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gbmc/linux/refs/heads/master/./drivers/gpu/drm/amd/display/dc/dc.h
blob: 37714d4371fba13628e7fbffc26a9aad27aa9858 [file] [edit]
/*
* Copyright 2012-2026 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
*
*/
#ifndef DC_INTERFACE_H_
#define DC_INTERFACE_H_
#include "dc_types.h"
#include "dc_state.h"
#include "dc_plane.h"
#include "grph_object_defs.h"
#include "logger_types.h"
#include "hdcp_msg_types.h"
#include "gpio_types.h"
#include "link_service_types.h"
#include "grph_object_ctrl_defs.h"
#include <inc/hw/opp.h>
#include "hwss/hw_sequencer.h"
#include "inc/compressor.h"
#include "inc/hw/dmcu.h"
#include "dml/display_mode_lib.h"
#include "dml2_0/dml2_wrapper.h"
#include "dmub/inc/dmub_cmd.h"
#include "sspl/dc_spl_types.h"
struct abm_save_restore;
/* forward declaration */
struct aux_payload;
struct set_config_cmd_payload;
struct dmub_notification;
struct dcn_hubbub_reg_state;
struct dcn_hubp_reg_state;
struct dcn_dpp_reg_state;
struct dcn_mpc_reg_state;
struct dcn_opp_reg_state;
struct dcn_dsc_reg_state;
struct dcn_optc_reg_state;
struct dcn_dccg_reg_state;
#define DC_VER "3.2.378"
/**
* MAX_SURFACES - representative of the upper bound of surfaces that can be piped to a single CRTC
*/
#define MAX_SURFACES 4
/**
* MAX_PLANES - representative of the upper bound of planes that are supported by the HW
*/
#define MAX_PLANES 6
#define MAX_STREAMS 6
#define MIN_VIEWPORT_SIZE 12
#define MAX_NUM_EDP 2
#define MAX_SUPPORTED_FORMATS 7
#define MAX_HOST_ROUTERS_NUM 3
#define MAX_DPIA_PER_HOST_ROUTER 3
#define MAX_DPIA_NUM (MAX_HOST_ROUTERS_NUM * MAX_DPIA_PER_HOST_ROUTER)
#define NUM_FAST_FLIPS_TO_STEADY_STATE 20
/* Display Core Interfaces */
struct dc_versions {
const char *dc_ver;
struct dmcu_version dmcu_version;
};
enum dp_protocol_version {
DP_VERSION_1_4 = 0,
DP_VERSION_2_1,
DP_VERSION_UNKNOWN,
};
enum dc_plane_type {
DC_PLANE_TYPE_INVALID,
DC_PLANE_TYPE_DCE_RGB,
DC_PLANE_TYPE_DCE_UNDERLAY,
DC_PLANE_TYPE_DCN_UNIVERSAL,
};
// Sizes defined as multiples of 64KB
enum det_size {
DET_SIZE_DEFAULT = 0,
DET_SIZE_192KB = 3,
DET_SIZE_256KB = 4,
DET_SIZE_320KB = 5,
DET_SIZE_384KB = 6
};
struct dc_plane_cap {
enum dc_plane_type type;
uint32_t per_pixel_alpha : 1;
struct {
uint32_t argb8888 : 1;
uint32_t nv12 : 1;
uint32_t fp16 : 1;
uint32_t p010 : 1;
uint32_t ayuv : 1;
} pixel_format_support;
// max upscaling factor x1000
// upscaling factors are always >= 1
// for example, 1080p -> 8K is 4.0, or 4000 raw value
struct {
uint32_t argb8888;
uint32_t nv12;
uint32_t fp16;
} max_upscale_factor;
// max downscale factor x1000
// downscale factors are always <= 1
// for example, 8K -> 1080p is 0.25, or 250 raw value
struct {
uint32_t argb8888;
uint32_t nv12;
uint32_t fp16;
} max_downscale_factor;
// minimal width/height
uint32_t min_width;
uint32_t min_height;
};
/**
* DOC: color-management-caps
*
* **Color management caps (DPP and MPC)**
*
* Modules/color calculates various color operations which are translated to
* abstracted HW. DCE 5-12 had almost no important changes, but starting with
* DCN1, every new generation comes with fairly major differences in color
* pipeline. Therefore, we abstract color pipe capabilities so modules/DM can
* decide mapping to HW block based on logical capabilities.
*/
/**
* struct rom_curve_caps - predefined transfer function caps for degamma and regamma
* @srgb: RGB color space transfer func
* @bt2020: BT.2020 transfer func
* @gamma2_2: standard gamma
* @pq: perceptual quantizer transfer function
* @hlg: hybrid log–gamma transfer function
*/
struct rom_curve_caps {
uint16_t srgb : 1;
uint16_t bt2020 : 1;
uint16_t gamma2_2 : 1;
uint16_t pq : 1;
uint16_t hlg : 1;
};
/**
* struct dpp_color_caps - color pipeline capabilities for display pipe and
* plane blocks
*
* @dcn_arch: all DCE generations treated the same
* @input_lut_shared: shared with DGAM. Input LUT is different than most LUTs,
* just plain 256-entry lookup
* @icsc: input color space conversion
* @dgam_ram: programmable degamma LUT
* @post_csc: post color space conversion, before gamut remap
* @gamma_corr: degamma correction
* @hw_3d_lut: 3D LUT support. It implies a shaper LUT before. It may be shared
* with MPC by setting mpc:shared_3d_lut flag
* @ogam_ram: programmable out/blend gamma LUT
* @ocsc: output color space conversion
* @dgam_rom_for_yuv: pre-defined degamma LUT for YUV planes
* @dgam_rom_caps: pre-definied curve caps for degamma 1D LUT
* @ogam_rom_caps: pre-definied curve caps for regamma 1D LUT
*
* Note: hdr_mult and gamut remap (CTM) are always available in DPP (in that order)
*/
struct dpp_color_caps {
uint16_t dcn_arch : 1;
uint16_t input_lut_shared : 1;
uint16_t icsc : 1;
uint16_t dgam_ram : 1;
uint16_t post_csc : 1;
uint16_t gamma_corr : 1;
uint16_t hw_3d_lut : 1;
uint16_t ogam_ram : 1;
uint16_t ocsc : 1;
uint16_t dgam_rom_for_yuv : 1;
struct rom_curve_caps dgam_rom_caps;
struct rom_curve_caps ogam_rom_caps;
};
/* Below structure is to describe the HW support for mem layout, extend support
range to match what OS could handle in the roadmap */
struct lut3d_caps {
uint32_t dma_3d_lut : 1; /*< DMA mode support for 3D LUT */
struct {
uint32_t swizzle_3d_rgb : 1;
uint32_t swizzle_3d_bgr : 1;
uint32_t linear_1d : 1;
} mem_layout_support;
struct {
uint32_t unorm_12msb : 1;
uint32_t unorm_12lsb : 1;
uint32_t float_fp1_5_10 : 1;
} mem_format_support;
struct {
uint32_t order_rgba : 1;
uint32_t order_bgra : 1;
} mem_pixel_order_support;
/*< size options are 9, 17, 33, 45, 65 */
struct {
uint32_t dim_9 : 1; /* 3D LUT support for 9x9x9 */
uint32_t dim_17 : 1; /* 3D LUT support for 17x17x17 */
uint32_t dim_33 : 1; /* 3D LUT support for 33x33x33 */
uint32_t dim_45 : 1; /* 3D LUT support for 45x45x45 */
uint32_t dim_65 : 1; /* 3D LUT support for 65x65x65 */
} lut_dim_caps;
};
/**
* struct mpc_color_caps - color pipeline capabilities for multiple pipe and
* plane combined blocks
*
* @gamut_remap: color transformation matrix
* @ogam_ram: programmable out gamma LUT
* @ocsc: output color space conversion matrix
* @num_3dluts: MPC 3D LUT; always assumes a preceding shaper LUT
* @num_rmcm_3dluts: number of RMCM 3D LUTS; always assumes a preceding shaper LUT
* @shared_3d_lut: shared 3D LUT flag. Can be either DPP or MPC, but single
* instance
* @ogam_rom_caps: pre-definied curve caps for regamma 1D LUT
* @mcm_3d_lut_caps: HW support cap for MCM LUT memory
* @rmcm_3d_lut_caps: HW support cap for RMCM LUT memory
* @preblend: whether color manager supports preblend with MPC
*/
struct mpc_color_caps {
uint16_t gamut_remap : 1;
uint16_t ogam_ram : 1;
uint16_t ocsc : 1;
uint16_t num_3dluts : 3;
uint16_t num_rmcm_3dluts : 3;
uint16_t shared_3d_lut:1;
struct rom_curve_caps ogam_rom_caps;
struct lut3d_caps mcm_3d_lut_caps;
struct lut3d_caps rmcm_3d_lut_caps;
bool preblend;
};
/**
* struct dc_color_caps - color pipes capabilities for DPP and MPC hw blocks
* @dpp: color pipes caps for DPP
* @mpc: color pipes caps for MPC
*/
struct dc_color_caps {
struct dpp_color_caps dpp;
struct mpc_color_caps mpc;
};
struct dc_dmub_caps {
bool psr;
bool mclk_sw;
bool subvp_psr;
bool gecc_enable;
uint8_t fams_ver;
bool aux_backlight_support;
};
struct dc_scl_caps {
bool sharpener_support;
};
struct dc_check_config {
/**
* max video plane width that can be safely assumed to be always
* supported by single DPP pipe.
*/
unsigned int max_optimizable_video_width;
bool enable_legacy_fast_update;
bool deferred_transition_state;
unsigned int transition_countdown_to_steady_state;
};
struct dc_caps {
uint32_t max_streams;
uint32_t max_links;
uint32_t max_audios;
uint32_t max_slave_planes;
uint32_t max_slave_yuv_planes;
uint32_t max_slave_rgb_planes;
uint32_t max_planes;
uint32_t max_downscale_ratio;
uint32_t i2c_speed_in_khz;
uint32_t i2c_speed_in_khz_hdcp;
uint32_t dmdata_alloc_size;
unsigned int max_cursor_size;
unsigned int max_buffered_cursor_size;
unsigned int max_video_width;
unsigned int min_horizontal_blanking_period;
int linear_pitch_alignment;
bool dcc_const_color;
bool dynamic_audio;
bool is_apu;
bool dual_link_dvi;
bool post_blend_color_processing;
bool force_dp_tps4_for_cp2520;
bool disable_dp_clk_share;
bool psp_setup_panel_mode;
bool extended_aux_timeout_support;
bool dmcub_support;
bool zstate_support;
bool ips_support;
bool ips_v2_support;
uint32_t num_of_internal_disp;
enum dp_protocol_version max_dp_protocol_version;
unsigned int mall_size_per_mem_channel;
unsigned int mall_size_total;
unsigned int cursor_cache_size;
struct dc_plane_cap planes[MAX_PLANES];
struct dc_color_caps color;
struct dc_dmub_caps dmub_caps;
bool dp_hpo;
bool dp_hdmi21_pcon_support;
bool edp_dsc_support;
bool vbios_lttpr_aware;
bool vbios_lttpr_enable;
bool fused_io_supported;
uint32_t max_otg_num;
uint32_t max_cab_allocation_bytes;
uint32_t cache_line_size;
uint32_t cache_num_ways;
uint16_t subvp_fw_processing_delay_us;
uint8_t subvp_drr_max_vblank_margin_us;
uint16_t subvp_prefetch_end_to_mall_start_us;
uint8_t subvp_swath_height_margin_lines; // subvp start line must be aligned to 2 x swath height
uint16_t subvp_pstate_allow_width_us;
uint16_t subvp_vertical_int_margin_us;
bool seamless_odm;
uint32_t max_v_total;
bool vtotal_limited_by_fp2;
uint32_t max_disp_clock_khz_at_vmin;
uint8_t subvp_drr_vblank_start_margin_us;
bool cursor_not_scaled;
bool dcmode_power_limits_present;
bool sequential_ono;
/* Conservative limit for DCC cases which require ODM4:1 to support*/
uint32_t dcc_plane_width_limit;
struct dc_scl_caps scl_caps;
uint8_t num_of_host_routers;
uint8_t num_of_dpias_per_host_router;
/* limit of the ODM only, could be limited by other factors (like pipe count)*/
uint8_t max_odm_combine_factor;
};
struct dc_bug_wa {
bool no_connect_phy_config;
bool dedcn20_305_wa;
bool skip_clock_update;
bool lt_early_cr_pattern;
struct {
uint8_t uclk : 1;
uint8_t fclk : 1;
uint8_t dcfclk : 1;
uint8_t dcfclk_ds: 1;
} clock_update_disable_mask;
bool skip_psr_ips_crtc_disable;
};
struct dc_dcc_surface_param {
struct dc_size surface_size;
enum surface_pixel_format format;
unsigned int plane0_pitch;
struct dc_size plane1_size;
unsigned int plane1_pitch;
union {
enum swizzle_mode_values swizzle_mode;
enum swizzle_mode_addr3_values swizzle_mode_addr3;
};
enum dc_scan_direction scan;
};
struct dc_dcc_setting {
unsigned int max_compressed_blk_size;
unsigned int max_uncompressed_blk_size;
bool independent_64b_blks;
//These bitfields to be used starting with DCN 3.0
struct {
uint32_t dcc_256_64_64 : 1;//available in ASICs before DCN 3.0 (the worst compression case)
uint32_t dcc_128_128_uncontrained : 1; //available in ASICs before DCN 3.0
uint32_t dcc_256_128_128 : 1; //available starting with DCN 3.0
uint32_t dcc_256_256_unconstrained : 1; //available in ASICs before DCN 3.0 (the best compression case)
uint32_t dcc_256_256 : 1; //available in ASICs starting with DCN 4.0x (the best compression case)
uint32_t dcc_256_128 : 1; //available in ASICs starting with DCN 4.0x
uint32_t dcc_256_64 : 1; //available in ASICs starting with DCN 4.0x (the worst compression case)
} dcc_controls;
};
struct dc_surface_dcc_cap {
union {
struct {
struct dc_dcc_setting rgb;
} grph;
struct {
struct dc_dcc_setting luma;
struct dc_dcc_setting chroma;
} video;
};
bool capable;
bool const_color_support;
};
struct dc_static_screen_params {
struct {
bool force_trigger;
bool cursor_update;
bool surface_update;
bool overlay_update;
} triggers;
unsigned int num_frames;
};
/* Surface update type is used by dc_update_surfaces_and_stream
* The update type is determined at the very beginning of the function based
* on parameters passed in and decides how much programming (or updating) is
* going to be done during the call.
*
* UPDATE_TYPE_FAST is used for really fast updates that do not require much
* logical calculations or hardware register programming. This update MUST be
* ISR safe on windows. Currently fast update will only be used to flip surface
* address.
*
* UPDATE_TYPE_MED is used for slower updates which require significant hw
* re-programming however do not affect bandwidth consumption or clock
* requirements. At present, this is the level at which front end updates
* that do not require us to run bw_calcs happen. These are in/out transfer func
* updates, viewport offset changes, recout size changes and pixel depth changes.
* This update can be done at ISR, but we want to minimize how often this happens.
*
* UPDATE_TYPE_FULL is slow. Really slow. This requires us to recalculate our
* bandwidth and clocks, possibly rearrange some pipes and reprogram anything front
* end related. Any time viewport dimensions, recout dimensions, scaling ratios or
* gamma need to be adjusted or pipe needs to be turned on (or disconnected) we do
* a full update. This cannot be done at ISR level and should be a rare event.
* Unless someone is stress testing mpo enter/exit, playing with colour or adjusting
* underscan we don't expect to see this call at all.
*/
enum surface_update_type {
UPDATE_TYPE_FAST, /* super fast, safe to execute in isr */
UPDATE_TYPE_MED, /* ISR safe, most of programming needed, no bw/clk change*/
UPDATE_TYPE_FULL, /* may need to shuffle resources */
};
enum dc_lock_descriptor {
LOCK_DESCRIPTOR_NONE = 0x0,
LOCK_DESCRIPTOR_STREAM = 0x1,
LOCK_DESCRIPTOR_LINK = 0x2,
LOCK_DESCRIPTOR_GLOBAL = 0x4,
};
struct surface_update_descriptor {
enum surface_update_type update_type;
enum dc_lock_descriptor lock_descriptor;
};
/* Forward declaration*/
struct dc;
struct dc_plane_state;
struct dc_state;
struct dc_cap_funcs {
bool (*get_dcc_compression_cap)(const struct dc *dc,
const struct dc_dcc_surface_param *input,
struct dc_surface_dcc_cap *output);
bool (*get_subvp_en)(struct dc *dc, struct dc_state *context);
};
struct link_training_settings;
union allow_lttpr_non_transparent_mode {
struct {
bool DP1_4A : 1;
bool DP2_0 : 1;
} bits;
unsigned char raw;
};
/* Structure to hold configuration flags set by dm at dc creation. */
struct dc_config {
bool gpu_vm_support;
bool disable_disp_pll_sharing;
bool fbc_support;
bool disable_fractional_pwm;
bool allow_seamless_boot_optimization;
bool seamless_boot_edp_requested;
bool edp_not_connected;
bool edp_no_power_sequencing;
bool force_enum_edp;
bool forced_clocks;
union allow_lttpr_non_transparent_mode allow_lttpr_non_transparent_mode;
bool multi_mon_pp_mclk_switch;
bool disable_dmcu;
bool allow_4to1MPC;
bool enable_windowed_mpo_odm;
bool forceHBR2CP2520; // Used for switching between test patterns TPS4 and CP2520
uint32_t allow_edp_hotplug_detection;
bool skip_riommu_prefetch_wa;
bool clamp_min_dcfclk;
uint64_t vblank_alignment_dto_params;
uint8_t vblank_alignment_max_frame_time_diff;
bool is_asymmetric_memory;
bool is_single_rank_dimm;
bool is_vmin_only_asic;
bool use_spl;
bool prefer_easf;
bool use_pipe_ctx_sync_logic;
int smart_mux_version;
bool ignore_dpref_ss;
bool enable_mipi_converter_optimization;
bool use_default_clock_table;
bool force_bios_enable_lttpr;
uint8_t force_bios_fixed_vs;
int sdpif_request_limit_words_per_umc;
bool dc_mode_clk_limit_support;
bool EnableMinDispClkODM;
bool enable_auto_dpm_test_logs;
unsigned int disable_ips;
unsigned int disable_ips_rcg;
unsigned int disable_ips_in_vpb;
bool disable_ips_in_dpms_off;
bool usb4_bw_alloc_support;
bool allow_0_dtb_clk;
bool use_assr_psp_message;
bool support_edp0_on_dp1;
unsigned int enable_fpo_flicker_detection;
bool disable_hbr_audio_dp2;
bool consolidated_dpia_dp_lt;
bool set_pipe_unlock_order;
bool enable_dpia_pre_training;
bool unify_link_enc_assignment;
bool enable_cursor_offload;
bool frame_update_cmd_version2;
struct spl_sharpness_range dcn_sharpness_range;
struct spl_sharpness_range dcn_override_sharpness_range;
bool no_native422_support;
};
enum visual_confirm {
VISUAL_CONFIRM_DISABLE = 0,
VISUAL_CONFIRM_SURFACE = 1,
VISUAL_CONFIRM_HDR = 2,
VISUAL_CONFIRM_MPCTREE = 4,
VISUAL_CONFIRM_PSR = 5,
VISUAL_CONFIRM_SWAPCHAIN = 6,
VISUAL_CONFIRM_FAMS = 7,
VISUAL_CONFIRM_SWIZZLE = 9,
VISUAL_CONFIRM_SMARTMUX_DGPU = 10,
VISUAL_CONFIRM_REPLAY = 12,
VISUAL_CONFIRM_SUBVP = 14,
VISUAL_CONFIRM_MCLK_SWITCH = 16,
VISUAL_CONFIRM_FAMS2 = 19,
VISUAL_CONFIRM_HW_CURSOR = 20,
VISUAL_CONFIRM_VABC = 21,
VISUAL_CONFIRM_DCC = 22,
VISUAL_CONFIRM_BOOSTED_REFRESH_RATE = 23,
VISUAL_CONFIRM_EXPLICIT = 0x80000000,
};
enum dc_psr_power_opts {
psr_power_opt_invalid = 0x0,
psr_power_opt_smu_opt_static_screen = 0x1,
psr_power_opt_z10_static_screen = 0x10,
psr_power_opt_ds_disable_allow = 0x100,
};
enum dml_hostvm_override_opts {
DML_HOSTVM_NO_OVERRIDE = 0x0,
DML_HOSTVM_OVERRIDE_FALSE = 0x1,
DML_HOSTVM_OVERRIDE_TRUE = 0x2,
};
enum dc_replay_power_opts {
replay_power_opt_invalid = 0x0,
replay_power_opt_smu_opt_static_screen = 0x1,
replay_power_opt_z10_static_screen = 0x10,
};
enum dcc_option {
DCC_ENABLE = 0,
DCC_DISABLE = 1,
DCC_HALF_REQ_DISALBE = 2,
};
enum in_game_fams_config {
INGAME_FAMS_SINGLE_DISP_ENABLE, // enable in-game fams
INGAME_FAMS_DISABLE, // disable in-game fams
INGAME_FAMS_MULTI_DISP_ENABLE, //enable in-game fams for multi-display
INGAME_FAMS_MULTI_DISP_CLAMPED_ONLY, //enable in-game fams for multi-display only for clamped RR strategies
};
/**
* enum pipe_split_policy - Pipe split strategy supported by DCN
*
* This enum is used to define the pipe split policy supported by DCN. By
* default, DC favors MPC_SPLIT_DYNAMIC.
