msm8998/sdm/include/private/hw_info_types.h - platform/hardware/qcom/display - Git at Google

 /*
 * Copyright (c) 2015-2017, The Linux Foundation. All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without modification, are permitted
 * provided that the following conditions are met:
 *    * Redistributions of source code must retain the above copyright notice, this list of
 *      conditions and the following disclaimer.
 *    * Redistributions in binary form must reproduce the above copyright notice, this list of
 *      conditions and the following disclaimer in the documentation and/or other materials provided
 *      with the distribution.
 *    * Neither the name of The Linux Foundation nor the names of its contributors may be used to
 *      endorse or promote products derived from this software without specific prior written
 *      permission.
 *
 * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
 * NON-INFRINGEMENT ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
 * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */

 #ifndef __HW_INFO_TYPES_H__
 #define __HW_INFO_TYPES_H__

 #include <stdint.h>
 #include <core/display_interface.h>
 #include <core/core_interface.h>
 #include <vector>
 #include <map>
 #include <string>
 #include <bitset>

 namespace sdm {
 using std::string;

 const int kMaxSDELayers = 16;   // Maximum number of layers that can be handled by hardware in a
                                 // given layer stack.
 #define MAX_PLANES 4

 #define MAX_DETAIL_ENHANCE_CURVE 3

 enum HWDeviceType {
   kDevicePrimary,
   kDeviceHDMI,
   kDeviceVirtual,
   kDeviceRotator,
   kDeviceMax,
 };

 enum HWBlockType {
   kHWPrimary,
   kHWHDMI,
   kHWWriteback0,
   kHWWriteback1,
   kHWWriteback2,
   kHWBlockMax
 };

 enum HWDisplayMode {
   kModeDefault,
   kModeVideo,
   kModeCommand,
 };

 enum PipeType {
   kPipeTypeUnused,
   kPipeTypeVIG,
   kPipeTypeRGB,
   kPipeTypeDMA,
   kPipeTypeCursor,
 };

 enum HWSubBlockType {
   kHWVIGPipe,
   kHWRGBPipe,
   kHWDMAPipe,
   kHWCursorPipe,
   kHWRotatorInput,
   kHWRotatorOutput,
   kHWWBIntfOutput,
   kHWDestinationScalar,
   kHWSubBlockMax,
 };

 enum HWAlphaInterpolation {
   kInterpolationPixelRepeat,
   kInterpolationBilinear,
   kInterpolationMax,
 };

 enum HWBlendingFilter {
   kBlendFilterCircular,
   kBlendFilterSeparable,
   kBlendFilterMax,
 };

 enum HWPipeFlags {
   kIGC = 0x01,
   kMultiRect = 0x02,
   kMultiRectParallelMode = 0x04,
 };

 enum HWAVRModes {
   kContinuousMode,  // Mode to enable AVR feature for every frame.
   kOneShotMode,     // Mode to enable AVR feature for particular frame.
 };

 typedef std::map<HWSubBlockType, std::vector<LayerBufferFormat>> FormatsMap;

 struct HWDynBwLimitInfo {
   uint32_t cur_mode = kBwDefault;
   uint32_t total_bw_limit[kBwModeMax] = { 0 };
   uint32_t pipe_bw_limit[kBwModeMax] = { 0 };
 };

 struct HWPipeCaps {
   PipeType type = kPipeTypeUnused;
   uint32_t id = 0;
   uint32_t max_rects = 1;
 };

 struct HWRotatorInfo {
   enum { ROT_TYPE_MDSS, ROT_TYPE_V4L2 };
   uint32_t type = ROT_TYPE_MDSS;
   uint32_t num_rotator = 0;
   bool has_downscale = false;
   std::string device_path = "";
   float min_downscale = 2.0f;
   bool downscale_compression = false;

   void Reset() { *this = HWRotatorInfo(); }
 };

 struct HWDestScalarInfo {
   uint32_t count = 0;
   uint32_t max_input_width = 0;
   uint32_t max_output_width = 0;
   uint32_t max_scale_up = 1;
 };

