FFmpeg  4.3
camellia.c
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1 /*
2  * An implementation of the CAMELLIA algorithm as mentioned in RFC3713
3  * Copyright (c) 2014 Supraja Meedinti
4  *
5  * This file is part of FFmpeg.
6  *
7  * FFmpeg is free software; you can redistribute it and/or
8  * modify it under the terms of the GNU Lesser General Public
9  * License as published by the Free Software Foundation; either
10  * version 2.1 of the License, or (at your option) any later version.
11  *
12  * FFmpeg is distributed in the hope that it will be useful,
13  * but WITHOUT ANY WARRANTY; without even the implied warranty of
14  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
15  * Lesser General Public License for more details.
16  *
17  * You should have received a copy of the GNU Lesser General Public
18  * License along with FFmpeg; if not, write to the Free Software
19  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
20  */
21 #include "camellia.h"
22 #include "common.h"
23 #include "intreadwrite.h"
24 #include "attributes.h"
25 
26 #define LR32(x,c) ((x) << (c) | (x) >> (32 - (c)))
27 #define RR32(x,c) ((x) >> (c) | (x) << (32 - (c)))
28 
29 #define MASK8 0xff
30 #define MASK32 0xffffffff
31 #define MASK64 0xffffffffffffffff
32 
33 #define Sigma1 0xA09E667F3BCC908B
34 #define Sigma2 0xB67AE8584CAA73B2
35 #define Sigma3 0xC6EF372FE94F82BE
36 #define Sigma4 0x54FF53A5F1D36F1C
37 #define Sigma5 0x10E527FADE682D1D
38 #define Sigma6 0xB05688C2B3E6C1FD
39 
40 static uint64_t SP[8][256];
41 
42 typedef struct AVCAMELLIA {
43  uint64_t Kw[4];
44  uint64_t Ke[6];
45  uint64_t K[24];
46  int key_bits;
47 } AVCAMELLIA;
48 
49 static const uint8_t SBOX1[256] = {
50 112, 130, 44, 236, 179, 39, 192, 229, 228, 133, 87, 53, 234, 12, 174, 65,
51  35, 239, 107, 147, 69, 25, 165, 33, 237, 14, 79, 78, 29, 101, 146, 189,
52 134, 184, 175, 143, 124, 235, 31, 206, 62, 48, 220, 95, 94, 197, 11, 26,
53 166, 225, 57, 202, 213, 71, 93, 61, 217, 1, 90, 214, 81, 86, 108, 77,
54 139, 13, 154, 102, 251, 204, 176, 45, 116, 18, 43, 32, 240, 177, 132, 153,
55 223, 76, 203, 194, 52, 126, 118, 5, 109, 183, 169, 49, 209, 23, 4, 215,
56  20, 88, 58, 97, 222, 27, 17, 28, 50, 15, 156, 22, 83, 24, 242, 34,
57 254, 68, 207, 178, 195, 181, 122, 145, 36, 8, 232, 168, 96, 252, 105, 80,
58 170, 208, 160, 125, 161, 137, 98, 151, 84, 91, 30, 149, 224, 255, 100, 210,
59  16, 196, 0, 72, 163, 247, 117, 219, 138, 3, 230, 218, 9, 63, 221, 148,
60 135, 92, 131, 2, 205, 74, 144, 51, 115, 103, 246, 243, 157, 127, 191, 226,
61  82, 155, 216, 38, 200, 55, 198, 59, 129, 150, 111, 75, 19, 190, 99, 46,
62 233, 121, 167, 140, 159, 110, 188, 142, 41, 245, 249, 182, 47, 253, 180, 89,
63 120, 152, 6, 106, 231, 70, 113, 186, 212, 37, 171, 66, 136, 162, 141, 250,
64 114, 7, 185, 85, 248, 238, 172, 10, 54, 73, 42, 104, 60, 56, 241, 164,
65  64, 40, 211, 123, 187, 201, 67, 193, 21, 227, 173, 244, 119, 199, 128, 158