*/
enum pipe_split_policy {
/**
* @MPC_SPLIT_DYNAMIC: DC will automatically decide how to split the
* pipe in order to bring the best trade-off between performance and
* power consumption. This is the recommended option.
*/
MPC_SPLIT_DYNAMIC = 0,
/**
* @MPC_SPLIT_AVOID: Avoid pipe split, which means that DC will not
* try any sort of split optimization.
*/
MPC_SPLIT_AVOID = 1,
/**
* @MPC_SPLIT_AVOID_MULT_DISP: With this option, DC will only try to
* optimize the pipe utilization when using a single display; if the
* user connects to a second display, DC will avoid pipe split.
*/
MPC_SPLIT_AVOID_MULT_DISP = 2,
};
enum wm_report_mode {
WM_REPORT_DEFAULT = 0,
WM_REPORT_OVERRIDE = 1,
};
enum dtm_pstate{
dtm_level_p0 = 0,/*highest voltage*/
dtm_level_p1,
dtm_level_p2,
dtm_level_p3,
dtm_level_p4,/*when active_display_count = 0*/
};
enum dcn_pwr_state {
DCN_PWR_STATE_UNKNOWN = -1,
DCN_PWR_STATE_MISSION_MODE = 0,
DCN_PWR_STATE_LOW_POWER = 3,
};
enum dcn_zstate_support_state {
DCN_ZSTATE_SUPPORT_UNKNOWN,
DCN_ZSTATE_SUPPORT_ALLOW,
DCN_ZSTATE_SUPPORT_ALLOW_Z8_ONLY,
DCN_ZSTATE_SUPPORT_ALLOW_Z8_Z10_ONLY,
DCN_ZSTATE_SUPPORT_ALLOW_Z10_ONLY,
DCN_ZSTATE_SUPPORT_DISALLOW,
};
/*
* struct dc_clocks - DC pipe clocks
*
* For any clocks that may differ per pipe only the max is stored in this
* structure
*/
struct dc_clocks {
int dispclk_khz;
int actual_dispclk_khz;
int dppclk_khz;
int actual_dppclk_khz;
int disp_dpp_voltage_level_khz;
int dcfclk_khz;
int socclk_khz;
int dcfclk_deep_sleep_khz;
int fclk_khz;
int phyclk_khz;
int dramclk_khz;
bool p_state_change_support;
enum dcn_zstate_support_state zstate_support;
bool dtbclk_en;
int ref_dtbclk_khz;
bool fclk_p_state_change_support;
enum dcn_pwr_state pwr_state;
/*
* Elements below are not compared for the purposes of
* optimization required
*/
bool prev_p_state_change_support;
bool fclk_prev_p_state_change_support;
int num_ways;
int host_router_bw_kbps[MAX_HOST_ROUTERS_NUM];
/*
* @fw_based_mclk_switching
*
* DC has a mechanism that leverage the variable refresh rate to switch
* memory clock in cases that we have a large latency to achieve the
* memory clock change and a short vblank window. DC has some
* requirements to enable this feature, and this field describes if the
* system support or not such a feature.
*/
bool fw_based_mclk_switching;
bool fw_based_mclk_switching_shut_down;
int prev_num_ways;
enum dtm_pstate dtm_level;
int max_supported_dppclk_khz;
int max_supported_dispclk_khz;
int bw_dppclk_khz; /*a copy of dppclk_khz*/
int bw_dispclk_khz;
int idle_dramclk_khz;
int idle_fclk_khz;
int subvp_prefetch_dramclk_khz;
int subvp_prefetch_fclk_khz;
/* Stutter efficiency is technically not clock values
* but stored here so the values are part of the update_clocks call similar to num_ways
* Efficiencies are stored as percentage (0-100)
*/
struct {
uint8_t base_efficiency; //LP1
uint8_t low_power_efficiency; //LP2
uint8_t z8_stutter_efficiency;
int z8_stutter_period;
} stutter_efficiency;
};
struct dc_bw_validation_profile {
bool enable;
unsigned long long total_ticks;
unsigned long long voltage_level_ticks;
unsigned long long watermark_ticks;
unsigned long long rq_dlg_ticks;
unsigned long long total_count;
unsigned long long skip_fast_count;
unsigned long long skip_pass_count;
unsigned long long skip_fail_count;
};
#define BW_VAL_TRACE_SETUP() \
unsigned long long end_tick = 0; \
unsigned long long voltage_level_tick = 0; \
unsigned long long watermark_tick = 0; \
unsigned long long start_tick = dc->debug.bw_val_profile.enable ? \
dm_get_timestamp(dc->ctx) : 0
#define BW_VAL_TRACE_COUNT() \
if (dc->debug.bw_val_profile.enable) \
dc->debug.bw_val_profile.total_count++
#define BW_VAL_TRACE_SKIP(status) \
if (dc->debug.bw_val_profile.enable) { \
if (!voltage_level_tick) \
voltage_level_tick = dm_get_timestamp(dc->ctx); \
dc->debug.bw_val_profile.skip_ ## status ## _count++; \
}
#define BW_VAL_TRACE_END_VOLTAGE_LEVEL() \
if (dc->debug.bw_val_profile.enable) \
voltage_level_tick = dm_get_timestamp(dc->ctx)
#define BW_VAL_TRACE_END_WATERMARKS() \
if (dc->debug.bw_val_profile.enable) \
watermark_tick = dm_get_timestamp(dc->ctx)
#define BW_VAL_TRACE_FINISH() \
if (dc->debug.bw_val_profile.enable) { \
end_tick = dm_get_timestamp(dc->ctx); \
dc->debug.bw_val_profile.total_ticks += end_tick - start_tick; \
dc->debug.bw_val_profile.voltage_level_ticks += voltage_level_tick - start_tick; \
if (watermark_tick) { \
dc->debug.bw_val_profile.watermark_ticks += watermark_tick - voltage_level_tick; \
dc->debug.bw_val_profile.rq_dlg_ticks += end_tick - watermark_tick; \
} \
}
union mem_low_power_enable_options {
struct {
bool vga: 1;
bool i2c: 1;
bool dmcu: 1;
bool dscl: 1;
bool cm: 1;
bool mpc: 1;
bool optc: 1;
bool vpg: 1;
bool afmt: 1;
} bits;
uint32_t u32All;
};
union root_clock_optimization_options {
struct {
bool dpp: 1;
bool dsc: 1;
bool hdmistream: 1;
bool hdmichar: 1;
bool dpstream: 1;
bool symclk32_se: 1;
bool symclk32_le: 1;
bool symclk_fe: 1;
bool physymclk: 1;
bool dpiasymclk: 1;
uint32_t reserved: 22;
} bits;
uint32_t u32All;
};
union fine_grain_clock_gating_enable_options {
struct {
bool dccg_global_fgcg_rep : 1; /* Global fine grain clock gating of repeaters */
bool dchub : 1; /* Display controller hub */
bool dchubbub : 1;
bool dpp : 1; /* Display pipes and planes */
bool opp : 1; /* Output pixel processing */
bool optc : 1; /* Output pipe timing combiner */
bool dio : 1; /* Display output */
bool dwb : 1; /* Display writeback */
bool mmhubbub : 1; /* Multimedia hub */
bool dmu : 1; /* Display core management unit */
bool az : 1; /* Azalia */
bool dchvm : 1;
bool dsc : 1; /* Display stream compression */
uint32_t reserved : 19;
} bits;
uint32_t u32All;
};
enum pg_hw_pipe_resources {
PG_HUBP = 0,
PG_DPP,
PG_DSC,
PG_MPCC,
PG_OPP,
PG_OPTC,
PG_DPSTREAM,
PG_HDMISTREAM,
PG_PHYSYMCLK,
PG_HW_PIPE_RESOURCES_NUM_ELEMENT
};
enum pg_hw_resources {
PG_DCCG = 0,
PG_DCIO,
PG_DIO,
PG_DCHUBBUB,
PG_DCHVM,
PG_DWB,
PG_HPO,
PG_DCOH,
PG_HW_RESOURCES_NUM_ELEMENT
};
struct pg_block_update {
bool pg_pipe_res_update[PG_HW_PIPE_RESOURCES_NUM_ELEMENT][MAX_PIPES];
bool pg_res_update[PG_HW_RESOURCES_NUM_ELEMENT];
};
union dpia_debug_options {
struct {
uint32_t disable_dpia:1; /* bit 0 */
uint32_t force_non_lttpr:1; /* bit 1 */
uint32_t extend_aux_rd_interval:1; /* bit 2 */
uint32_t disable_mst_dsc_work_around:1; /* bit 3 */
uint32_t enable_force_tbt3_work_around:1; /* bit 4 */
uint32_t disable_usb4_pm_support:1; /* bit 5 */
uint32_t enable_usb4_bw_zero_alloc_patch:1; /* bit 6 */
uint32_t reserved:25;
} bits;
uint32_t raw;
};
/* AUX wake work around options
* 0: enable/disable work around
* 1: use default timeout LINK_AUX_WAKE_TIMEOUT_MS
* 15-2: reserved
* 31-16: timeout in ms
*/
union aux_wake_wa_options {
struct {
uint32_t enable_wa : 1;
uint32_t use_default_timeout : 1;
uint32_t rsvd: 14;
uint32_t timeout_ms : 16;
} bits;
uint32_t raw;
};
struct dc_debug_data {
uint32_t ltFailCount;
uint32_t i2cErrorCount;
uint32_t auxErrorCount;
struct pipe_topology_history topology_history;
};
struct dc_phy_addr_space_config {
struct {
uint64_t start_addr;
uint64_t end_addr;
uint64_t fb_top;
uint64_t fb_offset;
uint64_t fb_base;
uint64_t agp_top;
uint64_t agp_bot;
uint64_t agp_base;
} system_aperture;
struct {
uint64_t page_table_start_addr;
uint64_t page_table_end_addr;
uint64_t page_table_base_addr;
bool base_addr_is_mc_addr;
} gart_config;
bool valid;
bool is_hvm_enabled;
uint64_t page_table_default_page_addr;
};
struct dc_virtual_addr_space_config {
uint64_t page_table_base_addr;
uint64_t page_table_start_addr;
uint64_t page_table_end_addr;
uint32_t page_table_block_size_in_bytes;
uint8_t page_table_depth; // 1 = 1 level, 2 = 2 level, etc. 0 = invalid
};
struct dc_bounding_box_overrides {
int sr_exit_time_ns;
int sr_enter_plus_exit_time_ns;
int sr_exit_z8_time_ns;
int sr_enter_plus_exit_z8_time_ns;
int urgent_latency_ns;
int percent_of_ideal_drambw;
int dram_clock_change_latency_ns;
int dummy_clock_change_latency_ns;
int fclk_clock_change_latency_ns;
/* This forces a hard min on the DCFCLK we use
* for DML. Unlike the debug option for forcing
* DCFCLK, this override affects watermark calculations
*/
int min_dcfclk_mhz;
};
struct dc_qos_info {
uint32_t actual_peak_bw_in_mbps;
uint32_t qos_bandwidth_lb_in_mbps;
uint32_t actual_avg_bw_in_mbps;
uint32_t calculated_avg_bw_in_mbps;
uint32_t actual_max_latency_in_ns;
uint32_t actual_min_latency_in_ns;
uint32_t qos_max_latency_ub_in_ns;
uint32_t actual_avg_latency_in_ns;
uint32_t qos_avg_latency_ub_in_ns;
uint32_t dcn_bandwidth_ub_in_mbps;
};
struct dc_state;
struct resource_pool;
struct dce_hwseq;
struct link_service;
/*
* struct dc_debug_options - DC debug struct
*
* This struct provides a simple mechanism for developers to change some
* configurations, enable/disable features, and activate extra debug options.
* This can be very handy to narrow down whether some specific feature is
* causing an issue or not.
*/
struct dc_debug_options {
bool disable_dsc;
enum visual_confirm visual_confirm;
int visual_confirm_rect_height;
bool sanity_checks;
bool max_disp_clk;
bool surface_trace;
bool clock_trace;
bool validation_trace;
bool bandwidth_calcs_trace;
int max_downscale_src_width;
/* stutter efficiency related */
bool disable_stutter;
bool use_max_lb;
enum dcc_option disable_dcc;
/*
* @pipe_split_policy: Define which pipe split policy is used by the
* display core.
*/
enum pipe_split_policy pipe_split_policy;
bool force_single_disp_pipe_split;
bool voltage_align_fclk;
bool disable_min_fclk;
bool hdcp_lc_force_fw_enable;
bool hdcp_lc_enable_sw_fallback;
bool disable_dfs_bypass;
bool disable_dpp_power_gate;
bool disable_hubp_power_gate;
bool disable_dsc_power_gate;
bool disable_optc_power_gate;
bool disable_hpo_power_gate;
bool disable_io_clk_power_gate;
bool disable_mem_power_gate;
bool disable_dio_power_gate;
int dsc_min_slice_height_override;
int dsc_bpp_increment_div;
bool disable_pplib_wm_range;
enum wm_report_mode pplib_wm_report_mode;
unsigned int min_disp_clk_khz;
unsigned int min_dpp_clk_khz;
unsigned int min_dram_clk_khz;
int sr_exit_time_dpm0_ns;
int sr_enter_plus_exit_time_dpm0_ns;
int sr_exit_time_ns;
int sr_enter_plus_exit_time_ns;
int sr_exit_z8_time_ns;
int sr_enter_plus_exit_z8_time_ns;
int urgent_latency_ns;
uint32_t underflow_assert_delay_us;
int percent_of_ideal_drambw;
int dram_clock_change_latency_ns;
bool optimized_watermark;
int always_scale;
bool disable_pplib_clock_request;
bool disable_clock_gate;
bool disable_mem_low_power;
bool pstate_enabled;
bool disable_dmcu;
bool force_abm_enable;
bool disable_stereo_support;
bool vsr_support;
bool performance_trace;
bool az_endpoint_mute_only;
bool always_use_regamma;
bool recovery_enabled;
bool avoid_vbios_exec_table;
bool scl_reset_length10;
bool hdmi20_disable;
bool skip_detection_link_training;
uint32_t edid_read_retry_times;
uint8_t force_odm_combine; //bit vector based on otg inst
uint8_t seamless_boot_odm_combine;
uint8_t force_odm_combine_4to1; //bit vector based on otg inst
int minimum_z8_residency_time;
int minimum_z10_residency_time;
bool disable_z9_mpc;
unsigned int force_fclk_khz;
bool enable_tri_buf;
bool ips_disallow_entry;
bool dmub_offload_enabled;
bool dmcub_emulation;
bool disable_idle_power_optimizations;
unsigned int mall_size_override;
unsigned int mall_additional_timer_percent;
bool mall_error_as_fatal;
bool dmub_command_table; /* for testing only */
struct dc_bw_validation_profile bw_val_profile;
bool disable_fec;
bool disable_48mhz_pwrdwn;
/* This forces a hard min on the DCFCLK requested to SMU/PP
* watermarks are not affected.
