Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Harry Wentland | 4074 | 88.55% | 5 | 15.15% |
Nikola Cornij | 295 | 6.41% | 8 | 24.24% |
Eryk Brol | 51 | 1.11% | 2 | 6.06% |
Roman Li | 44 | 0.96% | 1 | 3.03% |
Dmytro Laktyushkin | 26 | 0.57% | 4 | 12.12% |
Eric Bernstein | 25 | 0.54% | 2 | 6.06% |
Wenjing Liu | 20 | 0.43% | 1 | 3.03% |
Yi-Ling Chen | 19 | 0.41% | 1 | 3.03% |
David Francis | 16 | 0.35% | 1 | 3.03% |
Alex Deucher | 13 | 0.28% | 2 | 6.06% |
Dave Airlie | 6 | 0.13% | 1 | 3.03% |
Ding Wang | 4 | 0.09% | 1 | 3.03% |
Thomas Zimmermann | 3 | 0.07% | 1 | 3.03% |
Charlene Liu | 2 | 0.04% | 1 | 3.03% |
Yue Hin Lau | 2 | 0.04% | 1 | 3.03% |
Colin Ian King | 1 | 0.02% | 1 | 3.03% |
Total | 4601 | 33 |
/* * 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/display/drm_dsc_helper.h> #include "reg_helper.h" #include "dcn20_dsc.h" #include "dsc/dscc_types.h" static void dsc_log_pps(struct display_stream_compressor *dsc, struct drm_dsc_config *pps); static bool dsc_prepare_config(const struct dsc_config *dsc_cfg, struct dsc_reg_values *dsc_reg_vals, struct dsc_optc_config *dsc_optc_cfg); static void dsc_init_reg_values(struct dsc_reg_values *reg_vals); static void dsc_update_from_dsc_parameters(struct dsc_reg_values *reg_vals, const struct dsc_parameters *dsc_params); static void dsc_write_to_registers(struct display_stream_compressor *dsc, const struct dsc_reg_values *reg_vals); static enum dsc_pixel_format dsc_dc_pixel_encoding_to_dsc_pixel_format(enum dc_pixel_encoding dc_pix_enc, bool is_ycbcr422_simple); static enum dsc_bits_per_comp dsc_dc_color_depth_to_dsc_bits_per_comp(enum dc_color_depth); /* Object I/F functions */ static void dsc2_get_enc_caps(struct dsc_enc_caps *dsc_enc_caps, int pixel_clock_100Hz); static void dsc2_read_state(struct display_stream_compressor *dsc, struct dcn_dsc_state *s); static bool dsc2_validate_stream(struct display_stream_compressor *dsc, const struct dsc_config *dsc_cfg); static void dsc2_set_config(struct display_stream_compressor *dsc, const struct dsc_config *dsc_cfg, struct dsc_optc_config *dsc_optc_cfg); static bool dsc2_get_packed_pps(struct display_stream_compressor *dsc, const struct dsc_config *dsc_cfg, uint8_t *dsc_packed_pps); static void dsc2_enable(struct display_stream_compressor *dsc, int opp_pipe); static void dsc2_disable(struct display_stream_compressor *dsc); static void dsc2_disconnect(struct display_stream_compressor *dsc); const struct dsc_funcs dcn20_dsc_funcs = { .dsc_get_enc_caps = dsc2_get_enc_caps, .dsc_read_state = dsc2_read_state, .dsc_validate_stream = dsc2_validate_stream, .dsc_set_config = dsc2_set_config, .dsc_get_packed_pps = dsc2_get_packed_pps, .dsc_enable = dsc2_enable, .dsc_disable = dsc2_disable, .dsc_disconnect = dsc2_disconnect, }; /* Macro definitios for REG_SET macros*/ #define CTX \ dsc20->base.ctx #define REG(reg)\ dsc20->dsc_regs->reg #undef FN #define FN(reg_name, field_name) \ dsc20->dsc_shift->field_name, dsc20->dsc_mask->field_name #define DC_LOGGER \ dsc->ctx->logger enum dsc_bits_per_comp { DSC_BPC_8 = 8, DSC_BPC_10 = 10, DSC_BPC_12 = 12, DSC_BPC_UNKNOWN }; /* API functions (external or via structure->function_pointer) */ void dsc2_construct(struct dcn20_dsc *dsc, struct dc_context *ctx, int inst, const struct dcn20_dsc_registers *dsc_regs, const struct dcn20_dsc_shift *dsc_shift, const struct dcn20_dsc_mask *dsc_mask) { dsc->base.ctx = ctx; dsc->base.inst = inst; dsc->base.funcs = &dcn20_dsc_funcs; dsc->dsc_regs = dsc_regs; dsc->dsc_shift = dsc_shift; dsc->dsc_mask = dsc_mask; dsc->max_image_width = 5184; } #define DCN20_MAX_PIXEL_CLOCK_Mhz 1188 #define DCN20_MAX_DISPLAY_CLOCK_Mhz 1200 /* This returns the capabilities for a single DSC encoder engine. Number of