/* * Copyright 2022 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 * */ /* FILE POLICY AND INTENDED USAGE: * This file implements retrieval and configuration of eDP panel features such * as PSR and ABM and it also manages specs defined eDP panel power sequences. */ #include "link_edp_panel_control.h" #include "link_dpcd.h" #include "link_dp_capability.h" #include "dm_helpers.h" #include "dal_asic_id.h" #include "link_dp_phy.h" #include "dce/dmub_psr.h" #include "dc/dc_dmub_srv.h" #include "dce/dmub_replay.h" #include "abm.h" #define DC_LOGGER \ link->ctx->logger #define DC_LOGGER_INIT(logger) #define DP_SINK_PR_ENABLE_AND_CONFIGURATION 0x37B /* Travis */ static const uint8_t DP_VGA_LVDS_CONVERTER_ID_2[] = "sivarT"; /* Nutmeg */ static const uint8_t DP_VGA_LVDS_CONVERTER_ID_3[] = "dnomlA"; void dp_set_panel_mode(struct dc_link *link, enum dp_panel_mode panel_mode) { union dpcd_edp_config edp_config_set; bool panel_mode_edp = false; enum dc_status result; memset(&edp_config_set, '\0', sizeof(union dpcd_edp_config)); switch (panel_mode) { case DP_PANEL_MODE_EDP: case DP_PANEL_MODE_SPECIAL: panel_mode_edp = true; break; default: break; } /*set edp panel mode in receiver*/ result = core_link_read_dpcd( link, DP_EDP_CONFIGURATION_SET, &edp_config_set.raw, sizeof(edp_config_set.raw)); if (result == DC_OK && edp_config_set.bits.PANEL_MODE_EDP != panel_mode_edp) { edp_config_set.bits.PANEL_MODE_EDP = panel_mode_edp; result = core_link_write_dpcd( link, DP_EDP_CONFIGURATION_SET, &edp_config_set.raw, sizeof(edp_config_set.raw)); ASSERT(result == DC_OK); } link->panel_mode = panel_mode; DC_LOG_DETECTION_DP_CAPS("Link: %d eDP panel mode supported: %d " "eDP panel mode enabled: %d \n", link->link_index, link->dpcd_caps.panel_mode_edp, panel_mode_edp); } enum dp_panel_mode dp_get_panel_mode(struct dc_link *link) { /* We need to explicitly check that connector * is not DP. Some Travis_VGA get reported * by video bios as DP. */ if (link->connector_signal != SIGNAL_TYPE_DISPLAY_PORT) { switch (link->dpcd_caps.branch_dev_id) { case DP_BRANCH_DEVICE_ID_0022B9: /* alternate scrambler reset is required for Travis * for the case when external chip does not * provide sink device id, alternate scrambler * scheme will be overriden later by querying * Encoder features */ if (strncmp( link->dpcd_caps.branch_dev_name, DP_VGA_LVDS_CONVERTER_ID_2, sizeof( link->dpcd_caps. branch_dev_name)) == 0) { return DP_PANEL_MODE_SPECIAL; } break; case DP_BRANCH_DEVICE_ID_00001A: /* alternate scrambler reset is required for Travis * for the case when external chip does not provide * sink device id, alternate scrambler scheme will * be overriden later by querying Encoder feature */ if (strncmp(link->dpcd_caps.branch_dev_name, DP_VGA_LVDS_CONVERTER_ID_3, sizeof( link->dpcd_caps. branch_dev_name)) == 0) { return DP_PANEL_MODE_SPECIAL; } break; default: break; } } if (link->dpcd_caps.panel_mode_edp && (link->connector_signal == SIGNAL_TYPE_EDP || (link->connector_signal == SIGNAL_TYPE_DISPLAY_PORT && link->is_internal_display))) { return DP_PANEL_MODE_EDP; } return DP_PANEL_MODE_DEFAULT; } bool edp_set_backlight_level_nits(struct dc_link *link, bool isHDR, uint32_t backlight_millinits, uint32_t transition_time_in_ms) { struct dpcd_source_backlight_set dpcd_backlight_set; uint8_t backlight_control = isHDR ? 