1 /* 2 * 3 * Bluetooth low-complexity, subband codec (SBC) library 4 * 5 * Copyright (C) 2008-2010 Nokia Corporation 6 * Copyright (C) 2004-2010 Marcel Holtmann <marcel (at) holtmann.org> 7 * Copyright (C) 2004-2005 Henryk Ploetz <henryk (at) ploetzli.ch> 8 * Copyright (C) 2005-2006 Brad Midgley <bmidgley (at) xmission.com> 9 * 10 * 11 * This library is free software; you can redistribute it and/or 12 * modify it under the terms of the GNU Lesser General Public 13 * License as published by the Free Software Foundation; either 14 * version 2.1 of the License, or (at your option) any later version. 15 * 16 * This library is distributed in the hope that it will be useful, 17 * but WITHOUT ANY WARRANTY; without even the implied warranty of 18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 19 * Lesser General Public License for more details. 20 * 21 * You should have received a copy of the GNU Lesser General Public 22 * License along with this library; if not, write to the Free Software 23 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA 24 * 25 */ 26 27 /* A2DP specification: Appendix B, page 69 */ 28 static const int sbc_offset4[4][4] = { 29 { -1, 0, 0, 0 }, 30 { -2, 0, 0, 1 }, 31 { -2, 0, 0, 1 }, 32 { -2, 0, 0, 1 } 33 }; 34 35 /* A2DP specification: Appendix B, page 69 */ 36 static const int sbc_offset8[4][8] = { 37 { -2, 0, 0, 0, 0, 0, 0, 1 }, 38 { -3, 0, 0, 0, 0, 0, 1, 2 }, 39 { -4, 0, 0, 0, 0, 0, 1, 2 }, 40 { -4, 0, 0, 0, 0, 0, 1, 2 } 41 }; 42 43 44 #define SS4(val) ASR(val, SCALE_SPROTO4_TBL) 45 #define SS8(val) ASR(val, SCALE_SPROTO8_TBL) 46 #define SN4(val) ASR(val, SCALE_NPROTO4_TBL) 47 #define SN8(val) ASR(val, SCALE_NPROTO8_TBL) 48 49 static const int32_t sbc_proto_4_40m0[] = { 50 SS4(0x00000000), SS4(0xffa6982f), SS4(0xfba93848), SS4(0x0456c7b8), 51 SS4(0x005967d1), SS4(0xfffb9ac7), SS4(0xff589157), SS4(0xf9c2a8d8), 52 SS4(0x027c1434), SS4(0x0019118b), SS4(0xfff3c74c), SS4(0xff137330), 53 SS4(0xf81b8d70), SS4(0x00ec1b8b), SS4(0xfff0b71a), SS4(0xffe99b00), 54 SS4(0xfef84470), SS4(0xf6fb4370), SS4(0xffcdc351), SS4(0xffe01dc7) 55 }; 56 57 static const int32_t sbc_proto_4_40m1[] = { 58 SS4(0xffe090ce), SS4(0xff2c0475), SS4(0xf694f800), SS4(0xff2c0475), 59 SS4(0xffe090ce), SS4(0xffe01dc7), SS4(0xffcdc351), SS4(0xf6fb4370), 60 SS4(0xfef84470), SS4(0xffe99b00), SS4(0xfff0b71a), SS4(0x00ec1b8b), 61 SS4(0xf81b8d70), SS4(0xff137330), SS4(0xfff3c74c), SS4(0x0019118b), 62 SS4(0x027c1434), SS4(0xf9c2a8d8), SS4(0xff589157), SS4(0xfffb9ac7) 63 }; 64 65 static const int32_t sbc_proto_8_80m0[] = { 66 SS8(0x00000000), SS8(0xfe8d1970), SS8(0xee979f00), SS8(0x11686100), 67 SS8(0x0172e690), SS8(0xfff5bd1a), SS8(0xfdf1c8d4), SS8(0xeac182c0), 68 SS8(0x0d9daee0), SS8(0x00e530da), SS8(0xffe9811d), SS8(0xfd52986c), 69 SS8(0xe7054ca0), SS8(0x0a00d410), SS8(0x006c1de4), SS8(0xffdba705), 70 SS8(0xfcbc98e8), SS8(0xe3889d20), SS8(0x06af2308), SS8(0x000bb7db), 71 SS8(0xffca00ed), SS8(0xfc3fbb68), SS8(0xe071bc00), SS8(0x03bf7948), 72 SS8(0xffc4e05c), SS8(0xffb54b3b), SS8(0xfbedadc0), SS8(0xdde26200), 73 SS8(0x0142291c), SS8(0xff960e94), SS8(0xff9f3e17), SS8(0xfbd8f358), 74 SS8(0xdbf79400), SS8(0xff405e01), SS8(0xff7d4914), SS8(0xff8b1a31), 75 SS8(0xfc1417b8), SS8(0xdac7bb40), SS8(0xfdbb828c), SS8(0xff762170) 76 }; 77 78 static const int32_t sbc_proto_8_80m1[] = { 79 SS8(0xff7c272c), SS8(0xfcb02620), SS8(0xda612700), SS8(0xfcb02620), 80 SS8(0xff7c272c), SS8(0xff762170), SS8(0xfdbb828c), SS8(0xdac7bb40), 81 SS8(0xfc1417b8), SS8(0xff8b1a31), SS8(0xff7d4914), SS8(0xff405e01), 82 SS8(0xdbf79400), SS8(0xfbd8f358), SS8(0xff9f3e17), SS8(0xff960e94), 83 