 struct HWResourceInfo {
   uint32_t hw_version = 0;
   uint32_t hw_revision = 0;
   uint32_t num_dma_pipe = 0;
   uint32_t num_vig_pipe = 0;
   uint32_t num_rgb_pipe = 0;
   uint32_t num_cursor_pipe = 0;
   uint32_t num_blending_stages = 0;
   uint32_t num_control = 0;
   uint32_t num_mixer_to_disp = 0;
   uint32_t smp_total = 0;
   uint32_t smp_size = 0;
   uint32_t num_smp_per_pipe = 0;
   uint32_t max_scale_up = 1;
   uint32_t max_scale_down = 1;
   uint64_t max_bandwidth_low = 0;
   uint64_t max_bandwidth_high = 0;
   uint32_t max_mixer_width = 2048;
   uint32_t max_pipe_width = 2048;
   uint32_t max_cursor_size = 0;
   uint32_t max_pipe_bw =  0;
   uint32_t max_sde_clk = 0;
   float clk_fudge_factor = 1.0f;
   uint32_t macrotile_nv12_factor = 0;
   uint32_t macrotile_factor = 0;
   uint32_t linear_factor = 0;
   uint32_t scale_factor = 0;
   uint32_t extra_fudge_factor = 0;
   uint32_t amortizable_threshold = 0;
   uint32_t system_overhead_lines = 0;
   bool has_bwc = false;
   bool has_ubwc = false;
   bool has_decimation = false;
   bool has_macrotile = false;
   bool has_non_scalar_rgb = false;
   bool is_src_split = false;
   bool perf_calc = false;
   bool has_dyn_bw_support = false;
   bool separate_rotator = false;
   bool has_qseed3 = false;
   bool has_concurrent_writeback = false;
   bool has_ppp = false;
   uint32_t writeback_index = kHWBlockMax;
   HWDynBwLimitInfo dyn_bw_info;
   std::vector<HWPipeCaps> hw_pipes;
   FormatsMap supported_formats_map;
   HWRotatorInfo hw_rot_info;
   HWDestScalarInfo hw_dest_scalar_info;
   bool has_avr = false;
   bool has_hdr = false;

   void Reset() { *this = HWResourceInfo(); }
 };

 struct HWSplitInfo {
   uint32_t left_split = 0;
   uint32_t right_split = 0;

   bool operator !=(const HWSplitInfo &split_info) {
     return ((left_split != split_info.left_split) || (right_split != split_info.right_split));
   }

   bool operator ==(const HWSplitInfo &split_info) {
     return !(operator !=(split_info));
   }
 };

 enum HWS3DMode {
   kS3DModeNone,
   kS3DModeLR,
   kS3DModeRL,
   kS3DModeTB,
   kS3DModeFP,
   kS3DModeMax,
 };

 struct HWColorPrimaries {
   uint32_t white_point[2] = {};       // White point
   uint32_t red[2] = {};               // Red color primary
   uint32_t green[2] = {};             // Green color primary
   uint32_t blue[2] = {};              // Blue color primary
 };

 struct HWPanelOrientation {
   bool rotation = false;
   bool flip_horizontal = false;
   bool flip_vertical = false;
 };

 struct HWPanelInfo {
   DisplayPort port = kPortDefault;    // Display port
   HWDisplayMode mode = kModeDefault;  // Display mode
   bool partial_update = false;        // Partial update feature
   int left_align = 0;                 // ROI left alignment restriction
   int width_align = 0;                // ROI width alignment restriction
   int top_align = 0;                  // ROI top alignment restriction
   int height_align = 0;               // ROI height alignment restriction
   int min_roi_width = 0;              // Min width needed for ROI
   int min_roi_height = 0;             // Min height needed for ROI
   bool needs_roi_merge = false;       // Merge ROI's of both the DSI's
   bool dynamic_fps = false;           // Panel Supports dynamic fps
   bool dfps_porch_mode = false;       // dynamic fps VFP or HFP mode
   bool ping_pong_split = false;       // Supports Ping pong split
   uint32_t min_fps = 0;               // Min fps supported by panel
   uint32_t max_fps = 0;               // Max fps supported by panel
   bool is_primary_panel = false;      // Panel is primary display
   bool is_pluggable = false;          // Panel is pluggable
   HWSplitInfo split_info;             // Panel split configuration
   char panel_name[256] = {0};         // Panel name
   HWS3DMode s3d_mode = kS3DModeNone;  // Panel's current s3d mode.
   int panel_max_brightness = 0;       // Max panel brightness
   uint32_t left_roi_count = 1;        // Number if ROI supported on left panel
   uint32_t right_roi_count = 1;       // Number if ROI supported on right panel
   bool hdr_enabled = false;           // HDR feature supported
   uint32_t peak_luminance = 0;        // Panel's peak luminance level
   uint32_t average_luminance = 0;     // Panel's average luminance level
   uint32_t blackness_level = 0;       // Panel's blackness level
   HWColorPrimaries primaries = {};    // WRGB color primaries
   HWPanelOrientation panel_orientation = {};  // Panel Orientation