*/
unsigned int force_min_dcfclk_mhz;
int dwb_fi_phase;
bool disable_timing_sync;
bool cm_in_bypass;
int force_clock_mode;/*every mode change.*/
bool disable_dram_clock_change_vactive_support;
bool validate_dml_output;
bool enable_dmcub_surface_flip;
bool usbc_combo_phy_reset_wa;
bool enable_dram_clock_change_one_display_vactive;
/* TODO - remove once tested */
bool legacy_dp2_lt;
bool set_mst_en_for_sst;
bool disable_uhbr;
bool force_dp2_lt_fallback_method;
bool ignore_cable_id;
union mem_low_power_enable_options enable_mem_low_power;
union root_clock_optimization_options root_clock_optimization;
union fine_grain_clock_gating_enable_options enable_fine_grain_clock_gating;
bool hpo_optimization;
bool force_vblank_alignment;
/* Enable dmub aux for legacy ddc */
bool enable_dmub_aux_for_legacy_ddc;
bool disable_fams;
enum in_game_fams_config disable_fams_gaming;
/* FEC/PSR1 sequence enable delay in 100us */
uint8_t fec_enable_delay_in100us;
bool enable_driver_sequence_debug;
enum det_size crb_alloc_policy;
int crb_alloc_policy_min_disp_count;
bool disable_z10;
bool enable_z9_disable_interface;
bool psr_skip_crtc_disable;
uint32_t ips_skip_crtc_disable_mask;
union dpia_debug_options dpia_debug;
bool disable_fixed_vs_aux_timeout_wa;
uint32_t fixed_vs_aux_delay_config_wa;
bool force_disable_subvp;
bool force_subvp_mclk_switch;
bool allow_sw_cursor_fallback;
unsigned int force_subvp_num_ways;
unsigned int force_mall_ss_num_ways;
bool alloc_extra_way_for_cursor;
uint32_t subvp_extra_lines;
bool disable_force_pstate_allow_on_hw_release;
bool force_usr_allow;
/* uses value at boot and disables switch */
bool disable_dtb_ref_clk_switch;
bool extended_blank_optimization;
union aux_wake_wa_options aux_wake_wa;
uint32_t mst_start_top_delay;
uint8_t psr_power_use_phy_fsm;
enum dml_hostvm_override_opts dml_hostvm_override;
bool dml_disallow_alternate_prefetch_modes;
bool use_legacy_soc_bb_mechanism;
bool exit_idle_opt_for_cursor_updates;
bool using_dml2;
bool enable_single_display_2to1_odm_policy;
bool enable_double_buffered_dsc_pg_support;
bool enable_dp_dig_pixel_rate_div_policy;
bool using_dml21;
enum lttpr_mode lttpr_mode_override;
unsigned int dsc_delay_factor_wa_x1000;
unsigned int min_prefetch_in_strobe_ns;
bool disable_unbounded_requesting;
bool dig_fifo_off_in_blank;
bool override_dispclk_programming;
bool otg_crc_db;
bool disallow_dispclk_dppclk_ds;
bool disable_fpo_optimizations;
bool support_eDP1_5;
uint32_t fpo_vactive_margin_us;
bool disable_fpo_vactive;
bool disable_boot_optimizations;
bool override_odm_optimization;
bool minimize_dispclk_using_odm;
bool disable_subvp_high_refresh;
bool disable_dp_plus_plus_wa;
uint32_t fpo_vactive_min_active_margin_us;
uint32_t fpo_vactive_max_blank_us;
bool enable_hpo_pg_support;
bool disable_dc_mode_overwrite;
bool replay_skip_crtc_disabled;
bool ignore_pg;/*do nothing, let pmfw control it*/
bool psp_disabled_wa;
unsigned int ips2_eval_delay_us;
unsigned int ips2_entry_delay_us;
bool optimize_ips_handshake;
bool disable_dmub_reallow_idle;
bool disable_timeout;
bool disable_extblankadj;
bool enable_idle_reg_checks;
unsigned int static_screen_wait_frames;
uint32_t pwm_freq;
bool force_chroma_subsampling_1tap;
unsigned int dcc_meta_propagation_delay_us;
bool disable_422_left_edge_pixel;
bool dml21_force_pstate_method;
uint32_t dml21_force_pstate_method_values[MAX_PIPES];
uint32_t dml21_disable_pstate_method_mask;
union fw_assisted_mclk_switch_version fams_version;
union dmub_fams2_global_feature_config fams2_config;
unsigned int force_cositing;
unsigned int disable_spl;
unsigned int force_easf;
unsigned int force_sharpness;
unsigned int force_sharpness_level;
unsigned int force_lls;
bool notify_dpia_hr_bw;
bool enable_ips_visual_confirm;
unsigned int sharpen_policy;
unsigned int scale_to_sharpness_policy;
unsigned int enable_oled_edp_power_up_opt;
bool enable_hblank_borrow;
bool force_subvp_df_throttle;
uint32_t acpi_transition_bitmasks[MAX_PIPES];
bool enable_pg_cntl_debug_logs;
unsigned int auxless_alpm_lfps_setup_ns;
unsigned int auxless_alpm_lfps_period_ns;
unsigned int auxless_alpm_lfps_silence_ns;
unsigned int auxless_alpm_lfps_t1t2_us;
short auxless_alpm_lfps_t1t2_offset_us;
bool disable_stutter_for_wm_program;
bool enable_block_sequence_programming;
uint32_t custom_psp_footer_size;
bool disable_deferred_minimal_transitions;
unsigned int num_fast_flips_to_steady_state_override;
bool enable_dmu_recovery;
unsigned int force_vmin_threshold;
bool enable_otg_frame_sync_pwa;
unsigned int min_deep_sleep_dcfclk_khz;
};
/* Generic structure that can be used to query properties of DC. More fields
* can be added as required.
*/
struct dc_current_properties {
unsigned int cursor_size_limit;
};
enum frame_buffer_mode {
FRAME_BUFFER_MODE_LOCAL_ONLY = 0,
FRAME_BUFFER_MODE_ZFB_ONLY,
FRAME_BUFFER_MODE_MIXED_ZFB_AND_LOCAL,
} ;
struct dchub_init_data {
int64_t zfb_phys_addr_base;
int64_t zfb_mc_base_addr;
uint64_t zfb_size_in_byte;
enum frame_buffer_mode fb_mode;
bool dchub_initialzied;
bool dchub_info_valid;
};
struct dml2_soc_bb;
struct dc_init_data {
struct hw_asic_id asic_id;
void *driver; /* ctx */
struct cgs_device *cgs_device;
struct dc_bounding_box_overrides bb_overrides;
int num_virtual_links;
/*
* If 'vbios_override' not NULL, it will be called instead
* of the real VBIOS. Intended use is Diagnostics on FPGA.
*/
struct dc_bios *vbios_override;
enum dce_environment dce_environment;
struct dmub_offload_funcs *dmub_if;
struct dc_reg_helper_state *dmub_offload;
struct dc_config flags;
uint64_t log_mask;
struct dpcd_vendor_signature vendor_signature;
bool force_smu_not_present;
/*
* IP offset for run time initializaion of register addresses
*
* DCN3.5+ will fail dc_create() if these fields are null for them. They are
* applicable starting with DCN32/321 and are not used for ASICs upstreamed
* before them.
*/
uint32_t *dcn_reg_offsets;
uint32_t *nbio_reg_offsets;
uint32_t *clk_reg_offsets;
void *bb_from_dmub;
};
struct dc_callback_init {
struct cp_psp cp_psp;
};
struct dc *dc_create(const struct dc_init_data *init_params);
void dc_hardware_init(struct dc *dc);
int dc_get_vmid_use_vector(struct dc *dc);
void dc_setup_vm_context(struct dc *dc, struct dc_virtual_addr_space_config *va_config, int vmid);
/* Returns the number of vmids supported */
int dc_setup_system_context(struct dc *dc, struct dc_phy_addr_space_config *pa_config);
void dc_init_callbacks(struct dc *dc,
const struct dc_callback_init *init_params);
void dc_deinit_callbacks(struct dc *dc);
void dc_destroy(struct dc **dc);
/* Surface Interfaces */
enum {
TRANSFER_FUNC_POINTS = 1025
};
struct dc_hdr_static_metadata {
/* display chromaticities and white point in units of 0.00001 */
unsigned int chromaticity_green_x;
unsigned int chromaticity_green_y;
unsigned int chromaticity_blue_x;
unsigned int chromaticity_blue_y;
unsigned int chromaticity_red_x;
unsigned int chromaticity_red_y;
unsigned int chromaticity_white_point_x;
unsigned int chromaticity_white_point_y;
uint32_t min_luminance;
uint32_t max_luminance;
uint32_t maximum_content_light_level;
uint32_t maximum_frame_average_light_level;
};
enum dc_transfer_func_type {
TF_TYPE_PREDEFINED,
TF_TYPE_DISTRIBUTED_POINTS,
TF_TYPE_BYPASS,
TF_TYPE_HWPWL
};
struct dc_transfer_func_distributed_points {
struct fixed31_32 red[TRANSFER_FUNC_POINTS];
struct fixed31_32 green[TRANSFER_FUNC_POINTS];
struct fixed31_32 blue[TRANSFER_FUNC_POINTS];
uint16_t end_exponent;
uint16_t x_point_at_y1_red;
uint16_t x_point_at_y1_green;
uint16_t x_point_at_y1_blue;
};
enum dc_transfer_func_predefined {
TRANSFER_FUNCTION_SRGB,
TRANSFER_FUNCTION_BT709,
TRANSFER_FUNCTION_PQ,
TRANSFER_FUNCTION_LINEAR,
TRANSFER_FUNCTION_UNITY,
TRANSFER_FUNCTION_HLG,
TRANSFER_FUNCTION_HLG12,
TRANSFER_FUNCTION_GAMMA22,
TRANSFER_FUNCTION_GAMMA24,
TRANSFER_FUNCTION_GAMMA26
};
struct dc_transfer_func {
struct kref refcount;
enum dc_transfer_func_type type;
enum dc_transfer_func_predefined tf;
/* FP16 1.0 reference level in nits, default is 80 nits, only for PQ*/
uint32_t sdr_ref_white_level;
union {
struct pwl_params pwl;
struct dc_transfer_func_distributed_points tf_pts;
};
};
union dc_3dlut_state {
struct {
uint32_t initialized:1; /*if 3dlut is went through color module for initialization */
uint32_t rmu_idx_valid:1; /*if mux settings are valid*/
uint32_t rmu_mux_num:3; /*index of mux to use*/
uint32_t mpc_rmu0_mux:4; /*select mpcc on mux, one of the following : mpcc0, mpcc1, mpcc2, mpcc3*/
uint32_t mpc_rmu1_mux:4;
uint32_t mpc_rmu2_mux:4;
uint32_t reserved:15;
} bits;
uint32_t raw;
};
#define MATRIX_9C__DIM_128_ALIGNED_LEN 16 // 9+8 : 9 * 8 + 7 * 8 = 72 + 56 = 128 % 128 = 0
#define MATRIX_17C__DIM_128_ALIGNED_LEN 32 //17+15: 17 * 8 + 15 * 8 = 136 + 120 = 256 % 128 = 0
#define MATRIX_33C__DIM_128_ALIGNED_LEN 64 //17+47: 17 * 8 + 47 * 8 = 136 + 376 = 512 % 128 = 0
struct lut_rgb {
uint16_t b;
uint16_t g;
uint16_t r;
uint16_t padding;
};
//this structure maps directly to how the lut will read it from memory
struct lut_mem_mapping {
union {
//NATIVE MODE 1, 2
//RGB layout [b][g][r] //red is 128 byte aligned
//BGR layout [r][g][b] //blue is 128 byte aligned
struct lut_rgb rgb_17c[17][17][MATRIX_17C__DIM_128_ALIGNED_LEN];
struct lut_rgb rgb_33c[33][33][MATRIX_33C__DIM_128_ALIGNED_LEN];
//TRANSFORMED
uint16_t linear_rgb[(33*33*33*4/128+1)*128];
};
uint16_t size;
};
struct dc_rmcm_3dlut {
bool isInUse;
const struct dc_stream_state *stream;
};
struct dc_3dlut {
struct kref refcount;
struct tetrahedral_params lut_3d;
union dc_3dlut_state state;
};
/* 3DLUT DMA (Fast Load) params */
struct dc_3dlut_dma {
struct dc_plane_address addr;
enum dc_cm_lut_swizzle swizzle;
enum dc_cm_lut_pixel_format format;
uint16_t bias; /* FP1.5.10 */
uint16_t scale; /* FP1.5.10 */
enum dc_cm_lut_size size;
};
/* color manager */
union dc_plane_cm_flags {
unsigned int all;
struct {
unsigned int shaper_enable : 1;
unsigned int lut3d_enable : 1;
unsigned int blend_enable : 1;
/* whether legacy (lut3d_func) or DMA is valid */
unsigned int lut3d_dma_enable : 1;
/* RMCM lut to be used instead of MCM */
unsigned int rmcm_enable : 1;
unsigned int reserved: 27;
} bits;
};
struct dc_plane_cm {
struct kref refcount;
struct dc_transfer_func shaper_func;
union {
struct dc_3dlut lut3d_func;
struct dc_3dlut_dma lut3d_dma;
};
struct dc_transfer_func blend_func;
union dc_plane_cm_flags flags;
};
/*
* This structure is filled in by dc_surface_get_status and contains
* the last requested address and the currently active address so the called
* can determine if there are any outstanding flips
*/
struct dc_plane_status {
struct dc_plane_address requested_address;
struct dc_plane_address current_address;
bool is_flip_pending;
bool is_right_eye;
struct cm_hist cm_hist;
};
union surface_update_flags {
struct {
uint32_t addr_update:1;
/* Medium updates */
uint32_t dcc_change:1;
uint32_t color_space_change:1;
uint32_t horizontal_mirror_change:1;
uint32_t per_pixel_alpha_change:1;
uint32_t global_alpha_change:1;
uint32_t hdr_mult:1;
uint32_t rotation_change:1;
uint32_t swizzle_change:1;
uint32_t scaling_change:1;
uint32_t position_change:1;
uint32_t in_transfer_func_change:1;
uint32_t input_csc_change:1;
uint32_t coeff_reduction_change:1;
uint32_t pixel_format_change:1;
uint32_t plane_size_change:1;
uint32_t gamut_remap_change:1;
/* Full updates */
uint32_t new_plane:1;
uint32_t bpp_change:1;
uint32_t gamma_change:1;
uint32_t bandwidth_change:1;
uint32_t clock_change:1;
uint32_t stereo_format_change:1;
uint32_t lut_3d:1;
uint32_t tmz_changed:1;
uint32_t mcm_transfer_function_enable_change:1; /* disable or enable MCM transfer func */
uint32_t full_update:1;
uint32_t sdr_white_level_nits:1;
uint32_t cm_hist_change:1;
} bits;
uint32_t raw;
};
#define DC_REMOVE_PLANE_POINTERS 1
struct dc_plane_state {
struct dc_plane_address address;
struct dc_plane_flip_time time;
bool triplebuffer_flips;
struct scaling_taps scaling_quality;
struct rect src_rect;
struct rect dst_rect;
struct rect clip_rect;
struct plane_size plane_size;
struct dc_tiling_info tiling_info;
struct dc_plane_dcc_param dcc;
struct dc_gamma gamma_correction;
struct dc_transfer_func in_transfer_func;
struct dc_bias_and_scale bias_and_scale;
struct dc_csc_transform input_csc_color_matrix;
struct fixed31_32 coeff_reduction_factor;
struct fixed31_32 hdr_mult;
struct colorspace_transform gamut_remap_matrix;
enum dc_color_space color_space;
bool lut_bank_a;
struct dc_hdr_static_metadata hdr_static_ctx;
struct dc_3dlut lut3d_func;
struct dc_transfer_func in_shaper_func;
struct dc_transfer_func blend_tf;
enum dc_cm2_shaper_3dlut_setting mcm_shaper_3dlut_setting;
bool mcm_lut1d_enable;
struct dc_cm2_func_luts mcm_luts;
enum mpcc_movable_cm_location mcm_location;
struct dc_plane_cm cm;
struct dc_transfer_func *gamcor_tf;
enum surface_pixel_format format;
enum dc_rotation_angle rotation;
enum plane_stereo_format stereo_format;
bool is_tiling_rotated;
bool per_pixel_alpha;
bool pre_multiplied_alpha;
bool global_alpha;
int global_alpha_value;
bool visible;
bool flip_immediate;
bool horizontal_mirror;
int layer_index;
union surface_update_flags update_flags;
bool flip_int_enabled;
bool skip_manual_trigger;
/* private to DC core */
struct dc_plane_status status;
struct dc_context *ctx;
/* HACK: Workaround for forcing full reprogramming under some conditions */
bool force_full_update;
bool is_phantom; // TODO: Change mall_stream_config into mall_plane_config instead
/* private to dc_surface.c */
enum dc_irq_source irq_source;
struct kref refcount;
struct tg_color visual_confirm_color;
bool is_statically_allocated;
enum chroma_cositing cositing;
struct dc_csc_transform cursor_csc_color_matrix;
bool adaptive_sharpness_en;
int adaptive_sharpness_policy;
int sharpness_level;
enum linear_light_scaling linear_light_scaling;
unsigned int sdr_white_level_nits;
struct cm_hist_control cm_hist_control;
struct spl_sharpness_range sharpness_range;
enum sharpness_range_source sharpness_source;
};
struct dc_plane_info {
struct plane_size plane_size;
struct dc_tiling_info tiling_info;
struct dc_plane_dcc_param dcc;
enum surface_pixel_format format;
enum dc_rotation_angle rotation;
enum plane_stereo_format stereo_format;
enum dc_color_space color_space;
bool horizontal_mirror;
bool visible;
bool per_pixel_alpha;
bool pre_multiplied_alpha;
bool global_alpha;
int global_alpha_value;
bool input_csc_enabled;
int layer_index;
enum chroma_cositing cositing;
};
#include "dc_stream.h"
struct dc_scratch_space {
/* used to temporarily backup plane states of a stream during
* dc update. The reason is that plane states are overwritten
* with surface updates in dc update. Once they are overwritten
* current state is no longer valid. We want to temporarily
* store current value in plane states so we can still recover
* a valid current state during dc update.
*/
struct dc_plane_state plane_states[MAX_SURFACES];
struct dc_stream_state stream_state;
};
/*
* A link contains one or more sinks and their connected status.
* The currently active signal type (HDMI, DP-SST, DP-MST) is also reported.
*/
struct dc_link {
struct dc_sink *remote_sinks[MAX_SINKS_PER_LINK];
unsigned int sink_count;
struct dc_sink *local_sink;
unsigned int link_index;
enum dc_connection_type type;
enum signal_type connector_signal;
enum dc_irq_source irq_source_hpd;
enum dc_irq_source irq_source_hpd_rx;/* aka DP Short Pulse */
enum dc_irq_source irq_source_read_request;/* Read Request */
bool is_hpd_filter_disabled;
bool dp_ss_off;
/**
* @link_state_valid:
*
* If there is no link and local sink, this variable should be set to
* false. Otherwise, it should be set to true; usually, the function
* core_link_enable_stream sets this field to true.
*/
bool link_state_valid;
bool aux_access_disabled;
bool sync_lt_in_progress;
bool skip_stream_reenable;
bool is_internal_display;
/** @todo Rename. Flag an endpoint as having a programmable mapping to a DIG encoder. */
bool is_dig_mapping_flexible;
bool hpd_status; /* HPD status of link without physical HPD pin. */
bool is_hpd_pending; /* Indicates a new received hpd */
/* USB4 DPIA links skip verifying link cap, instead performing the fallback method
* for every link training. This is incompatible with DP LL compliance automation,
* which expects the same link settings to be used every retry on a link loss.
* This flag is used to skip the fallback when link loss occurs during automation.
*/
bool skip_fallback_on_link_loss;
bool edp_sink_present;
struct dp_trace dp_trace;
/* caps is the same as reported_link_cap. link_traing use
* reported_link_cap. Will clean up. TODO
*/
struct dc_link_settings reported_link_cap;
struct dc_link_settings verified_link_cap;
struct dc_link_settings cur_link_settings;
struct dc_lane_settings cur_lane_setting[LANE_COUNT_DP_MAX];
struct dc_link_settings preferred_link_setting;
/* preferred_training_settings are override values that
* come from DM. DM is responsible for the memory
* management of the override pointers.
*/
struct dc_link_training_overrides preferred_training_settings;
struct dp_audio_test_data audio_test_data;
enum gpio_ddc_line ddc_hw_inst;
uint8_t hpd_src;
uint8_t link_enc_hw_inst;
/* DIG link encoder ID. Used as index in link encoder resource pool.
* For links with fixed mapping to DIG, this is not changed after dc_link
* object creation.
*/
enum engine_id eng_id;
enum engine_id dpia_preferred_eng_id;
bool test_pattern_enabled;
/* Pending/Current test pattern are only used to perform and track
* FIXED_VS retimer test pattern/lane adjustment override state.
* Pending allows link HWSS to differentiate PHY vs non-PHY pattern,
* to perform specific lane adjust overrides before setting certain
* PHY test patterns. In cases when lane adjust and set test pattern
* calls are not performed atomically (i.e. performing link training),
* pending_test_pattern will be invalid or contain a non-PHY test pattern
* and current_test_pattern will contain required context for any future
* set pattern/set lane adjust to transition between override state(s).
* */
enum dp_test_pattern current_test_pattern;
enum dp_test_pattern pending_test_pattern;
union compliance_test_state compliance_test_state;
void *priv;
struct ddc_service *ddc;
enum dp_panel_mode panel_mode;
bool aux_mode;
/* Private to DC core */
const struct dc *dc;
struct dc_context *ctx;
struct panel_cntl *panel_cntl;
struct link_encoder *link_enc;
struct graphics_object_id link_id;
/* External encoder eg. NUTMEG or TRAVIS used on CIK APUs. */
struct graphics_object_id ext_enc_id;
/* Endpoint type distinguishes display endpoints which do not have entries
* in the BIOS connector table from those that do. Helps when tracking link
* encoder to display endpoint assignments.
