]);
248 	(void)_addcarry_u64(k, t3, 0, &d[3]);
249 
250 #endif
251 }
252 
253 /*
254  * Multiplication.
255  */
256 static inline void
257 f255_mul(uint64_t *d, uint64_t *a, uint64_t *b)
258 {
259 #if BR_INT128
260 
261 	unsigned __int128 z;
262 	uint64_t t0, t1, t2, t3, t4, t5, t6, t7, th;
263 
264 	/*
265 	 * Compute the product a*b over plain integers.
266 	 */
267 	z = (unsigned __int128)a[0] * (unsigned __int128)b[0];
268 	t0 = (uint64_t)z;
269 	z = (unsigned __int128)a[0] * (unsigned __int128)b[1] + (z >> 64);
270 	t1 = (uint64_t)z;
271 	z = (unsigned __int128)a[0] * (unsigned __int128)b[2] + (z >> 64);
272 	t2 = (uint64_t)z;
273 	z = (unsigned __int128)a[0] * (unsigned __int128)b[3] + (z >> 64);
274 	t3 = (uint64_t)z;
275 	t4 = (uint64_t)(z >> 64);
276 
277 	z = (unsigned __int128)a[1] * (unsigned __int128)b[0]
278 		+ (unsigned __int128)t1;
279 	t1 = (uint64_t)z;
280 	z = (unsigned __int128)a[1] * (unsigned __int128)b[1]
281 		+ (unsigned __int128)t2 + (z >> 64);
282 	t2 = (uint64_t)z;
283 	z = (unsigned __int128)a[1] * (unsigned __int128)b[2]
284 		+ (unsigned __int128)t3 + (z >> 64);
285 	t3 = (uint64_t)z;
286 	z = (unsigned __int128)a[1] * (unsigned __int128)b[3]
287 		+ (unsigned __int128)t4 + (z >> 64);
288 	t4 = (uint64_t)z;
289 	t5 = (uint64_t)(z >> 64);
290 
291 	z = (unsigned __int128)a[2] * (unsigned __int128)b[0]
292 		+ (unsigned __int128)t2;
293 	t2 = (uint64_t)z;
294 	z = (unsigned __int128)a[2] * (unsigned __int128)b[1]
295 		+ (unsigned __int128)t3 + (z >> 64);
296 	t3 = (uint64_t)z;
297 	z = (unsigned __int128)a[2] * (unsigned __int128)b[2]
298 		+ (unsigned __int128)t4 + (z >> 64);
299 	t4 = (uint64_t)z;
300 	z = (unsigned __int128)a[2] * (unsigned __int128)b[3]
301 		+ (unsigned __int128)t5 + (z >> 64);
302 	t5 = (uint64_t)z;
303 	t6 = (uint64_t)(z >> 64);
304 
305 	z = (unsigned __int128)a[3] * (unsigned __int128)b[0]
306 		+ (unsigned __int128)t3;
307 	t3 = (uint64_t)z;
308 	z = (unsigned __int128)a[3] * (unsigned __int128)b[1]
309 		+ (unsigned __int128)t4 + (z >> 64);
310 	t4 = (uint64_t)z;
311 	z = (unsigned __int128)a[3] * (unsigned __int128)b[2]
312 		+ (unsigned __int128)t5 + (z >> 64);
313 	t5 = (uint64_t)z;
314 	z = (unsigned __int128)a[3] * (unsigned __int128)b[3]
315 		+ (unsigned __int128)t6 + (z >> 64);
316 	t6 = (uint64_t)z;
317 	t7 = (uint64_t)(z >> 64);
318 
319 	/*
320 	 * Modulo p, we have:
321 	 *
322 	 *   2^255 = 19
323 	 *   2^510 = 19*19 = 361
324 	 *
325 	 * We split the intermediate t into three parts, in basis
326 	 * 2^255. The low one will be in t0..t3; the middle one in t4..t7.
327 	 * The upper one can only be a single bit (th), since the
328 	 * multiplication operands are at most 2^255+37 each.
329 	 */
330 	th = t7 >> 62;
331 	t7 = ((t7 << 1) | (t6 >> 63)) & MASK63;
332 	t6 = (t6 << 1) | (t5 >> 63);
333 	t5 = (t5 << 1) | (t4 >> 63);
334 	t4 = (t4 << 1) | (t3 >> 63);
335 	t3 &= MASK63;
336 
337 	/*
338 	 * Multiply the middle part (t4..t7) by 19. We truncate it to
339 	 * 255 bits; the extra bits will go along with th.