slices and total throughput * can be doubled, tripled etc. by using additional DSC engines. */ static void dsc2_get_enc_caps(struct dsc_enc_caps *dsc_enc_caps, int pixel_clock_100Hz) { dsc_enc_caps->dsc_version = 0x21; /* v1.2 - DP spec defined it in reverse order and we kept it */ dsc_enc_caps->slice_caps.bits.NUM_SLICES_1 = 1; dsc_enc_caps->slice_caps.bits.NUM_SLICES_2 = 1; dsc_enc_caps->slice_caps.bits.NUM_SLICES_3 = 1; dsc_enc_caps->slice_caps.bits.NUM_SLICES_4 = 1; dsc_enc_caps->lb_bit_depth = 13; dsc_enc_caps->is_block_pred_supported = true; dsc_enc_caps->color_formats.bits.RGB = 1; dsc_enc_caps->color_formats.bits.YCBCR_444 = 1; dsc_enc_caps->color_formats.bits.YCBCR_SIMPLE_422 = 1; dsc_enc_caps->color_formats.bits.YCBCR_NATIVE_422 = 0; dsc_enc_caps->color_formats.bits.YCBCR_NATIVE_420 = 1; dsc_enc_caps->color_depth.bits.COLOR_DEPTH_8_BPC = 1; dsc_enc_caps->color_depth.bits.COLOR_DEPTH_10_BPC = 1; dsc_enc_caps->color_depth.bits.COLOR_DEPTH_12_BPC = 1; /* Maximum total throughput with all the slices combined. This is different from how DP spec specifies it. * Our decoder's total throughput in Pix/s is equal to DISPCLK. This is then shared between slices. * The value below is the absolute maximum value. The actual throughput may be lower, but it'll always * be sufficient to process the input pixel rate fed into a single DSC engine. */ dsc_enc_caps->max_total_throughput_mps = DCN20_MAX_DISPLAY_CLOCK_Mhz; /* For pixel clock bigger than a single-pipe limit we'll need two engines, which then doubles our * throughput and number of slices, but also introduces a lower limit of 2 slices */ if (pixel_clock_100Hz >= DCN20_MAX_PIXEL_CLOCK_Mhz*10000) { dsc_enc_caps->slice_caps.bits.NUM_SLICES_1 = 0; dsc_enc_caps->slice_caps.bits.NUM_SLICES_8 = 1; dsc_enc_caps->max_total_throughput_mps = DCN20_MAX_DISPLAY_CLOCK_Mhz * 2; } // TODO DSC: This is actually image width limitation, not a slice width. This should be added to the criteria to use ODM. dsc_enc_caps->max_slice_width = 5184; /* (including 64 overlap pixels for eDP MSO mode) */ dsc_enc_caps->bpp_increment_div = 16; /* 1/16th of a bit */ } /* this function read dsc related register fields to be logged later in dcn10_log_hw_state * into a dcn_dsc_state struct. */ static void dsc2_read_state(struct display_stream_compressor *dsc, struct dcn_dsc_state *s) { struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); REG_GET(DSC_TOP_CONTROL, DSC_CLOCK_EN, &s->dsc_clock_en); REG_GET(DSCC_PPS_CONFIG3, SLICE_WIDTH, &s->dsc_slice_width); REG_GET(DSCC_PPS_CONFIG1, BITS_PER_PIXEL, &s->dsc_bits_per_pixel); REG_GET(DSCC_PPS_CONFIG3, SLICE_HEIGHT, &s->dsc_slice_height); REG_GET(DSCC_PPS_CONFIG1, CHUNK_SIZE, &s->dsc_chunk_size); REG_GET(DSCC_PPS_CONFIG2, PIC_WIDTH, &s->dsc_pic_width); REG_GET(DSCC_PPS_CONFIG2, PIC_HEIGHT, &s->dsc_pic_height); REG_GET(DSCC_PPS_CONFIG7, SLICE_BPG_OFFSET, &s->dsc_slice_bpg_offset); REG_GET_2(DSCRM_DSC_FORWARD_CONFIG, DSCRM_DSC_FORWARD_EN, &s->dsc_fw_en, DSCRM_DSC_OPP_PIPE_SOURCE, &s->dsc_opp_source); } static bool dsc2_validate_stream(struct display_stream_compressor *dsc, const struct dsc_config *dsc_cfg) { struct dsc_optc_config dsc_optc_cfg; struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); if (dsc_cfg->pic_width > dsc20->max_image_width) return false; return dsc_prepare_config(dsc_cfg, &dsc20->reg_vals, &dsc_optc_cfg); } static void dsc_config_log(struct display_stream_compressor *dsc, const struct dsc_config *config) { DC_LOG_DSC("\tnum_slices_h %d", config->dc_dsc_cfg.num_slices_h); DC_LOG_DSC("\tnum_slices_v %d", config->dc_dsc_cfg.num_slices_v); DC_LOG_DSC("\tbits_per_pixel %d (%d.