66 };
67 
68 static const uint8_t SBOX2[256] = {
69 224, 5, 88, 217, 103, 78, 129, 203, 201, 11, 174, 106, 213, 24, 93, 130,
70  70, 223, 214, 39, 138, 50, 75, 66, 219, 28, 158, 156, 58, 202, 37, 123,
71  13, 113, 95, 31, 248, 215, 62, 157, 124, 96, 185, 190, 188, 139, 22, 52,
72  77, 195, 114, 149, 171, 142, 186, 122, 179, 2, 180, 173, 162, 172, 216, 154,
73  23, 26, 53, 204, 247, 153, 97, 90, 232, 36, 86, 64, 225, 99, 9, 51,
74 191, 152, 151, 133, 104, 252, 236, 10, 218, 111, 83, 98, 163, 46, 8, 175,
75  40, 176, 116, 194, 189, 54, 34, 56, 100, 30, 57, 44, 166, 48, 229, 68,
76 253, 136, 159, 101, 135, 107, 244, 35, 72, 16, 209, 81, 192, 249, 210, 160,
77  85, 161, 65, 250, 67, 19, 196, 47, 168, 182, 60, 43, 193, 255, 200, 165,
78  32, 137, 0, 144, 71, 239, 234, 183, 21, 6, 205, 181, 18, 126, 187, 41,
79  15, 184, 7, 4, 155, 148, 33, 102, 230, 206, 237, 231, 59, 254, 127, 197,
80 164, 55, 177, 76, 145, 110, 141, 118, 3, 45, 222, 150, 38, 125, 198, 92,
81 211, 242, 79, 25, 63, 220, 121, 29, 82, 235, 243, 109, 94, 251, 105, 178,
82 240, 49, 12, 212, 207, 140, 226, 117, 169, 74, 87, 132, 17, 69, 27, 245,
83 228, 14, 115, 170, 241, 221, 89, 20, 108, 146, 84, 208, 120, 112, 227, 73,
84 128, 80, 167, 246, 119, 147, 134, 131, 42, 199, 91, 233, 238, 143, 1, 61
85 };
86 
87 static const uint8_t SBOX3[256] = {
88  56, 65, 22, 118, 217, 147, 96, 242, 114, 194, 171, 154, 117, 6, 87, 160,
89 145, 247, 181, 201, 162, 140, 210, 144, 246, 7, 167, 39, 142, 178, 73, 222,
90  67, 92, 215, 199, 62, 245, 143, 103, 31, 24, 110, 175, 47, 226, 133, 13,
91  83, 240, 156, 101, 234, 163, 174, 158, 236, 128, 45, 107, 168, 43, 54, 166,
92 197, 134, 77, 51, 253, 102, 88, 150, 58, 9, 149, 16, 120, 216, 66, 204,
93 239, 38, 229, 97, 26, 63, 59, 130, 182, 219, 212, 152, 232, 139, 2, 235,
94  10, 44, 29, 176, 111, 141, 136, 14, 25, 135, 78, 11, 169, 12, 121, 17,
95 127, 34, 231, 89, 225, 218, 61, 200, 18, 4, 116, 84, 48, 126, 180, 40,
96  85, 104, 80, 190, 208, 196, 49, 203, 42, 173, 15, 202, 112, 255, 50, 105,
97  8, 98, 0, 36, 209, 251, 186, 237, 69, 129, 115, 109, 132, 159, 238, 74,
98 195, 46, 193, 1, 230, 37, 72, 153, 185, 179, 123, 249, 206, 191, 223, 113,
99  41, 205, 108, 19, 100, 155, 99, 157, 192, 75, 183, 165, 137, 95, 177, 23,
100 244, 188, 211, 70, 207, 55, 94, 71, 148, 250, 252, 91, 151, 254, 90, 172,
101  60, 76, 3, 53, 243, 35, 184, 93, 106, 146, 213, 33, 68, 81, 198, 125,
102  57, 131, 220, 170, 124, 119, 86, 5, 27, 164, 21, 52, 30, 28, 248, 82,
103  32, 20, 233, 189, 221, 228, 161, 224, 138, 241, 214, 122, 187, 227, 64, 79
104 };
105 
106 static const uint8_t SBOX4[256] = {
107 112, 44, 179, 192, 228, 87, 234, 174, 35, 107, 69, 165, 237, 79, 29, 146,
108 134, 175, 124, 31, 62, 220, 94, 11, 166, 57, 213, 93, 217, 90, 81, 108,
109 139, 154, 251, 176, 116, 43, 240, 132, 223, 203, 52, 118, 109, 169, 209, 4,
110  20, 58, 222, 17, 50, 156, 83, 242, 254, 207, 195, 122, 36, 232, 96, 105,