1 : 0; if (!link || (link->connector_signal != SIGNAL_TYPE_EDP && link->connector_signal != SIGNAL_TYPE_DISPLAY_PORT)) return false; // OLEDs have no PWM, they can only use AUX if (link->dpcd_sink_ext_caps.bits.oled == 1) backlight_control = 1; *(uint32_t *)&dpcd_backlight_set.backlight_level_millinits = backlight_millinits; *(uint16_t *)&dpcd_backlight_set.backlight_transition_time_ms = (uint16_t)transition_time_in_ms; if (!link->dpcd_caps.panel_luminance_control) { if (core_link_write_dpcd(link, DP_SOURCE_BACKLIGHT_LEVEL, (uint8_t *)(&dpcd_backlight_set), sizeof(dpcd_backlight_set)) != DC_OK) return false; if (core_link_write_dpcd(link, DP_SOURCE_BACKLIGHT_CONTROL, &backlight_control, 1) != DC_OK) return false; } else { uint8_t backlight_enable = 0; struct target_luminance_value *target_luminance = NULL; //if target luminance value is greater than 24 bits, clip the value to 24 bits if (backlight_millinits > 0xFFFFFF) backlight_millinits = 0xFFFFFF; target_luminance = (struct target_luminance_value *)&backlight_millinits; core_link_read_dpcd(link, DP_EDP_BACKLIGHT_MODE_SET_REGISTER, &backlight_enable, sizeof(uint8_t)); backlight_enable |= DP_EDP_PANEL_LUMINANCE_CONTROL_ENABLE; if (core_link_write_dpcd(link, DP_EDP_BACKLIGHT_MODE_SET_REGISTER, &backlight_enable, sizeof(backlight_enable)) != DC_OK) return false; if (core_link_write_dpcd(link, DP_EDP_PANEL_TARGET_LUMINANCE_VALUE, (uint8_t *)(target_luminance), sizeof(struct target_luminance_value)) != DC_OK) return false; } return true; } bool edp_get_backlight_level_nits(struct dc_link *link, uint32_t *backlight_millinits_avg, uint32_t *backlight_millinits_peak) { union dpcd_source_backlight_get dpcd_backlight_get; memset(&dpcd_backlight_get, 0, sizeof(union dpcd_source_backlight_get)); if (!link || (link->connector_signal != SIGNAL_TYPE_EDP && link->connector_signal != SIGNAL_TYPE_DISPLAY_PORT)) return false; if (!core_link_read_dpcd(link, DP_SOURCE_BACKLIGHT_CURRENT_PEAK, dpcd_backlight_get.raw, sizeof(union dpcd_source_backlight_get))) return false; *backlight_millinits_avg = dpcd_backlight_get.bytes.backlight_millinits_avg; *backlight_millinits_peak = dpcd_backlight_get.bytes.backlight_millinits_peak; /* On non-supported panels dpcd_read usually succeeds with 0 returned */ if (*backlight_millinits_avg == 0 || *backlight_millinits_avg > *backlight_millinits_peak) return false; return true; } bool edp_backlight_enable_aux(struct dc_link *link, bool enable) { uint8_t backlight_enable = enable ? 1 : 0; if (!link || (link->connector_signal != SIGNAL_TYPE_EDP && link->connector_signal != SIGNAL_TYPE_DISPLAY_PORT)) return false; if (core_link_write_dpcd(link, DP_SOURCE_BACKLIGHT_ENABLE, &backlight_enable, 1) != DC_OK) return false; return true; } // we read default from 0x320 because we expect BIOS wrote it there // regular get_backlight_nit reads from panel set at 0x326 static bool read_default_bl_aux(struct dc_link *link, uint32_t *backlight_millinits) { if (!link || (link->connector_signal != SIGNAL_TYPE_EDP && link->connector_signal != SIGNAL_TYPE_DISPLAY_PORT)) return false; if (!link->dpcd_caps.panel_luminance_control) { if (!core_link_read_dpcd(link, DP_SOURCE_BACKLIGHT_LEVEL, (uint8_t *)backlight_millinits, sizeof(uint32_t))) return false; } else { //setting to 0 as a precaution, since target_luminance_value is 3 bytes memset(backlight_millinits, 0, sizeof(uint32_t)); if (!core_link_read_dpcd(link, DP_EDP_PANEL_TARGET_LUMINANCE_VALUE, (uint8_t *)backlight_millinits, sizeof(struct target_luminance_value))) return false; } return true; } bool set_default_brightness_aux(struct dc_link *link) { uint32_t default_backlight; if (link && link->dpcd_sink_ext_caps.bits.oled == 1) { if (!read_default_bl_aux(link, &default_backlight)) default_backlight = 150000; // if > 5000, it might be wrong readback. 0 nits is a valid default value for OLED panel. if (default_backlight < 1000 || default_backlight > 5000000) default_backlight = 150000; return edp_set_backlight_level_nits(link, true, default_backlight, 0); } return false; } bool edp_is_ilr_optimization_enabled(struct dc_link *link) { if (link->dpcd_caps.edp_supported_link_rates_count == 0 || !link->panel_config.ilr.optimize_edp_link_rate) return false; return true; } enum dc_link_rate get_max_link_rate_from_ilr_table(struct dc_link *link) { enum dc_link_rate link_rate = link->reported_link_cap.link_rate; for (int i = 0; i < link->dpcd_caps.edp_supported_link_rates_count; i++) { if (link_rate < link->dpcd_caps.edp_supported_link_rates[i]) link_rate = link->dpcd_caps.edp_supported_link_rates[i]; } return link_rate; } bool edp_is_ilr_optimization_required(struct dc_link *link, struct dc_crtc_timing *crtc_timing) { struct dc_link_settings link_setting; uint8_t link_bw_set; uint8_t link_rate_set; uint32_t req_bw; union lane_count_set lane_count_set = {0}; ASSERT(link || crtc_timing); // invalid input if (!edp_is_ilr_optimization_enabled(link)) return false; // Read DPCD 00100h to find if standard link rates are set core_link_read_dpcd(link, DP_LINK_BW_SET, &link_bw_set, sizeof(link_bw_set)); if (link_bw_set) { DC_LOG_EVENT_LINK_TRAINING("eDP ILR: Optimization required, VBIOS used link_bw_set\n"); return true; } // Read DPCD 00115h to find the edp link rate set used core_link_read_dpcd(link, DP_LINK_RATE_SET, &link_rate_set, sizeof(link_rate_set)); // Read DPCD 00101h to find out the number of lanes currently set core_link_read_dpcd(link, DP_LANE_COUNT_SET, &lane_count_set.raw, sizeof(lane_count_set)); req_bw = dc_bandwidth_in_kbps_from_timing(crtc_timing, dc_link_get_highest_encoding_format(link)); if (!crtc_timing->flags.DSC) edp_decide_link_settings(link, &link_setting, req_bw); else decide_edp_link_settings_with_dsc(link, &link_setting, req_bw, LINK_RATE_UNKNOWN); if (link->dpcd_caps.edp_supported_link_rates[link_rate_set] != link_setting.link_rate || lane_count_set.bits.LANE_COUNT_SET != link_setting.lane_count) { DC_LOG_EVENT_LINK_TRAINING("eDP ILR: Optimization required, VBIOS link_rate_set not optimal\n"); return true; } DC_LOG_EVENT_LINK_TRAINING("eDP ILR: No optimization required, VBIOS set optimal link_rate_set\n"); return false; } void edp_panel_backlight_power_on(struct dc_link *link, bool wait_for_hpd) { if (link->connector_signal != SIGNAL_TYPE_EDP) return; link->dc->hwss.edp_power_control(link, true); if (wait_for_hpd) link->dc->hwss.edp_wait_for_hpd_ready(link, true); if (link->dc->hwss.edp_backlight_control) link->dc->hwss.edp_backlight_control(link, true); } void edp_set_panel_power(struct dc_link *link, bool powerOn) { if (powerOn) { // 1. panel VDD on if (!link->dc->config.edp_no_power_sequencing) link->dc->hwss.edp_power_control(link, true); link->dc->hwss.edp_wait_for_hpd_ready(link, true); // 2. panel BL on if (link->dc->hwss.edp_backlight_control) link->dc->hwss.edp_backlight_control(link, true); // 3. Rx power on dpcd_write_rx_power_ctrl(link, true); } else { // 3. Rx power off dpcd_write_rx_power_ctrl(link, false); // 2. panel BL off if (link->dc->hwss.edp_backlight_control) link->dc->hwss.edp_backlight_control(link, false); // 1. panel VDD off if (!link->dc->config.edp_no_power_sequencing) link->dc->hwss.edp_power_control(link, false); } } bool edp_wait_for_t12(struct dc_link *link) { if (link->connector_signal == SIGNAL_TYPE_EDP && link->dc->hwss.edp_wait_for_T12) { link->dc->hwss.edp_wait_for_T12(link); return true; } return false; } void edp_add_delay_for_T9(struct dc_link *link) { if (link && link->panel_config.pps.extra_delay_backlight_off > 0) fsleep(link->panel_config.pps.extra_delay_backlight_off * 1000); } bool edp_receiver_ready_T9(struct dc_link *link) { unsigned int tries = 0; unsigned char sinkstatus = 0; unsigned char edpRev = 0; enum dc_status result = DC_OK; result = core_link_read_dpcd(link, DP_EDP_DPCD_REV, &edpRev, sizeof(edpRev)); /* start from eDP version 1.2, SINK_STAUS indicate the sink is ready.*/ if (result == DC_OK && edpRev >= DP_EDP_12) { do { sinkstatus = 1; result = core_link_read_dpcd(link, DP_SINK_STATUS, &sinkstatus, sizeof(sinkstatus)); if (sinkstatus == 0) break; if (result != DC_OK) break; udelay(100); //MAx T9 } while (++tries < 50); } return result; } bool edp_receiver_ready_T7(struct dc_link *link) { unsigned char sinkstatus = 0; unsigned char edpRev = 0; enum dc_status result = DC_OK; /* use absolute time stamp to constrain max T7*/ unsigned long long enter_timestamp = 0; unsigned long long finish_timestamp = 0; unsigned long long time_taken_in_ns = 0; result = core_link_read_dpcd(link, DP_EDP_DPCD_REV, &edpRev, sizeof(edpRev)); if (result == DC_OK && edpRev >= DP_EDP_12) { /* start from eDP version 1.2, SINK_STAUS indicate the sink is ready.