*/
enum display_endpoint_type ep_type;
union ddi_channel_mapping ddi_channel_mapping;
struct connector_device_tag_info device_tag;
struct dpcd_caps dpcd_caps;
uint32_t dongle_max_pix_clk;
unsigned short chip_caps;
unsigned int dpcd_sink_count;
struct hdcp_caps hdcp_caps;
enum edp_revision edp_revision;
union dpcd_sink_ext_caps dpcd_sink_ext_caps;
struct psr_settings psr_settings;
struct replay_settings replay_settings;
/* Drive settings read from integrated info table */
struct dc_lane_settings bios_forced_drive_settings;
/* Vendor specific LTTPR workaround variables */
uint8_t vendor_specific_lttpr_link_rate_wa;
bool apply_vendor_specific_lttpr_link_rate_wa;
/* MST record stream using this link */
struct link_flags {
bool dp_keep_receiver_powered;
bool dp_skip_DID2;
bool dp_skip_reset_segment;
bool dp_skip_fs_144hz;
bool dp_mot_reset_segment;
/* Some USB4 docks do not handle turning off MST DSC once it has been enabled. */
bool dpia_mst_dsc_always_on;
/* Forced DPIA into TBT3 compatibility mode. */
bool dpia_forced_tbt3_mode;
bool dongle_mode_timing_override;
bool blank_stream_on_ocs_change;
bool read_dpcd204h_on_irq_hpd;
bool force_dp_ffe_preset;
bool skip_phy_ssc_reduction;
} wa_flags;
union dc_dp_ffe_preset forced_dp_ffe_preset;
struct link_mst_stream_allocation_table mst_stream_alloc_table;
struct dc_link_status link_status;
struct dprx_states dprx_states;
enum dc_link_fec_state fec_state;
bool is_dds;
bool is_display_mux_present;
bool link_powered_externally; // Used to bypass hardware sequencing delays when panel is powered down forcibly
struct dc_panel_config panel_config;
enum dc_panel_type panel_type;
struct phy_state phy_state;
uint32_t phy_transition_bitmask;
// BW ALLOCATON USB4 ONLY
struct dc_dpia_bw_alloc dpia_bw_alloc_config;
bool skip_implict_edp_power_control;
enum backlight_control_type backlight_control_type;
};
struct dc {
struct dc_debug_options debug;
struct dc_versions versions;
struct dc_caps caps;
struct dc_check_config check_config;
struct dc_cap_funcs cap_funcs;
struct dc_config config;
struct dc_bounding_box_overrides bb_overrides;
struct dc_bug_wa work_arounds;
struct dc_context *ctx;
struct dc_phy_addr_space_config vm_pa_config;
uint8_t link_count;
struct dc_link *links[MAX_LINKS];
uint8_t lowest_dpia_link_index;
struct link_service *link_srv;
struct dc_state *current_state;
struct resource_pool *res_pool;
struct clk_mgr *clk_mgr;
/* Display Engine Clock levels */
struct dm_pp_clock_levels sclk_lvls;
/* Inputs into BW and WM calculations. */
struct bw_calcs_dceip *bw_dceip;
struct bw_calcs_vbios *bw_vbios;
struct dcn_soc_bounding_box *dcn_soc;
struct dcn_ip_params *dcn_ip;
struct display_mode_lib dml;
/* HW functions */
struct hw_sequencer_funcs hwss;
struct dce_hwseq *hwseq;
/* Require to optimize clocks and bandwidth for added/removed planes */
bool optimized_required;
bool idle_optimizations_allowed;
bool enable_c20_dtm_b0;
/* Require to maintain clocks and bandwidth for UEFI enabled HW */
/* For eDP to know the switching state of SmartMux */
bool is_switch_in_progress_orig;
bool is_switch_in_progress_dest;
/* FBC compressor */
struct compressor *fbc_compressor;
struct dc_debug_data debug_data;
struct dpcd_vendor_signature vendor_signature;
const char *build_id;
struct vm_helper *vm_helper;
uint32_t *dcn_reg_offsets;
uint32_t *nbio_reg_offsets;
uint32_t *clk_reg_offsets;
/* Scratch memory */
struct {
struct {
/*
* For matching clock_limits table in driver with table
* from PMFW.
*/
struct _vcs_dpi_voltage_scaling_st clock_limits[DC__VOLTAGE_STATES];
} update_bw_bounding_box;
struct dc_scratch_space current_state;
struct dc_scratch_space new_state;
struct dc_stream_state temp_stream; // Used so we don't need to allocate stream on the stack
struct dc_link temp_link;
bool pipes_to_unlock_first[MAX_PIPES]; /* Any of the pipes indicated here should be unlocked first */
} scratch;
struct dml2_configuration_options dml2_options;
struct dml2_configuration_options dml2_dc_power_options;
enum dc_acpi_cm_power_state power_state;
struct soc_and_ip_translator *soc_and_ip_translator;
};
struct dc_scaling_info {
struct rect src_rect;
struct rect dst_rect;
struct rect clip_rect;
struct scaling_taps scaling_quality;
};
struct dc_fast_update {
const struct dc_flip_addrs *flip_addr;
const struct dc_gamma *gamma;
const struct colorspace_transform *gamut_remap_matrix;
const struct dc_csc_transform *input_csc_color_matrix;
const struct fixed31_32 *coeff_reduction_factor;
struct dc_transfer_func *out_transfer_func;
struct dc_csc_transform *output_csc_transform;
const struct dc_csc_transform *cursor_csc_color_matrix;
#if defined(CONFIG_DRM_AMD_DC_DCN4_2)
struct cm_hist_control *cm_hist_control;
#endif
};
struct dc_surface_update {
struct dc_plane_state *surface;
/* isr safe update parameters. null means no updates */
const struct dc_flip_addrs *flip_addr;
const struct dc_plane_info *plane_info;
const struct dc_scaling_info *scaling_info;
struct fixed31_32 hdr_mult;
/* following updates require alloc/sleep/spin that is not isr safe,
* null means no updates
*/
const struct dc_gamma *gamma;
const struct dc_transfer_func *in_transfer_func;
const struct dc_csc_transform *input_csc_color_matrix;
const struct fixed31_32 *coeff_reduction_factor;
const struct dc_transfer_func *func_shaper;
const struct dc_3dlut *lut3d_func;
const struct dc_transfer_func *blend_tf;
const struct colorspace_transform *gamut_remap_matrix;
/*
* Color Transformations for pre-blend MCM (Shaper, 3DLUT, 1DLUT)
*
* change cm2_params.component_settings: Full update
* change cm2_params.cm2_luts: Fast update
*/
const struct dc_cm2_parameters *cm2_params;
const struct dc_plane_cm *cm;
const struct dc_csc_transform *cursor_csc_color_matrix;
unsigned int sdr_white_level_nits;
struct dc_bias_and_scale bias_and_scale;
struct cm_hist_control *cm_hist_control;
};
struct dc_underflow_debug_data {
struct dcn_hubbub_reg_state *hubbub_reg_state;
struct dcn_hubp_reg_state *hubp_reg_state[MAX_PIPES];
struct dcn_dpp_reg_state *dpp_reg_state[MAX_PIPES];
struct dcn_mpc_reg_state *mpc_reg_state[MAX_PIPES];
struct dcn_opp_reg_state *opp_reg_state[MAX_PIPES];
struct dcn_dsc_reg_state *dsc_reg_state[MAX_PIPES];
struct dcn_optc_reg_state *optc_reg_state[MAX_PIPES];
struct dcn_dccg_reg_state *dccg_reg_state[MAX_PIPES];
};
struct power_features {
bool ips;
bool rcg;
bool replay;
bool dds;
bool sprs;
bool psr;
bool fams;
bool mpo;
bool uclk_p_state;
};
/*
* Create a new surface with default parameters;
*/
void dc_gamma_retain(struct dc_gamma *dc_gamma);
void dc_gamma_release(struct dc_gamma **dc_gamma);
struct dc_gamma *dc_create_gamma(void);
void dc_transfer_func_retain(struct dc_transfer_func *dc_tf);
void dc_transfer_func_release(struct dc_transfer_func *dc_tf);
struct dc_transfer_func *dc_create_transfer_func(void);
struct dc_3dlut *dc_create_3dlut_func(void);
void dc_3dlut_func_release(struct dc_3dlut *lut);
void dc_3dlut_func_retain(struct dc_3dlut *lut);
struct dc_plane_cm *dc_plane_cm_create(void);
void dc_plane_cm_release(struct dc_plane_cm *cm);
void dc_plane_cm_retain(struct dc_plane_cm *cm);
void dc_post_update_surfaces_to_stream(
struct dc *dc);
/*
* dc_get_default_tiling_info() - Retrieve an ASIC-appropriate default tiling
* description for (typically) linear surfaces.
*
* This is used by OS/DM paths that need a valid, fully-initialized tiling
* description without hardcoding gfx-version specifics in the caller.
*/
void dc_get_default_tiling_info(const struct dc *dc, struct dc_tiling_info *tiling_info);
/**
* struct dc_validation_set - Struct to store surface/stream associations for validation
*/
struct dc_validation_set {
/**
* @stream: Stream state properties
*/
struct dc_stream_state *stream;
/**
* @plane_states: Surface state
*/
struct dc_plane_state *plane_states[MAX_SURFACES];
/**
* @plane_count: Total of active planes
*/
uint8_t plane_count;
};
bool dc_validate_boot_timing(const struct dc *dc,
const struct dc_sink *sink,
struct dc_crtc_timing *crtc_timing);
enum dc_status dc_validate_plane(struct dc *dc, const struct dc_plane_state *plane_state);
enum dc_status dc_validate_with_context(struct dc *dc,
const struct dc_validation_set set[],
int set_count,
struct dc_state *context,
enum dc_validate_mode validate_mode);
bool dc_set_generic_gpio_for_stereo(bool enable,
struct gpio_service *gpio_service);
enum dc_status dc_validate_global_state(
struct dc *dc,
struct dc_state *new_ctx,
enum dc_validate_mode validate_mode);
bool dc_acquire_release_mpc_3dlut(
struct dc *dc, bool acquire,
struct dc_stream_state *stream,
struct dc_3dlut **lut,
struct dc_transfer_func **shaper);
bool dc_resource_is_dsc_encoding_supported(const struct dc *dc);
void get_audio_check(struct audio_info *aud_modes,
struct audio_check *aud_chk);
bool fast_nonaddr_updates_exist(struct dc_fast_update *fast_update, int surface_count);
void populate_fast_updates(struct dc_fast_update *fast_update,
struct dc_surface_update *srf_updates,
int surface_count,
struct dc_stream_update *stream_update);
/*
* Set up streams and links associated to drive sinks
* The streams parameter is an absolute set of all active streams.
*
* After this call:
* Phy, Encoder, Timing Generator are programmed and enabled.
* New streams are enabled with blank stream; no memory read.
*/
enum dc_status dc_commit_streams(struct dc *dc, struct dc_commit_streams_params *params);
struct dc_plane_state *dc_get_surface_for_mpcc(struct dc *dc,
struct dc_stream_state *stream,
int mpcc_inst);
uint32_t dc_get_opp_for_plane(struct dc *dc, struct dc_plane_state *plane);
void dc_set_disable_128b_132b_stream_overhead(bool disable);
/* The function returns minimum bandwidth required to drive a given timing
* return - minimum required timing bandwidth in kbps.
*/
uint32_t dc_bandwidth_in_kbps_from_timing(
const struct dc_crtc_timing *timing,
const enum dc_link_encoding_format link_encoding);
/* Link Interfaces */
/* Return an enumerated dc_link.
* dc_link order is constant and determined at
* boot time. They cannot be created or destroyed.
* Use dc_get_caps() to get number of links.
*/
struct dc_link *dc_get_link_at_index(struct dc *dc, uint32_t link_index);
/* Return instance id of the edp link. Inst 0 is primary edp link. */
bool dc_get_edp_link_panel_inst(const struct dc *dc,
const struct dc_link *link,
unsigned int *inst_out);
/* Return an array of link pointers to edp links. */
void dc_get_edp_links(const struct dc *dc,
struct dc_link **edp_links,
unsigned int *edp_num);
void dc_set_edp_power(const struct dc *dc, struct dc_link *edp_link,
bool powerOn);
/* The function initiates detection handshake over the given link. It first
* determines if there are display connections over the link. If so it initiates
* detection protocols supported by the connected receiver device. The function
* contains protocol specific handshake sequences which are sometimes mandatory
* to establish a proper connection between TX and RX. So it is always
* recommended to call this function as the first link operation upon HPD event
* or power up event. Upon completion, the function will update link structure
* in place based on latest RX capabilities. The function may also cause dpms
* to be reset to off for all currently enabled streams to the link. It is DM's
* responsibility to serialize detection and DPMS updates.
*
* @reason - Indicate which event triggers this detection. dc may customize
* detection flow depending on the triggering events.
* return false - if detection is not fully completed. This could happen when
* there is an unrecoverable error during detection or detection is partially
* completed (detection has been delegated to dm mst manager ie.
* link->connection_type == dc_connection_mst_branch when returning false).
* return true - detection is completed, link has been fully updated with latest
* detection result.
*/
bool dc_link_detect(struct dc_link *link, enum dc_detect_reason reason);
struct dc_sink_init_data;
/* When link connection type is dc_connection_mst_branch, remote sink can be
* added to the link. The interface creates a remote sink and associates it with
* current link. The sink will be retained by link until remove remote sink is
* called.
*
* @dc_link - link the remote sink will be added to.
* @edid - byte array of EDID raw data.
* @len - size of the edid in byte
* @init_data -
*/
struct dc_sink *dc_link_add_remote_sink(
struct dc_link *dc_link,
const uint8_t *edid,
int len,
struct dc_sink_init_data *init_data);
/* Remove remote sink from a link with dc_connection_mst_branch connection type.
* @link - link the sink should be removed from
* @sink - sink to be removed.
*/
void dc_link_remove_remote_sink(
struct dc_link *link,
struct dc_sink *sink);
/* Enable HPD interrupt handler for a given link */
void dc_link_enable_hpd(const struct dc_link *link);
/* Disable HPD interrupt handler for a given link */
void dc_link_disable_hpd(const struct dc_link *link);
/* determine if there is a sink connected to the link
*
* @type - dc_connection_single if connected, dc_connection_none otherwise.
* return - false if an unexpected error occurs, true otherwise.
*
* NOTE: This function doesn't detect downstream sink connections i.e
* dc_connection_mst_branch, dc_connection_sst_branch. In this case, it will
* return dc_connection_single if the branch device is connected despite of
* downstream sink's connection status.
*/
bool dc_link_detect_connection_type(struct dc_link *link,
enum dc_connection_type *type);
/* query current hpd pin value
* return - true HPD is asserted (HPD high), false otherwise (HPD low)
*
*/
bool dc_link_get_hpd_state(struct dc_link *link);
/* Getter for cached link status from given link */
const struct dc_link_status *dc_link_get_status(const struct dc_link *link);
/* enable/disable hardware HPD filter.
*
* @link - The link the HPD pin is associated with.
* @enable = true - enable hardware HPD filter. HPD event will only queued to irq
* handler once after no HPD change has been detected within dc default HPD
* filtering interval since last HPD event. i.e if display keeps toggling hpd
* pulses within default HPD interval, no HPD event will be received until HPD
* toggles have stopped. Then HPD event will be queued to irq handler once after
* dc default HPD filtering interval since last HPD event.
*
* @enable = false - disable hardware HPD filter. HPD event will be queued
* immediately to irq handler after no HPD change has been detected within
* IRQ_HPD (aka HPD short pulse) interval (i.e 2ms).
*/
void dc_link_enable_hpd_filter(struct dc_link *link, bool enable);
/* submit i2c read/write payloads through ddc channel
* @link_index - index to a link with ddc in i2c mode
* @cmd - i2c command structure
* return - true if success, false otherwise.
*/
bool dc_submit_i2c(
struct dc *dc,
uint32_t link_index,
struct i2c_command *cmd);
/* submit i2c read/write payloads through oem channel
* @link_index - index to a link with ddc in i2c mode
* @cmd - i2c command structure
* return - true if success, false otherwise.
*/
bool dc_submit_i2c_oem(
struct dc *dc,
struct i2c_command *cmd);
enum aux_return_code_type;
/* Attempt to transfer the given aux payload. This function does not perform
* retries or handle error states. The reply is returned in the payload->reply
* and the result through operation_result. Returns the number of bytes
* transferred,or -1 on a failure.
*/
int dc_link_aux_transfer_raw(struct ddc_service *ddc,
struct aux_payload *payload,
enum aux_return_code_type *operation_result);
struct ddc_service *
dc_get_oem_i2c_device(struct dc *dc);
bool dc_is_oem_i2c_device_present(
struct dc *dc,
size_t slave_address
);
/* return true if the connected receiver supports the hdcp version */
bool dc_link_is_hdcp14(struct dc_link *link, enum signal_type signal);
bool dc_link_is_hdcp22(struct dc_link *link, enum signal_type signal);
/* Notify DC about DP RX Interrupt (aka DP IRQ_HPD).
*
* TODO - When defer_handling is true the function will have a different purpose.
* It no longer does complete hpd rx irq handling. We should create a separate
* interface specifically for this case.
*
* Return:
* true - Downstream port status changed. DM should call DC to do the
* detection.
* false - no change in Downstream port status. No further action required
* from DM.
*/
bool dc_link_handle_hpd_rx_irq(struct dc_link *dc_link,
union hpd_irq_data *hpd_irq_dpcd_data, bool *out_link_loss,
bool defer_handling, bool *has_left_work);
/* handle DP specs define test automation sequence*/
void dc_link_dp_handle_automated_test(struct dc_link *link);
/* handle DP Link loss sequence and try to recover RX link loss with best
* effort
*/
void dc_link_dp_handle_link_loss(struct dc_link *link);
/* Determine if hpd rx irq should be handled or ignored
* return true - hpd rx irq should be handled.
* return false - it is safe to ignore hpd rx irq event
*/
bool dc_link_dp_allow_hpd_rx_irq(const struct dc_link *link);
/* Determine if link loss is indicated with a given hpd_irq_dpcd_data.
* @link - link the hpd irq data associated with
* @hpd_irq_dpcd_data - input hpd irq data
* return - true if hpd irq data indicates a link lost
*/
bool dc_link_check_link_loss_status(struct dc_link *link,
union hpd_irq_data *hpd_irq_dpcd_data);
/* Read hpd rx irq data from a given link
* @link - link where the hpd irq data should be read from
* @irq_data - output hpd irq data
* return - DC_OK if hpd irq data is read successfully, otherwise hpd irq data
* read has failed.
*/
enum dc_status dc_link_dp_read_hpd_rx_irq_data(
struct dc_link *link,
union hpd_irq_data *irq_data);
/* The function clears recorded DP RX states in the link. DM should call this
* function when it is resuming from S3 power state to previously connected links.
*
* TODO - in the future we should consider to expand link resume interface to
* support clearing previous rx states. So we don't have to rely on dm to call
* this interface explicitly.
*/
void dc_link_clear_dprx_states(struct dc_link *link);
/* Destruct the mst topology of the link and reset the allocated payload table
*
* NOTE: this should only be called if DM chooses not to call dc_link_detect but
* still wants to reset MST topology on an unplug event */
bool dc_link_reset_cur_dp_mst_topology(struct dc_link *link);
/* The function calculates effective DP link bandwidth when a given link is
* using the given link settings.
*
* return - total effective link bandwidth in kbps.
