Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Chandan Uddaraju | 7474 | 75.09% | 1 | 2.13% |
Kuogee Hsieh | 1219 | 12.25% | 19 | 40.43% |
Stephen Boyd | 456 | 4.58% | 5 | 10.64% |
Vinod Polimera | 218 | 2.19% | 1 | 2.13% |
Lee Jones | 211 | 2.12% | 1 | 2.13% |
Rob Clark | 90 | 0.90% | 4 | 8.51% |
Jeykumar Sankaran | 73 | 0.73% | 1 | 2.13% |
Sankeerth Billakanti | 64 | 0.64% | 2 | 4.26% |
Dmitry Eremin-Solenikov | 61 | 0.61% | 3 | 6.38% |
Doug Anderson | 20 | 0.20% | 1 | 2.13% |
Sean Paul | 19 | 0.19% | 1 | 2.13% |
Archit Taneja | 16 | 0.16% | 2 | 4.26% |
Stephen Chandler Paul | 12 | 0.12% | 2 | 4.26% |
Yangtao Li | 9 | 0.09% | 1 | 2.13% |
Maitreyee Rao | 8 | 0.08% | 1 | 2.13% |
Thomas Zimmermann | 2 | 0.02% | 1 | 2.13% |
Thomas Gleixner | 1 | 0.01% | 1 | 2.13% |
Total | 9953 | 47 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2012-2020, The Linux Foundation. All rights reserved. */ #define pr_fmt(fmt) "[drm-dp] %s: " fmt, __func__ #include <linux/types.h> #include <linux/completion.h> #include <linux/delay.h> #include <linux/phy/phy.h> #include <linux/phy/phy-dp.h> #include <linux/pm_opp.h> #include <drm/display/drm_dp_helper.h> #include <drm/drm_fixed.h> #include <drm/drm_print.h> #include "dp_reg.h" #include "dp_ctrl.h" #include "dp_link.h" #define DP_KHZ_TO_HZ 1000 #define IDLE_PATTERN_COMPLETION_TIMEOUT_JIFFIES (30 * HZ / 1000) /* 30 ms */ #define PSR_OPERATION_COMPLETION_TIMEOUT_JIFFIES (300 * HZ / 1000) /* 300 ms */ #define WAIT_FOR_VIDEO_READY_TIMEOUT_JIFFIES (HZ / 2) #define DP_CTRL_INTR_READY_FOR_VIDEO BIT(0) #define DP_CTRL_INTR_IDLE_PATTERN_SENT BIT(3) #define MR_LINK_TRAINING1 0x8 #define MR_LINK_SYMBOL_ERM 0x80 #define MR_LINK_PRBS7 0x100 #define MR_LINK_CUSTOM80 0x200 #define MR_LINK_TRAINING4 0x40 enum { DP_TRAINING_NONE, DP_TRAINING_1, DP_TRAINING_2, }; struct dp_tu_calc_input { u64 lclk; /* 162, 270, 540 and 810 */ u64 pclk_khz; /* in KHz */ u64 hactive; /* active h-width */ u64 hporch; /* bp + fp + pulse */ int nlanes; /* no.of.lanes */ int bpp; /* bits */ int pixel_enc; /* 444, 420, 422 */ int dsc_en; /* dsc on/off */ int async_en; /* async mode */ int fec_en; /* fec */ int compress_ratio; /* 2:1 = 200, 3:1 = 300, 3.75:1 = 375 */ int num_of_dsc_slices; /* number of slices per line */ }; struct dp_vc_tu_mapping_table { u32 vic; u8 lanes; u8 lrate; /* DP_LINK_RATE -> 162(6), 270(10), 540(20), 810 (30) */ u8 bpp; u8 valid_boundary_link; u16 delay_start_link; bool boundary_moderation_en; u8 valid_lower_boundary_link; u8 upper_boundary_count; u8 lower_boundary_count; u8 tu_size_minus1; }; struct dp_ctrl_private { struct dp_ctrl dp_ctrl; struct drm_device *drm_dev; struct device *dev; struct drm_dp_aux *aux; struct dp_panel *panel; struct dp_link *link; struct dp_power *power; struct dp_parser *parser; struct dp_catalog *catalog; struct completion idle_comp; struct completion psr_op_comp; struct completion video_comp; }; static int dp_aux_link_configure(struct drm_dp_aux *aux, struct dp_link_info *link) { u8 values[2]; int err; values[0] = drm_dp_link_rate_to_bw_code(link->rate); values[1] = link->num_lanes; if (link->capabilities & DP_LINK_CAP_ENHANCED_FRAMING) values[1] |= DP_LANE_COUNT_ENHANCED_FRAME_EN; err = drm_dp_dpcd_write(aux, DP_LINK_BW_SET, values, sizeof(values)); if (err < 0) return err; return 0; } void dp_ctrl_push_idle(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); reinit_completion(&ctrl->idle_comp); dp_catalog_ctrl_state_ctrl(ctrl->catalog, DP_STATE_CTRL_PUSH_IDLE); if (!wait_for_completion_timeout(&ctrl->idle_comp, IDLE_PATTERN_COMPLETION_TIMEOUT_JIFFIES)) pr_warn("PUSH_IDLE pattern timedout\n"); drm_dbg_dp(ctrl->drm_dev, "mainlink off\n"); } static void dp_ctrl_config_ctrl(struct dp_ctrl_private *ctrl) { u32 config = 0, tbd; const u8 *dpcd = ctrl->panel->dpcd; /* Default-> LSCLK DIV: 1/4 LCLK */ config |= (2 << DP_CONFIGURATION_CTRL_LSCLK_DIV_SHIFT); /* Scrambler reset enable */ if (drm_dp_alternate_scrambler_reset_cap(dpcd)) config |= DP_CONFIGURATION_CTRL_ASSR; tbd = dp_link_get_test_bits_depth(ctrl->link, ctrl->panel->dp_mode.bpp); if (tbd == DP_TEST_BIT_DEPTH_UNKNOWN) { pr_debug("BIT_DEPTH not set. Configure default\n"); tbd = DP_TEST_BIT_DEPTH_8; } config |= tbd << DP_CONFIGURATION_CTRL_BPC_SHIFT; /* Num of Lanes */ config |= ((ctrl->link->link_params.num_lanes - 1) << DP_CONFIGURATION_CTRL_NUM_OF_LANES_SHIFT); if (drm_dp_enhanced_frame_cap(dpcd)) config |= DP_CONFIGURATION_CTRL_ENHANCED_FRAMING; config |= DP_CONFIGURATION_CTRL_P_INTERLACED; /* progressive video */ /* sync clock & static Mvid */ config |= DP_CONFIGURATION_CTRL_STATIC_DYNAMIC_CN; config |= DP_CONFIGURATION_CTRL_SYNC_ASYNC_CLK; if (ctrl->panel->psr_cap.version) config |= DP_CONFIGURATION_CTRL_SEND_VSC; dp_catalog_ctrl_config_ctrl(ctrl->catalog, config); } static void dp_ctrl_configure_source_params(struct dp_ctrl_private *ctrl) { u32 cc, tb; dp_catalog_ctrl_lane_mapping(ctrl->catalog); dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, true); dp_ctrl_config_ctrl(ctrl); tb = dp_link_get_test_bits_depth(ctrl->link, ctrl->panel->dp_mode.bpp); cc = dp_link_get_colorimetry_config(ctrl->link); dp_catalog_ctrl_config_misc(ctrl->catalog, cc, tb); dp_panel_timing_cfg(ctrl->panel); } /* * The structure and few functions present below are IP/Hardware * specific implementation. Most of the implementation will not * have coding comments */ struct tu_algo_data { s64 lclk_fp; s64 pclk_fp; s64 lwidth; s64 lwidth_fp; s64 hbp_relative_to_pclk; s64 hbp_relative_to_pclk_fp; int nlanes; int bpp; int pixelEnc; int dsc_en; int async_en; int bpc; uint delay_start_link_extra_pixclk; int extra_buffer_margin; s64 ratio_fp; s64 original_ratio_fp; s64 err_fp; s64 n_err_fp; s64 n_n_err_fp; int tu_size; int tu_size_desired; int tu_size_minus1; int valid_boundary_link; s64 resulting_valid_fp; s64 total_valid_fp; s64 effective_valid_fp; s64 effective_valid_recorded_fp; int n_tus; int n_tus_per_lane; int paired_tus; int remainder_tus; int remainder_tus_upper; int remainder_tus_lower; int extra_bytes; int filler_size; int delay_start_link; int extra_pclk_cycles; int extra_pclk_cycles_in_link_clk; s64 ratio_by_tu_fp; s64 average_valid2_fp; int new_valid_boundary_link; int remainder_symbols_exist; int n_symbols; s64 n_remainder_symbols_per_lane_fp; s64 last_partial_tu_fp; s64 TU_ratio_err_fp; int n_tus_incl_last_incomplete_tu; int extra_pclk_cycles_tmp; int extra_pclk_cycles_in_link_clk_tmp; int extra_required_bytes_new_tmp; int filler_size_tmp; int lower_filler_size_tmp; int delay_start_link_tmp; bool boundary_moderation_en; int boundary_mod_lower_err; int upper_boundary_count; int lower_boundary_count; int i_upper_boundary_count; int i_lower_boundary_count; int valid_lower_boundary_link; int even_distribution_BF; int even_distribution_legacy; int even_distribution; int min_hblank_violated; s64 delay_start_time_fp; s64 hbp_time_fp; s64 hactive_time_fp; s64 diff_abs_fp; s64 ratio; }; static int _tu_param_compare(s64 a, s64 b) { u32 a_sign; u32 b_sign; s64 a_temp, b_temp, minus_1; if (a == b) return 0; minus_1 = drm_fixp_from_fraction(-1, 1); a_sign = (a >> 32) & 0x80000000 ? 