%04d)", config->dc_dsc_cfg.bits_per_pixel, config->dc_dsc_cfg.bits_per_pixel / 16, ((config->dc_dsc_cfg.bits_per_pixel % 16) * 10000) / 16); DC_LOG_DSC("\tcolor_depth %d", config->color_depth); } static void dsc2_set_config(struct display_stream_compressor *dsc, const struct dsc_config *dsc_cfg, struct dsc_optc_config *dsc_optc_cfg) { bool is_config_ok; struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); DC_LOG_DSC(" "); DC_LOG_DSC("Setting DSC Config at DSC inst %d", dsc->inst); dsc_config_log(dsc, dsc_cfg); is_config_ok = dsc_prepare_config(dsc_cfg, &dsc20->reg_vals, dsc_optc_cfg); ASSERT(is_config_ok); DC_LOG_DSC("programming DSC Picture Parameter Set (PPS):"); dsc_log_pps(dsc, &dsc20->reg_vals.pps); dsc_write_to_registers(dsc, &dsc20->reg_vals); } static bool dsc2_get_packed_pps(struct display_stream_compressor *dsc, const struct dsc_config *dsc_cfg, uint8_t *dsc_packed_pps) { bool is_config_ok; struct dsc_reg_values dsc_reg_vals; struct dsc_optc_config dsc_optc_cfg; memset(&dsc_reg_vals, 0, sizeof(dsc_reg_vals)); memset(&dsc_optc_cfg, 0, sizeof(dsc_optc_cfg)); DC_LOG_DSC("Getting packed DSC PPS for DSC Config:"); dsc_config_log(dsc, dsc_cfg); DC_LOG_DSC("DSC Picture Parameter Set (PPS):"); is_config_ok = dsc_prepare_config(dsc_cfg, &dsc_reg_vals, &dsc_optc_cfg); ASSERT(is_config_ok); drm_dsc_pps_payload_pack((struct drm_dsc_picture_parameter_set *)dsc_packed_pps, &dsc_reg_vals.pps); dsc_log_pps(dsc, &dsc_reg_vals.pps); return is_config_ok; } static void dsc2_enable(struct display_stream_compressor *dsc, int opp_pipe) { struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); int dsc_clock_en; int dsc_fw_config; int enabled_opp_pipe; DC_LOG_DSC("enable DSC %d at opp pipe %d", dsc->inst, opp_pipe); REG_GET(DSC_TOP_CONTROL, DSC_CLOCK_EN, &dsc_clock_en); REG_GET_2(DSCRM_DSC_FORWARD_CONFIG, DSCRM_DSC_FORWARD_EN, &dsc_fw_config, DSCRM_DSC_OPP_PIPE_SOURCE, &enabled_opp_pipe); if ((dsc_clock_en || dsc_fw_config) && enabled_opp_pipe != opp_pipe) { DC_LOG_DSC("ERROR: DSC %d at opp pipe %d already enabled!", dsc->inst, enabled_opp_pipe); ASSERT(0); } REG_UPDATE(DSC_TOP_CONTROL, DSC_CLOCK_EN, 1); REG_UPDATE_2(DSCRM_DSC_FORWARD_CONFIG, DSCRM_DSC_FORWARD_EN, 1, DSCRM_DSC_OPP_PIPE_SOURCE, opp_pipe); } static void dsc2_disable(struct display_stream_compressor *dsc) { struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); int dsc_clock_en; int dsc_fw_config; int enabled_opp_pipe; DC_LOG_DSC("disable DSC %d", dsc->inst); REG_GET(DSC_TOP_CONTROL, DSC_CLOCK_EN, &dsc_clock_en); REG_GET_2(DSCRM_DSC_FORWARD_CONFIG, DSCRM_DSC_FORWARD_EN, &dsc_fw_config, DSCRM_DSC_OPP_PIPE_SOURCE, &enabled_opp_pipe); if (!dsc_clock_en || !dsc_fw_config) { DC_LOG_DSC("ERROR: DSC %d at opp pipe %d already disabled!", dsc->inst, enabled_opp_pipe); ASSERT(0); } REG_UPDATE(DSCRM_DSC_FORWARD_CONFIG, DSCRM_DSC_FORWARD_EN, 0); REG_UPDATE(DSC_TOP_CONTROL, DSC_CLOCK_EN, 0); } static void dsc2_disconnect(struct display_stream_compressor *dsc) { struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); DC_LOG_DSC("disconnect DSC %d", dsc->inst); REG_UPDATE(DSCRM_DSC_FORWARD_CONFIG, DSCRM_DSC_FORWARD_EN, 0); } /* This module's internal functions */ static void dsc_log_pps(struct display_stream_compressor *dsc, struct drm_dsc_config *pps) { int i; int bits_per_pixel = pps->bits_per_pixel; DC_LOG_DSC("\tdsc_version_major %d", pps->dsc_version_major); DC_LOG_DSC("\tdsc_version_minor %d", pps->dsc_version_minor); DC_LOG_DSC("\tbits_per_component %d", pps->bits_per_component); DC_LOG_DSC("\tline_buf_depth %d", pps->line_buf_depth); DC_LOG_DSC("\tblock_pred_enable %d", pps->block_pred_enable); DC_LOG_DSC("\tconvert_rgb %d", pps->convert_rgb); DC_LOG_DSC("\tsimple_422 %d", pps->simple_422); DC_LOG_DSC("\tvbr_enable %d", pps->vbr_enable); DC_LOG_DSC("\tbits_per_pixel %d (%d.