111 170, 160, 161, 98, 84, 30, 224, 100, 16, 0, 163, 117, 138, 230, 9, 221,
112 135, 131, 205, 144, 115, 246, 157, 191, 82, 216, 200, 198, 129, 111, 19, 99,
113 233, 167, 159, 188, 41, 249, 47, 180, 120, 6, 231, 113, 212, 171, 136, 141,
114 114, 185, 248, 172, 54, 42, 60, 241, 64, 211, 187, 67, 21, 173, 119, 128,
115 130, 236, 39, 229, 133, 53, 12, 65, 239, 147, 25, 33, 14, 78, 101, 189,
116 184, 143, 235, 206, 48, 95, 197, 26, 225, 202, 71, 61, 1, 214, 86, 77,
117  13, 102, 204, 45, 18, 32, 177, 153, 76, 194, 126, 5, 183, 49, 23, 215,
118  88, 97, 27, 28, 15, 22, 24, 34, 68, 178, 181, 145, 8, 168, 252, 80,
119 208, 125, 137, 151, 91, 149, 255, 210, 196, 72, 247, 219, 3, 218, 63, 148,
120  92, 2, 74, 51, 103, 243, 127, 226, 155, 38, 55, 59, 150, 75, 190, 46,
121 121, 140, 110, 142, 245, 182, 253, 89, 152, 106, 70, 186, 37, 66, 162, 250,
122  7, 85, 238, 10, 73, 104, 56, 164, 40, 123, 201, 193, 227, 244, 199, 158
123 };
124 
125 const int av_camellia_size = sizeof(AVCAMELLIA);
126 
127 static void LR128(uint64_t d[2], const uint64_t K[2], int x)
128 {
129  int i = 0;
130  if (64 <= x && x < 128) {
131  i = 1;
132  x -= 64;
133  }
134  if (x <= 0 || x >= 128) {
135  d[0] = K[i];
136  d[1] = K[!i];
137  return;
138  }
139  d[0] = (K[i] << x | K[!i] >> (64 - x));
140  d[1] = (K[!i] << x | K[i] >> (64 - x));
141 }
142 
143 static uint64_t F(uint64_t F_IN, uint64_t KE)
144 {
145  KE ^= F_IN;
146  F_IN=SP[0][KE >> 56]^SP[1][(KE >> 48) & MASK8]^SP[2][(KE >> 40) & MASK8]^SP[3][(KE >> 32) & MASK8]^SP[4][(KE >> 24) & MASK8]^SP[5][(KE >> 16) & MASK8]^SP[6][(KE >> 8) & MASK8]^SP[7][KE & MASK8];
147  return F_IN;
148 }
149 
150 static uint64_t FL(uint64_t FL_IN, uint64_t KE)
151 {
152  uint32_t x1, x2, k1, k2;
153  x1 = FL_IN >> 32;
154  x2 = FL_IN & MASK32;
155  k1 = KE >> 32;
156  k2 = KE & MASK32;
157  x2 = x2 ^ LR32((x1 & k1), 1);
158  x1 = x1 ^ (x2 | k2);
159  return ((uint64_t)x1 << 32) | (uint64_t)x2;
160 }
161 
162 static uint64_t FLINV(uint64_t FLINV_IN, uint64_t KE)
163 {
164  uint32_t x1, x2, k1, k2;
165  x1 = FLINV_IN >> 32;
166  x2 = FLINV_IN & MASK32;
167  k1 = KE >> 32;
168  k2 = KE & MASK32;
169  x1 = x1 ^ (x2 | k2);
170  x2 = x2 ^ LR32((x1 & k1), 1);
171  return ((uint64_t)x1 << 32) | (uint64_t)x2;
172 }
173 
174 static const uint8_t shifts[2][12] = {
175  {0, 15, 15, 45, 45, 60, 94, 94, 111},
176  {0, 15, 15, 30, 45, 45, 60, 60, 77, 94, 94, 111}
177 };
178 
179 static const uint8_t vars[2][12] = {
180  {2, 0, 2, 0, 2, 2, 0, 2, 0},
181  {3, 1, 2, 3, 0, 2, 1, 3, 0, 1, 2, 0}
182 };
183 
184 static void generate_round_keys(AVCAMELLIA *cs, uint64_t Kl[2], uint64_t Kr[2], uint64_t Ka[2], uint64_t Kb[2])
185 {
186  int i;
187  uint64_t *Kd[4], d[2];
188  Kd[0] = Kl;
189  Kd[1] = Kr;
190  Kd[2] = Ka;
191  Kd[3] = Kb;
192  cs->Kw[0] = Kl[0];
193  cs->Kw[1] = Kl[1];
194  if (cs->key_bits == 128) {
195  for (i = 0; i < 9; i++) {