1 : 0; b_sign = (b >> 32) & 0x80000000 ? 1 : 0; if (a_sign > b_sign) return 2; else if (b_sign > a_sign) return 1; if (!a_sign && !b_sign) { /* positive */ if (a > b) return 1; else return 2; } else { /* negative */ a_temp = drm_fixp_mul(a, minus_1); b_temp = drm_fixp_mul(b, minus_1); if (a_temp > b_temp) return 2; else return 1; } } static void dp_panel_update_tu_timings(struct dp_tu_calc_input *in, struct tu_algo_data *tu) { int nlanes = in->nlanes; int dsc_num_slices = in->num_of_dsc_slices; int dsc_num_bytes = 0; int numerator; s64 pclk_dsc_fp; s64 dwidth_dsc_fp; s64 hbp_dsc_fp; int tot_num_eoc_symbols = 0; int tot_num_hor_bytes = 0; int tot_num_dummy_bytes = 0; int dwidth_dsc_bytes = 0; int eoc_bytes = 0; s64 temp1_fp, temp2_fp, temp3_fp; tu->lclk_fp = drm_fixp_from_fraction(in->lclk, 1); tu->pclk_fp = drm_fixp_from_fraction(in->pclk_khz, 1000); tu->lwidth = in->hactive; tu->hbp_relative_to_pclk = in->hporch; tu->nlanes = in->nlanes; tu->bpp = in->bpp; tu->pixelEnc = in->pixel_enc; tu->dsc_en = in->dsc_en; tu->async_en = in->async_en; tu->lwidth_fp = drm_fixp_from_fraction(in->hactive, 1); tu->hbp_relative_to_pclk_fp = drm_fixp_from_fraction(in->hporch, 1); if (tu->pixelEnc == 420) { temp1_fp = drm_fixp_from_fraction(2, 1); tu->pclk_fp = drm_fixp_div(tu->pclk_fp, temp1_fp); tu->lwidth_fp = drm_fixp_div(tu->lwidth_fp, temp1_fp); tu->hbp_relative_to_pclk_fp = drm_fixp_div(tu->hbp_relative_to_pclk_fp, 2); } if (tu->pixelEnc == 422) { switch (tu->bpp) { case 24: tu->bpp = 16; tu->bpc = 8; break; case 30: tu->bpp = 20; tu->bpc = 10; break; default: tu->bpp = 16; tu->bpc = 8; break; } } else { tu->bpc = tu->bpp/3; } if (!in->dsc_en) goto fec_check; temp1_fp = drm_fixp_from_fraction(in->compress_ratio, 100); temp2_fp = drm_fixp_from_fraction(in->bpp, 1); temp3_fp = drm_fixp_div(temp2_fp, temp1_fp); temp2_fp = drm_fixp_mul(tu->lwidth_fp, temp3_fp); temp1_fp = drm_fixp_from_fraction(8, 1); temp3_fp = drm_fixp_div(temp2_fp, temp1_fp); numerator = drm_fixp2int(temp3_fp); dsc_num_bytes = numerator / dsc_num_slices; eoc_bytes = dsc_num_bytes % nlanes; tot_num_eoc_symbols = nlanes * dsc_num_slices; tot_num_hor_bytes = dsc_num_bytes * dsc_num_slices; tot_num_dummy_bytes = (nlanes - eoc_bytes) * dsc_num_slices; if (dsc_num_bytes == 0) pr_info("incorrect no of bytes per slice=%d\n", dsc_num_bytes); dwidth_dsc_bytes = (tot_num_hor_bytes + tot_num_eoc_symbols + (eoc_bytes == 0 ? 0 : tot_num_dummy_bytes)); dwidth_dsc_fp = drm_fixp_from_fraction(dwidth_dsc_bytes, 3); temp2_fp = drm_fixp_mul(tu->pclk_fp, dwidth_dsc_fp); temp1_fp = drm_fixp_div(temp2_fp, tu->lwidth_fp); pclk_dsc_fp = temp1_fp; temp1_fp = drm_fixp_div(pclk_dsc_fp, tu->pclk_fp); temp2_fp = drm_fixp_mul(tu->hbp_relative_to_pclk_fp, temp1_fp); hbp_dsc_fp = temp2_fp; /* output */ tu->pclk_fp = pclk_dsc_fp; tu->lwidth_fp = dwidth_dsc_fp; tu->hbp_relative_to_pclk_fp = hbp_dsc_fp; fec_check: if (in->fec_en) { temp1_fp = drm_fixp_from_fraction(976, 1000); /* 0.976 */ tu->lclk_fp = drm_fixp_mul(tu->lclk_fp, temp1_fp); } } static void _tu_valid_boundary_calc(struct tu_algo_data *tu) { s64 temp1_fp, temp2_fp, temp, temp1, temp2; int compare_result_1, compare_result_2, compare_result_3; temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); temp2_fp = drm_fixp_mul(tu->ratio_fp, temp1_fp); tu->new_valid_boundary_link = drm_fixp2int_ceil(temp2_fp); temp = (tu->i_upper_boundary_count * tu->new_valid_boundary_link + tu->i_lower_boundary_count * (tu->new_valid_boundary_link-1)); tu->average_valid2_fp = drm_fixp_from_fraction(temp, (tu->i_upper_boundary_count + tu->i_lower_boundary_count)); temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp2_fp = tu->lwidth_fp; temp1_fp = drm_fixp_mul(temp2_fp, temp1_fp); temp2_fp = drm_fixp_div(temp1_fp, tu->average_valid2_fp); tu->n_tus = drm_fixp2int(temp2_fp); if ((temp2_fp & 0xFFFFFFFF) > 0xFFFFF000) tu->n_tus += 1; temp1_fp = drm_fixp_from_fraction(tu->n_tus, 1); temp2_fp = drm_fixp_mul(temp1_fp, tu->average_valid2_fp); temp1_fp = drm_fixp_from_fraction(tu->n_symbols, 1); temp2_fp = temp1_fp - temp2_fp; temp1_fp = drm_fixp_from_fraction(tu->nlanes, 1); temp2_fp = drm_fixp_div(temp2_fp, temp1_fp); tu->n_remainder_symbols_per_lane_fp = temp2_fp; temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); tu->last_partial_tu_fp = drm_fixp_div(tu->n_remainder_symbols_per_lane_fp, temp1_fp); if (tu->n_remainder_symbols_per_lane_fp != 0) tu->remainder_symbols_exist = 1; else tu->remainder_symbols_exist = 0; temp1_fp = drm_fixp_from_fraction(tu->n_tus, tu->nlanes); tu->n_tus_per_lane = drm_fixp2int(temp1_fp); tu->paired_tus = (int)((tu->n_tus_per_lane) / (tu->i_upper_boundary_count + tu->i_lower_boundary_count)); tu->remainder_tus = tu->n_tus_per_lane - tu->paired_tus * (tu->i_upper_boundary_count + tu->i_lower_boundary_count); if ((tu->remainder_tus - tu->i_upper_boundary_count) > 0) { tu->remainder_tus_upper = tu->i_upper_boundary_count; tu->remainder_tus_lower = tu->remainder_tus - tu->i_upper_boundary_count; } else { tu->remainder_tus_upper = tu->remainder_tus; tu->remainder_tus_lower = 0; } temp = tu->paired_tus * (tu->i_upper_boundary_count * tu->new_valid_boundary_link + tu->i_lower_boundary_count * (tu->new_valid_boundary_link - 1)) + (tu->remainder_tus_upper * tu->new_valid_boundary_link) + (tu->remainder_tus_lower * (tu->new_valid_boundary_link - 1)); tu->total_valid_fp = drm_fixp_from_fraction(temp, 1); if (tu->remainder_symbols_exist) { temp1_fp = tu->total_valid_fp + tu->n_remainder_symbols_per_lane_fp; temp2_fp = drm_fixp_from_fraction(tu->n_tus_per_lane, 1); temp2_fp = temp2_fp + tu->last_partial_tu_fp; temp1_fp = drm_fixp_div(temp1_fp, temp2_fp); } else { temp2_fp = drm_fixp_from_fraction(tu->n_tus_per_lane, 1); temp1_fp = drm_fixp_div(tu->total_valid_fp, temp2_fp); } tu->effective_valid_fp = temp1_fp; temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); temp2_fp = drm_fixp_mul(tu->ratio_fp, temp1_fp); tu->n_n_err_fp = tu->effective_valid_fp - temp2_fp; temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); temp2_fp = drm_fixp_mul(tu->ratio_fp, temp1_fp); tu->n_err_fp = tu->average_valid2_fp - temp2_fp; tu->even_distribution = tu->n_tus % tu->nlanes == 0 ? 