%04d)", bits_per_pixel, bits_per_pixel / 16, ((bits_per_pixel % 16) * 10000) / 16); DC_LOG_DSC("\tpic_height %d", pps->pic_height); DC_LOG_DSC("\tpic_width %d", pps->pic_width); DC_LOG_DSC("\tslice_height %d", pps->slice_height); DC_LOG_DSC("\tslice_width %d", pps->slice_width); DC_LOG_DSC("\tslice_chunk_size %d", pps->slice_chunk_size); DC_LOG_DSC("\tinitial_xmit_delay %d", pps->initial_xmit_delay); DC_LOG_DSC("\tinitial_dec_delay %d", pps->initial_dec_delay); DC_LOG_DSC("\tinitial_scale_value %d", pps->initial_scale_value); DC_LOG_DSC("\tscale_increment_interval %d", pps->scale_increment_interval); DC_LOG_DSC("\tscale_decrement_interval %d", pps->scale_decrement_interval); DC_LOG_DSC("\tfirst_line_bpg_offset %d", pps->first_line_bpg_offset); DC_LOG_DSC("\tnfl_bpg_offset %d", pps->nfl_bpg_offset); DC_LOG_DSC("\tslice_bpg_offset %d", pps->slice_bpg_offset); DC_LOG_DSC("\tinitial_offset %d", pps->initial_offset); DC_LOG_DSC("\tfinal_offset %d", pps->final_offset); DC_LOG_DSC("\tflatness_min_qp %d", pps->flatness_min_qp); DC_LOG_DSC("\tflatness_max_qp %d", pps->flatness_max_qp); /* DC_LOG_DSC("\trc_parameter_set %d", pps->rc_parameter_set); */ DC_LOG_DSC("\tnative_420 %d", pps->native_420); DC_LOG_DSC("\tnative_422 %d", pps->native_422); DC_LOG_DSC("\tsecond_line_bpg_offset %d", pps->second_line_bpg_offset); DC_LOG_DSC("\tnsl_bpg_offset %d", pps->nsl_bpg_offset); DC_LOG_DSC("\tsecond_line_offset_adj %d", pps->second_line_offset_adj); DC_LOG_DSC("\trc_model_size %d", pps->rc_model_size); DC_LOG_DSC("\trc_edge_factor %d", pps->rc_edge_factor); DC_LOG_DSC("\trc_quant_incr_limit0 %d", pps->rc_quant_incr_limit0); DC_LOG_DSC("\trc_quant_incr_limit1 %d", pps->rc_quant_incr_limit1); DC_LOG_DSC("\trc_tgt_offset_high %d", pps->rc_tgt_offset_high); DC_LOG_DSC("\trc_tgt_offset_low %d", pps->rc_tgt_offset_low); for (i = 0; i < NUM_BUF_RANGES - 1; i++) DC_LOG_DSC("\trc_buf_thresh[%d] %d", i, pps->rc_buf_thresh[i]); for (i = 0; i < NUM_BUF_RANGES; i++) { DC_LOG_DSC("\trc_range_parameters[%d].range_min_qp %d", i, pps->rc_range_params[i].range_min_qp); DC_LOG_DSC("\trc_range_parameters[%d].range_max_qp %d", i, pps->rc_range_params[i].range_max_qp); DC_LOG_DSC("\trc_range_parameters[%d].range_bpg_offset %d", i, pps->rc_range_params[i].range_bpg_offset); } } static bool dsc_prepare_config(const struct dsc_config *dsc_cfg, struct dsc_reg_values *dsc_reg_vals, struct dsc_optc_config *dsc_optc_cfg) { struct dsc_parameters dsc_params; /* Validate input parameters */ ASSERT(dsc_cfg->dc_dsc_cfg.num_slices_h); ASSERT(dsc_cfg->dc_dsc_cfg.num_slices_v); ASSERT(dsc_cfg->dc_dsc_cfg.version_minor == 1 || dsc_cfg->dc_dsc_cfg.version_minor == 2); ASSERT(dsc_cfg->pic_width); ASSERT(dsc_cfg->pic_height); ASSERT((dsc_cfg->dc_dsc_cfg.version_minor == 1 && (8 <= dsc_cfg->dc_dsc_cfg.linebuf_depth && dsc_cfg->dc_dsc_cfg.linebuf_depth <= 13)) || (dsc_cfg->dc_dsc_cfg.version_minor == 2 && ((8 <= dsc_cfg->dc_dsc_cfg.linebuf_depth && dsc_cfg->dc_dsc_cfg.linebuf_depth <= 15) || dsc_cfg->dc_dsc_cfg.linebuf_depth == 0))); ASSERT(96 <= dsc_cfg->dc_dsc_cfg.bits_per_pixel && dsc_cfg->dc_dsc_cfg.bits_per_pixel <= 0x3ff); // 6.0 <= bits_per_pixel <= 63.9375 if (!dsc_cfg->dc_dsc_cfg.num_slices_v || !dsc_cfg->dc_dsc_cfg.num_slices_h || !(dsc_cfg->dc_dsc_cfg.version_minor == 1 || dsc_cfg->dc_dsc_cfg.version_minor == 2) || !dsc_cfg->pic_width || !dsc_cfg->pic_height || !((dsc_cfg->dc_dsc_cfg.version_minor == 1 && // v1.1 line buffer depth range: 8 <= dsc_cfg->dc_dsc_cfg.linebuf_depth && dsc_cfg->dc_dsc_cfg.linebuf_depth <= 13) || (dsc_cfg->dc_dsc_cfg.version_minor == 2 && // v1.2 line buffer depth range: ((8 <= dsc_cfg->dc_dsc_cfg.linebuf_depth && dsc_cfg->dc_dsc_cfg.linebuf_depth <= 15) || dsc_cfg->dc_dsc_cfg.linebuf_depth == 0))) || !