Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Harry Wentland | 1675 | 85.59% | 4 | 26.67% |
Wenjing Liu | 106 | 5.42% | 1 | 6.67% |
Eric Bernstein | 63 | 3.22% | 2 | 13.33% |
Igor Kravchenko | 54 | 2.76% | 1 | 6.67% |
Charlene Liu | 26 | 1.33% | 2 | 13.33% |
Bhawanpreet Lakha | 12 | 0.61% | 1 | 6.67% |
Leo (Hanghong) Ma | 12 | 0.61% | 1 | 6.67% |
Samson Tam | 7 | 0.36% | 1 | 6.67% |
Derek Lai | 1 | 0.05% | 1 | 6.67% |
Alex Deucher | 1 | 0.05% | 1 | 6.67% |
Total | 1957 | 15 |
/* * Copyright 2012-15 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 "reg_helper.h" #include "core_types.h" #include "link_encoder.h" #include "dcn20_link_encoder.h" #include "stream_encoder.h" #include "i2caux_interface.h" #include "dc_bios_types.h" #include "gpio_service_interface.h" #define CTX \ enc10->base.ctx #define DC_LOGGER \ enc10->base.ctx->logger #define REG(reg)\ (enc10->link_regs->reg) #undef FN #define FN(reg_name, field_name) \ enc10->link_shift->field_name, enc10->link_mask->field_name #define IND_REG(index) \ (enc10->link_regs->index) #ifndef MAX #define MAX(X, Y) ((X) > (Y) ? (X) : (Y)) #endif #ifndef MIN #define MIN(X, Y) ((X) < (Y) ? (X) : (Y)) #endif static struct mpll_cfg dcn2_mpll_cfg[] = { // RBR { .hdmimode_enable = 1, .ref_range = 3, .ref_clk_mpllb_div = 2, .mpllb_ssc_en = 1, .mpllb_div5_clk_en = 1, .mpllb_multiplier = 226, .mpllb_fracn_en = 1, .mpllb_fracn_quot = 39321, .mpllb_fracn_rem = 3, .mpllb_fracn_den = 5, .mpllb_ssc_up_spread = 0, .mpllb_ssc_peak = 38221, .mpllb_ssc_stepsize = 49314, .mpllb_div_clk_en = 0, .mpllb_div_multiplier = 0, .mpllb_hdmi_div = 0, .mpllb_tx_clk_div = 2, .tx_vboost_lvl = 4, .mpllb_pmix_en = 1, .mpllb_word_div2_en = 0, .mpllb_ana_v2i = 2, .mpllb_ana_freq_vco = 2, .mpllb_ana_cp_int = 7, .mpllb_ana_cp_prop = 18, .hdmi_pixel_clk_div = 0, }, // HBR { .hdmimode_enable = 1, .ref_range = 3, .ref_clk_mpllb_div = 2, .mpllb_ssc_en = 1, .mpllb_div5_clk_en = 1, .mpllb_multiplier = 184, .mpllb_fracn_en = 0, .mpllb_fracn_quot = 0, .mpllb_fracn_rem = 0, .mpllb_fracn_den = 1, .mpllb_ssc_up_spread = 0, .mpllb_ssc_peak = 31850, .mpllb_ssc_stepsize = 41095, .mpllb_div_clk_en = 0, .mpllb_div_multiplier = 0, .mpllb_hdmi_div = 0, .mpllb_tx_clk_div = 1, .tx_vboost_lvl = 4, .mpllb_pmix_en = 1, .mpllb_word_div2_en = 0, .mpllb_ana_v2i = 2, .mpllb_ana_freq_vco = 3, .mpllb_ana_cp_int = 7, .mpllb_ana_cp_prop = 18, .hdmi_pixel_clk_div = 0, }, //HBR2 { .hdmimode_enable = 1, .ref_range = 3, .ref_clk_mpllb_div = 2, .mpllb_ssc_en = 1, .mpllb_div5_clk_en = 1, .mpllb_multiplier = 184, .mpllb_fracn_en = 0, .mpllb_fracn_quot = 0, .mpllb_fracn_rem = 0, .mpllb_fracn_den = 1, .mpllb_ssc_up_spread = 0, .mpllb_ssc_peak = 31850, .mpllb_ssc_stepsize = 41095, .mpllb_div_clk_en = 0, .mpllb_div_multiplier = 0, .mpllb_hdmi_div = 0, .mpllb_tx_clk_div = 0, .tx_vboost_lvl = 4, .mpllb_pmix_en = 