196  LR128(d, Kd[vars[0][i]], shifts[0][i]);
197  cs->K[2*i] = d[0];
198  cs->K[2*i+1] = d[1];
199  }
200  LR128(d, Kd[0], 60);
201  cs->K[9] = d[1];
202  LR128(d, Kd[2], 30);
203  cs->Ke[0] = d[0];
204  cs->Ke[1] = d[1];
205  LR128(d, Kd[0], 77);
206  cs->Ke[2] = d[0];
207  cs->Ke[3] = d[1];
208  LR128(d, Kd[2], 111);
209  cs->Kw[2] = d[0];
210  cs->Kw[3] = d[1];
211  } else {
212  for (i = 0; i < 12; i++) {
213  LR128(d, Kd[vars[1][i]], shifts[1][i]);
214  cs->K[2*i] = d[0];
215  cs->K[2*i+1] = d[1];
216  }
217  LR128(d, Kd[1], 30);
218  cs->Ke[0] = d[0];
219  cs->Ke[1] = d[1];
220  LR128(d, Kd[0], 60);
221  cs->Ke[2] = d[0];
222  cs->Ke[3] = d[1];
223  LR128(d, Kd[2], 77);
224  cs->Ke[4] = d[0];
225  cs->Ke[5] = d[1];
226  LR128(d, Kd[3], 111);
227  cs->Kw[2] = d[0];
228  cs->Kw[3] = d[1];
229  }
230 }
231 
232 static void camellia_encrypt(AVCAMELLIA *cs, uint8_t *dst, const uint8_t *src)
233 {
234  uint64_t D1, D2;
235  D1 = AV_RB64(src);
236  D2 = AV_RB64(src + 8);
237  D1 ^= cs->Kw[0];
238  D2 ^= cs->Kw[1];
239  D2 ^= F(D1, cs->K[0]);
240  D1 ^= F(D2, cs->K[1]);
241  D2 ^= F(D1, cs->K[2]);
242  D1 ^= F(D2, cs->K[3]);
243  D2 ^= F(D1, cs->K[4]);
244  D1 ^= F(D2, cs->K[5]);
245  D1 = FL(D1, cs->Ke[0]);
246  D2 = FLINV(D2, cs->Ke[1]);
247  D2 ^= F(D1, cs->K[6]);
248  D1 ^= F(D2, cs->K[7]);
249  D2 ^= F(D1, cs->K[8]);
250  D1 ^= F(D2, cs->K[9]);
251  D2 ^= F(D1, cs->K[10]);
252  D1 ^= F(D2, cs->K[11]);
253  D1 = FL(D1, cs->Ke[2]);
254  D2 = FLINV(D2, cs->Ke[3]);
255  D2 ^= F(D1, cs->K[12]);
256  D1 ^= F(D2, cs->K[13]);
257  D2 ^= F(D1, cs->K[14]);
258  D1 ^= F(D2, cs->K[15]);
259  D2 ^= F(D1, cs->K[16]);
260  D1 ^= F(D2, cs->K[17]);
261  if (cs->key_bits != 128) {
262  D1 = FL(D1, cs->Ke[4]);
263  D2 = FLINV(D2, cs->Ke[5]);
264  D2 ^= F(D1, cs->K[18]);
265  D1 ^= F(D2, cs->K[19]);
266  D2 ^= F(D1, cs->K[20]);
267  D1 ^= F(D2, cs->K[21]);
268  D2 ^= F(D1, cs->K[22]);
269  D1 ^= F(D2, cs->K[23]);
270  }
271  D2 ^= cs->Kw[2];
272  D1 ^= cs->Kw[3];
273  AV_WB64(dst, D2);
274  AV_WB64(dst + 8, D1);
275 }
276 
277 static void camellia_decrypt(AVCAMELLIA *cs, uint8_t *dst, const uint8_t *src, uint8_t *iv)
278 {
279  uint64_t D1, D2;
280  D1 = AV_RB64(src);
281  D2 = AV_RB64(src + 8);
282  D1 ^= cs->Kw[2];
283  D2 ^= cs->Kw[3];
284  if (cs->key_bits != 128) {
285  D2 ^= F(D1, cs->K[23]);
286  D1 ^= F(D2, cs->K[22]);
287  D2 ^= F(D1, cs->K[21]);
288  D1 ^= F(D2, cs->K[20]);
289  D2 ^= F(D1, cs->K[19]);
290  D1 ^= F(D2, cs->K[18]);
291  D1 = FL(D1, cs->Ke[5]);
292  D2 = FLINV(D2, cs->Ke[4]);
293  }
294  D2 ^= F(D1, cs->K[17]);
295  D1 ^= F(D2, cs->K[16]);
296  D2 ^= F(D1, cs->K[15]);
297  D1 ^= F(D2, cs->K[14]);
298  D2 ^= F(D1, cs->K[13]);
299  D1 ^= F(D2, cs->K[12]);
300  D1 = FL(D1, cs->Ke[3]);
301  D2 = FLINV(D2, cs->Ke[2]);
302  D2 ^= F(D1, cs->K[11]);
303  D1 ^= F(D2, cs->K[10]);
304  D2 ^= F(D1, cs->K[9]);
305  D1 ^= F(D2, cs->K[8]);