(96 <= dsc_cfg->dc_dsc_cfg.bits_per_pixel && dsc_cfg->dc_dsc_cfg.bits_per_pixel <= 0x3ff)) { dm_output_to_console("%s: Invalid parameters\n", __func__); return false; } dsc_init_reg_values(dsc_reg_vals); /* Copy input config */ dsc_reg_vals->pixel_format = dsc_dc_pixel_encoding_to_dsc_pixel_format(dsc_cfg->pixel_encoding, dsc_cfg->dc_dsc_cfg.ycbcr422_simple); dsc_reg_vals->num_slices_h = dsc_cfg->dc_dsc_cfg.num_slices_h; dsc_reg_vals->num_slices_v = dsc_cfg->dc_dsc_cfg.num_slices_v; dsc_reg_vals->pps.dsc_version_minor = dsc_cfg->dc_dsc_cfg.version_minor; dsc_reg_vals->pps.pic_width = dsc_cfg->pic_width; dsc_reg_vals->pps.pic_height = dsc_cfg->pic_height; dsc_reg_vals->pps.bits_per_component = dsc_dc_color_depth_to_dsc_bits_per_comp(dsc_cfg->color_depth); dsc_reg_vals->pps.block_pred_enable = dsc_cfg->dc_dsc_cfg.block_pred_enable; dsc_reg_vals->pps.line_buf_depth = dsc_cfg->dc_dsc_cfg.linebuf_depth; dsc_reg_vals->alternate_ich_encoding_en = dsc_reg_vals->pps.dsc_version_minor == 1 ? 0 : 1; dsc_reg_vals->ich_reset_at_eol = (dsc_cfg->is_odm || dsc_reg_vals->num_slices_h > 1) ? 0xF : 0; // TODO: in addition to validating slice height (pic height must be divisible by slice height), // see what happens when the same condition doesn't apply for slice_width/pic_width. dsc_reg_vals->pps.slice_width = dsc_cfg->pic_width / dsc_cfg->dc_dsc_cfg.num_slices_h; dsc_reg_vals->pps.slice_height = dsc_cfg->pic_height / dsc_cfg->dc_dsc_cfg.num_slices_v; ASSERT(dsc_reg_vals->pps.slice_height * dsc_cfg->dc_dsc_cfg.num_slices_v == dsc_cfg->pic_height); if (!(dsc_reg_vals->pps.slice_height * dsc_cfg->dc_dsc_cfg.num_slices_v == dsc_cfg->pic_height)) { dm_output_to_console("%s: pix height %d not divisible by num_slices_v %d\n\n", __func__, dsc_cfg->pic_height, dsc_cfg->dc_dsc_cfg.num_slices_v); return false; } dsc_reg_vals->bpp_x32 = dsc_cfg->dc_dsc_cfg.bits_per_pixel << 1; if (dsc_reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR420 || dsc_reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR422) dsc_reg_vals->pps.bits_per_pixel = dsc_reg_vals->bpp_x32; else dsc_reg_vals->pps.bits_per_pixel = dsc_reg_vals->bpp_x32 >> 1; dsc_reg_vals->pps.convert_rgb = dsc_reg_vals->pixel_format == DSC_PIXFMT_RGB ? 1 : 0; dsc_reg_vals->pps.native_422 = (dsc_reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR422); dsc_reg_vals->pps.native_420 = (dsc_reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR420); dsc_reg_vals->pps.simple_422 = (dsc_reg_vals->pixel_format == DSC_PIXFMT_SIMPLE_YCBCR422); if (dscc_compute_dsc_parameters(&dsc_reg_vals->pps, &dsc_params)) { dm_output_to_console("%s: DSC config failed\n", __func__); return false; } dsc_update_from_dsc_parameters(dsc_reg_vals, &dsc_params); dsc_optc_cfg->bytes_per_pixel = dsc_params.bytes_per_pixel; dsc_optc_cfg->slice_width = dsc_reg_vals->pps.slice_width; dsc_optc_cfg->is_pixel_format_444 = dsc_reg_vals->pixel_format == DSC_PIXFMT_RGB || dsc_reg_vals->pixel_format == DSC_PIXFMT_YCBCR444 || dsc_reg_vals->pixel_format == DSC_PIXFMT_SIMPLE_YCBCR422; return true; } static enum dsc_pixel_format dsc_dc_pixel_encoding_to_dsc_pixel_format(enum dc_pixel_encoding dc_pix_enc, bool is_ycbcr422_simple) { enum dsc_pixel_format dsc_pix_fmt = DSC_PIXFMT_UNKNOWN; /* NOTE: We don't support DSC_PIXFMT_SIMPLE_YCBCR422 */ switch (dc_pix_enc) { case PIXEL_ENCODING_RGB: dsc_pix_fmt = DSC_PIXFMT_RGB; break; case PIXEL_ENCODING_YCBCR422: if (is_ycbcr422_simple) dsc_pix_fmt = DSC_PIXFMT_SIMPLE_YCBCR422; else dsc_pix_fmt = DSC_PIXFMT_NATIVE_YCBCR422; break; case PIXEL_ENCODING_YCBCR444: dsc_pix_fmt = DSC_PIXFMT_YCBCR444; break; case PIXEL_ENCODING_YCBCR420: dsc_pix_fmt = DSC_PIXFMT_NATIVE_YCBCR420; break; default: dsc_pix_fmt = DSC_PIXFMT_UNKNOWN; break; } ASSERT(dsc_pix_fmt != DSC_PIXFMT_UNKNOWN); return dsc_pix_fmt; } static enum dsc_bits_per_comp dsc_dc_color_depth_to_dsc_bits_per_comp(enum dc_color_depth dc_color_depth) { enum dsc_bits_per_comp bpc = DSC_BPC_UNKNOWN; switch (dc_color_depth) { case COLOR_DEPTH_888: bpc = DSC_BPC_8; break; case COLOR_DEPTH_101010: bpc = DSC_BPC_10; break; case COLOR_DEPTH_121212: bpc = DSC_BPC_12; break; default: bpc = DSC_BPC_UNKNOWN; break; } return bpc; } static void dsc_init_reg_values(struct dsc_reg_values *reg_vals) { int i; memset(reg_vals, 0, sizeof(struct dsc_reg_values)); /* Non-PPS values */ reg_vals->dsc_clock_enable = 1; reg_vals->dsc_clock_gating_disable = 0; reg_vals->underflow_recovery_en = 0; reg_vals->underflow_occurred_int_en = 0; reg_vals->underflow_occurred_status = 0; reg_vals->ich_reset_at_eol = 0; reg_vals->alternate_ich_encoding_en = 0; reg_vals->rc_buffer_model_size = 0; /*reg_vals->disable_ich = 0;*/ reg_vals->dsc_dbg_en = 0; for (i = 0; i < 4; i++) reg_vals->rc_buffer_model_overflow_int_en[i] = 0; /* PPS values */ reg_vals->pps.dsc_version_minor = 2; reg_vals->pps.dsc_version_major = 1; reg_vals->pps.line_buf_depth = 9; reg_vals->pps.bits_per_component = 8; reg_vals->pps.block_pred_enable = 1; reg_vals->pps.slice_chunk_size = 0; reg_vals->pps.pic_width = 0; reg_vals->pps.pic_height = 0; reg_vals->pps.slice_width = 0; reg_vals->pps.slice_height = 0; reg_vals->pps.initial_xmit_delay = 170; reg_vals->pps.initial_dec_delay = 0; reg_vals->pps.initial_scale_value = 0; reg_vals->pps.scale_increment_interval = 0; reg_vals->pps.scale_decrement_interval = 0; reg_vals->pps.nfl_bpg_offset = 0; reg_vals->pps.slice_bpg_offset = 0; reg_vals->pps.nsl_bpg_offset = 0; reg_vals->pps.initial_offset = 6144; reg_vals->pps.final_offset = 0; reg_vals->pps.flatness_min_qp = 3; reg_vals->pps.flatness_max_qp = 12; reg_vals->pps.rc_model_size = 8192; reg_vals->pps.rc_edge_factor = 6; reg_vals->pps.rc_quant_incr_limit0 = 11; reg_vals->pps.rc_quant_incr_limit1 = 11; reg_vals->pps.rc_tgt_offset_low = 3; reg_vals->pps.rc_tgt_offset_high = 3; } /* Updates dsc_reg_values::reg_vals::xxx fields based on the values from computed params. * This is required because dscc_compute_dsc_parameters returns a modified PPS, which in turn * affects non-PPS register values. */ static void dsc_update_from_dsc_parameters(struct dsc_reg_values *reg_vals, const struct dsc_parameters *dsc_params) { int i; reg_vals->pps = dsc_params->pps; // pps_computed will have the "expanded" values; need to shift them to make them fit for regs. for (i = 0; i < NUM_BUF_RANGES - 1; i++) reg_vals->pps.rc_buf_thresh[i] = reg_vals->pps.rc_buf_thresh[i] >> 6; reg_vals->rc_buffer_model_size = dsc_params->rc_buffer_model_size; } static void dsc_write_to_registers(struct display_stream_compressor *dsc, const struct dsc_reg_values *reg_vals) { uint32_t temp_int; struct dcn20_dsc *dsc20 = TO_DCN20_DSC(dsc); REG_SET(DSC_DEBUG_CONTROL, 0, DSC_DBG_EN, reg_vals->dsc_dbg_en); // dsccif registers REG_SET_5(DSCCIF_CONFIG0, 0, INPUT_INTERFACE_UNDERFLOW_RECOVERY_EN, reg_vals->underflow_recovery_en, INPUT_INTERFACE_UNDERFLOW_OCCURRED_INT_EN, reg_vals->underflow_occurred_int_en, INPUT_INTERFACE_UNDERFLOW_OCCURRED_STATUS, reg_vals->underflow_occurred_status, INPUT_PIXEL_FORMAT, reg_vals->pixel_format, DSCCIF_CONFIG0__BITS_PER_COMPONENT, reg_vals->pps.bits_per_component); REG_SET_2(DSCCIF_CONFIG1, 0, PIC_WIDTH, reg_vals->pps.pic_width, PIC_HEIGHT, reg_vals->pps.pic_height); // dscc registers if (dsc20->dsc_mask->ICH_RESET_AT_END_OF_LINE == 0) { REG_SET_3(DSCC_CONFIG0, 0, NUMBER_OF_SLICES_PER_LINE, reg_vals->num_slices_h - 1, ALTERNATE_ICH_ENCODING_EN, reg_vals->alternate_ich_encoding_en, NUMBER_OF_SLICES_IN_VERTICAL_DIRECTION, reg_vals->num_slices_v - 1); } else { REG_SET_4(DSCC_CONFIG0, 0, ICH_RESET_AT_END_OF_LINE, reg_vals->ich_reset_at_eol, NUMBER_OF_SLICES_PER_LINE, reg_vals->num_slices_h - 1, ALTERNATE_ICH_ENCODING_EN, reg_vals->alternate_ich_encoding_en, NUMBER_OF_SLICES_IN_VERTICAL_DIRECTION, reg_vals->num_slices_v - 1); } REG_SET(DSCC_CONFIG1, 0, DSCC_RATE_CONTROL_BUFFER_MODEL_SIZE, reg_vals->rc_buffer_model_size); /*REG_SET_2(DSCC_CONFIG1, 0, DSCC_RATE_CONTROL_BUFFER_MODEL_SIZE, reg_vals->rc_buffer_model_size, DSCC_DISABLE_ICH, reg_vals->disable_ich);*/ REG_SET_4(DSCC_INTERRUPT_CONTROL_STATUS, 0, DSCC_RATE_CONTROL_BUFFER_MODEL0_OVERFLOW_OCCURRED_INT_EN, reg_vals->rc_buffer_model_overflow_int_en[0], DSCC_RATE_CONTROL_BUFFER_MODEL1_OVERFLOW_OCCURRED_INT_EN, reg_vals->rc_buffer_model_overflow_int_en[1], DSCC_RATE_CONTROL_BUFFER_MODEL2_OVERFLOW_OCCURRED_INT_EN, reg_vals->rc_buffer_model_overflow_int_en[2], DSCC_RATE_CONTROL_BUFFER_MODEL3_OVERFLOW_OCCURRED_INT_EN, reg_vals->rc_buffer_model_overflow_int_en[3]); REG_SET_3(DSCC_PPS_CONFIG0, 0, DSC_VERSION_MINOR, reg_vals->pps.dsc_version_minor, LINEBUF_DEPTH, reg_vals->pps.line_buf_depth, DSCC_PPS_CONFIG0__BITS_PER_COMPONENT, reg_vals->pps.bits_per_component); if (reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR420 || reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR422) temp_int = reg_vals->bpp_x32; else temp_int = reg_vals->bpp_x32 >> 1; REG_SET_7(DSCC_PPS_CONFIG1, 0, BITS_PER_PIXEL, temp_int, SIMPLE_422, reg_vals->pixel_format == DSC_PIXFMT_SIMPLE_YCBCR422, CONVERT_RGB, reg_vals->pixel_format == DSC_PIXFMT_RGB, BLOCK_PRED_ENABLE, reg_vals->pps.block_pred_enable, NATIVE_422, reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR422, NATIVE_420, reg_vals->pixel_format == DSC_PIXFMT_NATIVE_YCBCR420, CHUNK_SIZE, reg_vals->pps.slice_chunk_size); REG_SET_2(DSCC_PPS_CONFIG2, 0, PIC_WIDTH, reg_vals->pps.pic_width, PIC_HEIGHT, reg_vals->pps.pic_height); REG_SET_2(DSCC_PPS_CONFIG3, 0, SLICE_WIDTH, reg_vals->pps.slice_width, SLICE_HEIGHT, reg_vals->pps.slice_height); REG_SET(DSCC_PPS_CONFIG4, 0, INITIAL_XMIT_DELAY, reg_vals->pps.initial_xmit_delay); REG_SET_2(DSCC_PPS_CONFIG5, 0, INITIAL_SCALE_VALUE, reg_vals->pps.initial_scale_value, SCALE_INCREMENT_INTERVAL, reg_vals->pps.scale_increment_interval); REG_SET_3(DSCC_PPS_CONFIG6, 0, SCALE_DECREMENT_INTERVAL, reg_vals->pps.scale_decrement_interval, FIRST_LINE_BPG_OFFSET, reg_vals->pps.first_line_bpg_offset, SECOND_LINE_BPG_OFFSET, reg_vals->pps.second_line_bpg_offset); REG_SET_2(DSCC_PPS_CONFIG7, 0, NFL_BPG_OFFSET, reg_vals->pps.nfl_bpg_offset, SLICE_BPG_OFFSET, reg_vals->pps.slice_bpg_offset); REG_SET_2(DSCC_PPS_CONFIG8, 0, NSL_BPG_OFFSET, reg_vals->pps.nsl_bpg_offset, SECOND_LINE_OFFSET_ADJ, reg_vals->pps.second_line_offset_adj); REG_SET_2(DSCC_PPS_CONFIG9, 0, INITIAL_OFFSET, reg_vals->pps.initial_offset, FINAL_OFFSET, reg_vals->pps.final_offset); REG_SET_3(DSCC_PPS_CONFIG10, 0, FLATNESS_MIN_QP, reg_vals->pps.flatness_min_qp, FLATNESS_MAX_QP, reg_vals->pps.flatness_max_qp, RC_MODEL_SIZE, reg_vals->pps.rc_model_size); REG_SET_5(DSCC_PPS_CONFIG11, 0, RC_EDGE_FACTOR, reg_vals->pps.rc_edge_factor, RC_QUANT_INCR_LIMIT0, reg_vals->pps.rc_quant_incr_limit0, RC_QUANT_INCR_LIMIT1, reg_vals->pps.rc_quant_incr_limit1, RC_TGT_OFFSET_LO, reg_vals->pps.rc_tgt_offset_low, RC_TGT_OFFSET_HI, reg_vals->pps.rc_tgt_offset_high); REG_SET_4(DSCC_PPS_CONFIG12, 0, RC_BUF_THRESH0, reg_vals->pps.rc_buf_thresh[0], RC_BUF_THRESH1, reg_vals->pps.rc_buf_thresh[1], RC_BUF_THRESH2, reg_vals->pps.rc_buf_thresh[2], RC_BUF_THRESH3, reg_vals->pps.rc_buf_thresh[3]); REG_SET_4(DSCC_PPS_CONFIG13, 0, RC_BUF_THRESH4, reg_vals->pps.rc_buf_thresh[4], RC_BUF_THRESH5, reg_vals->pps.rc_buf_thresh[5], RC_BUF_THRESH6, reg_vals->pps.rc_buf_thresh[6], RC_BUF_THRESH7, reg_vals->pps.rc_buf_thresh[7]); REG_SET_4(DSCC_PPS_CONFIG14, 