1 : 0; temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp2_fp = tu->lwidth_fp; temp1_fp = drm_fixp_mul(temp2_fp, temp1_fp); temp2_fp = drm_fixp_div(temp1_fp, tu->average_valid2_fp); if (temp2_fp) tu->n_tus_incl_last_incomplete_tu = drm_fixp2int_ceil(temp2_fp); else tu->n_tus_incl_last_incomplete_tu = 0; temp1 = 0; temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); temp2_fp = drm_fixp_mul(tu->original_ratio_fp, temp1_fp); temp1_fp = tu->average_valid2_fp - temp2_fp; temp2_fp = drm_fixp_from_fraction(tu->n_tus_incl_last_incomplete_tu, 1); temp1_fp = drm_fixp_mul(temp2_fp, temp1_fp); if (temp1_fp) temp1 = drm_fixp2int_ceil(temp1_fp); temp = tu->i_upper_boundary_count * tu->nlanes; temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); temp2_fp = drm_fixp_mul(tu->original_ratio_fp, temp1_fp); temp1_fp = drm_fixp_from_fraction(tu->new_valid_boundary_link, 1); temp2_fp = temp1_fp - temp2_fp; temp1_fp = drm_fixp_from_fraction(temp, 1); temp2_fp = drm_fixp_mul(temp1_fp, temp2_fp); if (temp2_fp) temp2 = drm_fixp2int_ceil(temp2_fp); else temp2 = 0; tu->extra_required_bytes_new_tmp = (int)(temp1 + temp2); temp1_fp = drm_fixp_from_fraction(8, tu->bpp); temp2_fp = drm_fixp_from_fraction( tu->extra_required_bytes_new_tmp, 1); temp1_fp = drm_fixp_mul(temp2_fp, temp1_fp); if (temp1_fp) tu->extra_pclk_cycles_tmp = drm_fixp2int_ceil(temp1_fp); else tu->extra_pclk_cycles_tmp = 0; temp1_fp = drm_fixp_from_fraction(tu->extra_pclk_cycles_tmp, 1); temp2_fp = drm_fixp_div(tu->lclk_fp, tu->pclk_fp); temp1_fp = drm_fixp_mul(temp1_fp, temp2_fp); if (temp1_fp) tu->extra_pclk_cycles_in_link_clk_tmp = drm_fixp2int_ceil(temp1_fp); else tu->extra_pclk_cycles_in_link_clk_tmp = 0; tu->filler_size_tmp = tu->tu_size - tu->new_valid_boundary_link; tu->lower_filler_size_tmp = tu->filler_size_tmp + 1; tu->delay_start_link_tmp = tu->extra_pclk_cycles_in_link_clk_tmp + tu->lower_filler_size_tmp + tu->extra_buffer_margin; temp1_fp = drm_fixp_from_fraction(tu->delay_start_link_tmp, 1); tu->delay_start_time_fp = drm_fixp_div(temp1_fp, tu->lclk_fp); compare_result_1 = _tu_param_compare(tu->n_n_err_fp, tu->diff_abs_fp); if (compare_result_1 == 2) compare_result_1 = 1; else compare_result_1 = 0; compare_result_2 = _tu_param_compare(tu->n_n_err_fp, tu->err_fp); if (compare_result_2 == 2) compare_result_2 = 1; else compare_result_2 = 0; compare_result_3 = _tu_param_compare(tu->hbp_time_fp, tu->delay_start_time_fp); if (compare_result_3 == 2) compare_result_3 = 0; else compare_result_3 = 1; if (((tu->even_distribution == 1) || ((tu->even_distribution_BF == 0) && (tu->even_distribution_legacy == 0))) && tu->n_err_fp >= 0 && tu->n_n_err_fp >= 0 && compare_result_2 && (compare_result_1 || (tu->min_hblank_violated == 1)) && (tu->new_valid_boundary_link - 1) > 0 && compare_result_3 && (tu->delay_start_link_tmp <= 1023)) { tu->upper_boundary_count = tu->i_upper_boundary_count; tu->lower_boundary_count = tu->i_lower_boundary_count; tu->err_fp = tu->n_n_err_fp; tu->boundary_moderation_en = true; tu->tu_size_desired = tu->tu_size; tu->valid_boundary_link = tu->new_valid_boundary_link; tu->effective_valid_recorded_fp = tu->effective_valid_fp; tu->even_distribution_BF = 1; tu->delay_start_link = tu->delay_start_link_tmp; } else if (tu->boundary_mod_lower_err == 0) { compare_result_1 = _tu_param_compare(tu->n_n_err_fp, tu->diff_abs_fp); if (compare_result_1 == 2) tu->boundary_mod_lower_err = 1; } } static void _dp_ctrl_calc_tu(struct dp_ctrl_private *ctrl, struct dp_tu_calc_input *in, struct dp_vc_tu_mapping_table *tu_table) { struct tu_algo_data *tu; int compare_result_1, compare_result_2; u64 temp = 0; s64 temp_fp = 0, temp1_fp = 0, temp2_fp = 0; s64 LCLK_FAST_SKEW_fp = drm_fixp_from_fraction(6, 10000); /* 0.0006 */ s64 const_p49_fp = drm_fixp_from_fraction(49, 100); /* 0.49 */ s64 const_p56_fp = drm_fixp_from_fraction(56, 100); /* 0.56 */ s64 RATIO_SCALE_fp = drm_fixp_from_fraction(1001, 1000); u8 DP_BRUTE_FORCE = 1; s64 BRUTE_FORCE_THRESHOLD_fp = drm_fixp_from_fraction(1, 10); /* 0.1 */ uint EXTRA_PIXCLK_CYCLE_DELAY = 4; uint HBLANK_MARGIN = 4; tu = kzalloc(sizeof(*tu), GFP_KERNEL); if (!tu) return; dp_panel_update_tu_timings(in, tu); tu->err_fp = drm_fixp_from_fraction(1000, 1); /* 1000 */ temp1_fp = drm_fixp_from_fraction(4, 1); temp2_fp = drm_fixp_mul(temp1_fp, tu->lclk_fp); temp_fp = drm_fixp_div(temp2_fp, tu->pclk_fp); tu->extra_buffer_margin = drm_fixp2int_ceil(temp_fp); temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp2_fp = drm_fixp_mul(tu->pclk_fp, temp1_fp); temp1_fp = drm_fixp_from_fraction(tu->nlanes, 1); temp2_fp = drm_fixp_div(temp2_fp, temp1_fp); tu->ratio_fp = drm_fixp_div(temp2_fp, tu->lclk_fp); tu->original_ratio_fp = tu->ratio_fp; tu->boundary_moderation_en = false; tu->upper_boundary_count = 0; tu->lower_boundary_count = 0; tu->i_upper_boundary_count = 0; tu->i_lower_boundary_count = 0; tu->valid_lower_boundary_link = 0; tu->even_distribution_BF = 0; tu->even_distribution_legacy = 0; tu->even_distribution = 0; tu->delay_start_time_fp = 0; tu->err_fp = drm_fixp_from_fraction(1000, 1); tu->n_err_fp = 0; tu->n_n_err_fp = 0; tu->ratio = drm_fixp2int(tu->ratio_fp); temp1_fp = drm_fixp_from_fraction(tu->nlanes, 1); div64_u64_rem(tu->lwidth_fp, temp1_fp, &temp2_fp); if (temp2_fp != 0 && !tu->ratio && tu->dsc_en == 0) { tu->ratio_fp = drm_fixp_mul(tu->ratio_fp, RATIO_SCALE_fp); tu->ratio = drm_fixp2int(tu->ratio_fp); if (tu->ratio) tu->ratio_fp = drm_fixp_from_fraction(1, 1); } if (tu->ratio > 1) tu->ratio = 1; if (tu->ratio == 1) goto tu_size_calc; compare_result_1 = _tu_param_compare(tu->ratio_fp, const_p49_fp); if (!compare_result_1 || compare_result_1 == 1) compare_result_1 = 1; else compare_result_1 = 0; compare_result_2 = _tu_param_compare(tu->ratio_fp, const_p56_fp); if (!compare_result_2 || compare_result_2 == 2) compare_result_2 = 1; else compare_result_2 = 0; if (tu->dsc_en && compare_result_1 && compare_result_2) { HBLANK_MARGIN += 4; drm_dbg_dp(ctrl->drm_dev, "increase HBLANK_MARGIN to %d\n", HBLANK_MARGIN); } tu_size_calc: for (tu->tu_size = 32; tu->tu_size <= 64; tu->tu_size++) { temp1_fp = drm_fixp_from_fraction(tu->tu_size, 1); temp2_fp = drm_fixp_mul(tu->ratio_fp, temp1_fp); temp = drm_fixp2int_ceil(temp2_fp); temp1_fp = drm_fixp_from_fraction(temp, 1); tu->n_err_fp = temp1_fp - temp2_fp; if (tu->n_err_fp < tu->err_fp) { tu->err_fp = tu->n_err_fp; tu->tu_size_desired = tu->tu_size; } } tu->tu_size_minus1 = tu->tu_size_desired - 1; temp1_fp = drm_fixp_from_fraction(tu->tu_size_desired, 1); temp2_fp = drm_fixp_mul(tu->ratio_fp, temp1_fp); tu->valid_boundary_link = drm_fixp2int_ceil(temp2_fp); temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp2_fp = tu->lwidth_fp; temp2_fp = drm_fixp_mul(temp2_fp, temp1_fp); temp1_fp = drm_fixp_from_fraction(tu->valid_boundary_link, 1); temp2_fp = drm_fixp_div(temp2_fp, temp1_fp); tu->n_tus = drm_fixp2int(temp2_fp); if ((temp2_fp & 0xFFFFFFFF) > 0xFFFFF000) tu->n_tus += 1; tu->even_distribution_legacy = tu->n_tus % tu->nlanes == 0 ? 