*/ enter_timestamp = dm_get_timestamp(link->ctx); do { sinkstatus = 0; result = core_link_read_dpcd(link, DP_SINK_STATUS, &sinkstatus, sizeof(sinkstatus)); if (sinkstatus == 1) break; if (result != DC_OK) break; udelay(25); finish_timestamp = dm_get_timestamp(link->ctx); time_taken_in_ns = dm_get_elapse_time_in_ns(link->ctx, finish_timestamp, enter_timestamp); } while (time_taken_in_ns < 50 * 1000000); //MAx T7 is 50ms } if (link && link->panel_config.pps.extra_t7_ms > 0) fsleep(link->panel_config.pps.extra_t7_ms * 1000); return result; } bool edp_power_alpm_dpcd_enable(struct dc_link *link, bool enable) { bool ret = false; union dpcd_alpm_configuration alpm_config; if (link->psr_settings.psr_version == DC_PSR_VERSION_SU_1) { memset(&alpm_config, 0, sizeof(alpm_config)); alpm_config.bits.ENABLE = (enable ? true : false); ret = dm_helpers_dp_write_dpcd(link->ctx, link, DP_RECEIVER_ALPM_CONFIG, &alpm_config.raw, sizeof(alpm_config.raw)); } return ret; } static struct pipe_ctx *get_pipe_from_link(const struct dc_link *link) { int i; struct dc *dc = link->ctx->dc; struct pipe_ctx *pipe_ctx = NULL; for (i = 0; i < MAX_PIPES; i++) { if (dc->current_state->res_ctx.pipe_ctx[i].stream) { if (dc->current_state->res_ctx.pipe_ctx[i].stream->link == link) { pipe_ctx = &dc->current_state->res_ctx.pipe_ctx[i]; break; } } } return pipe_ctx; } bool edp_set_backlight_level(const struct dc_link *link, uint32_t backlight_pwm_u16_16, uint32_t frame_ramp) { struct dc *dc = link->ctx->dc; DC_LOGGER_INIT(link->ctx->logger); DC_LOG_BACKLIGHT("New Backlight level: %d (0x%X)\n", backlight_pwm_u16_16, backlight_pwm_u16_16); if (dc_is_embedded_signal(link->connector_signal)) { struct pipe_ctx *pipe_ctx = get_pipe_from_link(link); if (link->panel_cntl) link->panel_cntl->stored_backlight_registers.USER_LEVEL = backlight_pwm_u16_16; if (pipe_ctx) { /* Disable brightness ramping when the display is blanked * as it can hang the DMCU */ if (pipe_ctx->plane_state == NULL) frame_ramp = 0; } else { return false; } dc->hwss.set_backlight_level( pipe_ctx, backlight_pwm_u16_16, frame_ramp); } return true; } bool edp_set_psr_allow_active(struct dc_link *link, const bool *allow_active, bool wait, bool force_static, const unsigned int *power_opts) { struct dc *dc = link->ctx->dc; struct dmcu *dmcu = dc->res_pool->dmcu; struct dmub_psr *psr = dc->res_pool->psr; unsigned int panel_inst; if (psr == NULL && force_static) return false; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; if ((allow_active != NULL) && (*allow_active == true) && (link->type == dc_connection_none)) { // Don't enter PSR if panel is not connected return false; } /* Set power optimization flag */ if (power_opts && link->psr_settings.psr_power_opt != *power_opts) { link->psr_settings.psr_power_opt = *power_opts; if (psr != NULL && link->psr_settings.psr_feature_enabled && psr->funcs->psr_set_power_opt) psr->funcs->psr_set_power_opt(psr, link->psr_settings.psr_power_opt, panel_inst); } if (psr != NULL && link->psr_settings.psr_feature_enabled && force_static && psr->funcs->psr_force_static) psr->funcs->psr_force_static(psr, panel_inst); /* Enable or Disable PSR */ if (allow_active && link->psr_settings.psr_allow_active != *allow_active) { link->psr_settings.psr_allow_active = *allow_active; if (!link->psr_settings.psr_allow_active) dc_z10_restore(dc); if (psr != NULL && link->psr_settings.psr_feature_enabled) { psr->funcs->psr_enable(psr, link->psr_settings.psr_allow_active, wait, panel_inst); } else if ((dmcu != NULL && dmcu->funcs->is_dmcu_initialized(dmcu)) && link->psr_settings.psr_feature_enabled) dmcu->funcs->set_psr_enable(dmcu, link->psr_settings.psr_allow_active, wait); else return false; } return true; } bool edp_get_psr_state(const struct dc_link *link, enum dc_psr_state *state) { struct dc *dc = link->ctx->dc; struct dmcu *dmcu = dc->res_pool->dmcu; struct dmub_psr *psr = dc->res_pool->psr; unsigned int panel_inst; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; if (psr != NULL && link->psr_settings.psr_feature_enabled) psr->funcs->psr_get_state(psr, state, panel_inst); else if (dmcu != NULL && link->psr_settings.psr_feature_enabled) dmcu->funcs->get_psr_state(dmcu, state); return true; } static inline enum physical_phy_id transmitter_to_phy_id(struct dc_link *link) { struct dc_context *dc_ctx = link->ctx; enum transmitter transmitter_value = link->link_enc->transmitter; switch (transmitter_value) { case TRANSMITTER_UNIPHY_A: return PHYLD_0; case TRANSMITTER_UNIPHY_B: return PHYLD_1; case TRANSMITTER_UNIPHY_C: return PHYLD_2; case TRANSMITTER_UNIPHY_D: return PHYLD_3; case TRANSMITTER_UNIPHY_E: return PHYLD_4; case TRANSMITTER_UNIPHY_F: return PHYLD_5; case TRANSMITTER_NUTMEG_CRT: return PHYLD_6; case TRANSMITTER_TRAVIS_CRT: return PHYLD_7; case TRANSMITTER_TRAVIS_LCD: return PHYLD_8; case TRANSMITTER_UNIPHY_G: return PHYLD_9; case TRANSMITTER_COUNT: return PHYLD_COUNT; case TRANSMITTER_UNKNOWN: return PHYLD_UNKNOWN; default: DC_ERROR("Unknown transmitter value %d\n", transmitter_value); return PHYLD_UNKNOWN; } } bool edp_setup_psr(struct dc_link *link, const struct dc_stream_state *stream, struct psr_config *psr_config, struct psr_context *psr_context) { struct dc *dc; struct dmcu *dmcu; struct dmub_psr *psr; int i; unsigned int panel_inst; /* updateSinkPsrDpcdConfig*/ union dpcd_psr_configuration psr_configuration; union dpcd_sink_active_vtotal_control_mode vtotal_control = {0}; psr_context->controllerId = CONTROLLER_ID_UNDEFINED; if (!link) return false; dc = link->ctx->dc; dmcu = dc->res_pool->dmcu; psr = dc->res_pool->psr; if (!dmcu && !psr) return false; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; memset(&psr_configuration, 0, sizeof(psr_configuration)); psr_configuration.bits.ENABLE = 1; psr_configuration.bits.CRC_VERIFICATION = 1; psr_configuration.bits.FRAME_CAPTURE_INDICATION = psr_config->psr_frame_capture_indication_req; /* Check for PSR v2*/ if (link->psr_settings.psr_version == DC_PSR_VERSION_SU_1) { /* For PSR v2 selective update. * Indicates whether sink should start capturing * immediately following active scan line, * or starting with the 2nd active scan line. */ psr_configuration.bits.LINE_CAPTURE_INDICATION = 0; /*For PSR v2, determines whether Sink should generate * IRQ_HPD when CRC mismatch is detected. */ psr_configuration.bits.IRQ_HPD_WITH_CRC_ERROR = 1; /* For PSR v2, set the bit when the Source device will * be enabling PSR2 operation. */ psr_configuration.bits.ENABLE_PSR2 = 1; /* For PSR v2, the Sink device must be able to receive * SU region updates early in the frame time. */ psr_configuration.bits.EARLY_TRANSPORT_ENABLE = 1; } dm_helpers_dp_write_dpcd( link->ctx, link, 368, &psr_configuration.raw, sizeof(psr_configuration.raw)); if (link->psr_settings.psr_version == DC_PSR_VERSION_SU_1) { edp_power_alpm_dpcd_enable(link, true); psr_context->su_granularity_required = psr_config->su_granularity_required; psr_context->su_y_granularity = psr_config->su_y_granularity; psr_context->line_time_in_us = psr_config->line_time_in_us; /* linux must be able to expose AMD Source DPCD definition * in order to support FreeSync PSR */ if (link->psr_settings.psr_vtotal_control_support) { psr_context->rate_control_caps = psr_config->rate_control_caps; vtotal_control.bits.ENABLE = true; core_link_write_dpcd(link, DP_SINK_PSR_ACTIVE_VTOTAL_CONTROL_MODE, &vtotal_control.raw, sizeof(vtotal_control.raw)); } } psr_context->channel = link->ddc->ddc_pin->hw_info.ddc_channel; psr_context->transmitterId = link->link_enc->transmitter; psr_context->engineId = link->link_enc->preferred_engine; for (i = 0; i < MAX_PIPES; i++) { if (dc->current_state->res_ctx.pipe_ctx[i].stream == stream) { /* dmcu -1 for all controller id values, * therefore +1 here */ psr_context->controllerId = dc->current_state->res_ctx. pipe_ctx[i].stream_res.tg->inst + 1; break; } } /* Hardcoded for now. Can be Pcie or Uniphy (or Unknown)*/ psr_context->phyType = PHY_TYPE_UNIPHY; /*PhyId is associated with the transmitter id*/ psr_context->smuPhyId = transmitter_to_phy_id(link); psr_context->crtcTimingVerticalTotal = stream->timing.v_total; psr_context->vsync_rate_hz = div64_u64(div64_u64((stream-> timing.pix_clk_100hz * 100), stream->timing.v_total), stream->timing.h_total); psr_context->psrSupportedDisplayConfig = true; psr_context->psrExitLinkTrainingRequired = psr_config->psr_exit_link_training_required; psr_context->sdpTransmitLineNumDeadline = psr_config->psr_sdp_transmit_line_num_deadline; psr_context->psrFrameCaptureIndicationReq = psr_config->psr_frame_capture_indication_req; psr_context->skipPsrWaitForPllLock = 0; /* only = 1 in KV */ psr_context->numberOfControllers = link->dc->res_pool->timing_generator_count; psr_context->rfb_update_auto_en = true; /* 2 frames before enter PSR. */ psr_context->timehyst_frames = 2; /* half a frame * (units in 100 lines, i.e. a value of 1 represents 100 lines) */ psr_context->hyst_lines = stream->timing.v_total / 2 / 100; psr_context->aux_repeats = 10; psr_context->psr_level.u32all = 0; /*skip power down the single pipe since it blocks the cstate*/ if (link->ctx->asic_id.chip_family >= FAMILY_RV) { switch (link->ctx->asic_id.chip_family) { case FAMILY_YELLOW_CARP: case AMDGPU_FAMILY_GC_10_3_6: case AMDGPU_FAMILY_GC_11_0_1: if (dc->debug.disable_z10 || dc->debug.psr_skip_crtc_disable) psr_context->psr_level.bits.SKIP_CRTC_DISABLE = true; break; default: psr_context->psr_level.bits.SKIP_CRTC_DISABLE = true; break; } } /* SMU will perform additional powerdown sequence. * For unsupported ASICs, set psr_level flag to skip PSR * static screen notification to SMU. * (Always set for DAL2, did not check ASIC) */ psr_context->allow_smu_optimizations = psr_config->allow_smu_optimizations; psr_context->allow_multi_disp_optimizations = psr_config->allow_multi_disp_optimizations; /* Complete PSR entry before aborting to prevent intermittent * freezes on certain eDPs */ psr_context->psr_level.bits.DISABLE_PSR_ENTRY_ABORT = 1; /* Disable ALPM first for compatible non-ALPM panel now */ psr_context->psr_level.bits.DISABLE_ALPM = 0; psr_context->psr_level.bits.ALPM_DEFAULT_PD_MODE = 1; /* Controls additional delay after remote frame capture before * continuing power down, default = 0 */ psr_context->frame_delay = 0; psr_context->dsc_slice_height = psr_config->dsc_slice_height; if (psr) { link->psr_settings.psr_feature_enabled = psr->funcs->psr_copy_settings(psr, link, psr_context, panel_inst); link->psr_settings.psr_power_opt = 0; link->psr_settings.psr_allow_active = 0; } else { link->psr_settings.psr_feature_enabled = dmcu->funcs->setup_psr(dmcu, link, psr_context); } /* psr_enabled == 0 indicates setup_psr did not succeed, but this * should not happen since firmware should be running at this point */ if (link->psr_settings.psr_feature_enabled == 0) ASSERT(0); return true; } void edp_get_psr_residency(const struct dc_link *link, uint32_t *residency) { struct dc *dc = link->ctx->dc; struct dmub_psr *psr = dc->res_pool->psr; unsigned int panel_inst; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return; // PSR residency measurements only supported on DMCUB if (psr != NULL && link->psr_settings.psr_feature_enabled) psr->funcs->psr_get_residency(psr, residency, panel_inst); else *residency = 0; } bool edp_set_sink_vtotal_in_psr_active(const struct