*/
uint32_t dc_link_bandwidth_kbps(
const struct dc_link *link,
const struct dc_link_settings *link_setting);
struct dp_audio_bandwidth_params {
const struct dc_crtc_timing *crtc_timing;
enum dp_link_encoding link_encoding;
uint32_t channel_count;
uint32_t sample_rate_hz;
};
/* The function calculates the minimum size of hblank (in bytes) needed to
* support the specified channel count and sample rate combination, given the
* link encoding and timing to be used. This calculation is not supported
* for 8b/10b SST.
*
* return - min hblank size in bytes, 0 if 8b/10b SST.
*/
uint32_t dc_link_required_hblank_size_bytes(
const struct dc_link *link,
struct dp_audio_bandwidth_params *audio_params);
/* The function takes a snapshot of current link resource allocation state
* @dc: pointer to dc of the dm calling this
* @map: a dc link resource snapshot defined internally to dc.
*
* DM needs to capture a snapshot of current link resource allocation mapping
* and store it in its persistent storage.
*
* Some of the link resource is using first come first serve policy.
* The allocation mapping depends on original hotplug order. This information
* is lost after driver is loaded next time. The snapshot is used in order to
* restore link resource to its previous state so user will get consistent
* link capability allocation across reboot.
*
*/
void dc_get_cur_link_res_map(const struct dc *dc, uint32_t *map);
/* This function restores link resource allocation state from a snapshot
* @dc: pointer to dc of the dm calling this
* @map: a dc link resource snapshot defined internally to dc.
*
* DM needs to call this function after initial link detection on boot and
* before first commit streams to restore link resource allocation state
* from previous boot session.
*
* Some of the link resource is using first come first serve policy.
* The allocation mapping depends on original hotplug order. This information
* is lost after driver is loaded next time. The snapshot is used in order to
* restore link resource to its previous state so user will get consistent
* link capability allocation across reboot.
*
*/
void dc_restore_link_res_map(const struct dc *dc, uint32_t *map);
/* TODO: this is not meant to be exposed to DM. Should switch to stream update
* interface i.e stream_update->dsc_config
*/
bool dc_link_update_dsc_config(struct pipe_ctx *pipe_ctx);
/* translate a raw link rate data to bandwidth in kbps */
uint32_t dc_link_bw_kbps_from_raw_frl_link_rate_data(const struct dc *dc, uint8_t bw);
/* determine the optimal bandwidth given link and required bw.
* @link - current detected link
* @req_bw - requested bandwidth in kbps
* @link_settings - returned most optimal link settings that can fit the
* requested bandwidth
* return - false if link can't support requested bandwidth, true if link
* settings is found.
*/
bool dc_link_decide_edp_link_settings(struct dc_link *link,
struct dc_link_settings *link_settings,
uint32_t req_bw);
/* return the max dp link settings can be driven by the link without considering
* connected RX device and its capability
*/
bool dc_link_dp_get_max_link_enc_cap(const struct dc_link *link,
struct dc_link_settings *max_link_enc_cap);
/* determine when the link is driving MST mode, what DP link channel coding
* format will be used. The decision will remain unchanged until next HPD event.
*
* @link - a link with DP RX connection
* return - if stream is committed to this link with MST signal type, type of
* channel coding format dc will choose.
*/
enum dp_link_encoding dc_link_dp_mst_decide_link_encoding_format(
const struct dc_link *link);
/* get max dp link settings the link can enable with all things considered. (i.e
* TX/RX/Cable capabilities and dp override policies.
*
* @link - a link with DP RX connection
* return - max dp link settings the link can enable.
*
*/
const struct dc_link_settings *dc_link_get_link_cap(const struct dc_link *link);
/* Get the highest encoding format that the link supports; highest meaning the
* encoding format which supports the maximum bandwidth.
*
* @link - a link with DP RX connection
* return - highest encoding format link supports.
*/
enum dc_link_encoding_format dc_link_get_highest_encoding_format(const struct dc_link *link);
/* Check if a RX (ex. DP sink, MST hub, passive or active dongle) is connected
* to a link with dp connector signal type.
* @link - a link with dp connector signal type
* return - true if connected, false otherwise
*/
bool dc_link_is_dp_sink_present(struct dc_link *link);
/* Force DP lane settings update to main-link video signal and notify the change
* to DP RX via DPCD. This is a debug interface used for video signal integrity
* tuning purpose. The interface assumes link has already been enabled with DP
* signal.
*
* @lt_settings - a container structure with desired hw_lane_settings
*/
void dc_link_set_drive_settings(struct dc *dc,
struct link_training_settings *lt_settings,
struct dc_link *link);
/* Enable a test pattern in Link or PHY layer in an active link for compliance
* test or debugging purpose. The test pattern will remain until next un-plug.
*
* @link - active link with DP signal output enabled.
* @test_pattern - desired test pattern to output.
* NOTE: set to DP_TEST_PATTERN_VIDEO_MODE to disable previous test pattern.
* @test_pattern_color_space - for video test pattern choose a desired color
* space.
* @p_link_settings - For PHY pattern choose a desired link settings
* @p_custom_pattern - some test pattern will require a custom input to
* customize some pattern details. Otherwise keep it to NULL.
* @cust_pattern_size - size of the custom pattern input.
*
*/
bool dc_link_dp_set_test_pattern(
struct dc_link *link,
enum dp_test_pattern test_pattern,
enum dp_test_pattern_color_space test_pattern_color_space,
const struct link_training_settings *p_link_settings,
const unsigned char *p_custom_pattern,
unsigned int cust_pattern_size);
/* Force DP link settings to always use a specific value until reboot to a
* specific link. If link has already been enabled, the interface will also
* switch to desired link settings immediately. This is a debug interface to
* generic dp issue trouble shooting.
*/
void dc_link_set_preferred_link_settings(struct dc *dc,
struct dc_link_settings *link_setting,
struct dc_link *link);
/* Force DP link to customize a specific link training behavior by overriding to
* standard DP specs defined protocol. This is a debug interface to trouble shoot
* display specific link training issues or apply some display specific
* workaround in link training.
*
* @link_settings - if not NULL, force preferred link settings to the link.
* @lt_override - a set of override pointers. If any pointer is none NULL, dc
* will apply this particular override in future link training. If NULL is
* passed in, dc resets previous overrides.
* NOTE: DM must keep the memory from override pointers until DM resets preferred
* training settings.
*/
void dc_link_set_preferred_training_settings(struct dc *dc,
struct dc_link_settings *link_setting,
struct dc_link_training_overrides *lt_overrides,
struct dc_link *link,
bool skip_immediate_retrain);
/* return - true if FEC is supported with connected DP RX, false otherwise */
bool dc_link_is_fec_supported(const struct dc_link *link);
/* query FEC enablement policy to determine if FEC will be enabled by dc during
* link enablement.
* return - true if FEC should be enabled, false otherwise.
*/
bool dc_link_should_enable_fec(const struct dc_link *link);
/* determine lttpr mode the current link should be enabled with a specific link
* settings.
*/
enum lttpr_mode dc_link_decide_lttpr_mode(struct dc_link *link,
struct dc_link_settings *link_setting);
/* Force DP RX to update its power state.
* NOTE: this interface doesn't update dp main-link. Calling this function will
* cause DP TX main-link and DP RX power states out of sync. DM has to restore
* RX power state back upon finish DM specific execution requiring DP RX in a
* specific power state.
* @on - true to set DP RX in D0 power state, false to set DP RX in D3 power
* state.
*/
void dc_link_dp_receiver_power_ctrl(struct dc_link *link, bool on);
/* Force link to read base dp receiver caps from dpcd 000h - 00Fh and overwrite
* current value read from extended receiver cap from 02200h - 0220Fh.
* Some DP RX has problems of providing accurate DP receiver caps from extended
* field, this interface is a workaround to revert link back to use base caps.
*/
void dc_link_overwrite_extended_receiver_cap(
struct dc_link *link);
void dc_link_edp_panel_backlight_power_on(struct dc_link *link,
bool wait_for_hpd);
/* Set backlight level of an embedded panel (eDP, LVDS).
* backlight_pwm_u16_16 is unsigned 32 bit with 16 bit integer
* and 16 bit fractional, where 1.0 is max backlight value.
*/
bool dc_link_set_backlight_level(const struct dc_link *dc_link,
struct set_backlight_level_params *backlight_level_params);
/* Set/get nits-based backlight level of an embedded panel (eDP, LVDS). */
bool dc_link_set_backlight_level_nits(struct dc_link *link,
bool isHDR,
uint32_t backlight_millinits,
uint32_t transition_time_in_ms);
bool dc_link_get_backlight_level_nits(struct dc_link *link,
uint32_t *backlight_millinits,
uint32_t *backlight_millinits_peak);
int dc_link_get_backlight_level(const struct dc_link *dc_link);
int dc_link_get_target_backlight_pwm(const struct dc_link *link);
bool dc_link_set_psr_allow_active(struct dc_link *dc_link, const bool *enable,
bool wait, bool force_static, const unsigned int *power_opts);
bool dc_link_get_psr_state(const struct dc_link *dc_link, enum dc_psr_state *state);
bool dc_link_setup_psr(struct dc_link *dc_link,
const struct dc_stream_state *stream, struct psr_config *psr_config,
struct psr_context *psr_context);
/*
* Communicate with DMUB to allow or disallow Panel Replay on the specified link:
*
* @link: pointer to the dc_link struct instance
* @enable: enable(active) or disable(inactive) replay
* @wait: state transition need to wait the active set completed.
* @force_static: force disable(inactive) the replay
* @power_opts: set power optimazation parameters to DMUB.
*
* return: allow Replay active will return true, else will return false.
*/
bool dc_link_set_replay_allow_active(struct dc_link *dc_link, const bool *enable,
bool wait, bool force_static, const unsigned int *power_opts);
bool dc_link_get_replay_state(const struct dc_link *dc_link, uint64_t *state);
/*
* Enable or disable Panel Replay on the specified link:
*
* @link: pointer to the dc_link struct instance
* @enable: enable or disable Panel Replay
*
* return: true if successful, false otherwise
*/
bool dc_link_set_pr_enable(struct dc_link *link, bool enable);
/*
* Update Panel Replay state parameters:
*
* @link: pointer to the dc_link struct instance
* @update_state_data: pointer to state update data structure
*
* return: true if successful, false otherwise
*/
bool dc_link_update_pr_state(struct dc_link *link,
struct dmub_cmd_pr_update_state_data *update_state_data);
/*
* Send general command to Panel Replay firmware:
*
* @link: pointer to the dc_link struct instance
* @general_cmd_data: pointer to general command data structure
*
* return: true if successful, false otherwise
*/
bool dc_link_set_pr_general_cmd(struct dc_link *link,
struct dmub_cmd_pr_general_cmd_data *general_cmd_data);
/*
* Get Panel Replay state:
*
* @link: pointer to the dc_link struct instance
* @state: pointer to store the Panel Replay state
*
* return: true if successful, false otherwise
*/
bool dc_link_get_pr_state(const struct dc_link *link, uint64_t *state);
/* On eDP links this function call will stall until T12 has elapsed.
* If the panel is not in power off state, this function will return
* immediately.
*/
bool dc_link_wait_for_t12(struct dc_link *link);
/* Determine if dp trace has been initialized to reflect upto date result *
* return - true if trace is initialized and has valid data. False dp trace
* doesn't have valid result.
*/
bool dc_dp_trace_is_initialized(struct dc_link *link);
/* Query a dp trace flag to indicate if the current dp trace data has been
* logged before
*/
bool dc_dp_trace_is_logged(struct dc_link *link,
bool in_detection);
/* Set dp trace flag to indicate whether DM has already logged the current dp
* trace data. DM can set is_logged to true upon logging and check
* dc_dp_trace_is_logged before logging to avoid logging the same result twice.
*/
void dc_dp_trace_set_is_logged_flag(struct dc_link *link,
bool in_detection,
bool is_logged);
/* Obtain driver time stamp for last dp link training end. The time stamp is
* formatted based on dm_get_timestamp DM function.
* @in_detection - true to get link training end time stamp of last link
* training in detection sequence. false to get link training end time stamp
* of last link training in commit (dpms) sequence
*/
unsigned long long dc_dp_trace_get_lt_end_timestamp(struct dc_link *link,
bool in_detection);
/* Get how many link training attempts dc has done with latest sequence.
* @in_detection - true to get link training count of last link
* training in detection sequence. false to get link training count of last link
* training in commit (dpms) sequence
*/
const struct dp_trace_lt_counts *dc_dp_trace_get_lt_counts(struct dc_link *link,
bool in_detection);
/* Get how many link loss has happened since last link training attempts */
unsigned int dc_dp_trace_get_link_loss_count(struct dc_link *link);
/*
* USB4 DPIA BW ALLOCATION PUBLIC FUNCTIONS
*/
/*
* Send a request from DP-Tx requesting to allocate BW remotely after
* allocating it locally. This will get processed by CM and a CB function
* will be called.
*
* @link: pointer to the dc_link struct instance
* @req_bw: The requested bw in Kbyte to allocated
*
* return: none
*/
void dc_link_set_usb4_req_bw_req(struct dc_link *link, int req_bw);
/*
* Handle the USB4 BW Allocation related functionality here:
* Plug => Try to allocate max bw from timing parameters supported by the sink
* Unplug => de-allocate bw
*
* @link: pointer to the dc_link struct instance
* @peak_bw: Peak bw used by the link/sink
*
*/
void dc_link_dp_dpia_handle_usb4_bandwidth_allocation_for_link(
struct dc_link *link, int peak_bw);
/*
* Calculates the DP tunneling bandwidth required for the stream timing
* and aggregates the stream bandwidth for the respective DP tunneling link
*
* return: dc_status
*/
enum dc_status dc_link_validate_dp_tunneling_bandwidth(const struct dc *dc, const struct dc_state *new_ctx);
/*
* Get if ALPM is supported by the link
*/
void dc_link_get_alpm_support(struct dc_link *link, bool *auxless_support,
bool *auxwake_support);
/* Sink Interfaces - A sink corresponds to a display output device */
struct dc_container_id {
// 128bit GUID in binary form
unsigned char guid[16];
// 8 byte port ID -> ELD.PortID
unsigned int portId[2];
// 128bit GUID in binary formufacturer name -> ELD.ManufacturerName
unsigned short manufacturerName;
// 2 byte product code -> ELD.ProductCode
unsigned short productCode;
};
struct dc_sink_dsc_caps {
// 'true' if these are virtual DPCD's DSC caps (immediately upstream of sink in MST topology),
// 'false' if they are sink's DSC caps
bool is_virtual_dpcd_dsc;
// 'true' if MST topology supports DSC passthrough for sink
// 'false' if MST topology does not support DSC passthrough
bool is_dsc_passthrough_supported;
struct dsc_dec_dpcd_caps dsc_dec_caps;
};
struct dc_sink_hblank_expansion_caps {
// 'true' if these are virtual DPCD's HBlank expansion caps (immediately upstream of sink in MST topology),
// 'false' if they are sink's HBlank expansion caps
bool is_virtual_dpcd_hblank_expansion;
struct hblank_expansion_dpcd_caps dpcd_caps;
};
struct dc_sink_fec_caps {
bool is_rx_fec_supported;
bool is_topology_fec_supported;
};
struct scdc_caps {
union hdmi_scdc_manufacturer_OUI_data manufacturer_OUI;
union hdmi_scdc_device_id_data device_id;
};
/*
* The sink structure contains EDID and other display device properties
*/
struct dc_sink {
enum signal_type sink_signal;
struct dc_edid dc_edid; /* raw edid */
struct dc_edid_caps edid_caps; /* parse display caps */
struct dc_container_id *dc_container_id;
uint32_t dongle_max_pix_clk;
void *priv;
struct stereo_3d_features features_3d[TIMING_3D_FORMAT_MAX];
bool converter_disable_audio;
struct mccs_caps mccs_caps;
struct scdc_caps scdc_caps;
struct dc_sink_dsc_caps dsc_caps;
struct dc_sink_fec_caps fec_caps;
struct dc_sink_hblank_expansion_caps hblank_expansion_caps;
bool is_vsc_sdp_colorimetry_supported;
/* private to DC core */
struct dc_link *link;
struct dc_context *ctx;
uint32_t sink_id;
/* private to dc_sink.c */
// refcount must be the last member in dc_sink, since we want the
// sink structure to be logically cloneable up to (but not including)
// refcount
struct kref refcount;
};
void dc_sink_retain(struct dc_sink *sink);
void dc_sink_release(struct dc_sink *sink);
struct dc_sink_init_data {
enum signal_type sink_signal;
struct dc_link *link;
uint32_t dongle_max_pix_clk;
bool converter_disable_audio;
};
struct dc_sink *dc_sink_create(const struct dc_sink_init_data *init_params);
/* Newer interfaces */
struct dc_cursor {
struct dc_plane_address address;
struct dc_cursor_attributes attributes;
};
/* Interrupt interfaces */
enum dc_irq_source dc_interrupt_to_irq_source(
struct dc *dc,
uint32_t src_id,
uint32_t ext_id);
bool dc_interrupt_set(struct dc *dc, enum dc_irq_source src, bool enable);
void dc_interrupt_ack(struct dc *dc, enum dc_irq_source src);
enum dc_irq_source dc_get_hpd_irq_source_at_index(
struct dc *dc, uint32_t link_index);
void dc_notify_vsync_int_state(struct dc *dc, struct dc_stream_state *stream, bool enable);
/* Power Interfaces */
void dc_set_power_state(
struct dc *dc,
enum dc_acpi_cm_power_state power_state);
void dc_resume(struct dc *dc);
void dc_power_down_on_boot(struct dc *dc);
/*
* HDCP Interfaces
*/
enum hdcp_message_status dc_process_hdcp_msg(
enum signal_type signal,
struct dc_link *link,
struct hdcp_protection_message *message_info);
bool dc_is_dmcu_initialized(struct dc *dc);
enum dc_status dc_set_clock(struct dc *dc, enum dc_clock_type clock_type, uint32_t clk_khz, uint32_t stepping);
void dc_get_clock(struct dc *dc, enum dc_clock_type clock_type, struct dc_clock_config *clock_cfg);
bool dc_is_plane_eligible_for_idle_optimizations(struct dc *dc,
unsigned int pitch,
unsigned int height,
enum surface_pixel_format format,
struct dc_cursor_attributes *cursor_attr);
#define dc_allow_idle_optimizations(dc, allow) dc_allow_idle_optimizations_internal(dc, allow, __func__)
#define dc_exit_ips_for_hw_access(dc) dc_exit_ips_for_hw_access_internal(dc, __func__)
void dc_allow_idle_optimizations_internal(struct dc *dc, bool allow, const char *caller_name);
void dc_exit_ips_for_hw_access_internal(struct dc *dc, const char *caller_name);
bool dc_dmub_is_ips_idle_state(struct dc *dc);
/* set min and max memory clock to lowest and highest DPM level, respectively */
void dc_unlock_memory_clock_frequency(struct dc *dc);
/* set min memory clock to the min required for current mode, max to maxDPM */
void dc_lock_memory_clock_frequency(struct dc *dc);
/* set soft max for memclk, to be used for AC/DC switching clock limitations */
void dc_enable_dcmode_clk_limit(struct dc *dc, bool enable);
/* cleanup on driver unload */
void dc_hardware_release(struct dc *dc);
/* disables fw based mclk switch */
void dc_mclk_switch_using_fw_based_vblank_stretch_shut_down(struct dc *dc);
bool dc_set_psr_allow_active(struct dc *dc, bool enable);
bool dc_set_replay_allow_active(struct dc *dc, bool active);
bool dc_set_ips_disable(struct dc *dc, unsigned int disable_ips);
void dc_z10_restore(const struct dc *dc);
void dc_z10_save_init(struct dc *dc);
bool dc_is_dmub_outbox_supported(struct dc *dc);
bool dc_enable_dmub_notifications(struct dc *dc);
bool dc_abm_save_restore(
struct dc *dc,
struct dc_stream_state *stream,
struct abm_save_restore *pData);
void dc_enable_dmub_outbox(struct dc *dc);
bool dc_process_dmub_aux_transfer_async(struct dc *dc,
uint32_t link_index,
struct aux_payload *payload);
/*
* smart power OLED Interfaces
*/
bool dc_smart_power_oled_enable(const struct dc_link *link, bool enable, uint16_t peak_nits,
uint8_t debug_control, uint16_t fixed_CLL, uint32_t triggerline);
bool dc_smart_power_oled_get_max_cll(const struct dc_link *link, unsigned int *pCurrent_MaxCLL);
/* Get dc link index from dpia port index */
uint8_t get_link_index_from_dpia_port_index(const struct dc *dc,
uint8_t dpia_port_index);
bool dc_process_dmub_set_config_async(struct dc *dc,
uint32_t link_index,
struct set_config_cmd_payload *payload,
struct dmub_notification *notify);
enum dc_status dc_process_dmub_set_mst_slots(const struct dc *dc,
uint32_t link_index,
uint8_t mst_alloc_slots,
uint8_t *mst_slots_in_use);
void dc_process_dmub_dpia_set_tps_notification(const struct dc *dc, uint32_t link_index, uint8_t tps);
void dc_process_dmub_dpia_hpd_int_enable(const struct dc *dc,
uint32_t hpd_int_enable);
void dc_print_dmub_diagnostic_data(const struct dc *dc);
void dc_query_current_properties(struct dc *dc, struct dc_current_properties *properties);
struct dc_power_profile {
int power_level; /* Lower is better */
};
struct dc_power_profile dc_get_power_profile_for_dc_state(const struct dc_state *context);
unsigned int dc_get_det_buffer_size_from_state(const struct dc_state *context);
bool dc_get_host_router_index(const struct dc_link *link, unsigned int *host_router_index);
void dc_log_preos_dmcub_info(const struct dc *dc);
/* DSC Interfaces */
#include "dc_dsc.h"
void dc_get_visual_confirm_for_stream(
struct dc *dc,
struct dc_stream_state *stream_state,
struct tg_color *color);
/* Disable acc mode Interfaces */
void dc_disable_accelerated_mode(struct dc *dc);
bool dc_is_timing_changed(struct dc_stream_state *cur_stream,
struct dc_stream_state *new_stream);
bool dc_is_cursor_limit_pending(struct dc *dc);
bool dc_can_clear_cursor_limit(const struct dc *dc);
/**
* dc_get_underflow_debug_data_for_otg() - Retrieve underflow debug data.