SS8(0x0142291c), SS8(0xdde26200), SS8(0xfbedadc0), SS8(0xffb54b3b), 84 SS8(0xffc4e05c), SS8(0x03bf7948), SS8(0xe071bc00), SS8(0xfc3fbb68), 85 SS8(0xffca00ed), SS8(0x000bb7db), SS8(0x06af2308), SS8(0xe3889d20), 86 SS8(0xfcbc98e8), SS8(0xffdba705), SS8(0x006c1de4), SS8(0x0a00d410), 87 SS8(0xe7054ca0), SS8(0xfd52986c), SS8(0xffe9811d), SS8(0x00e530da), 88 SS8(0x0d9daee0), SS8(0xeac182c0), SS8(0xfdf1c8d4), SS8(0xfff5bd1a) 89 }; 90 91 static const int32_t synmatrix4[8][4] = { 92 { SN4(0x05a82798), SN4(0xfa57d868), SN4(0xfa57d868), SN4(0x05a82798) }, 93 { SN4(0x030fbc54), SN4(0xf89be510), SN4(0x07641af0), SN4(0xfcf043ac) }, 94 { SN4(0x00000000), SN4(0x00000000), SN4(0x00000000), SN4(0x00000000) }, 95 { SN4(0xfcf043ac), SN4(0x07641af0), SN4(0xf89be510), SN4(0x030fbc54) }, 96 { SN4(0xfa57d868), SN4(0x05a82798), SN4(0x05a82798), SN4(0xfa57d868) }, 97 { SN4(0xf89be510), SN4(0xfcf043ac), SN4(0x030fbc54), SN4(0x07641af0) }, 98 { SN4(0xf8000000), SN4(0xf8000000), SN4(0xf8000000), SN4(0xf8000000) }, 99 { SN4(0xf89be510), SN4(0xfcf043ac), SN4(0x030fbc54), SN4(0x07641af0) } 100 }; 101 102 static const int32_t synmatrix8[16][8] = { 103 { SN8(0x05a82798), SN8(0xfa57d868), SN8(0xfa57d868), SN8(0x05a82798), 104 SN8(0x05a82798), SN8(0xfa57d868), SN8(0xfa57d868), SN8(0x05a82798) }, 105 { SN8(0x0471ced0), SN8(0xf8275a10), SN8(0x018f8b84), SN8(0x06a6d988), 106 SN8(0xf9592678), SN8(0xfe70747c), SN8(0x07d8a5f0), SN8(0xfb8e3130) }, 107 { SN8(0x030fbc54), SN8(0xf89be510), SN8(0x07641af0), SN8(0xfcf043ac), 108 SN8(0xfcf043ac), SN8(0x07641af0), SN8(0xf89be510), SN8(0x030fbc54) }, 109 { SN8(0x018f8b84), SN8(0xfb8e3130), SN8(0x06a6d988), SN8(0xf8275a10), 110 SN8(0x07d8a5f0), SN8(0xf9592678), SN8(0x0471ced0), SN8(0xfe70747c) }, 111 { SN8(0x00000000), SN8(0x00000000), SN8(0x00000000), SN8(0x00000000), 112 SN8(0x00000000), SN8(0x00000000), SN8(0x00000000), SN8(0x00000000) }, 113 { SN8(0xfe70747c), SN8(0x0471ced0), SN8(0xf9592678), SN8(0x07d8a5f0), 114 SN8(0xf8275a10), SN8(0x06a6d988), SN8(0xfb8e3130), SN8(0x018f8b84) }, 115 { SN8(0xfcf043ac), SN8(0x07641af0), SN8(0xf89be510), SN8(0x030fbc54), 116 SN8(0x030fbc54), SN8(0xf89be510), SN8(0x07641af0), SN8(0xfcf043ac) }, 117 { SN8(0xfb8e3130), SN8(0x07d8a5f0), SN8(0xfe70747c), SN8(0xf9592678), 118 SN8(0x06a6d988), SN8(0x018f8b84), SN8(0xf8275a10), SN8(0x0471ced0) }, 119 { SN8(0xfa57d868), SN8(0x05a82798), SN8(0x05a82798), SN8(0xfa57d868), 120 SN8(0xfa57d868), SN8(0x05a82798), SN8(0x05a82798), SN8(0xfa57d868) }, 121 { SN8(0xf9592678), SN8(0x018f8b84), SN8(0x07d8a5f0), SN8(0x0471ced0), 122 SN8(0xfb8e3130), SN8(0xf8275a10), SN8(0xfe70747c), SN8(0x06a6d988) }, 123 { SN8(0xf89be510), SN8(0xfcf043ac), SN8(0x030fbc54), SN8(0x07641af0), 124 SN8(0x07641af0), SN8(0x030fbc54), SN8(0xfcf043ac), SN8(0xf89be510) }, 125 { SN8(0xf8275a10), SN8(0xf9592678), SN8(0xfb8e3130), SN8(0xfe70747c), 126 SN8(0x018f8b84), SN8(0x0471ced0), SN8(0x06a6d988), SN8(0x07d8a5f0) }, 127 { SN8(0xf8000000), SN8(0xf8000000), SN8(0xf8000000), SN8(0xf8000000), 128 SN8(0xf8000000), SN8(0xf8000000), SN8(0xf8000000), SN8(0xf8000000) }, 129 { SN8(0xf8275a10), SN8(0xf9592678), SN8(0xfb8e3130), SN8(0xfe70747c), 130 SN8(0x018f8b84), SN8(0x0471ced0), SN8(0x06a6d988), SN8(0x07d8a5f0) }, 131 { SN8(0xf89be510), SN8(0xfcf043ac), SN8(0x030fbc54), SN8(0x07641af0), 132 SN8(0x07641af0), SN8(0x030fbc54), SN8(0xfcf043ac), SN8(0xf89be510) }, 133 { SN8(0xf9592678), SN8(0x018f8b84), SN8(0x07d8a5f0), SN8(0x0471ced0), 134 SN8(0xfb8e3130), SN8(0xf8275a10), SN8(0xfe70747c), SN8(0x06a6d988) } 135 }; 136 137 /* Uncomment the following line to enable high precision build of SBC encoder */ 138 139 /* #define SBC_HIGH_PRECISION */ 140 141 #ifdef SBC_HIGH_PRECISION 142 #define FIXED_A int64_t /* data type for fixed point accumulator */ 143 #define FIXED_T int32_t /* data type for fixed point constants */ 144 #define SBC_FIXED_EXTRA_BITS 16 145 #else 146 #define FIXED_A int32_t /* data type for fixed point accumulator */ 147 #define FIXED_T int16_t /* data type for fixed point constants */ 148 #define SBC_FIXED_EXTRA_BITS 0 149 #endif 150 151 /* A2DP specification: Section 12.8 Tables 152 * 153 * Original values are premultiplied by 2 for better precision (that is the 154 * maximum which is possible without overflows) 155 * 156 * Note: in each block of 8 numbers sign was changed for elements 2 and 7 157 * in order to compensate the same change applied to cos_table_fixed_4 158 */ 159 #define SBC_PROTO_FIXED4_SCALE \ 160 ((sizeof(FIXED_T) * CHAR_BIT - 1) - SBC_FIXED_EXTRA_BITS + 1) 161 #define F_PROTO4(x) (FIXED_A) ((x * 2) * \ 162 ((FIXED_A) 1 << (sizeof(FIXED_T) * CHAR_BIT - 1)) + 0.5) 163 #define F(x) F_PROTO4(x) 164 static const FIXED_T _sbc_proto_fixed4[40] = { 165 F(0.00000000E+00), F(5.36548976E-04), 166 -F(1.49188357E-03), F(2.73370904E-03), 167 F(3.83720193E-03), F(3.89205149E-03), 168 F(1.86581691E-03), F(3.06012286E-03), 169 170 F(1.09137620E-02), F(2.04385087E-02), 171 -F(2.88757392E-02), F(3.21939290E-02), 172 F(2.58767811E-02), F(6.13245186E-03), 173 -F(2.88217274E-02), F(7.76463494E-02), 174 175 F(1.35593274E-01), F(1.94987841E-01), 176 -F(2.46636662E-01), F(2.81828203E-01), 177 F(2.94315332E-01), F(2.81828203E-01), 178 F(2.46636662E-01), -F(1.94987841E-01), 179 180 -F(1.35593274E-01), -F(7.76463494E-02), 181 F(2.88217274E-02), F(6.13245186E-03), 182 F(2.58767811E-02), F(3.21939290E-02), 183 F(2.88757392E-02), -F(2.04385087E-02), 184 185 -F(1.09137620E-02), -F(3.06012286E-03), 186 -F(1.86581691E-03), F(3.89205149E-03), 187 F(3.83720193E-03), F(2.73370904E-03), 188 F(1.49188357E-03), -F(5.36548976E-04), 189 }; 190 #undef F 191 192 /* 193 * To produce this cosine matrix in Octave: 194 * 195 * b = zeros(4, 8); 196 * for i = 0:3 197 * for j = 0:7 b(i+1, j+1) = cos((i + 0.5) * (j - 2) * (pi/4)) 198 * endfor 199 * endfor; 200 * printf("%.10f, ", b'); 201 * 202 * Note: in each block of 8 numbers sign was changed for elements 2 and 7 203 * 204 * Change of sign for element 2 allows to replace constant 1.0 (not 205 * representable in Q15 format) with -1.0 (fine with Q15). 206 * Changed sign for element 7 allows to have more similar constants 207 * and simplify subband filter function code. 208 */ 209 #define SBC_COS_TABLE_FIXED4_SCALE \ 210 ((sizeof(FIXED_T) * CHAR_BIT - 1) + SBC_FIXED_EXTRA_BITS) 211 #define F_COS4(x) (FIXED_A) ((x) * \ 212 ((FIXED_A) 1 << (sizeof(FIXED_T) * CHAR_BIT - 1)) + 0.5) 213 #define F(x) F_COS4(x) 214 static const FIXED_T cos_table_fixed_4[32] = { 215 F(0.7071067812), F(0.9238795325), -F(1.0000000000), F(0.9238795325), 216 F(0.7071067812), F(0.3826834324), F(0.0000000000), F(0.3826834324), 217 218 -F(0.7071067812), F(0.3826834324), -F(1.0000000000), F(0.3826834324), 219 -F(0.7071067812), -F(0.9238795325), -F(0.0000000000), -F(0.9238795325), 220 221 -F(0.7071067812), -F(0.3826834324), -F(1.0000000000), -F(0.3826834324), 222 -F(0.7071067812), F(0.9238795325), F(0.0000000000), F(0.9238795325), 223 224 F(0.7071067812), -F(0.9238795325), -F(1.0000000000), -F(0.9238795325), 225 F(0.7071067812), -F(0.3826834324), -F(0.0000000000), -F(0.3826834324), 226 }; 227 #undef F 228 229 /* A2DP specification: Section 12.8 Tables 230 * 231 * Original values are premultiplied by 4 for better precision (that is the 232 * maximum which is possible without overflows) 233 * 234 * Note: in