340 	 */
341 	z = (unsigned __int128)t4 * 19;
342 	t4 = (uint64_t)z;
343 	z = (unsigned __int128)t5 * 19 + (z >> 64);
344 	t5 = (uint64_t)z;
345 	z = (unsigned __int128)t6 * 19 + (z >> 64);
346 	t6 = (uint64_t)z;
347 	z = (unsigned __int128)t7 * 19 + (z >> 64);
348 	t7 = (uint64_t)z & MASK63;
349 
350 	th = (361 & -th) + (19 * (uint64_t)(z >> 63));
351 
352 	/*
353 	 * Add elements together.
354 	 * At this point:
355 	 *   t0..t3 fits on 255 bits.
356 	 *   t4..t7 fits on 255 bits.
357 	 *   th <= 361 + 342 = 703.
358 	 */
359 	z = (unsigned __int128)t0 + (unsigned __int128)t4
360 		+ (unsigned __int128)th;
361 	t0 = (uint64_t)z;
362 	z = (unsigned __int128)t1 + (unsigned __int128)t5 + (z >> 64);
363 	t1 = (uint64_t)z;
364 	z = (unsigned __int128)t2 + (unsigned __int128)t6 + (z >> 64);
365 	t2 = (uint64_t)z;
366 	z = (unsigned __int128)t3 + (unsigned __int128)t7 + (z >> 64);
367 	t3 = (uint64_t)z & MASK63;
368 	th = (uint64_t)(z >> 63);
369 
370 	/*
371 	 * Since the sum is at most 2^256 + 703, the two upper bits, in th,
372 	 * can only have value 0, 1 or 2. We just add th*19, which
373 	 * guarantees a result of at most 2^255+37.
374 	 */
375 	z = (unsigned __int128)t0 + (19 * th);
376 	d[0] = (uint64_t)z;
377 	z = (unsigned __int128)t1 + (z >> 64);
378 	d[1] = (uint64_t)z;
379 	z = (unsigned __int128)t2 + (z >> 64);
380 	d[2] = (uint64_t)z;
381 	d[3] = t3 + (uint64_t)(z >> 64);
382 
383 #elif BR_UMUL128
384 
385 	uint64_t t0, t1, t2, t3, t4, t5, t6, t7, th;
386 	uint64_t h0, h1, h2, h3;
387 	unsigned char k;
388 
389 	/*
390 	 * Compute the product a*b over plain integers.
391 	 */
392 	t0 = _umul128(a[0], b[0], &h0);
393 	t1 = _umul128(a[0], b[1], &h1);
394 	k = _addcarry_u64(0, t1, h0, &t1);
395 	t2 = _umul128(a[0], b[2], &h2);
396 	k = _addcarry_u64(k, t2, h1, &t2);
397 	t3 = _umul128(a[0], b[3], &h3);
398 	k = _addcarry_u64(k, t3, h2, &t3);
399 	(void)_addcarry_u64(k, h3, 0, &t4);
400 
401 	k = _addcarry_u64(0, _umul128(a[1], b[0], &h0), t1, &t1);
402 	k = _addcarry_u64(k, _umul128(a[1], b[1], &h1), t2, &t2);
403 	k = _addcarry_u64(k, _umul128(a[1], b[2], &h2), t3, &t3);
404 	k = _addcarry_u64(k, _umul128(a[1], b[3], &h3), t4, &t4);
405 	t5 = k;
406 	k = _addcarry_u64(0, t2, h0, &t2);
407 	k = _addcarry_u64(k, t3, h1, &t3);
408 	k = _addcarry_u64(k, t4, h2, &t4);
409 	(void)_addcarry_u64(k, t5, h3, &t5);
410 
411 	k = _addcarry_u64(0, _umul128(a[2], b[0], &h0), t2, &t2);
412 	k = _addcarry_u64(k, _umul128(a[2], b[1], &h1), t3, &t3);
413 	k = _addcarry_u64(k, _umul128(a[2], b[2], &h2), t4, &t4);
414 	k = _addcarry_u64(k, _umul128(a[2], b[3], &h3), t5, &t5);
415 	t6 = k;
416 	k = _addcarry_u64(0, t3, h0, &t3);
