/* * 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 #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 = MM_MIN, max = 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, u8 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, MM_MIN, bpp); get_qp_set(rc->qp_max, cm, bpc, 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, u8 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; u8 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; u8 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; }