each block of 16 numbers sign was changed for elements 4, 13, 14, 15 235 * in order to compensate the same change applied to cos_table_fixed_8 236 */ 237 #define SBC_PROTO_FIXED8_SCALE \ 238 ((sizeof(FIXED_T) * CHAR_BIT - 1) - SBC_FIXED_EXTRA_BITS + 1) 239 #define F_PROTO8(x) (FIXED_A) ((x * 2) * \ 240 ((FIXED_A) 1 << (sizeof(FIXED_T) * CHAR_BIT - 1)) + 0.5) 241 #define F(x) F_PROTO8(x) 242 static const FIXED_T _sbc_proto_fixed8[80] = { 243 F(0.00000000E+00), F(1.56575398E-04), 244 F(3.43256425E-04), F(5.54620202E-04), 245 -F(8.23919506E-04), F(1.13992507E-03), 246 F(1.47640169E-03), F(1.78371725E-03), 247 F(2.01182542E-03), F(2.10371989E-03), 248 F(1.99454554E-03), F(1.61656283E-03), 249 F(9.02154502E-04), F(1.78805361E-04), 250 F(1.64973098E-03), F(3.49717454E-03), 251 252 F(5.65949473E-03), F(8.02941163E-03), 253 F(1.04584443E-02), F(1.27472335E-02), 254 -F(1.46525263E-02), F(1.59045603E-02), 255 F(1.62208471E-02), F(1.53184106E-02), 256 F(1.29371806E-02), F(8.85757540E-03), 257 F(2.92408442E-03), -F(4.91578024E-03), 258 -F(1.46404076E-02), F(2.61098752E-02), 259 F(3.90751381E-02), F(5.31873032E-02), 260 261 F(6.79989431E-02), F(8.29847578E-02), 262 F(9.75753918E-02), F(1.11196689E-01), 263 -F(1.23264548E-01), F(1.33264415E-01), 264 F(1.40753505E-01), F(1.45389847E-01), 265 F(1.46955068E-01), F(1.45389847E-01), 266 F(1.40753505E-01), F(1.33264415E-01), 267 F(1.23264548E-01), -F(1.11196689E-01), 268 -F(9.75753918E-02), -F(8.29847578E-02), 269 270 -F(6.79989431E-02), -F(5.31873032E-02), 271 -F(3.90751381E-02), -F(2.61098752E-02), 272 F(1.46404076E-02), -F(4.91578024E-03), 273 F(2.92408442E-03), F(8.85757540E-03), 274 F(1.29371806E-02), F(1.53184106E-02), 275 F(1.62208471E-02), F(1.59045603E-02), 276 F(1.46525263E-02), -F(1.27472335E-02), 277 -F(1.04584443E-02), -F(8.02941163E-03), 278 279 -F(5.65949473E-03), -F(3.49717454E-03), 280 -F(1.64973098E-03), -F(1.78805361E-04), 281 -F(9.02154502E-04), F(1.61656283E-03), 282 F(1.99454554E-03), F(2.10371989E-03), 283 F(2.01182542E-03), F(1.78371725E-03), 284 F(1.47640169E-03), F(1.13992507E-03), 285 F(8.23919506E-04), -F(5.54620202E-04), 286 -F(3.43256425E-04), -F(1.56575398E-04), 287 }; 288 #undef F 289 290 /* 291 * To produce this cosine matrix in Octave: 292 * 293 * b = zeros(8, 16); 294 * for i = 0:7 295 * for j = 0:15 b(i+1, j+1) = cos((i + 0.5) * (j - 4) * (pi/8)) 296 * endfor endfor; 297 * printf("%.10f, ", b'); 298 * 299 * Note: in each block of 16 numbers sign was changed for elements 4, 13, 14, 15 300 * 301 * Change of sign for element 4 allows to replace constant 1.0 (not 302 * representable in Q15 format) with -1.0 (fine with Q15). 303 * Changed signs for elements 13, 14, 15 allow to have more similar constants 304 * and simplify subband filter function code. 305 */ 306 #define SBC_COS_TABLE_FIXED8_SCALE \ 307 ((sizeof(FIXED_T) * CHAR_BIT - 1) + SBC_FIXED_EXTRA_BITS) 308 #define F_COS8(x) (FIXED_A) ((x) * \ 309 ((FIXED_A) 1 << (sizeof(FIXED_T) * CHAR_BIT - 1)) + 0.5) 310 #define F(x) F_COS8(x) 311 static const FIXED_T cos_table_fixed_8[128] = { 312 F(0.7071067812), F(0.8314696123), F(0.9238795325), F(0.9807852804), 313 -F(1.0000000000), F(0.9807852804), F(0.9238795325), F(0.8314696123), 314 F(0.7071067812), F(0.5555702330), F(0.3826834324), F(0.1950903220), 315 F(0.0000000000), F(0.1950903220), F(0.3826834324), F(0.5555702330), 316 317 -F(0.7071067812), -F(0.1950903220), F(0.3826834324), F(0.8314696123), 318 -F(1.0000000000), F(0.8314696123), F(0.3826834324), -F(0.1950903220), 319 -F(0.7071067812), -F(0.9807852804), -F(0.9238795325), -F(0.5555702330), 320 -F(0.0000000000), -F(0.5555702330), -F(0.9238795325), -F(0.9807852804), 