417 	k = _addcarry_u64(k, t4, h1, &t4);
418 	k = _addcarry_u64(k, t5, h2, &t5);
419 	(void)_addcarry_u64(k, t6, h3, &t6);
420 
421 	k = _addcarry_u64(0, _umul128(a[3], b[0], &h0), t3, &t3);
422 	k = _addcarry_u64(k, _umul128(a[3], b[1], &h1), t4, &t4);
423 	k = _addcarry_u64(k, _umul128(a[3], b[2], &h2), t5, &t5);
424 	k = _addcarry_u64(k, _umul128(a[3], b[3], &h3), t6, &t6);
425 	t7 = k;
426 	k = _addcarry_u64(0, t4, h0, &t4);
427 	k = _addcarry_u64(k, t5, h1, &t5);
428 	k = _addcarry_u64(k, t6, h2, &t6);
429 	(void)_addcarry_u64(k, t7, h3, &t7);
430 
431 	/*
432 	 * Modulo p, we have:
433 	 *
434 	 *   2^255 = 19
435 	 *   2^510 = 19*19 = 361
436 	 *
437 	 * We split the intermediate t into three parts, in basis
438 	 * 2^255. The low one will be in t0..t3; the middle one in t4..t7.
439 	 * The upper one can only be a single bit (th), since the
440 	 * multiplication operands are at most 2^255+37 each.
441 	 */
442 	th = t7 >> 62;
443 	t7 = ((t7 << 1) | (t6 >> 63)) & MASK63;
444 	t6 = (t6 << 1) | (t5 >> 63);
445 	t5 = (t5 << 1) | (t4 >> 63);
446 	t4 = (t4 << 1) | (t3 >> 63);
447 	t3 &= MASK63;
448 
449 	/*
450 	 * Multiply the middle part (t4..t7) by 19. We truncate it to
451 	 * 255 bits; the extra bits will go along with th.
452 	 */
453 	t4 = _umul128(t4, 19, &h0);
454 	t5 = _umul128(t5, 19, &h1);
455 	t6 = _umul128(t6, 19, &h2);
456 	t7 = _umul128(t7, 19, &h3);
457 	k = _addcarry_u64(0, t5, h0, &t5);
458 	k = _addcarry_u64(k, t6, h1, &t6);
459 	k = _addcarry_u64(k, t7, h2, &t7);
460 	(void)_addcarry_u64(k, h3, 0, &h3);
461 	th = (361 & -th) + (19 * ((h3 << 1) + (t7 >> 63)));
462 	t7 &= MASK63;
463 
464 	/*
465 	 * Add elements together.
466 	 * At this point:
467 	 *   t0..t3 fits on 255 bits.
468 	 *   t4..t7 fits on 255 bits.
469 	 *   th <= 361 + 342 = 703.
470 	 */
471 	k = _addcarry_u64(0, t0, t4, &t0);
472 	k = _addcarry_u64(k, t1, t5, &t1);
473 	k = _addcarry_u64(k, t2, t6, &t2);
474 	k = _addcarry_u64(k, t3, t7, &t3);
475 	t4 = k;
476 	k = _addcarry_u64(0, t0, th, &t0);
477 	k = _addcarry_u64(k, t1, 0, &t1);
478 	k = _addcarry_u64(k, t2, 0, &t2);
479 	k = _addcarry_u64(k, t3, 0, &t3);
480 	(void)_addcarry_u64(k, t4, 0, &t4);
481 
482 	th = (t4 << 1) + (t3 >> 63);
483 	t3 &= MASK63;
484 
485 	/*
486 	 * Since the sum is at most 2^256 + 703, the two upper bits, in th,
487 	 * can only have value 0, 1 or 2. We just add th*19, which
488 	 * guarantees a result of at most 2^255+37.
489 	 */
490 	k = _addcarry_u64(0, t0, 19 * th, &d[0]);
491 	k = _addcarry_u64(k, t1, 0, &d[1]);
492 	k = _addcarry_u64(k, t2, 0, &d[2]);
493 	(void)_addcarry_u64(k, t3, 0, &d[3]);
494 
495 #endif
496 }
497 
498 /*
499  * Multiplication by A24 = 121665.