306  D2 ^= F(D1, cs->K[7]);
307  D1 ^= F(D2, cs->K[6]);
308  D1 = FL(D1, cs->Ke[1]);
309  D2 = FLINV(D2, cs->Ke[0]);
310  D2 ^= F(D1, cs->K[5]);
311  D1 ^= F(D2, cs->K[4]);
312  D2 ^= F(D1, cs->K[3]);
313  D1 ^= F(D2, cs->K[2]);
314  D2 ^= F(D1, cs->K[1]);
315  D1 ^= F(D2, cs->K[0]);
316  D2 ^= cs->Kw[0];
317  D1 ^= cs->Kw[1];
318  if (iv) {
319  D2 ^= AV_RB64(iv);
320  D1 ^= AV_RB64(iv + 8);
321  memcpy(iv, src, 16);
322  }
323  AV_WB64(dst, D2);
324  AV_WB64(dst + 8, D1);
325 }
326 
327 static void computeSP(void)
328 {
329  uint64_t z;
330  int i;
331  for (i = 0; i < 256; i++) {
332  z = SBOX1[i];
333  SP[0][i] = (z << 56) ^ (z << 48) ^ (z << 40) ^ (z << 24) ^ z;
334  SP[7][i] = (z << 56) ^ (z << 48) ^ (z << 40) ^ (z << 24) ^ (z << 16) ^ (z << 8);
335  z = SBOX2[i];
336  SP[1][i] = (z << 48) ^ (z << 40) ^ (z << 32) ^ (z << 24) ^ (z << 16);
337  SP[4][i] = (z << 48) ^ (z << 40) ^ (z << 32) ^ (z << 16) ^ (z << 8) ^ z;
338  z = SBOX3[i];
339  SP[2][i] = (z << 56) ^ (z << 40) ^ (z << 32) ^ (z << 16) ^ (z << 8);
340  SP[5][i] = (z << 56) ^ (z << 40) ^ (z << 32) ^ (z << 24) ^ (z << 8) ^ z;
341  z = SBOX4[i];
342  SP[3][i] = (z << 56) ^ (z << 48) ^ (z << 32) ^ (z << 8) ^ z;
343  SP[6][i] = (z << 56) ^ (z << 48) ^ (z << 32) ^ (z << 24) ^ (z << 16) ^ z;
344  }
345 }
346 
348 {
349  return av_mallocz(sizeof(struct AVCAMELLIA));
350 }
351 
353 {
354  uint64_t Kl[2], Kr[2], Ka[2], Kb[2];
355  uint64_t D1, D2;
356  if (key_bits != 128 && key_bits != 192 && key_bits != 256)
357  return AVERROR(EINVAL);
358  memset(Kb, 0, sizeof(Kb));
359  memset(Kr, 0, sizeof(Kr));
360  cs->key_bits = key_bits;
361  Kl[0] = AV_RB64(key);
362  Kl[1] = AV_RB64(key + 8);
363  if (key_bits == 192) {
364  Kr[0] = AV_RB64(key + 16);
365  Kr[1] = ~Kr[0];
366  } else if (key_bits == 256) {
367  Kr[0] = AV_RB64(key + 16);
368  Kr[1] = AV_RB64(key + 24);
369  }
370  computeSP();
371  D1 = Kl[0] ^ Kr[0];
372  D2 = Kl[1] ^ Kr[1];
373  D2 ^= F(D1, Sigma1);
374  D1 ^= F(D2, Sigma2);
375  D1 ^= Kl[0];
376  D2 ^= Kl[1];
377  D2 ^= F(D1, Sigma3);
378  D1 ^= F(D2, Sigma4);
379  Ka[0] = D1;
380  Ka[1] = D2;
381  if (key_bits != 128) {
382  D1 = Ka[0] ^ Kr[0];
383  D2 = Ka[1] ^ Kr[1];
384  D2 ^= F(D1, Sigma5);
385  D1 ^= F(D2, Sigma6);
386  Kb[0] = D1;
387  Kb[1] = D2;
388  }
389  generate_round_keys(cs, Kl, Kr, Ka, Kb);
390  return 0;
391 }
392 
393 void av_camellia_crypt(AVCAMELLIA *cs, uint8_t *dst, const uint8_t *src, int count, uint8_t *iv, int decrypt)
394 {
395  int i;
396  while (count--) {
397  if (decrypt) {
398  camellia_decrypt(cs, dst, src, iv);
399  } else {
400  if (iv) {
401  for (i = 0; i < 16; i++)
402  dst[i] = src[i] ^ iv[i];
403  camellia_encrypt(cs, dst, dst);
404  memcpy(iv, dst, 16);
405  } else {
406  camellia_encrypt(cs, dst, src);
407  }
408  }
409  src = src + 16;
410  dst = dst + 16;
411  }
412 }
Sigma2
#define Sigma2
Definition: camellia.c:34
AVERROR