dc_link *link, uint16_t psr_vtotal_idle, uint16_t psr_vtotal_su) { struct dc *dc = link->ctx->dc; struct dmub_psr *psr = dc->res_pool->psr; if (psr == NULL || !link->psr_settings.psr_feature_enabled || !link->psr_settings.psr_vtotal_control_support) return false; psr->funcs->psr_set_sink_vtotal_in_psr_active(psr, psr_vtotal_idle, psr_vtotal_su); return true; } bool edp_set_replay_allow_active(struct dc_link *link, const bool *allow_active, bool wait, bool force_static, const unsigned int *power_opts) { struct dc *dc = link->ctx->dc; struct dmub_replay *replay = dc->res_pool->replay; unsigned int panel_inst; if (replay == NULL && force_static) return false; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; /* Set power optimization flag */ if (power_opts && link->replay_settings.replay_power_opt_active != *power_opts) { if (replay != NULL && link->replay_settings.replay_feature_enabled && replay->funcs->replay_set_power_opt) { replay->funcs->replay_set_power_opt(replay, *power_opts, panel_inst); link->replay_settings.replay_power_opt_active = *power_opts; } } /* Activate or deactivate Replay */ if (allow_active && link->replay_settings.replay_allow_active != *allow_active) { // TODO: Handle mux change case if force_static is set // If force_static is set, just change the replay_allow_active state directly if (replay != NULL && link->replay_settings.replay_feature_enabled) replay->funcs->replay_enable(replay, *allow_active, wait, panel_inst); link->replay_settings.replay_allow_active = *allow_active; } return true; } bool edp_get_replay_state(const struct dc_link *link, uint64_t *state) { struct dc *dc = link->ctx->dc; struct dmub_replay *replay = dc->res_pool->replay; unsigned int panel_inst; enum replay_state pr_state = REPLAY_STATE_0; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; if (replay != NULL && link->replay_settings.replay_feature_enabled) replay->funcs->replay_get_state(replay, &pr_state, panel_inst); *state = pr_state; return true; } bool edp_setup_replay(struct dc_link *link, const struct dc_stream_state *stream) { /* To-do: Setup Replay */ struct dc *dc; struct dmub_replay *replay; int i; unsigned int panel_inst; struct replay_context replay_context = { 0 }; unsigned int lineTimeInNs = 0; union replay_enable_and_configuration replay_config; union dpcd_alpm_configuration alpm_config; replay_context.controllerId = CONTROLLER_ID_UNDEFINED; if (!link) return false; dc = link->ctx->dc; replay = dc->res_pool->replay; if (!replay) return false; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; replay_context.aux_inst = link->ddc->ddc_pin->hw_info.ddc_channel; replay_context.digbe_inst = link->link_enc->transmitter; replay_context.digfe_inst = link->link_enc->preferred_engine; for (i = 0; i < MAX_PIPES; i++) { if (dc->current_state->res_ctx.pipe_ctx[i].stream == stream) { /* dmcu -1 for all controller id values, * therefore +1 here */ replay_context.controllerId = dc->current_state->res_ctx.pipe_ctx[i].stream_res.tg->inst + 1; break; } } lineTimeInNs = ((stream->timing.h_total * 1000000) / (stream->timing.pix_clk_100hz / 10)) + 1; replay_context.line_time_in_ns = lineTimeInNs; link->replay_settings.replay_feature_enabled = replay->funcs->replay_copy_settings(replay, link, &replay_context, panel_inst); if (link->replay_settings.replay_feature_enabled) { replay_config.bits.FREESYNC_PANEL_REPLAY_MODE = 1; replay_config.bits.TIMING_DESYNC_ERROR_VERIFICATION = link->replay_settings.config.replay_timing_sync_supported; replay_config.bits.STATE_TRANSITION_ERROR_DETECTION = 1; dm_helpers_dp_write_dpcd(link->ctx, link, DP_SINK_PR_ENABLE_AND_CONFIGURATION, (uint8_t *)&(replay_config.raw), sizeof(uint8_t)); memset(&alpm_config, 0, sizeof(alpm_config)); alpm_config.bits.ENABLE = 1; dm_helpers_dp_write_dpcd( link->ctx, link, DP_RECEIVER_ALPM_CONFIG, &alpm_config.raw, sizeof(alpm_config.raw)); } return