0, RC_BUF_THRESH8, reg_vals->pps.rc_buf_thresh[8], RC_BUF_THRESH9, reg_vals->pps.rc_buf_thresh[9], RC_BUF_THRESH10, reg_vals->pps.rc_buf_thresh[10], RC_BUF_THRESH11, reg_vals->pps.rc_buf_thresh[11]); REG_SET_5(DSCC_PPS_CONFIG15, 0, RC_BUF_THRESH12, reg_vals->pps.rc_buf_thresh[12], RC_BUF_THRESH13, reg_vals->pps.rc_buf_thresh[13], RANGE_MIN_QP0, reg_vals->pps.rc_range_params[0].range_min_qp, RANGE_MAX_QP0, reg_vals->pps.rc_range_params[0].range_max_qp, RANGE_BPG_OFFSET0, reg_vals->pps.rc_range_params[0].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG16, 0, RANGE_MIN_QP1, reg_vals->pps.rc_range_params[1].range_min_qp, RANGE_MAX_QP1, reg_vals->pps.rc_range_params[1].range_max_qp, RANGE_BPG_OFFSET1, reg_vals->pps.rc_range_params[1].range_bpg_offset, RANGE_MIN_QP2, reg_vals->pps.rc_range_params[2].range_min_qp, RANGE_MAX_QP2, reg_vals->pps.rc_range_params[2].range_max_qp, RANGE_BPG_OFFSET2, reg_vals->pps.rc_range_params[2].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG17, 0, RANGE_MIN_QP3, reg_vals->pps.rc_range_params[3].range_min_qp, RANGE_MAX_QP3, reg_vals->pps.rc_range_params[3].range_max_qp, RANGE_BPG_OFFSET3, reg_vals->pps.rc_range_params[3].range_bpg_offset, RANGE_MIN_QP4, reg_vals->pps.rc_range_params[4].range_min_qp, RANGE_MAX_QP4, reg_vals->pps.rc_range_params[4].range_max_qp, RANGE_BPG_OFFSET4, reg_vals->pps.rc_range_params[4].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG18, 0, RANGE_MIN_QP5, reg_vals->pps.rc_range_params[5].range_min_qp, RANGE_MAX_QP5, reg_vals->pps.rc_range_params[5].range_max_qp, RANGE_BPG_OFFSET5, reg_vals->pps.rc_range_params[5].range_bpg_offset, RANGE_MIN_QP6, reg_vals->pps.rc_range_params[6].range_min_qp, RANGE_MAX_QP6, reg_vals->pps.rc_range_params[6].range_max_qp, RANGE_BPG_OFFSET6, reg_vals->pps.rc_range_params[6].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG19, 0, RANGE_MIN_QP7, reg_vals->pps.rc_range_params[7].range_min_qp, RANGE_MAX_QP7, reg_vals->pps.rc_range_params[7].range_max_qp, RANGE_BPG_OFFSET7, reg_vals->pps.rc_range_params[7].range_bpg_offset, RANGE_MIN_QP8, reg_vals->pps.rc_range_params[8].range_min_qp, RANGE_MAX_QP8, reg_vals->pps.rc_range_params[8].range_max_qp, RANGE_BPG_OFFSET8, reg_vals->pps.rc_range_params[8].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG20, 0, RANGE_MIN_QP9, reg_vals->pps.rc_range_params[9].range_min_qp, RANGE_MAX_QP9, reg_vals->pps.rc_range_params[9].range_max_qp, RANGE_BPG_OFFSET9, reg_vals->pps.rc_range_params[9].range_bpg_offset, RANGE_MIN_QP10, reg_vals->pps.rc_range_params[10].range_min_qp, RANGE_MAX_QP10, reg_vals->pps.rc_range_params[10].range_max_qp, RANGE_BPG_OFFSET10, reg_vals->pps.rc_range_params[10].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG21, 0, RANGE_MIN_QP11, reg_vals->pps.rc_range_params[11].range_min_qp, RANGE_MAX_QP11, reg_vals->pps.rc_range_params[11].range_max_qp, RANGE_BPG_OFFSET11, reg_vals->pps.rc_range_params[11].range_bpg_offset, RANGE_MIN_QP12, reg_vals->pps.rc_range_params[12].range_min_qp, RANGE_MAX_QP12, reg_vals->pps.rc_range_params[12].range_max_qp, RANGE_BPG_OFFSET12, reg_vals->pps.rc_range_params[12].range_bpg_offset); REG_SET_6(DSCC_PPS_CONFIG22, 0, RANGE_MIN_QP13, reg_vals->pps.rc_range_params[13].range_min_qp, RANGE_MAX_QP13, reg_vals->pps.rc_range_params[13].range_max_qp, RANGE_BPG_OFFSET13, reg_vals->pps.rc_range_params[13].range_bpg_offset, RANGE_MIN_QP14, reg_vals->pps.rc_range_params[14].range_min_qp, RANGE_MAX_QP14, reg_vals->pps.rc_range_params[14].range_max_qp, RANGE_BPG_OFFSET14, reg_vals->pps.rc_range_params[14].range_bpg_offset); }
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