1 : 0; drm_dbg_dp(ctrl->drm_dev, "n_sym = %d, num_of_tus = %d\n", tu->valid_boundary_link, tu->n_tus); temp1_fp = drm_fixp_from_fraction(tu->tu_size_desired, 1); temp2_fp = drm_fixp_mul(tu->original_ratio_fp, temp1_fp); temp1_fp = drm_fixp_from_fraction(tu->valid_boundary_link, 1); temp2_fp = temp1_fp - temp2_fp; temp1_fp = drm_fixp_from_fraction(tu->n_tus + 1, 1); temp2_fp = drm_fixp_mul(temp1_fp, temp2_fp); temp = drm_fixp2int(temp2_fp); if (temp && temp2_fp) tu->extra_bytes = drm_fixp2int_ceil(temp2_fp); else tu->extra_bytes = 0; temp1_fp = drm_fixp_from_fraction(tu->extra_bytes, 1); temp2_fp = drm_fixp_from_fraction(8, tu->bpp); temp1_fp = drm_fixp_mul(temp1_fp, temp2_fp); if (temp && temp1_fp) tu->extra_pclk_cycles = drm_fixp2int_ceil(temp1_fp); else tu->extra_pclk_cycles = drm_fixp2int(temp1_fp); temp1_fp = drm_fixp_div(tu->lclk_fp, tu->pclk_fp); temp2_fp = drm_fixp_from_fraction(tu->extra_pclk_cycles, 1); temp1_fp = drm_fixp_mul(temp2_fp, temp1_fp); if (temp1_fp) tu->extra_pclk_cycles_in_link_clk = drm_fixp2int_ceil(temp1_fp); else tu->extra_pclk_cycles_in_link_clk = drm_fixp2int(temp1_fp); tu->filler_size = tu->tu_size_desired - tu->valid_boundary_link; temp1_fp = drm_fixp_from_fraction(tu->tu_size_desired, 1); tu->ratio_by_tu_fp = drm_fixp_mul(tu->ratio_fp, temp1_fp); tu->delay_start_link = tu->extra_pclk_cycles_in_link_clk + tu->filler_size + tu->extra_buffer_margin; tu->resulting_valid_fp = drm_fixp_from_fraction(tu->valid_boundary_link, 1); temp1_fp = drm_fixp_from_fraction(tu->tu_size_desired, 1); temp2_fp = drm_fixp_div(tu->resulting_valid_fp, temp1_fp); tu->TU_ratio_err_fp = temp2_fp - tu->original_ratio_fp; temp1_fp = drm_fixp_from_fraction(HBLANK_MARGIN, 1); temp1_fp = tu->hbp_relative_to_pclk_fp - temp1_fp; tu->hbp_time_fp = drm_fixp_div(temp1_fp, tu->pclk_fp); temp1_fp = drm_fixp_from_fraction(tu->delay_start_link, 1); tu->delay_start_time_fp = drm_fixp_div(temp1_fp, tu->lclk_fp); compare_result_1 = _tu_param_compare(tu->hbp_time_fp, tu->delay_start_time_fp); if (compare_result_1 == 2) /* if (hbp_time_fp < delay_start_time_fp) */ tu->min_hblank_violated = 1; tu->hactive_time_fp = drm_fixp_div(tu->lwidth_fp, tu->pclk_fp); compare_result_2 = _tu_param_compare(tu->hactive_time_fp, tu->delay_start_time_fp); if (compare_result_2 == 2) tu->min_hblank_violated = 1; tu->delay_start_time_fp = 0; /* brute force */ tu->delay_start_link_extra_pixclk = EXTRA_PIXCLK_CYCLE_DELAY; tu->diff_abs_fp = tu->resulting_valid_fp - tu->ratio_by_tu_fp; temp = drm_fixp2int(tu->diff_abs_fp); if (!temp && tu->diff_abs_fp <= 0xffff) tu->diff_abs_fp = 0; /* if(diff_abs < 0) diff_abs *= -1 */ if (tu->diff_abs_fp < 0) tu->diff_abs_fp = drm_fixp_mul(tu->diff_abs_fp, -1); tu->boundary_mod_lower_err = 0; if ((tu->diff_abs_fp != 0 && ((tu->diff_abs_fp > BRUTE_FORCE_THRESHOLD_fp) || (tu->even_distribution_legacy == 0) || (DP_BRUTE_FORCE == 1))) || (tu->min_hblank_violated == 1)) { do { tu->err_fp = drm_fixp_from_fraction(1000, 1); temp1_fp = drm_fixp_div(tu->lclk_fp, tu->pclk_fp); temp2_fp = drm_fixp_from_fraction( tu->delay_start_link_extra_pixclk, 1); temp1_fp = drm_fixp_mul(temp2_fp, temp1_fp); if (temp1_fp) tu->extra_buffer_margin = drm_fixp2int_ceil(temp1_fp); else tu->extra_buffer_margin = 0; temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp1_fp = drm_fixp_mul(tu->lwidth_fp, temp1_fp); if (temp1_fp) tu->n_symbols = drm_fixp2int_ceil(temp1_fp); else tu->n_symbols = 0; for (tu->tu_size = 32; tu->tu_size <= 64; tu->tu_size++) { for (tu->i_upper_boundary_count = 1; tu->i_upper_boundary_count <= 15; tu->i_upper_boundary_count++) { for (tu->i_lower_boundary_count = 1; tu->i_lower_boundary_count <= 15; tu->i_lower_boundary_count++) { _tu_valid_boundary_calc(tu); } } } tu->delay_start_link_extra_pixclk--; } while (tu->boundary_moderation_en != true && tu->boundary_mod_lower_err == 1 && tu->delay_start_link_extra_pixclk != 0); if (tu->boundary_moderation_en == true) { temp1_fp = drm_fixp_from_fraction( (tu->upper_boundary_count * tu->valid_boundary_link + tu->lower_boundary_count * (tu->valid_boundary_link - 1)), 1); temp2_fp = drm_fixp_from_fraction( (tu->upper_boundary_count + tu->lower_boundary_count), 1); tu->resulting_valid_fp = drm_fixp_div(temp1_fp, temp2_fp); temp1_fp = drm_fixp_from_fraction( tu->tu_size_desired, 1); tu->ratio_by_tu_fp = drm_fixp_mul(tu->original_ratio_fp, temp1_fp); tu->valid_lower_boundary_link = tu->valid_boundary_link - 1; temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp1_fp = drm_fixp_mul(tu->lwidth_fp, temp1_fp); temp2_fp = drm_fixp_div(temp1_fp, tu->resulting_valid_fp); tu->n_tus = drm_fixp2int(temp2_fp); tu->tu_size_minus1 = tu->tu_size_desired - 1; tu->even_distribution_BF = 1; temp1_fp = drm_fixp_from_fraction(tu->tu_size_desired, 1); temp2_fp = drm_fixp_div(tu->resulting_valid_fp, temp1_fp); tu->TU_ratio_err_fp = temp2_fp - tu->original_ratio_fp; } } temp2_fp = drm_fixp_mul(LCLK_FAST_SKEW_fp, tu->lwidth_fp); if (temp2_fp) temp = drm_fixp2int_ceil(temp2_fp); else temp = 0; temp1_fp = drm_fixp_from_fraction(tu->nlanes, 1); temp2_fp = drm_fixp_mul(tu->original_ratio_fp, temp1_fp); temp1_fp = drm_fixp_from_fraction(tu->bpp, 8); temp2_fp = drm_fixp_div(temp1_fp, temp2_fp); temp1_fp = drm_fixp_from_fraction(temp, 1); temp2_fp = drm_fixp_mul(temp1_fp, temp2_fp); temp = drm_fixp2int(temp2_fp); if (tu->async_en) tu->delay_start_link += (int)temp; temp1_fp = drm_fixp_from_fraction(tu->delay_start_link, 1); tu->delay_start_time_fp = drm_fixp_div(temp1_fp, tu->lclk_fp); /* OUTPUTS */ tu_table->valid_boundary_link = tu->valid_boundary_link; tu_table->delay_start_link = tu->delay_start_link; tu_table->boundary_moderation_en = tu->boundary_moderation_en; tu_table->valid_lower_boundary_link = tu->valid_lower_boundary_link; tu_table->upper_boundary_count = tu->upper_boundary_count; tu_table->lower_boundary_count = tu->lower_boundary_count; tu_table->tu_size_minus1 = tu->tu_size_minus1; drm_dbg_dp(ctrl->drm_dev, "TU: valid_boundary_link: %d\n", tu_table->valid_boundary_link); drm_dbg_dp(ctrl->drm_dev, "TU: delay_start_link: %d\n", tu_table->delay_start_link); drm_dbg_dp(ctrl->drm_dev, "TU: boundary_moderation_en: %d\n", tu_table->boundary_moderation_en); drm_dbg_dp(ctrl->drm_dev, "TU: valid_lower_boundary_link: %d\n", tu_table->valid_lower_boundary_link); drm_dbg_dp(ctrl->drm_dev, "TU: upper_boundary_count: %d\n", tu_table->upper_boundary_count); drm_dbg_dp(ctrl->drm_dev, "TU: lower_boundary_count: %d\n", tu_table->lower_boundary_count); drm_dbg_dp(ctrl->drm_dev, "TU: tu_size_minus1: %d\n", tu_table->tu_size_minus1); kfree(tu); } static void dp_ctrl_calc_tu_parameters(struct dp_ctrl_private *ctrl, struct dp_vc_tu_mapping_table *tu_table) { struct dp_tu_calc_input in; struct drm_display_mode *drm_mode; drm_mode = &ctrl->panel->dp_mode.drm_mode; in.lclk = ctrl->link->link_params.rate / 1000; in.pclk_khz = drm_mode->clock; in.hactive = drm_mode->hdisplay; in.hporch = drm_mode->htotal - drm_mode->hdisplay; in.nlanes = ctrl->link->link_params.num_lanes; in.bpp = ctrl->panel->dp_mode.bpp; in.pixel_enc = 444; in.dsc_en = 0; in.async_en = 0; in.fec_en = 0; in.num_of_dsc_slices = 0; in.compress_ratio = 100; _dp_ctrl_calc_tu(ctrl, &in, tu_table); } static void dp_ctrl_setup_tr_unit(struct dp_ctrl_private *ctrl) { u32 dp_tu = 0x0; u32 valid_boundary = 0x0; u32 valid_boundary2 = 0x0; struct dp_vc_tu_mapping_table tu_calc_table; dp_ctrl_calc_tu_parameters(ctrl, &tu_calc_table); dp_tu |= tu_calc_table.tu_size_minus1; valid_boundary |= tu_calc_table.valid_boundary_link; valid_boundary |= (tu_calc_table.delay_start_link << 16); valid_boundary2 |= (tu_calc_table.valid_lower_boundary_link << 1); valid_boundary2 |= (tu_calc_table.upper_boundary_count << 16); valid_boundary2 |= (tu_calc_table.lower_boundary_count << 20); if (tu_calc_table.boundary_moderation_en) valid_boundary2 |= BIT(0); pr_debug("dp_tu=0x%x, valid_boundary=0x%x, valid_boundary2=0x%x\n", dp_tu, valid_boundary, valid_boundary2); dp_catalog_ctrl_update_transfer_unit(ctrl->catalog, dp_tu, valid_boundary, valid_boundary2); } static int dp_ctrl_wait4video_ready(struct dp_ctrl_private *ctrl) { int ret = 0; if (!wait_for_completion_timeout(&ctrl->video_comp, WAIT_FOR_VIDEO_READY_TIMEOUT_JIFFIES)) { DRM_ERROR("wait4video timedout\n"); ret = -ETIMEDOUT; } return ret; } static int dp_ctrl_update_vx_px(struct dp_ctrl_private *ctrl) { struct dp_link *link = ctrl->link; int ret = 0, lane, lane_cnt; u8 buf[4]; u32 max_level_reached = 0; u32 voltage_swing_level = link->phy_params.v_level; u32 pre_emphasis_level = link->phy_params.p_level; drm_dbg_dp(ctrl->drm_dev, "voltage level: %d emphasis level: %d\n", voltage_swing_level, pre_emphasis_level); ret = dp_catalog_ctrl_update_vx_px(ctrl->catalog, voltage_swing_level, pre_emphasis_level); if (ret) return ret; if (voltage_swing_level >= DP_TRAIN_VOLTAGE_SWING_MAX) { drm_dbg_dp(ctrl->drm_dev, "max. voltage swing level reached %d\n", voltage_swing_level); max_level_reached |= DP_TRAIN_MAX_SWING_REACHED; } if (pre_emphasis_level >= DP_TRAIN_PRE_EMPHASIS_MAX) { drm_dbg_dp(ctrl->drm_dev, "max. pre-emphasis level reached %d\n", pre_emphasis_level); max_level_reached |= DP_TRAIN_MAX_PRE_EMPHASIS_REACHED; } pre_emphasis_level <<= DP_TRAIN_PRE_EMPHASIS_SHIFT; lane_cnt = ctrl->link->link_params.num_lanes; for (lane = 0; lane < lane_cnt; lane++) buf[lane] = voltage_swing_level | pre_emphasis_level | max_level_reached; drm_dbg_dp(ctrl->drm_dev, "sink: p|v=0x%x\n", voltage_swing_level | pre_emphasis_level); ret = drm_dp_dpcd_write(ctrl->aux, DP_TRAINING_LANE0_SET, buf, lane_cnt); if (ret == lane_cnt) ret = 0; return ret; } static bool dp_ctrl_train_pattern_set(struct dp_ctrl_private *ctrl, u8 pattern) { u8 buf; int ret = 0; drm_dbg_dp(ctrl->drm_dev, "sink: pattern=%x\n", pattern); buf = pattern; if (pattern && pattern != DP_TRAINING_PATTERN_4) buf |= DP_LINK_SCRAMBLING_DISABLE; ret = drm_dp_dpcd_writeb(ctrl->aux, DP_TRAINING_PATTERN_SET, buf); return ret == 1; } static int dp_ctrl_read_link_status(struct dp_ctrl_private *ctrl, u8 *link_status) { int ret = 0, len; len = drm_dp_dpcd_read_link_status(ctrl->aux, link_status); if (len != DP_LINK_STATUS_SIZE) { DRM_ERROR("DP link status read failed, err: %d\n", len); ret = -EINVAL; } return ret; } static int dp_ctrl_link_train_1(struct dp_ctrl_private *ctrl, int *training_step) { int tries, old_v_level, ret = 0; u8 link_status[DP_LINK_STATUS_SIZE]; int const maximum_retries = 4; dp_catalog_ctrl_state_ctrl(ctrl->catalog, 0); *training_step = DP_TRAINING_1; ret = dp_catalog_ctrl_set_pattern_state_bit(ctrl->catalog, 1); if (ret) return ret; dp_ctrl_train_pattern_set(ctrl, DP_TRAINING_PATTERN_1 | DP_LINK_SCRAMBLING_DISABLE); ret = dp_ctrl_update_vx_px(ctrl); if (ret) return ret; tries = 0; old_v_level = ctrl->link->phy_params.v_level; for (tries = 0; tries < maximum_retries; tries++) { drm_dp_link_train_clock_recovery_delay(ctrl->aux, ctrl->panel->dpcd); ret = dp_ctrl_read_link_status(ctrl, link_status); if (ret) return ret; if (drm_dp_clock_recovery_ok(link_status, ctrl->link->link_params.num_lanes)) { return 0; } if (ctrl->link->phy_params.v_level >= DP_TRAIN_VOLTAGE_SWING_MAX) { DRM_ERROR_RATELIMITED("max v_level reached\n"); return -EAGAIN; } if (old_v_level != ctrl->link->phy_params.v_level) { tries = 0; old_v_level = ctrl->link->phy_params.v_level; } dp_link_adjust_levels(ctrl->link, link_status); ret = dp_ctrl_update_vx_px(ctrl); if (ret) return ret; } DRM_ERROR("max tries reached\n"); return -ETIMEDOUT; } static int dp_ctrl_link_rate_down_shift(struct dp_ctrl_private *ctrl) { int ret = 0; switch (ctrl->link->link_params.rate) { case 810000: ctrl->link->link_params.rate = 540000; break; case 540000: ctrl->link->link_params.rate = 270000; break; case 270000: ctrl->link->link_params.rate = 162000; break; case 162000: default: ret = -EINVAL; break; } if (!ret) { drm_dbg_dp(ctrl->drm_dev, "new rate=0x%x\n", ctrl->link->link_params.rate); } return ret; } static int dp_ctrl_link_lane_down_shift(struct dp_ctrl_private *ctrl) { if (ctrl->link->link_params.num_lanes == 1) return -1; ctrl->link->link_params.num_lanes /= 2; ctrl->link->link_params.rate = ctrl->panel->link_info.rate; ctrl->link->phy_params.p_level = 0; ctrl->link->phy_params.v_level = 0; return 0; } static void dp_ctrl_clear_training_pattern(struct dp_ctrl_private *ctrl) { dp_ctrl_train_pattern_set(ctrl, DP_TRAINING_PATTERN_DISABLE); drm_dp_link_train_channel_eq_delay(ctrl->aux, ctrl->panel->dpcd); } static int dp_ctrl_link_train_2(struct dp_ctrl_private *ctrl, int *training_step) { int tries = 0, ret = 0; u8 pattern; u32 state_ctrl_bit; int const maximum_retries = 5; u8 link_status[DP_LINK_STATUS_SIZE]; dp_catalog_ctrl_state_ctrl(ctrl->catalog, 0); *training_step = DP_TRAINING_2; if (drm_dp_tps4_supported(ctrl->panel->dpcd)) { pattern = DP_TRAINING_PATTERN_4; state_ctrl_bit = 4; } else if (drm_dp_tps3_supported(ctrl->panel->dpcd)) { pattern = DP_TRAINING_PATTERN_3; state_ctrl_bit = 3; } else { pattern = DP_TRAINING_PATTERN_2; state_ctrl_bit = 2; } ret = dp_catalog_ctrl_set_pattern_state_bit(ctrl->catalog, state_ctrl_bit); if (ret) return ret; dp_ctrl_train_pattern_set(ctrl, pattern); for (tries = 0; tries <= maximum_retries; tries++) { drm_dp_link_train_channel_eq_delay(ctrl->aux, ctrl->panel->dpcd); ret = dp_ctrl_read_link_status(ctrl, link_status); if (ret) return ret; if (drm_dp_channel_eq_ok(link_status, ctrl->link->link_params.num_lanes)) { return 0; } dp_link_adjust_levels(ctrl->link, link_status); ret = dp_ctrl_update_vx_px(ctrl); if (ret) return ret; } return -ETIMEDOUT; } static int dp_ctrl_link_train(struct dp_ctrl_private *ctrl, int *training_step) { int ret = 0; const u8 *dpcd = ctrl->panel->dpcd; u8 encoding[] = { 0, DP_SET_ANSI_8B10B }; u8 assr; struct dp_link_info link_info = {0}; dp_ctrl_config_ctrl(ctrl); link_info.num_lanes = ctrl->link->link_params.num_lanes; link_info.rate = ctrl->link->link_params.rate; link_info.capabilities = DP_LINK_CAP_ENHANCED_FRAMING; dp_aux_link_configure(ctrl->aux, &link_info); if (drm_dp_max_downspread(dpcd)) encoding[0] |= DP_SPREAD_AMP_0_5; /* config DOWNSPREAD_CTRL and MAIN_LINK_CHANNEL_CODING_SET */ drm_dp_dpcd_write(ctrl->aux, DP_DOWNSPREAD_CTRL, encoding, 2); if (drm_dp_alternate_scrambler_reset_cap(dpcd)) { assr = DP_ALTERNATE_SCRAMBLER_RESET_ENABLE; drm_dp_dpcd_write(ctrl->aux, DP_EDP_CONFIGURATION_SET, &assr, 1); } ret = dp_ctrl_link_train_1(ctrl, training_step); if (ret) { DRM_ERROR("link training #1 failed. ret=%d\n", ret); goto end; } /* print success info as this is a result of user initiated action */ drm_dbg_dp(ctrl->drm_dev, "link training #1 successful\n"); ret = dp_ctrl_link_train_2(ctrl, training_step); if (ret) { DRM_ERROR("link training #2 failed. ret=%d\n", ret); goto end; } /* print success info as this is a result of user initiated action */ drm_dbg_dp(ctrl->drm_dev, "link training #2 successful\n"); end: dp_catalog_ctrl_state_ctrl(ctrl->catalog, 0); return ret; } static int dp_ctrl_setup_main_link(struct dp_ctrl_private *ctrl, int *training_step) { int ret = 0; dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, true); if (ctrl->link->sink_request & DP_TEST_LINK_PHY_TEST_PATTERN) return ret; /* * As part of previous calls, DP controller state might have * transitioned to PUSH_IDLE. In order to start transmitting * a link training pattern, we have to first do soft reset. */ ret = dp_ctrl_link_train(ctrl, training_step); return ret; } static void dp_ctrl_set_clock_rate(struct dp_ctrl_private *ctrl, enum dp_pm_type module, char *name, unsigned long rate) { u32 num = ctrl->parser->mp[module].num_clk; struct clk_bulk_data *cfg = ctrl->parser->mp[module].clocks; while (num && strcmp(cfg->id, name)) { num--; cfg++; } drm_dbg_dp(ctrl->drm_dev, "setting rate=%lu on clk=%s\n", rate, name); if (num) clk_set_rate(cfg->clk, rate); else DRM_ERROR("%s clock doesn't exit to set rate %lu\n", name, rate); } static int dp_ctrl_enable_mainlink_clocks(struct dp_ctrl_private *ctrl) { int ret = 0; struct dp_io *dp_io = &ctrl->parser->io; struct phy *phy = dp_io->phy; struct phy_configure_opts_dp *opts_dp = &dp_io->phy_opts.dp; const u8 *dpcd = ctrl->panel->dpcd; opts_dp->lanes = ctrl->link->link_params.num_lanes; opts_dp->link_rate = ctrl->link->link_params.rate / 100; opts_dp->ssc = drm_dp_max_downspread(dpcd); phy_configure(phy, &dp_io->phy_opts); phy_power_on(phy); dev_pm_opp_set_rate(ctrl->dev, ctrl->link->link_params.rate * 1000); ret = dp_power_clk_enable(ctrl->power, DP_CTRL_PM, true); if (ret) DRM_ERROR("Unable to start link clocks. ret=%d\n", ret); drm_dbg_dp(ctrl->drm_dev, "link rate=%d\n", ctrl->link->link_params.rate); return ret; } void dp_ctrl_reset_irq_ctrl(struct dp_ctrl *dp_ctrl, bool enable) { struct dp_ctrl_private *ctrl; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); dp_catalog_ctrl_reset(ctrl->catalog); /* * all dp controller programmable registers will not * be reset to default value after DP_SW_RESET * therefore interrupt mask bits have to be updated * to enable/disable interrupts */ dp_catalog_ctrl_enable_irq(ctrl->catalog, enable); } void dp_ctrl_config_psr(struct dp_ctrl *dp_ctrl) { u8 cfg; struct dp_ctrl_private *ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); if (!ctrl->panel->psr_cap.version) return; dp_catalog_ctrl_config_psr(ctrl->catalog); cfg = DP_PSR_ENABLE; drm_dp_dpcd_write(ctrl->aux, DP_PSR_EN_CFG, &cfg, 1); } void dp_ctrl_set_psr(struct dp_ctrl *dp_ctrl, bool enter) { struct dp_ctrl_private *ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); if (!ctrl->panel->psr_cap.version) return; /* * When entering PSR, * 1. Send PSR enter SDP and wait for the PSR_UPDATE_INT * 2. Turn off video * 3. Disable the mainlink * * When exiting PSR, * 1. Enable the mainlink * 2. Send the PSR exit SDP */ if (enter) { reinit_completion(&ctrl->psr_op_comp); dp_catalog_ctrl_set_psr(ctrl->catalog, true); if (!wait_for_completion_timeout(&ctrl->psr_op_comp, PSR_OPERATION_COMPLETION_TIMEOUT_JIFFIES)) { DRM_ERROR("PSR_ENTRY timedout\n"); dp_catalog_ctrl_set_psr(ctrl->catalog, false); return; } dp_ctrl_push_idle(dp_ctrl); dp_catalog_ctrl_state_ctrl(ctrl->catalog, 0); dp_catalog_ctrl_psr_mainlink_enable(ctrl->catalog, false); } else { dp_catalog_ctrl_psr_mainlink_enable(ctrl->catalog, true); dp_catalog_ctrl_set_psr(ctrl->catalog, false); dp_catalog_ctrl_state_ctrl(ctrl->catalog, DP_STATE_CTRL_SEND_VIDEO); dp_ctrl_wait4video_ready(ctrl); dp_catalog_ctrl_state_ctrl(ctrl->catalog, 0); } } void dp_ctrl_phy_init(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; struct dp_io *dp_io; struct phy *phy; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); dp_io = &ctrl->parser->io; phy = dp_io->phy; dp_catalog_ctrl_phy_reset(ctrl->catalog); phy_init(phy); drm_dbg_dp(ctrl->drm_dev, "phy=%p init=%d power_on=%d\n", phy, phy->init_count, phy->power_count); } void dp_ctrl_phy_exit(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; struct dp_io *dp_io; struct phy *phy; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); dp_io = &ctrl->parser->io; phy = dp_io->phy; dp_catalog_ctrl_phy_reset(ctrl->catalog); phy_exit(phy); drm_dbg_dp(ctrl->drm_dev, "phy=%p init=%d power_on=%d\n", phy, phy->init_count, phy->power_count); } static bool dp_ctrl_use_fixed_nvid(struct dp_ctrl_private *ctrl) { const u8 *dpcd = ctrl->panel->dpcd; /* * For better interop experience, used a fixed NVID=0x8000 * whenever connected to a VGA dongle downstream. */ if (drm_dp_is_branch(dpcd)) return (drm_dp_has_quirk(&ctrl->panel->desc, DP_DPCD_QUIRK_CONSTANT_N)); return false; } static int dp_ctrl_reinitialize_mainlink(struct dp_ctrl_private *ctrl) { int ret = 0; struct dp_io *dp_io = &ctrl->parser->io; struct phy *phy = dp_io->phy; struct phy_configure_opts_dp *opts_dp = &dp_io->phy_opts.dp; dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, false); opts_dp->lanes = ctrl->link->link_params.num_lanes; phy_configure(phy, &dp_io->phy_opts); /* * Disable and re-enable the mainlink clock since the * link clock might have been adjusted as part of the * link maintenance. */ dev_pm_opp_set_rate(ctrl->dev, 0); ret = dp_power_clk_enable(ctrl->power, DP_CTRL_PM, false); if (ret) { DRM_ERROR("Failed to disable clocks. ret=%d\n", ret); return ret; } phy_power_off(phy); /* hw recommended delay before re-enabling clocks */ msleep(20); ret = dp_ctrl_enable_mainlink_clocks(ctrl); if (ret) { DRM_ERROR("Failed to enable mainlink clks. ret=%d\n", ret); return ret; } return ret; } static int dp_ctrl_deinitialize_mainlink(struct dp_ctrl_private *ctrl) { struct dp_io *dp_io; struct phy *phy; int ret; dp_io = &ctrl->parser->io; phy = dp_io->phy; dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, false); dp_catalog_ctrl_reset(ctrl->catalog); dev_pm_opp_set_rate(ctrl->dev, 