Filter the word “frame” indicates either a video frame or a group of audio as stored in an AVFrame structure Format for each input and each output the list of supported formats For video that means pixel format For audio that means channel sample they are references to shared objects When the negotiation mechanism computes the intersection of the formats supported at each end of a all references to both lists are replaced with a reference to the intersection And when a single format is eventually chosen for a link amongst the remaining all references to the list are updated That means that if a filter requires that its input and output have the same format amongst a supported all it has to do is use a reference to the same list of formats query_formats can leave some formats unset and return AVERROR(EAGAIN) to cause the negotiation mechanism toagain later. That can be used by filters with complex requirements to use the format negotiated on one link to set the formats supported on another. Frame references ownership and permissions
MASK8
#define MASK8
Definition: camellia.c:29
av_camellia_alloc
struct AVCAMELLIA * av_camellia_alloc(void)
Allocate an AVCAMELLIA context To free the struct: av_free(ptr)
Definition: camellia.c:347
SBOX2
static const uint8_t SBOX2[256]
Definition: camellia.c:68
AVCAMELLIA::K
uint64_t K[24]
Definition: camellia.c:45
AVCAMELLIA
Definition: camellia.c:42
computeSP
static void computeSP(void)
Definition: camellia.c:327
AV_WB64
#define AV_WB64(p, v)
Definition: intreadwrite.h:433
Sigma6
#define Sigma6
Definition: camellia.c:38
LR128
static void LR128(uint64_t d[2], const uint64_t K[2], int x)
Definition: camellia.c:127
x
FFmpeg Automated Testing Environment ************************************Introduction Using FATE from your FFmpeg source directory Submitting the results to the FFmpeg result aggregation server Uploading new samples to the fate suite FATE makefile targets and variables Makefile targets Makefile variables Examples Introduction **************FATE is an extended regression suite on the client side and a means for results aggregation and presentation on the server side The first part of this document explains how you can use FATE from your FFmpeg source directory to test your ffmpeg binary The second part describes how you can run FATE to submit the results to FFmpeg’s FATE server In any way you can have a look at the publicly viewable FATE results by visiting this as it can be seen if some test on some platform broke with their recent contribution This usually happens on the platforms the developers could not test on The second part of this document describes how you can run FATE to submit your results to FFmpeg’s FATE server If you want to submit your results be sure to check that your combination of OS and compiler is not already listed on the above mentioned website In the third part you can find a comprehensive listing of FATE makefile