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1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286 287 288 289 290 291 292 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390 391 392 | /* * Copyright 2017 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Authors: AMD * */ #include <drm/drm_dsc.h> #include "os_types.h" #include "rc_calc.h" #include "qp_tables.h" #define table_hash(mode, bpc, max_min) ((mode << 16) | (bpc << 8) | max_min) #define MODE_SELECT(val444, val422, val420) \ (cm == CM_444 || cm == CM_RGB) ? (val444) : (cm == CM_422 ? (val422) : (val420)) #define TABLE_CASE(mode, bpc, max) case (table_hash(mode, BPC_##bpc, max)): \ table = qp_table_##mode##_##bpc##bpc_##max; \ table_size = sizeof(qp_table_##mode##_##bpc##bpc_##max)/sizeof(*qp_table_##mode##_##bpc##bpc_##max); \ break static void get_qp_set(qp_set qps, enum colour_mode cm, enum bits_per_comp bpc, enum max_min max_min, float bpp) { int mode = MODE_SELECT(444, 422, 420); int sel = table_hash(mode, bpc, max_min); int table_size = 0; int index; const struct qp_entry *table = 0L; // alias enum enum { min = DAL_MM_MIN, max = DAL_MM_MAX }; switch (sel) { TABLE_CASE(444, 8, max); TABLE_CASE(444, 8, min); TABLE_CASE(444, 10, max); TABLE_CASE(444, 10, min); TABLE_CASE(444, 12, max); TABLE_CASE(444, 12, min); TABLE_CASE(422, 8, max); TABLE_CASE(422, 8, min); TABLE_CASE(422, 10, max); TABLE_CASE(422, 10, min); TABLE_CASE(422, 12, max); TABLE_CASE(422, 12, min); TABLE_CASE(420, 8, max); TABLE_CASE(420, 8, min); TABLE_CASE(420, 10, max); TABLE_CASE(420, 10, min); TABLE_CASE(420, 12, max); TABLE_CASE(420, 12, min); } if (table == 0) return; index = (bpp - table[0].bpp) * 2; /* requested size is bigger than the table */ if (index >= table_size) { dm_error("ERROR: Requested rc_calc to find a bpp entry that exceeds the table size\n"); return; } memcpy(qps, table[index].qps, sizeof(qp_set)); } static double dsc_roundf(double num) { if (num < 0.0) num = num - 0.5; else num = num + 0.5; return (int)(num); } static double dsc_ceil(double num) { double retval = (int)num; if (retval != num && num > 0) retval = num + 1; return (int)retval; } static void get_ofs_set(qp_set ofs, enum colour_mode mode, float bpp) { int *p = ofs; if (mode == CM_444 || mode == CM_RGB) { *p++ = (bpp <= 6) ? (0) : ((((bpp >= 8) && (bpp <= 12))) ? (2) : ((bpp >= 15) ? (10) : ((((bpp > 6) && (bpp < 8))) ? (0 + dsc_roundf((bpp - 6) * (2 / 2.0))) : (2 + dsc_roundf((bpp - 12) * (8 / 3.0)))))); *p++ = (bpp <= 6) ? (-2) : ((((bpp >= 8) && (bpp <= 12))) ? (0) : ((bpp >= 15) ? (8) : ((((bpp > 6) && (bpp < 8))) ? (-2 + dsc_roundf((bpp - 6) * (2 / 2.0))) : (0 + dsc_roundf((bpp - 