1, .mpllb_word_div2_en = 0, .mpllb_ana_v2i = 2, .mpllb_ana_freq_vco = 3, .mpllb_ana_cp_int = 7, .mpllb_ana_cp_prop = 18, .hdmi_pixel_clk_div = 0, }, //HBR3 { .hdmimode_enable = 1, .ref_range = 3, .ref_clk_mpllb_div = 2, .mpllb_ssc_en = 1, .mpllb_div5_clk_en = 1, .mpllb_multiplier = 292, .mpllb_fracn_en = 0, .mpllb_fracn_quot = 0, .mpllb_fracn_rem = 0, .mpllb_fracn_den = 1, .mpllb_ssc_up_spread = 0, .mpllb_ssc_peak = 47776, .mpllb_ssc_stepsize = 61642, .mpllb_div_clk_en = 0, .mpllb_div_multiplier = 0, .mpllb_hdmi_div = 0, .mpllb_tx_clk_div = 0, .tx_vboost_lvl = 4, .mpllb_pmix_en = 1, .mpllb_word_div2_en = 0, .mpllb_ana_v2i = 2, .mpllb_ana_freq_vco = 0, .mpllb_ana_cp_int = 7, .mpllb_ana_cp_prop = 18, .hdmi_pixel_clk_div = 0, }, }; void enc2_fec_set_enable(struct link_encoder *enc, bool enable) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); DC_LOG_DSC("%s FEC at link encoder inst %d", enable ? "Enabling" : "Disabling", enc->id.enum_id); REG_UPDATE(DP_DPHY_CNTL, DPHY_FEC_EN, enable); } void enc2_fec_set_ready(struct link_encoder *enc, bool ready) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); REG_UPDATE(DP_DPHY_CNTL, DPHY_FEC_READY_SHADOW, ready); } bool enc2_fec_is_active(struct link_encoder *enc) { uint32_t active = 0; struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); REG_GET(DP_DPHY_CNTL, DPHY_FEC_ACTIVE_STATUS, &active); return (active != 0); } /* this function reads dsc related register fields to be logged later in dcn10_log_hw_state * into a dcn_dsc_state struct. */ void link_enc2_read_state(struct link_encoder *enc, struct link_enc_state *s) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); REG_GET(DP_DPHY_CNTL, DPHY_FEC_EN, &s->dphy_fec_en); REG_GET(DP_DPHY_CNTL, DPHY_FEC_READY_SHADOW, &s->dphy_fec_ready_shadow); REG_GET(DP_DPHY_CNTL, DPHY_FEC_ACTIVE_STATUS, &s->dphy_fec_active_status); REG_GET(DP_LINK_CNTL, DP_LINK_TRAINING_COMPLETE, &s->dp_link_training_complete); } static bool update_cfg_data( struct dcn10_link_encoder *enc10, const struct dc_link_settings *link_settings, struct dpcssys_phy_seq_cfg *cfg) { int i; cfg->load_sram_fw = false; for (i = 0; i < link_settings->lane_count; i++) cfg->lane_en[i] = true; switch (link_settings->link_rate) { case LINK_RATE_LOW: cfg->mpll_cfg = dcn2_mpll_cfg[0]; break; case LINK_RATE_HIGH: cfg->mpll_cfg = dcn2_mpll_cfg[1]; break; case LINK_RATE_HIGH2: cfg->mpll_cfg = dcn2_mpll_cfg[2]; break; case LINK_RATE_HIGH3: cfg->mpll_cfg = dcn2_mpll_cfg[3]; break; default: DC_LOG_ERROR("%s: No supported link rate found %X!