*
* @dc: Pointer to the display core context.
* @primary_otg_inst: Instance index of the primary OTG that underflowed.
* @out_data: Pointer to a dc_underflow_debug_data struct to be filled with debug information.
*
* This function collects and logs underflow-related HW states when underflow happens,
* including OTG underflow status, current read positions, frame count, and per-HUBP debug data.
* The results are stored in the provided out_data structure for further analysis or logging.
*/
void dc_get_underflow_debug_data_for_otg(struct dc *dc, int primary_otg_inst, struct dc_underflow_debug_data *out_data);
void dc_get_power_feature_status(struct dc *dc, int primary_otg_inst, struct power_features *out_data);
/*
* Software state variables used to program register fields across the display pipeline
*/
struct dc_register_software_state {
/* HUBP register programming variables for each pipe */
struct {
bool valid_plane_state;
bool valid_stream;
bool min_dc_gfx_version9;
uint32_t vtg_sel; /* DCHUBP_CNTL->HUBP_VTG_SEL from pipe_ctx->stream_res.tg->inst */
uint32_t hubp_clock_enable; /* HUBP_CLK_CNTL->HUBP_CLOCK_ENABLE from power management */
uint32_t surface_pixel_format; /* DCSURF_SURFACE_CONFIG->SURFACE_PIXEL_FORMAT from plane_state->format */
uint32_t rotation_angle; /* DCSURF_SURFACE_CONFIG->ROTATION_ANGLE from plane_state->rotation */
uint32_t h_mirror_en; /* DCSURF_SURFACE_CONFIG->H_MIRROR_EN from plane_state->horizontal_mirror */
uint32_t surface_dcc_en; /* DCSURF_SURFACE_CONTROL->PRIMARY_SURFACE_DCC_EN from dcc->enable */
uint32_t surface_size_width; /* HUBP_SIZE->SURFACE_SIZE_WIDTH from plane_size.surface_size.width */
uint32_t surface_size_height; /* HUBP_SIZE->SURFACE_SIZE_HEIGHT from plane_size.surface_size.height */
uint32_t pri_viewport_width; /* DCSURF_PRI_VIEWPORT_DIMENSION->PRI_VIEWPORT_WIDTH from scaler_data.viewport.width */
uint32_t pri_viewport_height; /* DCSURF_PRI_VIEWPORT_DIMENSION->PRI_VIEWPORT_HEIGHT from scaler_data.viewport.height */
uint32_t pri_viewport_x_start; /* DCSURF_PRI_VIEWPORT_START->PRI_VIEWPORT_X_START from scaler_data.viewport.x */
uint32_t pri_viewport_y_start; /* DCSURF_PRI_VIEWPORT_START->PRI_VIEWPORT_Y_START from scaler_data.viewport.y */
uint32_t cursor_enable; /* CURSOR_CONTROL->CURSOR_ENABLE from cursor_attributes.enable */
uint32_t cursor_width; /* CURSOR_SETTINGS->CURSOR_WIDTH from cursor_position.width */
uint32_t cursor_height; /* CURSOR_SETTINGS->CURSOR_HEIGHT from cursor_position.height */
/* Additional DCC configuration */
uint32_t surface_dcc_ind_64b_blk; /* DCSURF_SURFACE_CONTROL->PRIMARY_SURFACE_DCC_IND_64B_BLK from dcc.independent_64b_blks */
uint32_t surface_dcc_ind_128b_blk; /* DCSURF_SURFACE_CONTROL->PRIMARY_SURFACE_DCC_IND_128B_BLK from dcc.independent_128b_blks */
/* Surface pitch configuration */
uint32_t surface_pitch; /* DCSURF_SURFACE_PITCH->PITCH from plane_size.surface_pitch */
uint32_t meta_pitch; /* DCSURF_SURFACE_PITCH->META_PITCH from dcc.meta_pitch */
uint32_t chroma_pitch; /* DCSURF_SURFACE_PITCH_C->PITCH_C from plane_size.chroma_pitch */
uint32_t meta_pitch_c; /* DCSURF_SURFACE_PITCH_C->META_PITCH_C from dcc.meta_pitch_c */
/* Surface addresses */
uint32_t primary_surface_address_low; /* DCSURF_PRIMARY_SURFACE_ADDRESS->PRIMARY_SURFACE_ADDRESS from address.grph.addr.low_part */
uint32_t primary_surface_address_high; /* DCSURF_PRIMARY_SURFACE_ADDRESS_HIGH->PRIMARY_SURFACE_ADDRESS_HIGH from address.grph.addr.high_part */
uint32_t primary_meta_surface_address_low; /* DCSURF_PRIMARY_META_SURFACE_ADDRESS->PRIMARY_META_SURFACE_ADDRESS from address.grph.meta_addr.low_part */
uint32_t primary_meta_surface_address_high; /* DCSURF_PRIMARY_META_SURFACE_ADDRESS_HIGH->PRIMARY_META_SURFACE_ADDRESS_HIGH from address.grph.meta_addr.high_part */
/* TMZ configuration */
uint32_t primary_surface_tmz; /* DCSURF_SURFACE_CONTROL->PRIMARY_SURFACE_TMZ from address.tmz_surface */
uint32_t primary_meta_surface_tmz; /* DCSURF_SURFACE_CONTROL->PRIMARY_META_SURFACE_TMZ from address.tmz_surface */
/* Tiling configuration */
uint32_t sw_mode; /* DCSURF_TILING_CONFIG->SW_MODE from tiling_info.gfx9.swizzle */
uint32_t num_pipes; /* DCSURF_ADDR_CONFIG->NUM_PIPES from tiling_info.gfx9.num_pipes */
uint32_t num_banks; /* DCSURF_ADDR_CONFIG->NUM_BANKS from tiling_info.gfx9.num_banks */
uint32_t pipe_interleave; /* DCSURF_ADDR_CONFIG->PIPE_INTERLEAVE from tiling_info.gfx9.pipe_interleave */
uint32_t num_shader_engines; /* DCSURF_ADDR_CONFIG->NUM_SE from tiling_info.gfx9.num_shader_engines */
uint32_t num_rb_per_se; /* DCSURF_ADDR_CONFIG->NUM_RB_PER_SE from tiling_info.gfx9.num_rb_per_se */
uint32_t num_pkrs; /* DCSURF_ADDR_CONFIG->NUM_PKRS from tiling_info.gfx9.num_pkrs */
/* DML Request Size Configuration - Luma */
uint32_t rq_chunk_size; /* DCHUBP_REQ_SIZE_CONFIG->CHUNK_SIZE from rq_regs.rq_regs_l.chunk_size */
uint32_t rq_min_chunk_size; /* DCHUBP_REQ_SIZE_CONFIG->MIN_CHUNK_SIZE from rq_regs.rq_regs_l.min_chunk_size */
uint32_t rq_meta_chunk_size; /* DCHUBP_REQ_SIZE_CONFIG->META_CHUNK_SIZE from rq_regs.rq_regs_l.meta_chunk_size */
uint32_t rq_min_meta_chunk_size; /* DCHUBP_REQ_SIZE_CONFIG->MIN_META_CHUNK_SIZE from rq_regs.rq_regs_l.min_meta_chunk_size */
uint32_t rq_dpte_group_size; /* DCHUBP_REQ_SIZE_CONFIG->DPTE_GROUP_SIZE from rq_regs.rq_regs_l.dpte_group_size */
uint32_t rq_mpte_group_size; /* DCHUBP_REQ_SIZE_CONFIG->MPTE_GROUP_SIZE from rq_regs.rq_regs_l.mpte_group_size */
uint32_t rq_swath_height_l; /* DCHUBP_REQ_SIZE_CONFIG->SWATH_HEIGHT_L from rq_regs.rq_regs_l.swath_height */
uint32_t rq_pte_row_height_l; /* DCHUBP_REQ_SIZE_CONFIG->PTE_ROW_HEIGHT_L from rq_regs.rq_regs_l.pte_row_height */
/* DML Request Size Configuration - Chroma */
uint32_t rq_chunk_size_c; /* DCHUBP_REQ_SIZE_CONFIG_C->CHUNK_SIZE_C from rq_regs.rq_regs_c.chunk_size */
uint32_t rq_min_chunk_size_c; /* DCHUBP_REQ_SIZE_CONFIG_C->MIN_CHUNK_SIZE_C from rq_regs.rq_regs_c.min_chunk_size */
uint32_t rq_meta_chunk_size_c; /* DCHUBP_REQ_SIZE_CONFIG_C->META_CHUNK_SIZE_C from rq_regs.rq_regs_c.meta_chunk_size */
uint32_t rq_min_meta_chunk_size_c; /* DCHUBP_REQ_SIZE_CONFIG_C->MIN_META_CHUNK_SIZE_C from rq_regs.rq_regs_c.min_meta_chunk_size */
uint32_t rq_dpte_group_size_c; /* DCHUBP_REQ_SIZE_CONFIG_C->DPTE_GROUP_SIZE_C from rq_regs.rq_regs_c.dpte_group_size */
uint32_t rq_mpte_group_size_c; /* DCHUBP_REQ_SIZE_CONFIG_C->MPTE_GROUP_SIZE_C from rq_regs.rq_regs_c.mpte_group_size */
uint32_t rq_swath_height_c; /* DCHUBP_REQ_SIZE_CONFIG_C->SWATH_HEIGHT_C from rq_regs.rq_regs_c.swath_height */
uint32_t rq_pte_row_height_c; /* DCHUBP_REQ_SIZE_CONFIG_C->PTE_ROW_HEIGHT_C from rq_regs.rq_regs_c.pte_row_height */
/* DML Expansion Modes */
uint32_t drq_expansion_mode; /* DCN_EXPANSION_MODE->DRQ_EXPANSION_MODE from rq_regs.drq_expansion_mode */
uint32_t prq_expansion_mode; /* DCN_EXPANSION_MODE->PRQ_EXPANSION_MODE from rq_regs.prq_expansion_mode */
uint32_t mrq_expansion_mode; /* DCN_EXPANSION_MODE->MRQ_EXPANSION_MODE from rq_regs.mrq_expansion_mode */
uint32_t crq_expansion_mode; /* DCN_EXPANSION_MODE->CRQ_EXPANSION_MODE from rq_regs.crq_expansion_mode */
/* DML DLG parameters - nominal */
uint32_t dst_y_per_vm_vblank; /* NOM_PARAMETERS_0->DST_Y_PER_VM_VBLANK from dlg_regs.dst_y_per_vm_vblank */
uint32_t dst_y_per_row_vblank; /* NOM_PARAMETERS_0->DST_Y_PER_ROW_VBLANK from dlg_regs.dst_y_per_row_vblank */
uint32_t dst_y_per_vm_flip; /* NOM_PARAMETERS_1->DST_Y_PER_VM_FLIP from dlg_regs.dst_y_per_vm_flip */
uint32_t dst_y_per_row_flip; /* NOM_PARAMETERS_1->DST_Y_PER_ROW_FLIP from dlg_regs.dst_y_per_row_flip */
/* DML prefetch settings */
uint32_t dst_y_prefetch; /* PREFETCH_SETTINS->DST_Y_PREFETCH from dlg_regs.dst_y_prefetch */
uint32_t vratio_prefetch; /* PREFETCH_SETTINS->VRATIO_PREFETCH from dlg_regs.vratio_prefetch */
uint32_t vratio_prefetch_c; /* PREFETCH_SETTINS_C->VRATIO_PREFETCH_C from dlg_regs.vratio_prefetch_c */
/* TTU parameters */
uint32_t qos_level_low_wm; /* TTU_CNTL1->QoSLevelLowWaterMark from ttu_regs.qos_level_low_wm */
uint32_t qos_level_high_wm; /* TTU_CNTL1->QoSLevelHighWaterMark from ttu_regs.qos_level_high_wm */
uint32_t qos_level_flip; /* TTU_CNTL2->QoS_LEVEL_FLIP_L from ttu_regs.qos_level_flip */
uint32_t min_ttu_vblank; /* DCN_GLOBAL_TTU_CNTL->MIN_TTU_VBLANK from ttu_regs.min_ttu_vblank */
} hubp[MAX_PIPES];
/* HUBBUB register programming variables */
struct {
/* Individual DET buffer control per pipe - software state that programs DET registers */
uint32_t det0_size; /* DCHUBBUB_DET0_CTRL->DET0_SIZE from hubbub->funcs->program_det_size(hubbub, 0, det_buffer_size_kb) */
uint32_t det1_size; /* DCHUBBUB_DET1_CTRL->DET1_SIZE from hubbub->funcs->program_det_size(hubbub, 1, det_buffer_size_kb) */
uint32_t det2_size; /* DCHUBBUB_DET2_CTRL->DET2_SIZE from hubbub->funcs->program_det_size(hubbub, 2, det_buffer_size_kb) */
uint32_t det3_size; /* DCHUBBUB_DET3_CTRL->DET3_SIZE from hubbub->funcs->program_det_size(hubbub, 3, det_buffer_size_kb) */
/* Compression buffer control - software state that programs COMPBUF registers */
uint32_t compbuf_size; /* DCHUBBUB_COMPBUF_CTRL->COMPBUF_SIZE from hubbub->funcs->program_compbuf_size(hubbub, compbuf_size_kb, safe_to_increase) */
uint32_t compbuf_reserved_space_64b; /* COMPBUF_RESERVED_SPACE->COMPBUF_RESERVED_SPACE_64B from hubbub2->pixel_chunk_size / 32 */
uint32_t compbuf_reserved_space_zs; /* COMPBUF_RESERVED_SPACE->COMPBUF_RESERVED_SPACE_ZS from hubbub2->pixel_chunk_size / 128 */
} hubbub;
/* DPP register programming variables for each pipe (simplified for available fields) */
struct {
uint32_t dpp_clock_enable; /* DPP_CONTROL->DPP_CLOCK_ENABLE from dppclk_enable */
/* Recout (Rectangle of Interest) configuration */
uint32_t recout_start_x; /* RECOUT_START->RECOUT_START_X from pipe_ctx->plane_res.scl_data.recout.x */
uint32_t recout_start_y; /* RECOUT_START->RECOUT_START_Y from pipe_ctx->plane_res.scl_data.recout.y */
uint32_t recout_width; /* RECOUT_SIZE->RECOUT_WIDTH from pipe_ctx->plane_res.scl_data.recout.width */
uint32_t recout_height; /* RECOUT_SIZE->RECOUT_HEIGHT from pipe_ctx->plane_res.scl_data.recout.height */
/* MPC (Multiple Pipe/Plane Combiner) size configuration */
uint32_t mpc_width; /* MPC_SIZE->MPC_WIDTH from pipe_ctx->plane_res.scl_data.h_active */
uint32_t mpc_height; /* MPC_SIZE->MPC_HEIGHT from pipe_ctx->plane_res.scl_data.v_active */
/* DSCL mode configuration */
uint32_t dscl_mode; /* SCL_MODE->DSCL_MODE from pipe_ctx->plane_res.scl_data.dscl_prog_data.dscl_mode */
/* Scaler ratios (simplified to integer parts) */
uint32_t horz_ratio_int; /* SCL_HORZ_FILTER_SCALE_RATIO->SCL_H_SCALE_RATIO integer part from ratios.horz */
uint32_t vert_ratio_int; /* SCL_VERT_FILTER_SCALE_RATIO->SCL_V_SCALE_RATIO integer part from ratios.vert */
/* Basic scaler taps */
uint32_t h_taps; /* SCL_TAP_CONTROL->SCL_H_NUM_TAPS from taps.h_taps */
uint32_t v_taps; /* SCL_TAP_CONTROL->SCL_V_NUM_TAPS from taps.v_taps */
} dpp[MAX_PIPES];
/* DCCG register programming variables */
struct {
/* Core Display Clock Control */
uint32_t dispclk_khz; /* DENTIST_DISPCLK_CNTL->DENTIST_DISPCLK_WDIVIDER from clk_mgr.dispclk_khz */
uint32_t dc_mem_global_pwr_req_dis; /* DC_MEM_GLOBAL_PWR_REQ_CNTL->DC_MEM_GLOBAL_PWR_REQ_DIS from memory power management settings */
/* DPP Clock Control - 4 fields per pipe */
uint32_t dppclk_khz[MAX_PIPES]; /* DPPCLK_CTRL->DPPCLK_R_GATE_DISABLE from dpp_clocks[pipe] */
uint32_t dppclk_enable[MAX_PIPES]; /* DPPCLK_CTRL->DPPCLK0_EN,DPPCLK1_EN,DPPCLK2_EN,DPPCLK3_EN from dccg31_update_dpp_dto() */
uint32_t dppclk_dto_enable[MAX_PIPES]; /* DPPCLK_DTO_CTRL->DPPCLK_DTO_ENABLE from dccg->dpp_clock_gated[dpp_inst] state */
uint32_t dppclk_dto_phase[MAX_PIPES]; /* DPPCLK0_DTO_PARAM->DPPCLK0_DTO_PHASE from phase calculation req_dppclk/ref_dppclk */
uint32_t dppclk_dto_modulo[MAX_PIPES]; /* DPPCLK0_DTO_PARAM->DPPCLK0_DTO_MODULO from modulo = 0xff */
/* DSC Clock Control - 4 fields per DSC resource */
uint32_t dscclk_khz[MAX_PIPES]; /* DSCCLK_DTO_CTRL->DSCCLK_DTO_ENABLE from dsc_clocks */
uint32_t dscclk_dto_enable[MAX_PIPES]; /* DSCCLK_DTO_CTRL->DSCCLK0_DTO_ENABLE,DSCCLK1_DTO_ENABLE,DSCCLK2_DTO_ENABLE,DSCCLK3_DTO_ENABLE */
uint32_t dscclk_dto_phase[MAX_PIPES]; /* DSCCLK0_DTO_PARAM->DSCCLK0_DTO_PHASE from dccg31_enable_dscclk() */
uint32_t dscclk_dto_modulo[MAX_PIPES]; /* DSCCLK0_DTO_PARAM->DSCCLK0_DTO_MODULO from dccg31_enable_dscclk() */
/* Pixel Clock Control - per pipe */
uint32_t pixclk_khz[MAX_PIPES]; /* PIXCLK_RESYNC_CNTL->PIXCLK_RESYNC_ENABLE from stream.timing.pix_clk_100hz */
uint32_t otg_pixel_rate_div[MAX_PIPES]; /* OTG_PIXEL_RATE_DIV->OTG_PIXEL_RATE_DIV from OTG pixel rate divider control */
uint32_t dtbclk_dto_enable[MAX_PIPES]; /* OTG0_PIXEL_RATE_CNTL->DTBCLK_DTO_ENABLE from dccg31_set_dtbclk_dto() */
uint32_t pipe_dto_src_sel[MAX_PIPES]; /* OTG0_PIXEL_RATE_CNTL->PIPE_DTO_SRC_SEL from dccg31_set_dtbclk_dto() source selection */
uint32_t dtbclk_dto_div[MAX_PIPES]; /* OTG0_PIXEL_RATE_CNTL->DTBCLK_DTO_DIV from dtbdto_div calculation */
uint32_t otg_add_pixel[MAX_PIPES]; /* OTG0_PIXEL_RATE_CNTL->OTG_ADD_PIXEL from dccg31_otg_add_pixel() */