targets and variables Using FATE from your FFmpeg source directory **********************************************If you want to run FATE on your machine you need to have the samples in place You can get the samples via the build target fate rsync Use this command from the top level source this will cause FATE to fail NOTE To use a custom wrapper to run the pass ‘ target exec’ to ‘configure’ or set the TARGET_EXEC Make variable Submitting the results to the FFmpeg result aggregation server ****************************************************************To submit your results to the server you should run fate through the shell script ‘tests fate sh’ from the FFmpeg sources This script needs to be invoked with a configuration file as its first argument tests fate sh path to fate_config A configuration file template with comments describing the individual configuration variables can be found at ‘doc fate_config sh template’ Create a configuration that suits your based on the configuration template The ‘slot’ configuration variable can be any string that is not yet but it is suggested that you name it adhering to the following pattern ‘ARCH OS COMPILER COMPILER VERSION’ The configuration file itself will be sourced in a shell therefore all shell features may be used This enables you to setup the environment as you need it for your build For your first test runs the ‘fate_recv’ variable should be empty or commented out This will run everything as normal except that it will omit the submission of the results to the server The following files should be present in $workdir as specified in the configuration it may help to try out the ‘ssh’ command with one or more ‘ v’ options You should get detailed output concerning your SSH configuration and the authentication process The only thing left is to automate the execution of the fate sh script and the synchronisation of the samples directory Uploading new samples to the fate suite *****************************************If you need a sample uploaded send a mail to samples request This is for developers who have an account on the fate suite server If you upload new please make sure they are as small as space on each network bandwidth and so on benefit from smaller test cases Also keep in mind older checkouts use existing sample that means in practice generally do not remove or overwrite files as it likely would break older checkouts or releases Also all needed samples for a commit should be ideally before the push If you need an account for frequently uploading samples or you wish to help others by doing that send a mail to ffmpeg devel rsync vauL Duo x
Definition: fate.txt:150
Sigma4
#define Sigma4
Definition: camellia.c:36
av_camellia_crypt
void av_camellia_crypt(AVCAMELLIA *cs, uint8_t *dst, const uint8_t *src, int count, uint8_t *iv, int decrypt)
Encrypt or decrypt a buffer using a previously initialized context.