\n", __func__, link_settings->link_rate); return false; } return true; } void dcn20_link_encoder_enable_dp_output( struct link_encoder *enc, const struct dc_link_settings *link_settings, enum clock_source_id clock_source) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); struct dcn20_link_encoder *enc20 = (struct dcn20_link_encoder *) enc10; struct dpcssys_phy_seq_cfg *cfg = &enc20->phy_seq_cfg; if (!enc->ctx->dc->debug.avoid_vbios_exec_table) { dcn10_link_encoder_enable_dp_output(enc, link_settings, clock_source); return; } if (!update_cfg_data(enc10, link_settings, cfg)) return; enc1_configure_encoder(enc10, link_settings); dcn10_link_encoder_setup(enc, SIGNAL_TYPE_DISPLAY_PORT); } void dcn20_link_encoder_get_max_link_cap(struct link_encoder *enc, struct dc_link_settings *link_settings) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); uint32_t is_in_usb_c_dp4_mode = 0; dcn10_link_encoder_get_max_link_cap(enc, link_settings); /* in usb c dp2 mode, max lane count is 2 */ if (enc->funcs->is_in_alt_mode && enc->funcs->is_in_alt_mode(enc)) { REG_GET(RDPCSTX_PHY_CNTL6, RDPCS_PHY_DPALT_DP4, &is_in_usb_c_dp4_mode); if (!is_in_usb_c_dp4_mode) link_settings->lane_count = MIN(LANE_COUNT_TWO, link_settings->lane_count); } } bool dcn20_link_encoder_is_in_alt_mode(struct link_encoder *enc) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); uint32_t dp_alt_mode_disable = 0; bool is_usb_c_alt_mode = false; if (enc->features.flags.bits.DP_IS_USB_C) { /* if value == 1 alt mode is disabled, otherwise it is enabled */ REG_GET(RDPCSTX_PHY_CNTL6, RDPCS_PHY_DPALT_DISABLE, &dp_alt_mode_disable); is_usb_c_alt_mode = (dp_alt_mode_disable == 0); } return is_usb_c_alt_mode; } #define AUX_REG(reg)\ (enc10->aux_regs->reg) #define AUX_REG_READ(reg_name) \ dm_read_reg(CTX, AUX_REG(reg_name)) #define AUX_REG_WRITE(reg_name, val) \ dm_write_reg(CTX, AUX_REG(reg_name), val) void enc2_hw_init(struct link_encoder *enc) { struct dcn10_link_encoder *enc10 = TO_DCN10_LINK_ENC(enc); /* 00 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__1to2 : 1/2 01 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__3to4 : 3/4 02 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__7to8 : 7/8 03 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__15to16 : 15/16 04 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__31to32 : 31/32 05 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__63to64 : 63/64 06 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__127to128 : 127/128 07 - DP_AUX_DPHY_RX_DETECTION_THRESHOLD__255to256 : 255/256 */ /* AUX_REG_UPDATE_5(AUX_DPHY_RX_CONTROL0, AUX_RX_START_WINDOW = 1 [6:4] AUX_RX_RECEIVE_WINDOW = 1 default is 2 [10:8] AUX_RX_HALF_SYM_DETECT_LEN = 1 [13:12] default is 1 AUX_RX_TRANSITION_FILTER_EN = 1 [16] default is 1 AUX_RX_ALLOW_BELOW_THRESHOLD_PHASE_DETECT [17] is 0 default is 0 AUX_RX_ALLOW_BELOW_THRESHOLD_START [18] is 1 default is 1 AUX_RX_ALLOW_BELOW_THRESHOLD_STOP [19] is 1 default is 1 AUX_RX_PHASE_DETECT_LEN, [21,20] = 0x3 default is 3 AUX_RX_DETECTION_THRESHOLD [30:28] = 1 */ if (enc->ctx->dc_bios->golden_table.dc_golden_table_ver > 