321 322 -F(0.7071067812), -F(0.9807852804), -F(0.3826834324), F(0.5555702330), 323 -F(1.0000000000), F(0.5555702330), -F(0.3826834324), -F(0.9807852804), 324 -F(0.7071067812), F(0.1950903220), F(0.9238795325), F(0.8314696123), 325 F(0.0000000000), F(0.8314696123), F(0.9238795325), F(0.1950903220), 326 327 F(0.7071067812), -F(0.5555702330), -F(0.9238795325), F(0.1950903220), 328 -F(1.0000000000), F(0.1950903220), -F(0.9238795325), -F(0.5555702330), 329 F(0.7071067812), F(0.8314696123), -F(0.3826834324), -F(0.9807852804), 330 -F(0.0000000000), -F(0.9807852804), -F(0.3826834324), F(0.8314696123), 331 332 F(0.7071067812), F(0.5555702330), -F(0.9238795325), -F(0.1950903220), 333 -F(1.0000000000), -F(0.1950903220), -F(0.9238795325), F(0.5555702330), 334 F(0.7071067812), -F(0.8314696123), -F(0.3826834324), F(0.9807852804), 335 F(0.0000000000), F(0.9807852804), -F(0.3826834324), -F(0.8314696123), 336 337 -F(0.7071067812), F(0.9807852804), -F(0.3826834324), -F(0.5555702330), 338 -F(1.0000000000), -F(0.5555702330), -F(0.3826834324), F(0.9807852804), 339 -F(0.7071067812), -F(0.1950903220), F(0.9238795325), -F(0.8314696123), 340 -F(0.0000000000), -F(0.8314696123), F(0.9238795325), -F(0.1950903220), 341 342 -F(0.7071067812), F(0.1950903220), F(0.3826834324), -F(0.8314696123), 343 -F(1.0000000000), -F(0.8314696123), F(0.3826834324), F(0.1950903220), 344 -F(0.7071067812), F(0.9807852804), -F(0.9238795325), F(0.5555702330), 345 -F(0.0000000000), F(0.5555702330), -F(0.9238795325), F(0.9807852804), 346 347 F(0.7071067812), -F(0.8314696123), F(0.9238795325), -F(0.9807852804), 348 -F(1.0000000000), -F(0.9807852804), F(0.9238795325), -F(0.8314696123), 349 F(0.7071067812), -F(0.5555702330), F(0.3826834324), -F(0.1950903220), 350 -F(0.0000000000), -F(0.1950903220), F(0.3826834324), -F(0.5555702330), 351 }; 352 #undef F 353 354 /* 355 * Enforce 16 byte alignment for the data, which is supposed to be used 356 * with SIMD optimized code. 357 */ 358 359 #define SBC_ALIGN_BITS 4 360 #define SBC_ALIGN_MASK ((1 << (SBC_ALIGN_BITS)) - 1) 361 362 #ifdef __GNUC__ 363 #define SBC_ALIGNED __attribute__((aligned(1 << (SBC_ALIGN_BITS)))) 364 #else 365 #define SBC_ALIGNED 366 #endif 367 368 /* 369 * Constant tables for the use in SIMD optimized analysis filters 370 * Each table consists of two parts: 371 * 1. reordered "proto" table 372 * 2. reordered "cos" table 373 * 374 * Due to non-symmetrical reordering, separate tables for "even" 375 * and "odd" cases are needed 376 */ 377 378 static const FIXED_T SBC_ALIGNED analysis_consts_fixed4_simd_even[40 + 16] = { 379 #define C0 1.0932568993 380 #define C1 1.3056875580 381 #define C2 1.3056875580 382 #define C3 1.6772280856 383 384 #define F(x) F_PROTO4(x) 385 F(0.00000000E+00 * C0), F(3.83720193E-03 * C0), 386 F(5.36548976E-04 * C1), F(2.73370904E-03 * C1), 387 F(3.06012286E-03 * C2), F(3.89205149E-03 * C2), 388 F(0.00000000E+00 * C3), -F(1.49188357E-03 * C3), 389 F(1.09137620E-02 * C0), F(2.58767811E-02 * C0), 390 F(2.04385087E-02 * C1), F(3.21939290E-02 * C1), 391 F(7.76463494E-02 * C2), F(6.13245186E-03 * C2), 392 F(0.00000000E+00 * C3), -F(2.88757392E-02 * C3), 393 F(1.35593274E-01 * C0), F(2.94315332E-01 * C0), 394 F(1.94987841E-01 * C1), F(2.81828203E-01 * C1), 395 -F(1.94987841E-01 * C2), F(2.81828203E-01 * C2), 396 F(0.00000000E+00 * C3), -F(2.46636662E-01 * C3), 397 -F(1.35593274E-01 * C0), F(2.58767811E-02 * C0), 398 -F(7.76463494E-02 * C1), F(6.13245186E-03 * C1), 399 -F(2.04385087E-02 * C2), F(3.21939290E-02 * C2), 400 F(0.00000000E+00 * C3), F(2.88217274E-02 * C3), 401 -F(1.09137620E-02 * C0), F(3.83720193E-03 * C0), 402 -F(3.06012286E-03 * C1), F(3.89205149E-03 * C1), 403 -F(5.36548976E-04 * C2), F(2.73370904E-03 * C2), 404 F(0.00000000E+00 * C3), -F(1.86581691E-03 * C3), 405 #undef F 406 #define F(x) F_COS4(x) 407 F(0.7071067812 / C0), F(0.9238795325 / C1), 408 -F(0.7071067812 / C0), F(0.3826834324 / C1), 409 -F(0.7071067812 / C0), -F(0.3826834324 / C1), 410 F(0.7071067812 / C0), -F(0.9238795325 / C1), 411 F(0.3826834324 / C2), -F(1.0000000000 / C3), 412 -F(0.9238795325 / C2), -F(1.0000000000 / C3), 413 F(0.9238795325 / C2), -F(1.0000000000 / C3), 414 -F(0.3826834324 / C2), -F(1.0000000000 / C3), 415 #undef F 416 417 #undef C0 418 #undef C1 419 #undef C2 420 #undef C3 421 }; 422 423 static const FIXED_T SBC_ALIGNED analysis_consts_fixed4_simd_odd[40 + 16] = { 424 #define C0 1.3056875580 425 #define C1 1.6772280856 426 #define C2 1.0932568993 427 #define C3 1.3056875580 428 429 #define F(x) F_PROTO4(x) 430 F(2.73370904E-03 * C0), F(5.36548976E-04 * C0), 431 -F(1.49188357E-03 * C1), F(0.00000000E+00 * C1), 432 F(3.83720193E-03 * C2), F(1.09137620E-02 * C2), 433 F(3.89205149E-03 * C3), F(3.06012286E-03 * C3), 434 F(3.21939290E-02 * C0), F(2.04385087E-02 * C0), 435 -F(2.88757392E-02 * C1), F(0.00000000E+00 * C1), 436 F(2.58767811E-02 * C2), F(1.35593274E-01 * C2), 437 F(6.13245186E-03 * C3), F(7.76463494E-02 * C3), 438 F(2.81828203E-01 * C0), F(1.94987841E-01 * C0), 439 -F(2.46636662E-01 * C1), F(0.00000000E+00 * C1), 440 F(2.94315332E-01 * C2), -F(1.35593274E-01 * C2), 441 F(2.81828203E-01 * C3), -F(1.94987841E-01 * C3), 442 F(6.13245186E-03 * C0), -F(7.76463494E-02 * C0), 443 F(2.88217274E-02 * C1), F(0.00000000E+00 * C1), 444 F(2.58767811E-02 * C2), -F(1.09137620E-02 * C2), 445 F(3.21939290E-02 * C3), -F(2.04385087E-02 * C3), 446 F(3.89205149E-03 * C0), -F(3.06012286E-03 * C0), 447 -F(1.86581691E-03 * C1), F(0.00000000E+00 * C1), 448 F(3.83720193E-03 * C2), F(0.00000000E+00 * C2), 449 F(2.73370904E-03 * C3), -F(5.36548976E-04 * C3), 450 #undef F 451 #define F(x) F_COS4(x) 452 F(0.9238795325 / C0), -F(1.0000000000 / C1), 453 F(0.3826834324 / C0), -F(1.0000000000 / C1), 454 -F(0.3826834324 / C0), -F(1.0000000000 / C1), 455 -F(0.9238795325 / C0), -F(1.0000000000 / C1), 456 F(0.7071067812 / C2), F(0.3826834324 / C3), 457 -F(0.7071067812 / C2), -F(0.9238795325 / C3), 458 -F(0.7071067812 / C2), F(0.9238795325 / C3), 459 F(0.7071067812 / C2), -F(0.3826834324 / C3), 460 #undef F 461 462 #undef C0 463 #undef C1 464 #undef C2 465 #undef C3 466 }; 467 468 static const FIXED_T SBC_ALIGNED analysis_consts_fixed8_simd_even[80 + 64] = { 469 #define C0 2.7906148894 470 #define C1 2.4270044280 471 #define C2 2.8015616024 472 #define C3 3.1710363741 473 #define C4 2.5377944043 474 #define C5 2.4270044280 475 #define C6 2.8015616024 476 #define C7 3.1710363741 477 478 #define F(x) F_PROTO8(x) 479 F(0.00000000E+00 * C0), F(2.01182542E-03 * C0), 480 F(1.56575398E-04 * C1), F(1.78371725E-03 * C1), 481 F(3.43256425E-04 * C2), F(1.47640169E-03 * C2), 482 F(5.54620202E-04 * C3), F(1.13992507E-03 * C3), 483 -F(8.23919506E-04 * C4), F(0.00000000E+00 * C4), 484 F(2.10371989E-03 * C5), F(3.49717454E-03 * C5), 485 F(1.99454554E-03 * C6), F(1.64973098E-03 * C6), 486 F(1.61656283E-03 * C7), F(1.78805361E-04 * C7), 487 F(5.65949473E-03 * C0), F(1.29371806E-02 * C0), 488 F(8.02941163E-03 * C1), F(1.53184106E-02 * C1), 489 F(1.04584443E-02 * C2), F(1.62208471E-02 * C2), 490 F(1.27472335E-02 * C3), F(1.59045603E-02 * C3), 491 -F(1.46525263E-02 * C4), F(0.00000000E+00 * C4), 492 F(8.85757540E-03 * C5), F(5.31873032E-02 * C5), 493 F(2.92408442E-03 * C6), F(3.90751381E-02 * C6), 494 -F(4.91578024E-03 * C7), F(2.61098752E-02 * C7), 495 F(6.79989431E-02 * C0), F(1.46955068E-01 * C0), 496 F(8.29847578E-02 * C1), F(1.45389847E-01 * C1), 497 F(9.75753918E-02 * C2), F(1.40753505E-01 * C2), 498 F(1.11196689E-01 * C3), F(1.33264415E-01 * C3), 499 -F(1.23264548E-01 * C4), F(0.00000000E+00 * C4), 500 F(1.45389847E-01 * C5), -F(8.29847578E-02 * C5), 501 F(1.40753505E-01 * C6), -F(9.75753918E-02 * C6), 502 F(1.33264415E-01 * C7), -F(1.11196689E-01 * C7), 503 -F(6.79989431E-02 * C0), F(1.29371806E-02 * C0), 504 -F(5.31873032E-02 * C1), F(8.85757540E-03 * C1), 505 -F(3.90751381E-02 * C2), F(2.92408442E-03 * C2), 506 -F(2.61098752E-02 * C3), -F(4.91578024E-03 * C3), 507 F(1.46404076E-02 * C4), F(0.00000000E+00 * C4), 508 F(1.53184106E-02 * C5), -F(8.02941163E-03 * C5), 509 F(1.62208471E-02 * C6), -F(1.04584443E-02 * C6), 510 F(1.59045603E-02 * C7), -F(1.27472335E-02 * C7), 511 -F(5.65949473E-03 * C0), F(2.01182542E-03 * C0), 512 -F(3.49717454E-03 * C1), F(2.10371989E-03 * C1), 513 -F(1.64973098E-03 * C2), F(1.99454554E-03 * C2), 514 -F(1.78805361E-04 * C3), F(1.61656283E-03 * C3), 515 -F(9.02154502E-04 * C4), F(0.00000000E+00 * C4), 516 F(1.78371725E-03 * C5), -F(1.56575398E-04 * C5), 517 F(1.47640169E-03 * C6), -F(3.43256425E-04 * C6), 518 F(1.13992507E-03 * C7), -F(5.54620202E-04 * C7), 519 #undef F 520 #define F(x) F_COS8(x) 521 F(0.7071067812 / C0), F(0.8314696123 / C1), 522 -F(0.7071067812 / C0), -F(0.1950903220 / C1), 523 -F(0.7071067812 / C0), -F(0.9807852804 / C1), 524 F(0.7071067812 / C0), -F(0.5555702330 / C1), 525 F(0.7071067812 / C0), F(0.5555702330 / C1), 526 -F(0.7071067812 / C0), F(0.9807852804 / C1), 527 -F(0.7071067812 / C0), F(0.1950903220 / C1), 528 F(0.7071067812 / C0), -F(0.8314696123 / C1), 529 F(0.9238795325 / C2), F(0.9807852804 / C3), 530 F(0.3826834324 / C2), F(0.8314696123 / C3), 531 -F(0.3826834324 / C2), F(0.5555702330 / C3), 532 -F(0.9238795325 / C2), F(0.1950903220 / C3), 533 -F(0.9238795325 / C2), -F(0.1950903220 / C3), 534 -F(0.3826834324 / C2), -F(0.5555702330 / C3), 535 F(0.3826834324 / C2), -F(0.8314696123 / C3), 536 F(0.9238795325 / C2), -F(0.9807852804 / C3), 537 -F(1.0000000000 / C4), F(0.5555702330 / C5), 538 -F(1.0000000000 / C4), -F(0.9807852804 / C5), 539 -F(1.0000000000 / C4), F(0.1950903220 / C5), 540 -F(1.0000000000 / C4), F(0.8314696123 / C5), 541 -F(1.0000000000 / C4), -F(0.8314696123 / C5), 542 -F(1.0000000000 / C4), -F(0.1950903220 / C5), 543 -F(1.0000000000 / C4), F(0.9807852804 / C5), 544 -F(1.0000000000 / C4), -F(0.5555702330 / C5), 545 F(0.3826834324 / C6), F(0.1950903220 / C7), 546 -F(0.9238795325 / C6), -F(0.5555702330 / C7), 547 F(0.9238795325 / C6), F(0.8314696123 / C7), 548 -F(0.3826834324 / C6), -F(0.9807852804 / C7), 549 -F(0.3826834324 / C6), F(0.9807852804 / C7), 550 F(0.9238795325 / C6), -F(0.8314696123 / C7), 551 -F(0.9238795325 / C6), F(0.5555702330 / C7), 552 F(0.3826834324 / C6), -F(0.1950903220 / C7), 553 #undef F 554 555 #undef C0 556 #undef C1 557 #undef C2 558 #undef C3 559 #undef C4 560 #undef C5 561 #undef C6 562 #undef C7 563 }; 564 565 static const FIXED_T SBC_ALIGNED analysis_consts_fixed8_simd_odd[80 + 64] = { 566 #define C0 2.5377944043 567 #define C1 2.4270044280 568 #define C2 2.8015616024 569 #define C3 3.1710363741 570 #define C4 2.7906148894 571 #define C5 2.4270044280 572 #define C6 2.8015616024 573 #define C7 3.1710363741 574 575 #define F(x) F_PROTO8(x) 576 F(0.00000000E+00 * C0), -F(8.23919506E-04 * C0), 577 F(1.56575398E-04 * C1), F(1.78371725E-03 * C1), 578 F(3.43256425E-04 * C2), F(1.47640169E-03 * C2), 579 F(5.54620202E-04 * C3), F(1.13992507E-03 * C3), 580 F(2.01182542E-03 * C4), F(5.65949473E-03 * C4), 581 F(2.10371989E-03 * C5), F(3.49717454E-03 * C5), 582 F(1.99454554E-03 * C6), F(1.64973098E-03 * C6), 583 F(1.61656283E-03 * C7), F(1.78805361E-04 * C7), 584 F(0.00000000E+00 * C0), -F(1.46525263E-02 * C0), 585 F(8.02941163E-03 * C1), F(1.53184106E-02 * C1), 586 F(1.04584443E-02 * C2), F(1.62208471E-02 * C2), 587 F(1.27472335E-02 * C3), F(1.59045603E-02 * C3), 588 F(1.29371806E-02 * C4), F(6.79989431E-02 * C4), 589 F(8.85757540E-03 * C5), F(5.31873032E-02 * C5), 590 F(2.92408442E-03 * C6), F(3.90751381E-02 * C6), 591 -F(4.91578024E-03 * C7), F(2.61098752E-02 * C7), 592 F(0.00000000E+00 * C0), -F(1.23264548E-01 * C0), 593 F(8.29847578E-02 * C1), F(1.45389847E-01 * C1), 594 F(9.75753918E-02 * C2), F(1.40753505E-01 * C2), 595 F(1.11196689E-01 * C3), F(1.33264415E-01 * C3), 596 F(1.46955068E-01 * C4), -F(6.79989431E-02 * C4), 597 F(1.45389847E-01 * C5), -F(8.29847578E-02 * C5), 598 F(1.40753505E-01 * C6), -F(9.75753918E-02 * C6), 599 F(1.33264415E-01 * C7), -F(1.11196689E-01 * C7), 600 F(0.00000000E+00 * C0), F(1.46404076E-02 * C0), 601 -F(5.31873032E-02 * C1), F(8.85757540E-03 * C1), 602 -F(3.90751381E-02 * C2), F(2.92408442E-03 * C2), 603 -F(2.61098752E-02 * C3), -F(4.91578024E-03 * C3), 604 F(1.29371806E-02 * C4), -F(5.65949473E-03 * C4), 605 F(1.53184106E-02 * C5), -F(8.02941163E-03 * C5), 606 F(1.62208471E-02 * C6), -F(1.04584443E-02 * C6), 607 F(1.59045603E-02 * C7), -F(1.27472335E-02 * C7), 608 F(0.00000000E+00 * C0), -F(9.02154502E-04 * C0), 609 -F(3.49717454E-03 * C1), F(2.10371989E-03 * C1), 610 -F(1.64973098E-03 * C2), F(1.99454554E-03 * C2), 611 -F(1.78805361E-04 * C3), F(1.61656283E-03 * C3), 612 F(2.01182542E-03 * C4), F(0.00000000E+00 * C4), 613 F(1.78371725E-03 * C5), -F(1.56575398E-04 * C5), 614 F(1.47640169E-03 * C6), -F(3.43256425E-04 * C6), 615 F(1.13992507E-03 * C7), -F(5.54620202E-04 * C7), 616 #undef F 617 #define F(x) F_COS8(x) 618 -F(1.0000000000 / C0), F(0.8314696123 / C1), 619 -F(1.0000000000 / C0), -F(0.1950903220 / C1), 620 -F(1.0000000000 / C0), -F(0.9807852804 / C1), 621 -F(1.0000000000 / C0), -F(0.5555702330 / C1), 622 -F(1.0000000000 / C0), F(0.5555702330 / C1), 623 -F(1.0000000000 / C0), F(0.9807852804 / C1), 624 -F(1.0000000000 / C0), F(0.1950903220 / C1), 625 -F(1.0000000000 / C0), -F(0.8314696123 / C1), 626 F(0.9238795325 / C2), F(0.9807852804 / C3), 627 F(0.3826834324 / C2), F(0.8314696123 / C3), 628 -F(0.3826834324 / C2), F(0.5555702330 / C3), 629 -F(0.9238795325 / C2), F(0.1950903220 / C3), 630 -F(0.9238795325 / C2), -F(0.1950903220 / C3), 631 -F(0.3826834324 / C2), -F(0.5555702330 / C3), 632 F(0.3826834324 / C2), -F(0.8314696123 / C3), 633 F(0.9238795325 / C2), -F(0.9807852804 / C3), 634 F(0.7071067812 / C4), F(0.5555702330 / C5), 635 -F(0.7071067812 / C4), -F(0.9807852804 / C5), 636 -F(0.7071067812 / C4), F(0.1950903220 / C5), 637 F(0.7071067812 / C4), F(0.8314696123 / C5), 638 F(0.7071067812 / C4), -F(0.8314696123 / C5), 639 -F(0.7071067812 / C4), -F(0.1950903220 / C5), 640 -F(0.7071067812 / C4), F(0.9807852804 / C5), 641 F(0.7071067812 / C4), -F(0.5555702330 / C5), 642 F(0.3826834324 / C6), F(0.1950903220 / C7), 643 -F(0.9238795325 / C6), -F(0.5555702330 / C7), 644 F(0.9238795325 / C6), F(0.8314696123 / C7), 645 -F(0.3826834324 / C6), -F(0.9807852804 / C7), 646 -F(0.3826834324 / C6), F(0.9807852804 / C7), 647 F(0.9238795325 / C6), -F(0.8314696123 / C7), 648 -F(0.9238795325 / C6), F(0.5555702330 / C7), 649 F(0.3826834324 / C6), -F(0.1950903220 / C7), 650 #undef F 651 652 #undef C0 653 #undef C1 654 #undef C2 655 #undef C3 656 #undef C4 657 #undef C5 658 #undef C6 659 #undef C7 660 }; 661