Definition: camellia.c:393
av_cold
#define av_cold
Definition: attributes.h:90
Sigma1
#define Sigma1
Definition: camellia.c:33
AV_RB64
#define AV_RB64
Definition: intreadwrite.h:164
intreadwrite.h
av_camellia_init
av_cold int av_camellia_init(AVCAMELLIA *cs, const uint8_t *key, int key_bits)
Initialize an AVCAMELLIA context.
Definition: camellia.c:352
av_camellia_size
const int av_camellia_size
Definition: camellia.c:125
av_mallocz
void * av_mallocz(size_t size)
Allocate a memory block with alignment suitable for all memory accesses (including vectors if availab...
Definition: mem.c:237
key
const char * key
Definition: hwcontext_opencl.c:168
vars
static const uint8_t vars[2][12]
Definition: camellia.c:179
SBOX3
static const uint8_t SBOX3[256]
Definition: camellia.c:87
src
#define src
Definition: vp8dsp.c:254
generate_round_keys
static void generate_round_keys(AVCAMELLIA *cs, uint64_t Kl[2], uint64_t Kr[2], uint64_t Ka[2], uint64_t Kb[2])
Definition: camellia.c:184
LR32
#define LR32(x, c)
Definition: camellia.c:26
AVCAMELLIA::Ke
uint64_t Ke[6]
Definition: camellia.c:44
camellia_decrypt
static void camellia_decrypt(AVCAMELLIA *cs, uint8_t *dst, const uint8_t *src, uint8_t *iv)
Definition: camellia.c:277
attributes.h
FLINV
static uint64_t FLINV(uint64_t FLINV_IN, uint64_t KE)
Definition: camellia.c:162
AVCAMELLIA::Kw
uint64_t Kw[4]
Definition: camellia.c:43
SBOX1
static const uint8_t SBOX1[256]
Definition: camellia.c:49
Sigma3
#define Sigma3
Definition: camellia.c:35
i
#define i(width, name, range_min, range_max)
Definition: cbs_h2645.c:269
common.h
uint8_t
uint8_t
Definition: audio_convert.c:194
SBOX4
static const uint8_t SBOX4[256]
Definition: camellia.c:106
Sigma5
#define Sigma5
Definition: camellia.c:37
FL
static uint64_t FL(uint64_t FL_IN, uint64_t KE)
Definition: camellia.c:150
camellia_encrypt
static void camellia_encrypt(AVCAMELLIA *cs, uint8_t *dst, const uint8_t *src)
Definition: camellia.c:232
AVCAMELLIA::key_bits
int key_bits
Definition: camellia.c:46
F
static uint64_t F(uint64_t F_IN, uint64_t KE)
Definition: camellia.c:143
SP
static uint64_t SP[8][256]
Definition: camellia.c:40
MASK32
#define MASK32
Definition: camellia.c:30
shifts
static const uint8_t shifts[2][12]
Definition: camellia.c:174
camellia.h
Public header for libavutil CAMELLIA algorithm.