0); ret = dp_power_clk_enable(ctrl->power, DP_CTRL_PM, false); if (ret) { DRM_ERROR("Failed to disable link clocks. ret=%d\n", ret); } phy_power_off(phy); /* aux channel down, reinit phy */ phy_exit(phy); phy_init(phy); drm_dbg_dp(ctrl->drm_dev, "phy=%p init=%d power_on=%d\n", phy, phy->init_count, phy->power_count); return 0; } static int dp_ctrl_link_maintenance(struct dp_ctrl_private *ctrl) { int ret = 0; int training_step = DP_TRAINING_NONE; dp_ctrl_push_idle(&ctrl->dp_ctrl); ctrl->link->phy_params.p_level = 0; ctrl->link->phy_params.v_level = 0; ret = dp_ctrl_setup_main_link(ctrl, &training_step); if (ret) goto end; dp_ctrl_clear_training_pattern(ctrl); dp_catalog_ctrl_state_ctrl(ctrl->catalog, DP_STATE_CTRL_SEND_VIDEO); ret = dp_ctrl_wait4video_ready(ctrl); end: return ret; } static bool dp_ctrl_send_phy_test_pattern(struct dp_ctrl_private *ctrl) { bool success = false; u32 pattern_sent = 0x0; u32 pattern_requested = ctrl->link->phy_params.phy_test_pattern_sel; drm_dbg_dp(ctrl->drm_dev, "request: 0x%x\n", pattern_requested); if (dp_catalog_ctrl_update_vx_px(ctrl->catalog, ctrl->link->phy_params.v_level, ctrl->link->phy_params.p_level)) { DRM_ERROR("Failed to set v/p levels\n"); return false; } dp_catalog_ctrl_send_phy_pattern(ctrl->catalog, pattern_requested); dp_ctrl_update_vx_px(ctrl); dp_link_send_test_response(ctrl->link); pattern_sent = dp_catalog_ctrl_read_phy_pattern(ctrl->catalog); switch (pattern_sent) { case MR_LINK_TRAINING1: success = (pattern_requested == DP_PHY_TEST_PATTERN_D10_2); break; case MR_LINK_SYMBOL_ERM: success = ((pattern_requested == DP_PHY_TEST_PATTERN_ERROR_COUNT) || (pattern_requested == DP_PHY_TEST_PATTERN_CP2520)); break; case MR_LINK_PRBS7: success = (pattern_requested == DP_PHY_TEST_PATTERN_PRBS7); break; case MR_LINK_CUSTOM80: success = (pattern_requested == DP_PHY_TEST_PATTERN_80BIT_CUSTOM); break; case MR_LINK_TRAINING4: success = (pattern_requested == DP_PHY_TEST_PATTERN_SEL_MASK); break; default: success = false; } drm_dbg_dp(ctrl->drm_dev, "%s: test->0x%x\n", success ? "success" : "failed", pattern_requested); return success; } static int dp_ctrl_process_phy_test_request(struct dp_ctrl_private *ctrl) { int ret; unsigned long pixel_rate; if (!ctrl->link->phy_params.phy_test_pattern_sel) { drm_dbg_dp(ctrl->drm_dev, "no test pattern selected by sink\n"); return 0; } /* * The global reset will need DP link related clocks to be * running. Add the global reset just before disabling the * link clocks and core clocks. */ ret = dp_ctrl_off(&ctrl->dp_ctrl); if (ret) { DRM_ERROR("failed to disable DP controller\n"); return ret; } ret = dp_ctrl_on_link(&ctrl->dp_ctrl); if (ret) { DRM_ERROR("failed to enable DP link controller\n"); return ret; } pixel_rate = ctrl->panel->dp_mode.drm_mode.clock; dp_ctrl_set_clock_rate(ctrl, DP_STREAM_PM, "stream_pixel", pixel_rate * 1000); ret = dp_power_clk_enable(ctrl->power, DP_STREAM_PM, true); if (ret) { DRM_ERROR("Failed to start pixel clocks. ret=%d\n", ret); return ret; } dp_ctrl_send_phy_test_pattern(ctrl); return 0; } void dp_ctrl_handle_sink_request(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; u32 sink_request = 0x0; if (!dp_ctrl) { DRM_ERROR("invalid input\n"); return; } ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); sink_request = ctrl->link->sink_request; if (sink_request & DP_TEST_LINK_PHY_TEST_PATTERN) { drm_dbg_dp(ctrl->drm_dev, "PHY_TEST_PATTERN request\n"); if (dp_ctrl_process_phy_test_request(ctrl)) { DRM_ERROR("process phy_test_req failed\n"); return; } } if (sink_request & DP_LINK_STATUS_UPDATED) { if (dp_ctrl_link_maintenance(ctrl)) { DRM_ERROR("LM failed: TEST_LINK_TRAINING\n"); return; } } if (sink_request & DP_TEST_LINK_TRAINING) { dp_link_send_test_response(ctrl->link); if (dp_ctrl_link_maintenance(ctrl)) { DRM_ERROR("LM failed: TEST_LINK_TRAINING\n"); return; } } } static bool dp_ctrl_clock_recovery_any_ok( const u8 link_status[DP_LINK_STATUS_SIZE], int lane_count) { int reduced_cnt; if (lane_count <= 1) return false; /* * only interested in the lane number after reduced * lane_count = 4, then only interested in 2 lanes * lane_count = 2, then only interested in 1 lane */ reduced_cnt = lane_count >> 1; return drm_dp_clock_recovery_ok(link_status, reduced_cnt); } static bool dp_ctrl_channel_eq_ok(struct dp_ctrl_private *ctrl) { u8 link_status[DP_LINK_STATUS_SIZE]; int num_lanes = ctrl->link->link_params.num_lanes; dp_ctrl_read_link_status(ctrl, link_status); return drm_dp_channel_eq_ok(link_status, num_lanes); } int dp_ctrl_on_link(struct dp_ctrl *dp_ctrl) { int rc = 0; struct dp_ctrl_private *ctrl; u32 rate; int link_train_max_retries = 5; u32 const phy_cts_pixel_clk_khz = 148500; u8 link_status[DP_LINK_STATUS_SIZE]; unsigned int training_step; unsigned long pixel_rate; if (!dp_ctrl) return -EINVAL; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); rate = ctrl->panel->link_info.rate; pixel_rate = ctrl->panel->dp_mode.drm_mode.clock; dp_power_clk_enable(ctrl->power, DP_CORE_PM, true); if (ctrl->link->sink_request & DP_TEST_LINK_PHY_TEST_PATTERN) { drm_dbg_dp(ctrl->drm_dev, "using phy test link parameters\n"); if (!pixel_rate) pixel_rate = phy_cts_pixel_clk_khz; } else { ctrl->link->link_params.rate = rate; ctrl->link->link_params.num_lanes = ctrl->panel->link_info.num_lanes; } drm_dbg_dp(ctrl->drm_dev, "rate=%d, num_lanes=%d, pixel_rate=%lu\n", ctrl->link->link_params.rate, ctrl->link->link_params.num_lanes, pixel_rate); rc = dp_ctrl_enable_mainlink_clocks(ctrl); if (rc) return rc; while (--link_train_max_retries) { rc = dp_ctrl_reinitialize_mainlink(ctrl); if (rc) { DRM_ERROR("Failed to reinitialize mainlink. rc=%d\n", rc); break; } training_step = DP_TRAINING_NONE; rc = dp_ctrl_setup_main_link(ctrl, &training_step); if (rc == 0) { /* training completed successfully */ break; } else if (training_step == DP_TRAINING_1) { /* link train_1 failed */ if (!dp_catalog_link_is_connected(ctrl->catalog)) break; dp_ctrl_read_link_status(ctrl, link_status); rc = dp_ctrl_link_rate_down_shift(ctrl); if (rc < 0) { /* already in RBR = 1.6G */ if (dp_ctrl_clock_recovery_any_ok(link_status, ctrl->link->link_params.num_lanes)) { /* * some lanes are ready, * reduce lane number */ rc = dp_ctrl_link_lane_down_shift(ctrl); if (rc < 0) { /* lane == 1 already */ /* end with failure */ break; } } else { /* end with failure */ break; /* lane == 1 already */ } } } else if (training_step == DP_TRAINING_2) { /* link train_2 failed */ if (!dp_catalog_link_is_connected(ctrl->catalog)) break; dp_ctrl_read_link_status(ctrl, link_status); if (!drm_dp_clock_recovery_ok(link_status, ctrl->link->link_params.num_lanes)) rc = dp_ctrl_link_rate_down_shift(ctrl); else rc = dp_ctrl_link_lane_down_shift(ctrl); if (rc < 0) { /* end with failure */ break; /* lane == 1 already */ } /* stop link training