uint32_t otg_drop_pixel[MAX_PIPES]; /* OTG0_PIXEL_RATE_CNTL->OTG_DROP_PIXEL from dccg31_otg_drop_pixel() */
/* DTBCLK DTO Control - 4 DTOs */
uint32_t dtbclk_dto_modulo[4]; /* DTBCLK_DTO0_MODULO->DTBCLK_DTO0_MODULO from dccg31_set_dtbclk_dto() modulo calculation */
uint32_t dtbclk_dto_phase[4]; /* DTBCLK_DTO0_PHASE->DTBCLK_DTO0_PHASE from phase calculation pixclk_khz/ref_dtbclk_khz */
uint32_t dtbclk_dto_dbuf_en; /* DTBCLK_DTO_DBUF_EN->DTBCLK DTO data buffer enable */
/* DP Stream Clock Control - 4 pipes */
uint32_t dpstreamclk_enable[MAX_PIPES]; /* DPSTREAMCLK_CNTL->DPSTREAMCLK_PIPE0_EN,DPSTREAMCLK_PIPE1_EN,DPSTREAMCLK_PIPE2_EN,DPSTREAMCLK_PIPE3_EN */
uint32_t dp_dto_modulo[4]; /* DP_DTO0_MODULO->DP_DTO0_MODULO from DP stream DTO programming */
uint32_t dp_dto_phase[4]; /* DP_DTO0_PHASE->DP_DTO0_PHASE from DP stream DTO programming */
uint32_t dp_dto_dbuf_en; /* DP_DTO_DBUF_EN->DP DTO data buffer enable */
/* PHY Symbol Clock Control - 5 PHYs (A,B,C,D,E) */
uint32_t phy_symclk_force_en[5]; /* PHYASYMCLK_CLOCK_CNTL->PHYASYMCLK_FORCE_EN from dccg31_set_physymclk() force_enable */
uint32_t phy_symclk_force_src_sel[5]; /* PHYASYMCLK_CLOCK_CNTL->PHYASYMCLK_FORCE_SRC_SEL from dccg31_set_physymclk() clk_src */
uint32_t phy_symclk_gate_disable[5]; /* DCCG_GATE_DISABLE_CNTL2->PHYASYMCLK_GATE_DISABLE from debug.root_clock_optimization.bits.physymclk */
/* SYMCLK32 SE Control - 4 instances */
uint32_t symclk32_se_src_sel[4]; /* SYMCLK32_SE_CNTL->SYMCLK32_SE0_SRC_SEL from dccg31_enable_symclk32_se() with get_phy_mux_symclk() mapping */
uint32_t symclk32_se_enable[4]; /* SYMCLK32_SE_CNTL->SYMCLK32_SE0_EN from dccg31_enable_symclk32_se() enable */
uint32_t symclk32_se_gate_disable[4]; /* DCCG_GATE_DISABLE_CNTL3->SYMCLK32_SE0_GATE_DISABLE from debug.root_clock_optimization.bits.symclk32_se */
/* SYMCLK32 LE Control - 2 instances */
uint32_t symclk32_le_src_sel[2]; /* SYMCLK32_LE_CNTL->SYMCLK32_LE0_SRC_SEL from dccg31_enable_symclk32_le() phyd32clk source */
uint32_t symclk32_le_enable[2]; /* SYMCLK32_LE_CNTL->SYMCLK32_LE0_EN from dccg31_enable_symclk32_le() enable */
uint32_t symclk32_le_gate_disable[2]; /* DCCG_GATE_DISABLE_CNTL3->SYMCLK32_LE0_GATE_DISABLE from debug.root_clock_optimization.bits.symclk32_le */
/* DPIA Clock Control */
uint32_t dpiaclk_540m_dto_modulo; /* DPIACLK_540M_DTO_MODULO->DPIA 540MHz DTO modulo */
uint32_t dpiaclk_540m_dto_phase; /* DPIACLK_540M_DTO_PHASE->DPIA 540MHz DTO phase */
uint32_t dpiaclk_810m_dto_modulo; /* DPIACLK_810M_DTO_MODULO->DPIA 810MHz DTO modulo */
uint32_t dpiaclk_810m_dto_phase; /* DPIACLK_810M_DTO_PHASE->DPIA 810MHz DTO phase */
uint32_t dpiaclk_dto_cntl; /* DPIACLK_DTO_CNTL->DPIA clock DTO control */
uint32_t dpiasymclk_cntl; /* DPIASYMCLK_CNTL->DPIA symbol clock control */
/* Clock Gating Control */
uint32_t dccg_gate_disable_cntl; /* DCCG_GATE_DISABLE_CNTL->Clock gate disable control from dccg31_init() */
uint32_t dpstreamclk_gate_disable; /* DCCG_GATE_DISABLE_CNTL3->DPSTREAMCLK_GATE_DISABLE from debug.root_clock_optimization.bits.dpstream */
uint32_t dpstreamclk_root_gate_disable; /* DCCG_GATE_DISABLE_CNTL3->DPSTREAMCLK_ROOT_GATE_DISABLE from debug.root_clock_optimization.bits.dpstream */
/* VSync Control */
uint32_t vsync_cnt_ctrl; /* DCCG_VSYNC_CNT_CTRL->VSync counter control */
uint32_t vsync_cnt_int_ctrl; /* DCCG_VSYNC_CNT_INT_CTRL->VSync counter interrupt control */
uint32_t vsync_otg_latch_value[6]; /* DCCG_VSYNC_OTG0_LATCH_VALUE->OTG0 VSync latch value (for OTG0-5) */
/* Time Base Control */
uint32_t microsecond_time_base_div; /* MICROSECOND_TIME_BASE_DIV->Microsecond time base divider */
uint32_t millisecond_time_base_div; /* MILLISECOND_TIME_BASE_DIV->Millisecond time base divider */
} dccg;
/* DSC essential configuration for underflow analysis */
struct {
/* DSC active state - critical for bandwidth analysis */
uint32_t dsc_clock_enable; /* DSC enabled - affects bandwidth requirements */
/* DSC configuration affecting bandwidth and timing */
uint32_t dsc_num_slices_h; /* Horizontal slice count - affects throughput */
uint32_t dsc_num_slices_v; /* Vertical slice count - affects throughput */
uint32_t dsc_bits_per_pixel; /* Compression ratio - affects bandwidth */
/* OPP integration - affects pipeline flow */
uint32_t dscrm_dsc_forward_enable; /* DSC forwarding to OPP enabled */
uint32_t dscrm_dsc_opp_pipe_source; /* Which OPP receives DSC output */
} dsc[MAX_PIPES];
/* MPC register programming variables */
struct {
/* MPCC blending tree and mode control */
uint32_t mpcc_mode[MAX_PIPES]; /* MPCC_CONTROL->MPCC_MODE from blend_cfg.blend_mode */
uint32_t mpcc_alpha_blend_mode[MAX_PIPES]; /* MPCC_CONTROL->MPCC_ALPHA_BLND_MODE from blend_cfg.alpha_mode */
uint32_t mpcc_alpha_multiplied_mode[MAX_PIPES]; /* MPCC_CONTROL->MPCC_ALPHA_MULTIPLIED_MODE from blend_cfg.pre_multiplied_alpha */
uint32_t mpcc_blnd_active_overlap_only[MAX_PIPES]; /* MPCC_CONTROL->MPCC_BLND_ACTIVE_OVERLAP_ONLY from blend_cfg.overlap_only */
uint32_t mpcc_global_alpha[MAX_PIPES]; /* MPCC_CONTROL->MPCC_GLOBAL_ALPHA from blend_cfg.global_alpha */
uint32_t mpcc_global_gain[MAX_PIPES]; /* MPCC_CONTROL->MPCC_GLOBAL_GAIN from blend_cfg.global_gain */
uint32_t mpcc_bg_bpc[MAX_PIPES]; /* MPCC_CONTROL->MPCC_BG_BPC from background color depth */
uint32_t mpcc_bot_gain_mode[MAX_PIPES]; /* MPCC_CONTROL->MPCC_BOT_GAIN_MODE from bottom layer gain control */
/* MPCC blending tree connections */
uint32_t mpcc_bot_sel[MAX_PIPES]; /* MPCC_BOT_SEL->MPCC_BOT_SEL from mpcc_state->bot_sel */
uint32_t mpcc_top_sel[MAX_PIPES]; /* MPCC_TOP_SEL->MPCC_TOP_SEL from mpcc_state->dpp_id */
/* MPCC output gamma control */
uint32_t mpcc_ogam_mode[MAX_PIPES]; /* MPCC_OGAM_CONTROL->MPCC_OGAM_MODE from output gamma mode */
uint32_t mpcc_ogam_select[MAX_PIPES]; /* MPCC_OGAM_CONTROL->MPCC_OGAM_SELECT from gamma LUT bank selection */
uint32_t mpcc_ogam_pwl_disable[MAX_PIPES]; /* MPCC_OGAM_CONTROL->MPCC_OGAM_PWL_DISABLE from PWL control */
/* MPCC pipe assignment and status */
uint32_t mpcc_opp_id[MAX_PIPES]; /* MPCC_OPP_ID->MPCC_OPP_ID from mpcc_state->opp_id */
uint32_t mpcc_idle[MAX_PIPES]; /* MPCC_STATUS->MPCC_IDLE from mpcc idle status */
uint32_t mpcc_busy[MAX_PIPES]; /* MPCC_STATUS->MPCC_BUSY from mpcc busy status */
/* MPC output processing */
uint32_t mpc_out_csc_mode; /* MPC_OUT_CSC_COEF->MPC_OUT_CSC_MODE from output_csc */
uint32_t mpc_out_gamma_mode; /* MPC_OUT_GAMMA_LUT->MPC_OUT_GAMMA_MODE from output_gamma */
} mpc;
/* OPP register programming variables for each pipe */
struct {
/* Display Pattern Generator (DPG) Control - 19 fields from DPG_CONTROL register */
uint32_t dpg_enable; /* DPG_CONTROL->DPG_EN from test_pattern parameter (enable/disable) */
/* Format Control (FMT) - 18 fields from FMT_CONTROL register */
uint32_t fmt_pixel_encoding; /* FMT_CONTROL->FMT_PIXEL_ENCODING from clamping->pixel_encoding */
uint32_t fmt_subsampling_mode; /* FMT_CONTROL->FMT_SUBSAMPLING_MODE from force_chroma_subsampling_1tap */
uint32_t fmt_cbcr_bit_reduction_bypass; /* FMT_CONTROL->FMT_CBCR_BIT_REDUCTION_BYPASS from pixel_encoding bypass control */
uint32_t fmt_stereosync_override; /* FMT_CONTROL->FMT_STEREOSYNC_OVERRIDE from stereo timing override */
uint32_t fmt_spatial_dither_frame_counter_max; /* FMT_CONTROL->FMT_SPATIAL_DITHER_FRAME_COUNTER_MAX from fmt_bit_depth->flags */
uint32_t fmt_spatial_dither_frame_counter_bit_swap; /* FMT_CONTROL->FMT_SPATIAL_DITHER_FRAME_COUNTER_BIT_SWAP from dither control */
uint32_t fmt_truncate_enable; /* FMT_CONTROL->FMT_TRUNCATE_EN from fmt_bit_depth->flags.TRUNCATE_ENABLED */
uint32_t fmt_truncate_depth; /* FMT_CONTROL->FMT_TRUNCATE_DEPTH from fmt_bit_depth->flags.TRUNCATE_DEPTH */
uint32_t fmt_truncate_mode; /* FMT_CONTROL->FMT_TRUNCATE_MODE from fmt_bit_depth->flags.TRUNCATE_MODE */
uint32_t fmt_spatial_dither_enable; /* FMT_CONTROL->FMT_SPATIAL_DITHER_EN from fmt_bit_depth->flags.SPATIAL_DITHER_ENABLED */
uint32_t fmt_spatial_dither_mode; /* FMT_CONTROL->FMT_SPATIAL_DITHER_MODE from fmt_bit_depth->flags.SPATIAL_DITHER_MODE */
uint32_t fmt_spatial_dither_depth; /* FMT_CONTROL->FMT_SPATIAL_DITHER_DEPTH from fmt_bit_depth->flags.SPATIAL_DITHER_DEPTH */
uint32_t fmt_temporal_dither_enable; /* FMT_CONTROL->FMT_TEMPORAL_DITHER_EN from fmt_bit_depth->flags.TEMPORAL_DITHER_ENABLED */
uint32_t fmt_clamp_data_enable; /* FMT_CONTROL->FMT_CLAMP_DATA_EN from clamping->clamping_range enable */
uint32_t fmt_clamp_color_format; /* FMT_CONTROL->FMT_CLAMP_COLOR_FORMAT from clamping->color_format */
uint32_t fmt_dynamic_exp_enable; /* FMT_CONTROL->FMT_DYNAMIC_EXP_EN from color_sp/color_dpth/signal */
uint32_t fmt_dynamic_exp_mode; /* FMT_CONTROL->FMT_DYNAMIC_EXP_MODE from color space mode mapping */
uint32_t fmt_bit_depth_control; /* Legacy field - kept for compatibility */
/* OPP Pipe Control - 1 field from OPP_PIPE_CONTROL register */
uint32_t opp_pipe_clock_enable; /* OPP_PIPE_CONTROL->OPP_PIPE_CLOCK_EN from enable parameter (bool) */
/* OPP CRC Control - 3 fields from OPP_PIPE_CRC_CONTROL register */
uint32_t opp_crc_enable; /* OPP_PIPE_CRC_CONTROL->CRC_EN from CRC enable control */
uint32_t opp_crc_select_source; /* OPP_PIPE_CRC_CONTROL->CRC_SELECT_SOURCE from CRC source selection */
uint32_t opp_crc_stereo_cont; /* OPP_PIPE_CRC_CONTROL->CRC_STEREO_CONT from stereo continuous CRC */
/* Output Buffer (OPPBUF) Control - 6 fields from OPPBUF_CONTROL register */
uint32_t oppbuf_active_width; /* OPPBUF_CONTROL->OPPBUF_ACTIVE_WIDTH from oppbuf_params->active_width */
uint32_t oppbuf_pixel_repetition; /* OPPBUF_CONTROL->OPPBUF_PIXEL_REPETITION from oppbuf_params->pixel_repetition */
uint32_t oppbuf_display_segmentation; /* OPPBUF_CONTROL->OPPBUF_DISPLAY_SEGMENTATION from oppbuf_params->mso_segmentation */
uint32_t oppbuf_overlap_pixel_num; /* OPPBUF_CONTROL->OPPBUF_OVERLAP_PIXEL_NUM from oppbuf_params->mso_overlap_pixel_num */
uint32_t oppbuf_3d_vact_space1_size; /* OPPBUF_CONTROL->OPPBUF_3D_VACT_SPACE1_SIZE from 3D timing space1_size */
uint32_t oppbuf_3d_vact_space2_size; /* OPPBUF_CONTROL->OPPBUF_3D_VACT_SPACE2_SIZE from 3D timing space2_size */
/* DSC Forward Config - 3 fields from DSCRM_DSC_FORWARD_CONFIG register */
uint32_t dscrm_dsc_forward_enable; /* DSCRM_DSC_FORWARD_CONFIG->DSCRM_DSC_FORWARD_EN from DSC forward enable control */
uint32_t dscrm_dsc_opp_pipe_source; /* DSCRM_DSC_FORWARD_CONFIG->DSCRM_DSC_OPP_PIPE_SOURCE from opp_pipe parameter */
uint32_t dscrm_dsc_forward_enable_status; /* DSCRM_DSC_FORWARD_CONFIG->DSCRM_DSC_FORWARD_EN_STATUS from DSC forward status (read-only) */
} opp[MAX_PIPES];
/* OPTC register programming variables for each pipe */
struct {
uint32_t otg_master_inst;
/* OTG_CONTROL register - 5 fields for OTG control */
uint32_t otg_master_enable; /* OTG_CONTROL->OTG_MASTER_EN from timing enable/disable control */
uint32_t otg_disable_point_cntl; /* OTG_CONTROL->OTG_DISABLE_POINT_CNTL from disable timing control */
uint32_t otg_start_point_cntl; /* OTG_CONTROL->OTG_START_POINT_CNTL from start timing control */
uint32_t otg_field_number_cntl; /* OTG_CONTROL->OTG_FIELD_NUMBER_CNTL from interlace field control */
uint32_t otg_out_mux; /* OTG_CONTROL->OTG_OUT_MUX from output mux selection */
/* OTG Horizontal Timing - 7 fields */
uint32_t otg_h_total; /* OTG_H_TOTAL->OTG_H_TOTAL from dc_crtc_timing->h_total */
uint32_t otg_h_blank_start; /* OTG_H_BLANK_START_END->OTG_H_BLANK_START from dc_crtc_timing->h_front_porch */
uint32_t otg_h_blank_end; /* OTG_H_BLANK_START_END->OTG_H_BLANK_END from dc_crtc_timing->h_addressable_video_pixel_width */
uint32_t otg_h_sync_start; /* OTG_H_SYNC_A->OTG_H_SYNC_A_START from dc_crtc_timing->h_sync_width */
uint32_t otg_h_sync_end; /* OTG_H_SYNC_A->OTG_H_SYNC_A_END from calculated sync end position */
uint32_t otg_h_sync_polarity; /* OTG_H_SYNC_A_CNTL->OTG_H_SYNC_A_POL from dc_crtc_timing->flags.HSYNC_POSITIVE_POLARITY */
uint32_t otg_h_timing_div_mode; /* OTG_H_TIMING_CNTL->OTG_H_TIMING_DIV_MODE from horizontal timing division mode */
/* OTG Vertical Timing - 7 fields */
uint32_t otg_v_total; /* OTG_V_TOTAL->OTG_V_TOTAL from dc_crtc_timing->v_total */
uint32_t otg_v_blank_start; /* OTG_V_BLANK_START_END->OTG_V_BLANK_START from dc_crtc_timing->v_front_porch */
uint32_t otg_v_blank_end; /* OTG_V_BLANK_START_END->OTG_V_BLANK_END from dc_crtc_timing->v_addressable_video_line_width */
uint32_t otg_v_sync_start; /* OTG_V_SYNC_A->OTG_V_SYNC_A_START from dc_crtc_timing->v_sync_width */
uint32_t otg_v_sync_end; /* OTG_V_SYNC_A->OTG_V_SYNC_A_END from calculated sync end position */
uint32_t otg_v_sync_polarity; /* OTG_V_SYNC_A_CNTL->OTG_V_SYNC_A_POL from dc_crtc_timing->flags.VSYNC_POSITIVE_POLARITY */
uint32_t otg_v_sync_mode; /* OTG_V_SYNC_A_CNTL->OTG_V_SYNC_MODE from sync mode selection */
/* OTG DRR (Dynamic Refresh Rate) Control - 8 fields */
uint32_t otg_v_total_max; /* OTG_V_TOTAL_MAX->OTG_V_TOTAL_MAX from drr_params->vertical_total_max */
uint32_t otg_v_total_min; /* OTG_V_TOTAL_MIN->OTG_V_TOTAL_MIN from drr_params->vertical_total_min */
uint32_t otg_v_total_mid; /* OTG_V_TOTAL_MID->OTG_V_TOTAL_MID from drr_params->vertical_total_mid */