12) * (8 / 3.0)))))); *p++ = (bpp <= 6) ? (-2) : ((((bpp >= 8) && (bpp <= 12))) ? (0) : ((bpp >= 15) ? (6) : ((((bpp > 6) && (bpp < 8))) ? (-2 + dsc_roundf((bpp - 6) * (2 / 2.0))) : (0 + dsc_roundf((bpp - 12) * (6 / 3.0)))))); *p++ = (bpp <= 6) ? (-4) : ((((bpp >= 8) && (bpp <= 12))) ? (-2) : ((bpp >= 15) ? (4) : ((((bpp > 6) && (bpp < 8))) ? (-4 + dsc_roundf((bpp - 6) * (2 / 2.0))) : (-2 + dsc_roundf((bpp - 12) * (6 / 3.0)))))); *p++ = (bpp <= 6) ? (-6) : ((((bpp >= 8) && (bpp <= 12))) ? (-4) : ((bpp >= 15) ? (2) : ((((bpp > 6) && (bpp < 8))) ? (-6 + dsc_roundf((bpp - 6) * (2 / 2.0))) : (-4 + dsc_roundf((bpp - 12) * (6 / 3.0)))))); *p++ = (bpp <= 12) ? (-6) : ((bpp >= 15) ? (0) : (-6 + dsc_roundf((bpp - 12) * (6 / 3.0)))); *p++ = (bpp <= 12) ? (-8) : ((bpp >= 15) ? (-2) : (-8 + dsc_roundf((bpp - 12) * (6 / 3.0)))); *p++ = (bpp <= 12) ? (-8) : ((bpp >= 15) ? (-4) : (-8 + dsc_roundf((bpp - 12) * (4 / 3.0)))); *p++ = (bpp <= 12) ? (-8) : ((bpp >= 15) ? (-6) : (-8 + dsc_roundf((bpp - 12) * (2 / 3.0)))); *p++ = (bpp <= 12) ? (-10) : ((bpp >= 15) ? (-8) : (-10 + dsc_roundf((bpp - 12) * (2 / 3.0)))); *p++ = -10; *p++ = (bpp <= 6) ? (-12) : ((bpp >= 8) ? (-10) : (-12 + dsc_roundf((bpp - 6) * (2 / 2.0)))); *p++ = -12; *p++ = -12; *p++ = -12; } else if (mode == CM_422) { *p++ = (bpp <= 8) ? (2) : ((bpp >= 10) ? (10) : (2 + dsc_roundf((bpp - 8) * (8 / 2.0)))); *p++ = (bpp <= 8) ? (0) : ((bpp >= 10) ? (8) : (0 + dsc_roundf((bpp - 8) * (8 / 2.0)))); *p++ = (bpp <= 8) ? (0) : ((bpp >= 10) ? (6) : (0 + dsc_roundf((bpp - 8) * (6 / 2.0)))); *p++ = (bpp <= 8) ? (-2) : ((bpp >= 10) ? (4) : (-2 + dsc_roundf((bpp - 8) * (6 / 2.0)))); *p++ = (bpp <= 8) ? (-4) : ((bpp >= 10) ? (2) : (-4 + dsc_roundf((bpp - 8) * (6 / 2.0)))); *p++ = (bpp <= 8) ? (-6) : ((bpp >= 10) ? (0) : (-6 + dsc_roundf((bpp - 8) * (6 / 2.0)))); *p++ = (bpp <= 8) ? (-8) : ((bpp >= 10) ? (-2) : (-8 + dsc_roundf((bpp - 8) * (6 / 2.0)))); *p++ = (bpp <= 8) ? (-8) : ((bpp >= 10) ? (-4) : (-8 + dsc_roundf((bpp - 8) * (4 / 2.0)))); *p++ = (bpp <= 8) ? (-8) : ((bpp >= 10) ? (-6) : (-8 + dsc_roundf((bpp - 8) * (2 / 2.0)))); *p++ = (bpp <= 8) ? (-10) : ((bpp >= 10) ? (-8) : (-10 + dsc_roundf((bpp - 8) * (2 / 2.0)))); *p++ = -10; *p++ = (bpp <= 6) ? (-12) : ((bpp >= 7) ? (-10) : (-12 + dsc_roundf((bpp - 6) * (2.0 / 1)))); *p++ = -12; *p++ = -12; *p++ = -12; } else { *p++ = (bpp <= 6) ? (2) : ((bpp >= 8) ? (10) : (2 + dsc_roundf((bpp - 6) * (8 / 2.0)))); *p++ = (bpp <= 6) ? (0) : ((bpp >= 8) ? (8) : (0 + dsc_roundf((bpp - 6) * (8 / 2.0)))); *p++ = (bpp <= 6) ? (0) : ((bpp >= 8) ? (6) : (0 + dsc_roundf((bpp - 6) * (6 / 2.0)))); *p++ = (bpp <= 6) ? (-2) : ((bpp >= 8) ? (4) : (-2 + dsc_roundf((bpp - 6) * (6 / 2.0)))); *p++ = (bpp <= 6) ? (-4) : ((bpp >= 8) ? (2) : (-4 + dsc_roundf((bpp - 6) * (6 / 2.0)))); *p++ = (bpp <= 6) ? (-6) : ((bpp >= 8) ? (0) : (-6 + dsc_roundf((bpp - 6) * (6 / 2.0)))); *p++ = (bpp <= 6) ? (-8) : ((bpp >= 8) ? (-2) : (-8 + dsc_roundf((bpp - 6) * (6 / 2.0)))); *p++ = (bpp <= 6) ? (-8) : ((bpp >= 8) ? (-4) : (-8 + dsc_roundf((bpp - 6) * (4 / 2.0)))); *p++ = (bpp <= 6) ? (-8) : ((bpp >= 8) ? (-6) : (-8 + dsc_roundf((bpp - 6) * (2 / 2.0)))); *p++ = (bpp <= 6) ? (-10) : ((bpp >= 8) ? (-8) : (-10 + dsc_roundf((bpp - 6) * (2 / 2.0)))); *p++ = -10; *p++ = (bpp <= 4) ? (-12) : ((bpp >= 5) ? (-10) : (-12 + dsc_roundf((bpp - 4) * (2 / 1.0)))); *p++ = -12; *p++ = -12; *p++ = -12; } } static int median3(int a, int b, int c) { if (a > b) swap(a, b); if (b > c) swap(b, c); if (a > b) swap(b, c); return b; } static void _do_calc_rc_params(struct rc_params *rc, enum colour_mode cm, enum bits_per_comp bpc, u16 drm_bpp, bool is_navite_422_or_420, int slice_width, int slice_height, int minor_version) { float bpp; float bpp_group; float initial_xmit_delay_factor; int padding_pixels; int i; bpp = ((float)drm_bpp / 16.0); /* in native_422 or native_420 modes, the bits_per_pixel is double the * target bpp (the latter is what calc_rc_params expects) */ if (is_navite_422_or_420) bpp /= 2.0; rc->rc_quant_incr_limit0 = ((bpc == BPC_8) ? 11 : (bpc == BPC_10 ? 15 : 19)) - ((minor_version == 1 && cm == CM_444) ? 1 : 0); rc->rc_quant_incr_limit1 = ((bpc == BPC_8) ? 11 : (bpc == BPC_10 ? 15 : 19)) - ((minor_version == 1 && cm == CM_444) ? 1 : 0); bpp_group = MODE_SELECT(bpp, bpp * 2.0, bpp * 2.0); switch (cm) { case CM_420: rc->initial_fullness_offset = (bpp >= 6) ? (2048) : ((bpp <= 4) ? (6144) : ((((bpp > 4) && (bpp <= 5))) ? (6144 - dsc_roundf((bpp - 4) * (512))) : (5632 - dsc_roundf((bpp - 5) * (3584))))); rc->first_line_bpg_offset = median3(0, (12 + (int) (0.09 * min(34, slice_height - 8))), (int)((3 * bpc * 3) - (3 * bpp_group))); rc->second_line_bpg_offset = median3(0, 12, (int)((3 * bpc * 3) - (3 * bpp_group))); break; case CM_422: rc->initial_fullness_offset = (bpp >= 8) ? (2048) : ((bpp <= 7) ? (5632) : (5632 - dsc_roundf((bpp - 7) * (3584)))); rc->first_line_bpg_offset = median3(0, (12 + (int) (0.09 * min(34, slice_height - 8))), (int)((3 * bpc * 4) - (3 * bpp_group))); rc->second_line_bpg_offset = 0; break; case CM_444: case CM_RGB: rc->initial_fullness_offset = (bpp >= 12) ? (2048) : ((bpp <= 8) ? (6144) : ((((bpp > 8) && (bpp <= 10))) ? (6144 - dsc_roundf((bpp - 8) * (512 / 2))) : (5632 - dsc_roundf((bpp - 10) * (3584 / 2))))); rc->first_line_bpg_offset = median3(0, (12 + (int) (0.09 * min(34, slice_height - 8))), (int)(((3 * bpc + (cm == CM_444 ? 