500  */
501 static inline void
502 f255_mul_a24(uint64_t *d, const uint64_t *a)
503 {
504 #if BR_INT128
505 
506 	uint64_t t0, t1, t2, t3;
507 	unsigned __int128 z;
508 
509 	z = (unsigned __int128)a[0] * 121665;
510 	t0 = (uint64_t)z;
511 	z = (unsigned __int128)a[1] * 121665 + (z >> 64);
512 	t1 = (uint64_t)z;
513 	z = (unsigned __int128)a[2] * 121665 + (z >> 64);
514 	t2 = (uint64_t)z;
515 	z = (unsigned __int128)a[3] * 121665 + (z >> 64);
516 	t3 = (uint64_t)z & MASK63;
517 
518 	z = (unsigned __int128)t0 + (19 * (uint64_t)(z >> 63));
519 	t0 = (uint64_t)z;
520 	z = (unsigned __int128)t1 + (z >> 64);
521 	t1 = (uint64_t)z;
522 	z = (unsigned __int128)t2 + (z >> 64);
523 	t2 = (uint64_t)z;
524 	t3 = t3 + (uint64_t)(z >> 64);
525 
526 	z = (unsigned __int128)t0 + (19 & -(t3 >> 63));
527 	d[0] = (uint64_t)z;
528 	z = (unsigned __int128)t1 + (z >> 64);
529 	d[1] = (uint64_t)z;
530 	z = (unsigned __int128)t2 + (z >> 64);
531 	d[2] = (uint64_t)z;
532 	d[3] = (t3 & MASK63) + (uint64_t)(z >> 64);
533 
534 #elif BR_UMUL128
535 
536 	uint64_t t0, t1, t2, t3, t4, h0, h1, h2, h3;
537 	unsigned char k;
538 
539 	t0 = _umul128(a[0], 121665, &h0);
540 	t1 = _umul128(a[1], 121665, &h1);
541 	k = _addcarry_u64(0, t1, h0, &t1);
542 	t2 = _umul128(a[2], 121665, &h2);
543 	k = _addcarry_u64(k, t2, h1, &t2);
544 	t3 = _umul128(a[3], 121665, &h3);
545 	k = _addcarry_u64(k, t3, h2, &t3);
546 	(void)_addcarry_u64(k, h3, 0, &t4);
547 
548 	t4 = (t4 << 1) + (t3 >> 63);
549 	t3 &= MASK63;
550 	k = _addcarry_u64(0, t0, 19 * t4, &t0);
551 	k = _addcarry_u64(k, t1, 0, &t1);
552 	k = _addcarry_u64(k, t2, 0, &t2);
553 	(void)_addcarry_u64(k, t3, 0, &t3);
554 
555 	t4 = 19 & -(t3 >> 63);
556 	t3 &= MASK63;
557 	k = _addcarry_u64(0, t0, t4, &d[0]);
558 	k = _addcarry_u64(k, t1, 0, &d[1]);
559 	k = _addcarry_u64(k, t2, 0, &d[2]);
560 	(void)_addcarry_u64(k, t3, 0, &d[3]);
561 
562 #endif
563 }
564 
565 /*
566  * Finalize reduction.
567  */
568 static inline void
569 f255_final_reduce(uint64_t *a)
570 {
571 #if BR_INT128
572 
573 	uint64_t t0, t1, t2, t3, m;
574 	unsigned __int128 z;
575 
576 	/*
577 	 * We add 19. If the result (in t) is below 2^255, then a[]
578 	 * is already less than 2^255-19, thus already reduced.
579 	 * Otherwise, we subtract 2^255 from t[], in which case we
580 	 * have t = a - (2^255-19), and that's our result.