before start re training */ dp_ctrl_clear_training_pattern(ctrl); } } if (ctrl->link->sink_request & DP_TEST_LINK_PHY_TEST_PATTERN) return rc; if (rc == 0) { /* link train successfully */ /* * do not stop train pattern here * stop link training at on_stream * to pass compliance test */ } else { /* * link training failed * end txing train pattern here */ dp_ctrl_clear_training_pattern(ctrl); dp_ctrl_deinitialize_mainlink(ctrl); rc = -ECONNRESET; } return rc; } static int dp_ctrl_link_retrain(struct dp_ctrl_private *ctrl) { int training_step = DP_TRAINING_NONE; return dp_ctrl_setup_main_link(ctrl, &training_step); } int dp_ctrl_on_stream(struct dp_ctrl *dp_ctrl, bool force_link_train) { int ret = 0; bool mainlink_ready = false; struct dp_ctrl_private *ctrl; unsigned long pixel_rate; unsigned long pixel_rate_orig; if (!dp_ctrl) return -EINVAL; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); pixel_rate = pixel_rate_orig = ctrl->panel->dp_mode.drm_mode.clock; if (dp_ctrl->wide_bus_en) pixel_rate >>= 1; drm_dbg_dp(ctrl->drm_dev, "rate=%d, num_lanes=%d, pixel_rate=%lu\n", ctrl->link->link_params.rate, ctrl->link->link_params.num_lanes, pixel_rate); if (!dp_power_clk_status(ctrl->power, DP_CTRL_PM)) { /* link clk is off */ ret = dp_ctrl_enable_mainlink_clocks(ctrl); if (ret) { DRM_ERROR("Failed to start link clocks. ret=%d\n", ret); goto end; } } dp_ctrl_set_clock_rate(ctrl, DP_STREAM_PM, "stream_pixel", pixel_rate * 1000); ret = dp_power_clk_enable(ctrl->power, DP_STREAM_PM, true); if (ret) { DRM_ERROR("Unable to start pixel clocks. ret=%d\n", ret); goto end; } if (force_link_train || !dp_ctrl_channel_eq_ok(ctrl)) dp_ctrl_link_retrain(ctrl); /* stop txing train pattern to end link training */ dp_ctrl_clear_training_pattern(ctrl); /* * Set up transfer unit values and set controller state to send * video. */ reinit_completion(&ctrl->video_comp); dp_ctrl_configure_source_params(ctrl); dp_catalog_ctrl_config_msa(ctrl->catalog, ctrl->link->link_params.rate, pixel_rate_orig, dp_ctrl_use_fixed_nvid(ctrl)); dp_ctrl_setup_tr_unit(ctrl); dp_catalog_ctrl_state_ctrl(ctrl->catalog, DP_STATE_CTRL_SEND_VIDEO); ret = dp_ctrl_wait4video_ready(ctrl); if (ret) return ret; mainlink_ready = dp_catalog_ctrl_mainlink_ready(ctrl->catalog); drm_dbg_dp(ctrl->drm_dev, "mainlink %s\n", mainlink_ready ? "READY" : "NOT READY"); end: return ret; } int dp_ctrl_off_link_stream(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; struct dp_io *dp_io; struct phy *phy; int ret; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); dp_io = &ctrl->parser->io; phy = dp_io->phy; /* set dongle to D3 (power off) mode */ dp_link_psm_config(ctrl->link, &ctrl->panel->link_info, true); dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, false); if (dp_power_clk_status(ctrl->power, DP_STREAM_PM)) { ret = dp_power_clk_enable(ctrl->power, DP_STREAM_PM, false); if (ret) { DRM_ERROR("Failed to disable pclk. ret=%d\n", ret); return ret; } } dev_pm_opp_set_rate(ctrl->dev, 0); ret = dp_power_clk_enable(ctrl->power, DP_CTRL_PM, false); if (ret) { DRM_ERROR("Failed to disable link clocks. ret=%d\n", ret); return ret; } phy_power_off(phy); /* aux channel down, reinit phy */ phy_exit(phy); phy_init(phy); drm_dbg_dp(ctrl->drm_dev, "phy=%p init=%d power_on=%d\n", phy, phy->init_count, phy->power_count); return ret; } int dp_ctrl_off_link(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; struct dp_io *dp_io; struct phy *phy; int ret; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); dp_io = &ctrl->parser->io; phy = dp_io->phy; dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, false); ret = dp_power_clk_enable(ctrl->power, DP_CTRL_PM, false); if (ret) { DRM_ERROR("Failed to disable link clocks. ret=%d\n", ret); } DRM_DEBUG_DP("Before, phy=%p init_count=%d power_on=%d\n", phy, phy->init_count, phy->power_count); phy_power_off(phy); DRM_DEBUG_DP("After, phy=%p init_count=%d power_on=%d\n", phy, phy->init_count, phy->power_count); return ret; } int dp_ctrl_off(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; struct dp_io *dp_io; struct phy *phy; int ret = 0; if (!dp_ctrl) return -EINVAL; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); dp_io = &ctrl->parser->io; phy = dp_io->phy; dp_catalog_ctrl_mainlink_ctrl(ctrl->catalog, false); dp_catalog_ctrl_reset(ctrl->catalog); ret = dp_power_clk_enable(ctrl->power, DP_STREAM_PM, false); if (ret) DRM_ERROR("Failed to disable pixel clocks. ret=%d\n", ret); dev_pm_opp_set_rate(ctrl->dev, 0); ret = dp_power_clk_enable(ctrl->power, DP_CTRL_PM, false); if (ret) { DRM_ERROR("Failed to disable link clocks. ret=%d\n", ret); } phy_power_off(phy); drm_dbg_dp(ctrl->drm_dev, "phy=%p init=%d power_on=%d\n", phy, phy->init_count, phy->power_count); return ret; } irqreturn_t dp_ctrl_isr(struct dp_ctrl *dp_ctrl) { struct dp_ctrl_private *ctrl; u32 isr; irqreturn_t ret = IRQ_NONE; if (!dp_ctrl) return IRQ_NONE; ctrl = container_of(dp_ctrl, struct dp_ctrl_private, dp_ctrl); if (ctrl->panel->psr_cap.version) { isr = dp_catalog_ctrl_read_psr_interrupt_status(ctrl->catalog); if (isr) complete(&ctrl->psr_op_comp); if (isr & PSR_EXIT_INT) drm_dbg_dp(ctrl->drm_dev, "PSR exit done\n"); if (isr & PSR_UPDATE_INT) drm_dbg_dp(ctrl->drm_dev, "PSR frame update done\n"); if (isr & PSR_CAPTURE_INT) drm_dbg_dp(ctrl->drm_dev, "PSR frame capture done\n"); } isr = dp_catalog_ctrl_get_interrupt(ctrl->catalog); if (isr & DP_CTRL_INTR_READY_FOR_VIDEO) { drm_dbg_dp(ctrl->drm_dev, "dp_video_ready\n"); complete(&ctrl->video_comp); ret = IRQ_HANDLED; } if (isr & DP_CTRL_INTR_IDLE_PATTERN_SENT) { drm_dbg_dp(ctrl->drm_dev, "idle_patterns_sent\n"); complete(&ctrl->idle_comp); ret = IRQ_HANDLED; } return ret; } struct dp_ctrl *dp_ctrl_get(struct device *dev, struct dp_link *link, struct dp_panel *panel, struct drm_dp_aux *aux, struct dp_power *power, struct dp_catalog *catalog, struct dp_parser *parser) { struct dp_ctrl_private *ctrl; int ret; if (!dev || !panel || !aux || !link || !catalog) { DRM_ERROR("invalid input\n"); return ERR_PTR(-EINVAL); } ctrl = devm_kzalloc(dev, sizeof(*ctrl), GFP_KERNEL); if (!ctrl) { DRM_ERROR("Mem allocation failure\n"); return ERR_PTR(-ENOMEM); } ret = devm_pm_opp_set_clkname(dev, "ctrl_link"); if (ret) { dev_err(dev, "invalid DP OPP table in device tree\n"); /* caller do PTR_ERR(opp_table) */ return (struct dp_ctrl *)ERR_PTR(ret); } /* OPP table is optional */ ret = devm_pm_opp_of_add_table(dev); if (ret) dev_err(dev, "failed to add DP OPP table\n"); init_completion(&ctrl->idle_comp); init_completion(&ctrl->psr_op_comp); init_completion(&ctrl->video_comp); /* in parameters */ ctrl->parser = parser; ctrl->panel = panel; ctrl->power = power; ctrl->aux = aux; ctrl->link = link; ctrl->catalog = catalog; ctrl->dev = dev; return &ctrl->dp_ctrl; }
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