0 : 2)) * 3) - (3 * bpp_group))); rc->second_line_bpg_offset = 0; break; } initial_xmit_delay_factor = (cm == CM_444 || cm == CM_RGB) ? 1.0 : 2.0; rc->initial_xmit_delay = dsc_roundf(8192.0/2.0/bpp/initial_xmit_delay_factor); if (cm == CM_422 || cm == CM_420) slice_width /= 2; padding_pixels = ((slice_width % 3) != 0) ? (3 - (slice_width % 3)) * (rc->initial_xmit_delay / slice_width) : 0; if (3 * bpp_group >= (((rc->initial_xmit_delay + 2) / 3) * (3 + (cm == CM_422)))) { if ((rc->initial_xmit_delay + padding_pixels) % 3 == 1) rc->initial_xmit_delay++; } rc->flatness_min_qp = ((bpc == BPC_8) ? (3) : ((bpc == BPC_10) ? (7) : (11))) - ((minor_version == 1 && cm == CM_444) ? 1 : 0); rc->flatness_max_qp = ((bpc == BPC_8) ? (12) : ((bpc == BPC_10) ? (16) : (20))) - ((minor_version == 1 && cm == CM_444) ? 1 : 0); rc->flatness_det_thresh = 2 << (bpc - 8); get_qp_set(rc->qp_min, cm, bpc, DAL_MM_MIN, bpp); get_qp_set(rc->qp_max, cm, bpc, DAL_MM_MAX, bpp); if (cm == CM_444 && minor_version == 1) { for (i = 0; i < QP_SET_SIZE; ++i) { rc->qp_min[i] = rc->qp_min[i] > 0 ? rc->qp_min[i] - 1 : 0; rc->qp_max[i] = rc->qp_max[i] > 0 ? rc->qp_max[i] - 1 : 0; } } get_ofs_set(rc->ofs, cm, bpp); /* fixed parameters */ rc->rc_model_size = 8192; rc->rc_edge_factor = 6; rc->rc_tgt_offset_hi = 3; rc->rc_tgt_offset_lo = 3; rc->rc_buf_thresh[0] = 896; rc->rc_buf_thresh[1] = 1792; rc->rc_buf_thresh[2] = 2688; rc->rc_buf_thresh[3] = 3584; rc->rc_buf_thresh[4] = 4480; rc->rc_buf_thresh[5] = 5376; rc->rc_buf_thresh[6] = 6272; rc->rc_buf_thresh[7] = 6720; rc->rc_buf_thresh[8] = 7168; rc->rc_buf_thresh[9] = 7616; rc->rc_buf_thresh[10] = 7744; rc->rc_buf_thresh[11] = 7872; rc->rc_buf_thresh[12] = 8000; rc->rc_buf_thresh[13] = 8064; } static u32 _do_bytes_per_pixel_calc(int slice_width, u16 drm_bpp, bool is_navite_422_or_420) { float bpp; u32 bytes_per_pixel; double d_bytes_per_pixel; bpp = ((float)drm_bpp / 16.0); d_bytes_per_pixel = dsc_ceil(bpp * slice_width / 8.0) / slice_width; // TODO: Make sure the formula for calculating this is precise (ceiling // vs. floor, and at what point they should be applied) if (is_navite_422_or_420) d_bytes_per_pixel /= 2; bytes_per_pixel = (u32)dsc_ceil(d_bytes_per_pixel * 0x10000000); return bytes_per_pixel; } static u32 _do_calc_dsc_bpp_x16(u32 stream_bandwidth_kbps, u32 pix_clk_100hz, u32 bpp_increment_div) { u32 dsc_target_bpp_x16; float f_dsc_target_bpp; float f_stream_bandwidth_100bps; // bpp_increment_div is actually precision u32 precision = bpp_increment_div; f_stream_bandwidth_100bps = stream_bandwidth_kbps * 10.0f; f_dsc_target_bpp = f_stream_bandwidth_100bps / pix_clk_100hz; // Round down to the nearest precision stop to bring it into DSC spec // range dsc_target_bpp_x16 = (u32)(f_dsc_target_bpp * precision); dsc_target_bpp_x16 = (dsc_target_bpp_x16 * 16) / precision; return dsc_target_bpp_x16; } /** * calc_rc_params - reads the user's cmdline mode * @rc: DC internal DSC parameters * @pps: DRM struct with all required DSC values * * This function expects a drm_dsc_config data struct with all the required DSC * values previously filled out by our driver and based on this information it * computes some of the DSC values. * * @note This calculation requires float point operation, most of it executes * under kernel_fpu_{begin,end}. */ void calc_rc_params(struct rc_params *rc, const struct drm_dsc_config *pps) { enum colour_mode mode; enum bits_per_comp bpc; bool is_navite_422_or_420; u16 drm_bpp = pps->bits_per_pixel; int slice_width = pps->slice_width; int slice_height = pps->slice_height; mode = pps->convert_rgb ? CM_RGB : (pps->simple_422 ? CM_444 : (pps->native_422 ? CM_422 : pps->native_420 ? CM_420 : CM_444)); bpc = (pps->bits_per_component == 8) ? BPC_8 : (pps->bits_per_component == 10) ? BPC_10 : BPC_12; is_navite_422_or_420 = pps->native_422 || pps->native_420; DC_FP_START(); _do_calc_rc_params(rc, mode, bpc, drm_bpp, is_navite_422_or_420, slice_width, slice_height, pps->dsc_version_minor); DC_FP_END(); } /** * calc_dsc_bytes_per_pixel - calculate bytes per pixel * @pps: DRM struct with all required DSC values * * Based on the information inside drm_dsc_config, this function calculates the * total of bytes per pixel. * * @note This calculation requires float point operation, most of it executes * under kernel_fpu_{begin,end}. * * Return: * Return the number of bytes per pixel */ u32 calc_dsc_bytes_per_pixel(const struct drm_dsc_config *pps) { u32 ret; u16 drm_bpp = pps->bits_per_pixel; int slice_width = pps->slice_width; bool is_navite_422_or_420 = pps->native_422 || pps->native_420; DC_FP_START(); ret = _do_bytes_per_pixel_calc(slice_width, drm_bpp, is_navite_422_or_420); DC_FP_END(); return ret; } /** * calc_dsc_bpp_x16 - retrieve the dsc bits per pixel * @stream_bandwidth_kbps: * @pix_clk_100hz: * @bpp_increment_div: * * Calculate the total of bits per pixel for DSC configuration. * * @note This calculation requires float point operation, most of it executes * under kernel_fpu_{begin,end}. */ u32 calc_dsc_bpp_x16(u32 stream_bandwidth_kbps, u32 pix_clk_100hz, u32 bpp_increment_div) { u32 dsc_bpp; DC_FP_START(); dsc_bpp = _do_calc_dsc_bpp_x16(stream_bandwidth_kbps, pix_clk_100hz, bpp_increment_div); DC_FP_END(); return dsc_bpp; } |