uint32_t otg_v_total_max_sel; /* OTG_V_TOTAL_CONTROL->OTG_V_TOTAL_MAX_SEL from DRR max selection enable */
uint32_t otg_v_total_min_sel; /* OTG_V_TOTAL_CONTROL->OTG_V_TOTAL_MIN_SEL from DRR min selection enable */
uint32_t otg_vtotal_mid_replacing_max_en; /* OTG_V_TOTAL_CONTROL->OTG_VTOTAL_MID_REPLACING_MAX_EN from DRR mid-frame enable */
uint32_t otg_vtotal_mid_frame_num; /* OTG_V_TOTAL_CONTROL->OTG_VTOTAL_MID_FRAME_NUM from drr_params->vertical_total_mid_frame_num */
uint32_t otg_set_v_total_min_mask; /* OTG_V_TOTAL_CONTROL->OTG_SET_V_TOTAL_MIN_MASK from DRR trigger mask */
uint32_t otg_force_lock_on_event; /* OTG_V_TOTAL_CONTROL->OTG_FORCE_LOCK_ON_EVENT from DRR force lock control */
/* OPTC Data Source and ODM - 6 fields */
uint32_t optc_seg0_src_sel; /* OPTC_DATA_SOURCE_SELECT->OPTC_SEG0_SRC_SEL from opp_id[0] ODM segment 0 source */
uint32_t optc_seg1_src_sel; /* OPTC_DATA_SOURCE_SELECT->OPTC_SEG1_SRC_SEL from opp_id[1] ODM segment 1 source */
uint32_t optc_seg2_src_sel; /* OPTC_DATA_SOURCE_SELECT->OPTC_SEG2_SRC_SEL from opp_id[2] ODM segment 2 source */
uint32_t optc_seg3_src_sel; /* OPTC_DATA_SOURCE_SELECT->OPTC_SEG3_SRC_SEL from opp_id[3] ODM segment 3 source */
uint32_t optc_num_of_input_segment; /* OPTC_DATA_SOURCE_SELECT->OPTC_NUM_OF_INPUT_SEGMENT from opp_cnt-1 number of input segments */
uint32_t optc_mem_sel; /* OPTC_MEMORY_CONFIG->OPTC_MEM_SEL from memory_mask ODM memory selection */
/* OPTC Data Format and DSC - 4 fields */
uint32_t optc_data_format; /* OPTC_DATA_FORMAT_CONTROL->OPTC_DATA_FORMAT from data format selection */
uint32_t optc_dsc_mode; /* OPTC_DATA_FORMAT_CONTROL->OPTC_DSC_MODE from dsc_mode parameter */
uint32_t optc_dsc_bytes_per_pixel; /* OPTC_BYTES_PER_PIXEL->OPTC_DSC_BYTES_PER_PIXEL from dsc_bytes_per_pixel parameter */
uint32_t optc_segment_width; /* OPTC_WIDTH_CONTROL->OPTC_SEGMENT_WIDTH from segment_width parameter */
uint32_t optc_dsc_slice_width; /* OPTC_WIDTH_CONTROL->OPTC_DSC_SLICE_WIDTH from dsc_slice_width parameter */
/* OPTC Clock and Underflow Control - 4 fields */
uint32_t optc_input_pix_clk_en; /* OPTC_INPUT_CLOCK_CONTROL->OPTC_INPUT_PIX_CLK_EN from pixel clock enable */
uint32_t optc_underflow_occurred_status; /* OPTC_INPUT_GLOBAL_CONTROL->OPTC_UNDERFLOW_OCCURRED_STATUS from underflow status (read-only) */
uint32_t optc_underflow_clear; /* OPTC_INPUT_GLOBAL_CONTROL->OPTC_UNDERFLOW_CLEAR from underflow clear control */
uint32_t otg_clock_enable; /* OTG_CLOCK_CONTROL->OTG_CLOCK_EN from OTG clock enable */
uint32_t otg_clock_gate_dis; /* OTG_CLOCK_CONTROL->OTG_CLOCK_GATE_DIS from clock gate disable */
/* OTG Stereo and 3D Control - 6 fields */
uint32_t otg_stereo_enable; /* OTG_STEREO_CONTROL->OTG_STEREO_EN from stereo enable control */
uint32_t otg_stereo_sync_output_line_num; /* OTG_STEREO_CONTROL->OTG_STEREO_SYNC_OUTPUT_LINE_NUM from timing->stereo_3d_format line num */
uint32_t otg_stereo_sync_output_polarity; /* OTG_STEREO_CONTROL->OTG_STEREO_SYNC_OUTPUT_POLARITY from stereo polarity control */
uint32_t otg_3d_structure_en; /* OTG_3D_STRUCTURE_CONTROL->OTG_3D_STRUCTURE_EN from 3D structure enable */
uint32_t otg_3d_structure_v_update_mode; /* OTG_3D_STRUCTURE_CONTROL->OTG_3D_STRUCTURE_V_UPDATE_MODE from 3D vertical update mode */
uint32_t otg_3d_structure_stereo_sel_ovr; /* OTG_3D_STRUCTURE_CONTROL->OTG_3D_STRUCTURE_STEREO_SEL_OVR from 3D stereo selection override */
uint32_t otg_interlace_enable; /* OTG_INTERLACE_CONTROL->OTG_INTERLACE_ENABLE from dc_crtc_timing->flags.INTERLACE */
/* OTG GSL (Global Sync Lock) Control - 5 fields */
uint32_t otg_gsl0_en; /* OTG_GSL_CONTROL->OTG_GSL0_EN from GSL group 0 enable */
uint32_t otg_gsl1_en; /* OTG_GSL_CONTROL->OTG_GSL1_EN from GSL group 1 enable */
uint32_t otg_gsl2_en; /* OTG_GSL_CONTROL->OTG_GSL2_EN from GSL group 2 enable */
uint32_t otg_gsl_master_en; /* OTG_GSL_CONTROL->OTG_GSL_MASTER_EN from GSL master enable */
uint32_t otg_gsl_master_mode; /* OTG_GSL_CONTROL->OTG_GSL_MASTER_MODE from gsl_params->gsl_master mode */
/* OTG DRR Advanced Control - 4 fields */
uint32_t otg_v_total_last_used_by_drr; /* OTG_DRR_CONTROL->OTG_V_TOTAL_LAST_USED_BY_DRR from last used DRR V_TOTAL (read-only) */
uint32_t otg_drr_trigger_window_start_x; /* OTG_DRR_TRIGGER_WINDOW->OTG_DRR_TRIGGER_WINDOW_START_X from window_start parameter */
uint32_t otg_drr_trigger_window_end_x; /* OTG_DRR_TRIGGER_WINDOW->OTG_DRR_TRIGGER_WINDOW_END_X from window_end parameter */
uint32_t otg_drr_v_total_change_limit; /* OTG_DRR_V_TOTAL_CHANGE->OTG_DRR_V_TOTAL_CHANGE_LIMIT from limit parameter */
/* OTG DSC Position Control - 2 fields */
uint32_t otg_dsc_start_position_x; /* OTG_DSC_START_POSITION->OTG_DSC_START_POSITION_X from DSC start X position */
uint32_t otg_dsc_start_position_line_num; /* OTG_DSC_START_POSITION->OTG_DSC_START_POSITION_LINE_NUM from DSC start line number */
/* OTG Double Buffer Control - 2 fields */
uint32_t otg_drr_timing_dbuf_update_mode; /* OTG_DOUBLE_BUFFER_CONTROL->OTG_DRR_TIMING_DBUF_UPDATE_MODE from DRR double buffer mode */
uint32_t otg_blank_data_double_buffer_en; /* OTG_DOUBLE_BUFFER_CONTROL->OTG_BLANK_DATA_DOUBLE_BUFFER_EN from blank data double buffer enable */
/* OTG Vertical Interrupts - 6 fields */
uint32_t otg_vertical_interrupt0_int_enable; /* OTG_VERTICAL_INTERRUPT0_CONTROL->OTG_VERTICAL_INTERRUPT0_INT_ENABLE from interrupt 0 enable */
uint32_t otg_vertical_interrupt0_line_start; /* OTG_VERTICAL_INTERRUPT0_POSITION->OTG_VERTICAL_INTERRUPT0_LINE_START from start_line parameter */
uint32_t otg_vertical_interrupt1_int_enable; /* OTG_VERTICAL_INTERRUPT1_CONTROL->OTG_VERTICAL_INTERRUPT1_INT_ENABLE from interrupt 1 enable */
uint32_t otg_vertical_interrupt1_line_start; /* OTG_VERTICAL_INTERRUPT1_POSITION->OTG_VERTICAL_INTERRUPT1_LINE_START from start_line parameter */
uint32_t otg_vertical_interrupt2_int_enable; /* OTG_VERTICAL_INTERRUPT2_CONTROL->OTG_VERTICAL_INTERRUPT2_INT_ENABLE from interrupt 2 enable */
uint32_t otg_vertical_interrupt2_line_start; /* OTG_VERTICAL_INTERRUPT2_POSITION->OTG_VERTICAL_INTERRUPT2_LINE_START from start_line parameter */
/* OTG Global Sync Parameters - 6 fields */
uint32_t otg_vready_offset; /* OTG_VREADY_PARAM->OTG_VREADY_OFFSET from vready_offset parameter */
uint32_t otg_vstartup_start; /* OTG_VSTARTUP_PARAM->OTG_VSTARTUP_START from vstartup_start parameter */
uint32_t otg_vupdate_offset; /* OTG_VUPDATE_PARAM->OTG_VUPDATE_OFFSET from vupdate_offset parameter */
uint32_t otg_vupdate_width; /* OTG_VUPDATE_PARAM->OTG_VUPDATE_WIDTH from vupdate_width parameter */
uint32_t master_update_lock_vupdate_keepout_start_offset; /* OTG_VUPDATE_KEEPOUT->MASTER_UPDATE_LOCK_VUPDATE_KEEPOUT_START_OFFSET from pstate_keepout start */
uint32_t master_update_lock_vupdate_keepout_end_offset; /* OTG_VUPDATE_KEEPOUT->MASTER_UPDATE_LOCK_VUPDATE_KEEPOUT_END_OFFSET from pstate_keepout end */
/* OTG Manual Trigger Control - 11 fields */
uint32_t otg_triga_source_select; /* OTG_TRIGA_CNTL->OTG_TRIGA_SOURCE_SELECT from trigger A source selection */
uint32_t otg_triga_source_pipe_select; /* OTG_TRIGA_CNTL->OTG_TRIGA_SOURCE_PIPE_SELECT from trigger A pipe selection */
uint32_t otg_triga_rising_edge_detect_cntl; /* OTG_TRIGA_CNTL->OTG_TRIGA_RISING_EDGE_DETECT_CNTL from trigger A rising edge detect */
uint32_t otg_triga_falling_edge_detect_cntl; /* OTG_TRIGA_CNTL->OTG_TRIGA_FALLING_EDGE_DETECT_CNTL from trigger A falling edge detect */
uint32_t otg_triga_polarity_select; /* OTG_TRIGA_CNTL->OTG_TRIGA_POLARITY_SELECT from trigger A polarity selection */
uint32_t otg_triga_frequency_select; /* OTG_TRIGA_CNTL->OTG_TRIGA_FREQUENCY_SELECT from trigger A frequency selection */
uint32_t otg_triga_delay; /* OTG_TRIGA_CNTL->OTG_TRIGA_DELAY from trigger A delay */
uint32_t otg_triga_clear; /* OTG_TRIGA_CNTL->OTG_TRIGA_CLEAR from trigger A clear */
uint32_t otg_triga_manual_trig; /* OTG_TRIGA_MANUAL_TRIG->OTG_TRIGA_MANUAL_TRIG from manual trigger A */
uint32_t otg_trigb_source_select; /* OTG_TRIGB_CNTL->OTG_TRIGB_SOURCE_SELECT from trigger B source selection */
uint32_t otg_trigb_polarity_select; /* OTG_TRIGB_CNTL->OTG_TRIGB_POLARITY_SELECT from trigger B polarity selection */
uint32_t otg_trigb_manual_trig; /* OTG_TRIGB_MANUAL_TRIG->OTG_TRIGB_MANUAL_TRIG from manual trigger B */
/* OTG Static Screen and Update Control - 6 fields */
uint32_t otg_static_screen_event_mask; /* OTG_STATIC_SCREEN_CONTROL->OTG_STATIC_SCREEN_EVENT_MASK from event_triggers parameter */
uint32_t otg_static_screen_frame_count; /* OTG_STATIC_SCREEN_CONTROL->OTG_STATIC_SCREEN_FRAME_COUNT from num_frames parameter */
uint32_t master_update_lock; /* OTG_MASTER_UPDATE_LOCK->MASTER_UPDATE_LOCK from update lock control */
uint32_t master_update_mode; /* OTG_MASTER_UPDATE_MODE->MASTER_UPDATE_MODE from update mode selection */
uint32_t otg_force_count_now_mode; /* OTG_FORCE_COUNT_NOW_CNTL->OTG_FORCE_COUNT_NOW_MODE from force count mode */
uint32_t otg_force_count_now_clear; /* OTG_FORCE_COUNT_NOW_CNTL->OTG_FORCE_COUNT_NOW_CLEAR from force count clear */
/* VTG Control - 3 fields */
uint32_t vtg0_enable; /* CONTROL->VTG0_ENABLE from VTG enable control */
uint32_t vtg0_fp2; /* CONTROL->VTG0_FP2 from VTG front porch 2 */
uint32_t vtg0_vcount_init; /* CONTROL->VTG0_VCOUNT_INIT from VTG vertical count init */
/* OTG Status (Read-Only) - 12 fields */
uint32_t otg_v_blank; /* OTG_STATUS->OTG_V_BLANK from vertical blank status (read-only) */
uint32_t otg_v_active_disp; /* OTG_STATUS->OTG_V_ACTIVE_DISP from vertical active display (read-only) */
uint32_t otg_frame_count; /* OTG_STATUS_FRAME_COUNT->OTG_FRAME_COUNT from frame count (read-only) */
uint32_t otg_horz_count; /* OTG_STATUS_POSITION->OTG_HORZ_COUNT from horizontal position (read-only) */
uint32_t otg_vert_count; /* OTG_STATUS_POSITION->OTG_VERT_COUNT from vertical position (read-only) */
uint32_t otg_horz_count_hv; /* OTG_STATUS_HV_COUNT->OTG_HORZ_COUNT from horizontal count (read-only) */
uint32_t otg_vert_count_nom; /* OTG_STATUS_HV_COUNT->OTG_VERT_COUNT_NOM from vertical count nominal (read-only) */
uint32_t otg_flip_pending; /* OTG_PIPE_UPDATE_STATUS->OTG_FLIP_PENDING from flip pending status (read-only) */
uint32_t otg_dc_reg_update_pending; /* OTG_PIPE_UPDATE_STATUS->OTG_DC_REG_UPDATE_PENDING from DC register update pending (read-only) */
uint32_t otg_cursor_update_pending; /* OTG_PIPE_UPDATE_STATUS->OTG_CURSOR_UPDATE_PENDING from cursor update pending (read-only) */
uint32_t otg_vupdate_keepout_status; /* OTG_PIPE_UPDATE_STATUS->OTG_VUPDATE_KEEPOUT_STATUS from VUPDATE keepout status (read-only) */
} optc[MAX_PIPES];
/* Metadata */
uint32_t active_pipe_count;
uint32_t active_stream_count;
bool state_valid;
};
/**
* dc_capture_register_software_state() - Capture software state for register programming
* @dc: DC context containing current display configuration
* @state: Pointer to dc_register_software_state structure to populate
*
* Extracts all software state variables that are used to program hardware register
* fields across the display driver pipeline. This provides a complete snapshot
* of the software configuration that drives hardware register programming.
*
* The function traverses the DC context and extracts values from:
* - Stream configurations (timing, format, DSC settings)
* - Plane states (surface format, rotation, scaling, cursor)
* - Pipe contexts (resource allocation, blending, viewport)
* - Clock manager (display clocks, DPP clocks, pixel clocks)
* - Resource context (DET buffer allocation, ODM configuration)
*
* This is essential for underflow debugging as it captures the exact software
* state that determines how registers are programmed, allowing analysis of
* whether underflow is caused by incorrect register programming or timing issues.
*
* Return: true if state was successfully captured, false on error
*/
bool dc_capture_register_software_state(struct dc *dc, struct dc_register_software_state *state);
/**
* dc_get_qos_info() - Retrieve Quality of Service (QoS) information from display core
* @dc: DC context containing current display configuration
* @info: Pointer to dc_qos_info structure to populate with QoS metrics
*
* This function retrieves QoS metrics from the display core that can be used by
* benchmark tools to analyze display system performance. The function may take
* several milliseconds to execute due to hardware measurement requirements.
*
* QoS information includes:
* - Bandwidth bounds (lower limits in Mbps)
* - Latency bounds (upper limits in nanoseconds)
* - Hardware-measured bandwidth metrics (peak/average in Mbps)
* - Hardware-measured latency metrics (maximum/average in nanoseconds)
*
* The function will populate the provided dc_qos_info structure with current
* QoS measurements. If hardware measurement functions are not available for
* the current DCN version, the function returns false with zero'd info structure.
*
* Return: true if QoS information was successfully retrieved, false if measurement
* functions are unavailable or hardware measurements cannot be performed
*/
bool dc_get_qos_info(struct dc *dc, struct dc_qos_info *info);
#endif /* DC_INTERFACE_H_ */