true; } /* * This is general Interface for Replay to set an 32 bit variable to dmub * replay_FW_Message_type: Indicates which instruction or variable pass to DMUB * cmd_data: Value of the config. */ bool edp_send_replay_cmd(struct dc_link *link, enum replay_FW_Message_type msg, union dmub_replay_cmd_set *cmd_data) { struct dc *dc = link->ctx->dc; struct dmub_replay *replay = dc->res_pool->replay; unsigned int panel_inst; if (!replay) return false; DC_LOGGER_INIT(link->ctx->logger); if (dc_get_edp_link_panel_inst(dc, link, &panel_inst)) cmd_data->panel_inst = panel_inst; else { DC_LOG_DC("%s(): get edp panel inst fail ", __func__); return false; } replay->funcs->replay_send_cmd(replay, msg, cmd_data); return true; } bool edp_set_coasting_vtotal(struct dc_link *link, uint32_t coasting_vtotal) { struct dc *dc = link->ctx->dc; struct dmub_replay *replay = dc->res_pool->replay; unsigned int panel_inst; if (!replay) return false; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; if (coasting_vtotal && link->replay_settings.coasting_vtotal != coasting_vtotal) { replay->funcs->replay_set_coasting_vtotal(replay, coasting_vtotal, panel_inst); link->replay_settings.coasting_vtotal = coasting_vtotal; } return true; } bool edp_replay_residency(const struct dc_link *link, unsigned int *residency, const bool is_start, const bool is_alpm) { struct dc *dc = link->ctx->dc; struct dmub_replay *replay = dc->res_pool->replay; unsigned int panel_inst; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; if (replay != NULL && link->replay_settings.replay_feature_enabled) replay->funcs->replay_residency(replay, panel_inst, residency, is_start, is_alpm); else *residency = 0; return true; } bool edp_set_replay_power_opt_and_coasting_vtotal(struct dc_link *link, const unsigned int *power_opts, uint32_t coasting_vtotal) { struct dc *dc = link->ctx->dc; struct dmub_replay *replay = dc->res_pool->replay; unsigned int panel_inst; if (!dc_get_edp_link_panel_inst(dc, link, &panel_inst)) return false; /* Only both power and coasting vtotal changed, this func could return true */ if (power_opts && link->replay_settings.replay_power_opt_active != *power_opts && coasting_vtotal && link->replay_settings.coasting_vtotal != coasting_vtotal) { if (link->replay_settings.replay_feature_enabled && replay->funcs->replay_set_power_opt_and_coasting_vtotal) { replay->funcs->replay_set_power_opt_and_coasting_vtotal(replay, *power_opts, panel_inst, coasting_vtotal); link->replay_settings.replay_power_opt_active = *power_opts; link->replay_settings.coasting_vtotal = coasting_vtotal; } else return false; } else return false; return true; } static struct abm *get_abm_from_stream_res(const struct dc_link *link) { int i; struct dc *dc = link->ctx->dc; struct abm *abm = NULL; for (i = 0; i < MAX_PIPES; i++) { struct pipe_ctx pipe_ctx = dc->current_state->res_ctx.pipe_ctx[i]; struct dc_stream_state *stream = pipe_ctx.stream; if (stream && stream->link == link) { abm = pipe_ctx.stream_res.abm; break; } } return abm; } int edp_get_backlight_level(const struct dc_link *link) { struct abm *abm = get_abm_from_stream_res(link); struct panel_cntl *panel_cntl = link->panel_cntl; struct dc *dc = link->ctx->dc; struct dmcu *dmcu = dc->res_pool->dmcu; bool fw_set_brightness = true; if (dmcu) fw_set_brightness = dmcu->funcs->is_dmcu_initialized(dmcu); if (!fw_set_brightness && panel_cntl->funcs->get_current_backlight) return panel_cntl->funcs->get_current_backlight(panel_cntl); else if (abm != NULL && abm->funcs->get_current_backlight != NULL) return (int) abm->funcs->get_current_backlight(abm); else return DC_ERROR_UNEXPECTED; } int edp_get_target_backlight_pwm(const struct dc_link *link) { struct abm *abm = get_abm_from_stream_res(link); if (abm == NULL || abm->funcs->get_target_backlight == NULL) return DC_ERROR_UNEXPECTED; return (int) abm->funcs->get_target_backlight(abm); }