581 	 */
582 	z = (unsigned __int128)a[0] + 19;
583 	t0 = (uint64_t)z;
584 	z = (unsigned __int128)a[1] + (z >> 64);
585 	t1 = (uint64_t)z;
586 	z = (unsigned __int128)a[2] + (z >> 64);
587 	t2 = (uint64_t)z;
588 	t3 = a[3] + (uint64_t)(z >> 64);
589 
590 	m = -(t3 >> 63);
591 	t3 &= MASK63;
592 	a[0] ^= m & (a[0] ^ t0);
593 	a[1] ^= m & (a[1] ^ t1);
594 	a[2] ^= m & (a[2] ^ t2);
595 	a[3] ^= m & (a[3] ^ t3);
596 
597 #elif BR_UMUL128
598 
599 	uint64_t t0, t1, t2, t3, m;
600 	unsigned char k;
601 
602 	/*
603 	 * We add 19. If the result (in t) is below 2^255, then a[]
604 	 * is already less than 2^255-19, thus already reduced.
605 	 * Otherwise, we subtract 2^255 from t[], in which case we
606 	 * have t = a - (2^255-19), and that's our result.
607 	 */
608 	k = _addcarry_u64(0, a[0], 19, &t0);
609 	k = _addcarry_u64(k, a[1], 0, &t1);
610 	k = _addcarry_u64(k, a[2], 0, &t2);
611 	(void)_addcarry_u64(k, a[3], 0, &t3);
612 
613 	m = -(t3 >> 63);
614 	t3 &= MASK63;
615 	a[0] ^= m & (a[0] ^ t0);
616 	a[1] ^= m & (a[1] ^ t1);
617 	a[2] ^= m & (a[2] ^ t2);
618 	a[3] ^= m & (a[3] ^ t3);
619 
620 #endif
621 }
622 
623 static uint32_t
624 api_mul(unsigned char *G, size_t Glen,
625 	const unsigned char *kb, size_t kblen, int curve)
626 {
627 	unsigned char k[32];
628 	uint64_t x1[4], x2[4], z2[4], x3[4], z3[4];
629 	uint32_t swap;
630 	int i;
631 
632 	(void)curve;
633 
634 	/*
635 	 * Points are encoded over exactly 32 bytes. Multipliers must fit
636 	 * in 32 bytes as well.
637 	 */
638 	if (Glen != 32 || kblen > 32) {
639 		return 0;
640 	}
641 
642 	/*
643 	 * RFC 7748 mandates that the high bit of the last point byte must
644 	 * be ignored/cleared.
645 	 */
646 	x1[0] = br_dec64le(&G[ 0]);
647 	x1[1] = br_dec64le(&G[ 8]);
648 	x1[2] = br_dec64le(&G[16]);
649 	x1[3] = br_dec64le(&G[24]) & MASK63;
650 
651 	/*
652 	 * We can use memset() to clear values, because exact-width types
653 	 * like uint64_t are guaranteed to have no padding bits or
654 	 * trap representations.
655 	 */
656 	memset(x2, 0, sizeof x2);
657 	x2[0] = 1;
658 	memset(z2, 0, sizeof z2);
659 	memcpy(x3, x1, sizeof x1);
660 	memcpy(z3, x2, sizeof x2);
661 
662 	/*
663 	 * The multiplier is provided in big-endian notation, and
664 	 * possibly shorter than 32 bytes.
665 	 */
666 	memset(k, 0, (sizeof k) - kblen);
667 	memcpy(k + (sizeof k) - kblen, kb, kblen);
668 	k[31] &= 0xF8;
669 	k[0] &= 0x7F;
670 	k[0] |= 0x40;
671 
672 	swap = 0;
673 
674 	for (i = 254; i >= 0; i --) {
675 		uint64_t a[4], aa[4], b[4], bb[4], e[4];
676 		uint64_t c[4], d[4], da[4], cb[4];
677 		uint32_t kt;
678 
679 		kt = (k[31 - (i >> 3)] >> (i & 7)) & 1;
680 		swap ^= kt;
681 		f255_cswap(x2, x3, swap);
682 		f255_cswap(z2, z3, swap);
683 		swap = kt;
684 
685 		/* A = x_2 + z_2 */
686 		f255_add(a, x2, z2);
687 
688 		/* AA = A^2 */
689 		f255_mul(aa, a, a);
690 
691 		/* B = x_2 - z_2 */
692 		f255_sub(b, x2, z2);
693 
694 		/* BB = B^2 */
695 		f255_mul(bb, b, b);
696 
697 		/* E = AA - BB */
698 		f255_sub(e, aa, bb);
699 
700 		/* C = x_3 + z_3 */
701 		f255_add(c, x3, z3);
702 
703 		/* D = x_3 - z_3 */
704 		f255_sub(d, x3, z3);
705 
706 		/* DA = D * A */
707 		f255_mul(da, d, a);
708 
709 		/* CB = C * B */
710 		f255_mul(cb, c, b);
711 
712 		/* x_3 = (DA + CB)^2 */
713 		f255_add(x3, da, cb);
714 		f255_mul(x3, x3, x3);
715 
716 		/* z_3 = x_1 * (DA - CB)^2 */
717 		f255_sub(z3, da, cb);
718 		f255_mul(z3, z3, z3);
719 		f255_mul(z3, x1, z3);
720 
721 		/* x_2 = AA * BB */
722 		f255_mul(x2, aa, bb);
723 
724 		/* z_2 = E * (AA + a24 * E) */
725 		f255_mul_a24(z2, e);
726 		f255_add(z2, aa, z2);
727 		f255_mul(z2, e, z2);
728 	}
729 
730 	f255_cswap(x2, x3, swap);
731 	f255_cswap(z2, z3, swap);
732 
733 	/*
734 	 * Compute 1/z2 = z2^(p-2). Since p = 2^255-19, we can mutualize
735 	 * most non-squarings. We use x1 and x3, now useless, as temporaries.