0) { AUX_REG_WRITE(AUX_DPHY_RX_CONTROL0, enc->ctx->dc_bios->golden_table.aux_dphy_rx_control0_val); AUX_REG_WRITE(AUX_DPHY_TX_CONTROL, enc->ctx->dc_bios->golden_table.aux_dphy_tx_control_val); AUX_REG_WRITE(AUX_DPHY_RX_CONTROL1, enc->ctx->dc_bios->golden_table.aux_dphy_rx_control1_val); } else { AUX_REG_WRITE(AUX_DPHY_RX_CONTROL0, 0x103d1110); AUX_REG_WRITE(AUX_DPHY_TX_CONTROL, 0x21c7a); } //AUX_DPHY_TX_REF_CONTROL'AUX_TX_REF_DIV HW default is 0x32; // Set AUX_TX_REF_DIV Divider to generate 2 MHz reference from refclk // 27MHz -> 0xd // 100MHz -> 0x32 // 48MHz -> 0x18 // Set TMDS_CTL0 to 1. This is a legacy setting. REG_UPDATE(TMDS_CTL_BITS, TMDS_CTL0, 1); dcn10_aux_initialize(enc10); } static const struct link_encoder_funcs dcn20_link_enc_funcs = { .read_state = link_enc2_read_state, .validate_output_with_stream = dcn10_link_encoder_validate_output_with_stream, .hw_init = enc2_hw_init, .setup = dcn10_link_encoder_setup, .enable_tmds_output = dcn10_link_encoder_enable_tmds_output_with_clk_pattern_wa, .enable_dp_output = dcn20_link_encoder_enable_dp_output, .enable_dp_mst_output = dcn10_link_encoder_enable_dp_mst_output, .disable_output = dcn10_link_encoder_disable_output, .dp_set_lane_settings = dcn10_link_encoder_dp_set_lane_settings, .dp_set_phy_pattern = dcn10_link_encoder_dp_set_phy_pattern, .update_mst_stream_allocation_table = dcn10_link_encoder_update_mst_stream_allocation_table, .psr_program_dp_dphy_fast_training = dcn10_psr_program_dp_dphy_fast_training, .psr_program_secondary_packet = dcn10_psr_program_secondary_packet, .connect_dig_be_to_fe = dcn10_link_encoder_connect_dig_be_to_fe, .enable_hpd = dcn10_link_encoder_enable_hpd, .disable_hpd = dcn10_link_encoder_disable_hpd, .is_dig_enabled = dcn10_is_dig_enabled, .destroy = dcn10_link_encoder_destroy, .fec_set_enable = enc2_fec_set_enable, .fec_set_ready = enc2_fec_set_ready, .fec_is_active = enc2_fec_is_active, .get_dig_mode = dcn10_get_dig_mode, .get_dig_frontend = dcn10_get_dig_frontend, .is_in_alt_mode = dcn20_link_encoder_is_in_alt_mode, .get_max_link_cap = dcn20_link_encoder_get_max_link_cap, }; void dcn20_link_encoder_construct( struct dcn20_link_encoder *enc20, const struct encoder_init_data *init_data, const struct encoder_feature_support *enc_features, const struct dcn10_link_enc_registers *link_regs, const struct dcn10_link_enc_aux_registers *aux_regs, const struct dcn10_link_enc_hpd_registers *hpd_regs, const struct dcn10_link_enc_shift *link_shift, const struct dcn10_link_enc_mask *link_mask) { struct bp_encoder_cap_info bp_cap_info = {0}; const struct dc_vbios_funcs *bp_funcs = init_data->ctx->dc_bios->funcs; enum bp_result result = BP_RESULT_OK; struct dcn10_link_encoder *enc10 = &enc20->enc10; enc10->base.funcs = &dcn20_link_enc_funcs; enc10->base.ctx = init_data->ctx; enc10->base.id = init_data->encoder; enc10->base.hpd_source = init_data->hpd_source; enc10->base.connector = init_data->connector; enc10->base.preferred_engine = ENGINE_ID_UNKNOWN; enc10->base.features = *enc_features; enc10->base.transmitter = init_data->transmitter; /* set the flag to indicate whether driver poll the I2C data pin * while doing the DP sink detect */ /* if (dal_adapter_service_is_feature_supported(as, FEATURE_DP_SINK_DETECT_POLL_DATA_PIN)) enc10->base.features.flags.bits. DP_SINK_DETECT_POLL_DATA_PIN = true;*/ enc10->base.output_signals = SIGNAL_TYPE_DVI_SINGLE_LINK | SIGNAL_TYPE_DVI_DUAL_LINK | SIGNAL_TYPE_LVDS | SIGNAL_TYPE_DISPLAY_PORT | SIGNAL_TYPE_DISPLAY_PORT_MST | SIGNAL_TYPE_EDP | SIGNAL_TYPE_HDMI_TYPE_A; /* For DCE 8.0 and 8.1, by design, UNIPHY is hardwired to DIG_BE. * SW always assign DIG_FE 1:1 mapped to DIG_FE for non-MST UNIPHY. * SW assign DIG_FE to non-MST UNIPHY first and MST last. So prefer * DIG is per UNIPHY and used by SST DP, eDP, HDMI, DVI and LVDS. * Prefer DIG assignment is decided by board design. * For DCE 8.0, there are only max 6 UNIPHYs, we assume board design * and VBIOS will filter out 7 UNIPHY for DCE 8.0. * By this, adding DIGG should not hurt DCE 8.0. * This will let DCE 8.1 share DCE 8.0 as much as possible */ enc10->link_regs = link_regs; enc10->aux_regs = aux_regs; enc10->hpd_regs = hpd_regs; enc10->link_shift = link_shift; enc10->link_mask = link_mask; switch (enc10->base.transmitter) { case TRANSMITTER_UNIPHY_A: enc10->base.preferred_engine = ENGINE_ID_DIGA; break; case TRANSMITTER_UNIPHY_B: enc10->base.preferred_engine = ENGINE_ID_DIGB; break; case TRANSMITTER_UNIPHY_C: enc10->base.preferred_engine = ENGINE_ID_DIGC; break; case TRANSMITTER_UNIPHY_D: enc10->base.preferred_engine = ENGINE_ID_DIGD; break; case TRANSMITTER_UNIPHY_E: enc10->base.preferred_engine = ENGINE_ID_DIGE; break; case TRANSMITTER_UNIPHY_F: enc10->base.preferred_engine = ENGINE_ID_DIGF; break; case TRANSMITTER_UNIPHY_G: enc10->base.preferred_engine = ENGINE_ID_DIGG; break; default: ASSERT_CRITICAL(false); enc10->base.preferred_engine = ENGINE_ID_UNKNOWN; } /* default to one to mirror Windows behavior */ enc10->base.features.flags.bits.HDMI_6GB_EN = 1; result = bp_funcs->get_encoder_cap_info(enc10->base.ctx->dc_bios, enc10->base.id, &bp_cap_info); /* Override features with DCE-specific values */ if (result == BP_RESULT_OK) { enc10->base.features.flags.bits.IS_HBR2_CAPABLE = bp_cap_info.DP_HBR2_EN; enc10->base.features.flags.bits.IS_HBR3_CAPABLE = bp_cap_info.DP_HBR3_EN; enc10->base.features.flags.bits.HDMI_6GB_EN = bp_cap_info.HDMI_6GB_EN; enc10->base.features.flags.bits.DP_IS_USB_C = bp_cap_info.DP_IS_USB_C; } else { DC_LOG_WARNING("%s: Failed to get encoder_cap_info from VBIOS with error code %d!\n", __func__, result); } if (enc10->base.ctx->dc->debug.hdmi20_disable) { enc10->base.features.flags.bits.HDMI_6GB_EN = 0; } }
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