736 	 */
737 	memcpy(x1, z2, sizeof z2);
738 	for (i = 0; i < 15; i ++) {
739 		f255_mul(x1, x1, x1);
740 		f255_mul(x1, x1, z2);
741 	}
742 	memcpy(x3, x1, sizeof x1);
743 	for (i = 0; i < 14; i ++) {
744 		int j;
745 
746 		for (j = 0; j < 16; j ++) {
747 			f255_mul(x3, x3, x3);
748 		}
749 		f255_mul(x3, x3, x1);
750 	}
751 	for (i = 14; i >= 0; i --) {
752 		f255_mul(x3, x3, x3);
753 		if ((0xFFEB >> i) & 1) {
754 			f255_mul(x3, z2, x3);
755 		}
756 	}
757 
758 	/*
759 	 * Compute x2/z2. We have 1/z2 in x3.
760 	 */
761 	f255_mul(x2, x2, x3);
762 	f255_final_reduce(x2);
763 
764 	/*
765 	 * Encode the final x2 value in little-endian.
766 	 */
767 	br_enc64le(G,      x2[0]);
768 	br_enc64le(G +  8, x2[1]);
769 	br_enc64le(G + 16, x2[2]);
770 	br_enc64le(G + 24, x2[3]);
771 	return 1;
772 }
773 
774 static size_t
775 api_mulgen(unsigned char *R,
776 	const unsigned char *x, size_t xlen, int curve)
777 {
778 	const unsigned char *G;
779 	size_t Glen;
780 
781 	G = api_generator(curve, &Glen);
782 	memcpy(R, G, Glen);
783 	api_mul(R, Glen, x, xlen, curve);
784 	return Glen;
785 }
786 
787 static uint32_t
788 api_muladd(unsigned char *A, const unsigned char *B, size_t len,
789 	const unsigned char *x, size_t xlen,
790 	const unsigned char *y, size_t ylen, int curve)
791 {
792 	/*
793 	 * We don't implement this method, since it is used for ECDSA
794 	 * only, and there is no ECDSA over Curve25519 (which instead
795 	 * uses EdDSA).
796 	 */
797 	(void)A;
798 	(void)B;
799 	(void)len;
800 	(void)x;
801 	(void)xlen;
802 	(void)y;
803 	(void)ylen;
804 	(void)curve;
805 	return 0;
806 }
807 
808 /* see bearssl_ec.h */
809 const br_ec_impl br_ec_c25519_m64 = {
810 	(uint32_t)0x20000000,
811 	&api_generator,
812 	&api_order,
813 	&api_xoff,
814 	&api_mul,
815 	&api_mulgen,
816 	&api_muladd
817 };
818 
819 /* see bearssl_ec.h */
820 const br_ec_impl *
821 br_ec_c25519_m64_get(void)
822 {
823 	return &br_ec_c25519_m64;
824 }
825 
826 #else
827 
828 /* see bearssl_ec.h */
829 const br_ec_impl *
830 br_ec_c25519_m64_get(void)
831 {
832 	return 0;
833 }
834 
835 #endif
836