   bool operator !=(const HWPanelInfo &panel_info) {
     return ((port != panel_info.port) || (mode != panel_info.mode) ||
             (partial_update != panel_info.partial_update) ||
             (left_align != panel_info.left_align) || (width_align != panel_info.width_align) ||
             (top_align != panel_info.top_align) || (height_align != panel_info.height_align) ||
             (min_roi_width != panel_info.min_roi_width) ||
             (min_roi_height != panel_info.min_roi_height) ||
             (needs_roi_merge != panel_info.needs_roi_merge) ||
             (dynamic_fps != panel_info.dynamic_fps) || (min_fps != panel_info.min_fps) ||
             (dfps_porch_mode != panel_info.dfps_porch_mode) ||
             (ping_pong_split != panel_info.ping_pong_split) ||
             (max_fps != panel_info.max_fps) || (is_primary_panel != panel_info.is_primary_panel) ||
             (split_info != panel_info.split_info) || (s3d_mode != panel_info.s3d_mode) ||
             (left_roi_count != panel_info.left_roi_count) ||
             (right_roi_count != panel_info.right_roi_count));
   }

   bool operator ==(const HWPanelInfo &panel_info) {
     return !(operator !=(panel_info));
   }
 };

 struct HWSessionConfig {
   LayerRect src_rect;
   LayerRect dst_rect;
   uint32_t buffer_count = 0;
   bool secure = false;
   uint32_t frame_rate = 0;
   LayerTransform transform;
   bool secure_camera = false;

   bool operator==(const HWSessionConfig& config) const {
     return (src_rect == config.src_rect &&
             dst_rect == config.dst_rect &&
             buffer_count == config.buffer_count &&
             secure == config.secure &&
             frame_rate == config.frame_rate &&
             transform == config.transform &&
             secure_camera == config.secure_camera);
   }

   bool operator!=(const HWSessionConfig& config) const {
     return !operator==(config);
   }
 };

 struct HWRotateInfo {
   int pipe_id = -1;  // Not actual pipe id, but the relative DMA id
   int writeback_id = -1;  // Writeback block id, but this is the same as DMA id
   LayerRect src_roi;  // Source crop of each split
   LayerRect dst_roi;  // Destination crop of each split
   bool valid = false;
   int rotate_id = -1;  // Actual rotator session id with driver

   void Reset() { *this = HWRotateInfo(); }
 };

 struct HWRotatorSession {
   HWRotateInfo hw_rotate_info[kMaxRotatePerLayer];
   uint32_t hw_block_count = 0;  // number of rotator hw blocks used by rotator session
   int session_id = -1;  // A handle with Session Manager
   HWSessionConfig hw_session_config;
   LayerBuffer input_buffer;  // Input to rotator
   LayerBuffer output_buffer;  // Output of rotator, crop width and stride are same
   float input_compression = 1.0f;
   float output_compression = 1.0f;
   bool is_buffer_cached = false;
 };

 struct HWScaleLutInfo {
   uint32_t dir_lut_size = 0;
   uint32_t cir_lut_size = 0;
   uint32_t sep_lut_size = 0;
   uint64_t dir_lut = 0;
   uint64_t cir_lut = 0;
   uint64_t sep_lut = 0;
 };

 struct HWDetailEnhanceData : DisplayDetailEnhancerData {
   uint16_t prec_shift = 0;
   int16_t adjust_a[MAX_DETAIL_ENHANCE_CURVE] = {0};
   int16_t adjust_b[MAX_DETAIL_ENHANCE_CURVE] = {0};
   int16_t adjust_c[MAX_DETAIL_ENHANCE_CURVE] = {0};
 };

 struct HWPixelExtension {
   int32_t extension = 0;  // Number of pixels extension in left, right, top and bottom directions
                           // for all color components. This pixel value for each color component
                           // should be sum of fetch and repeat pixels.

   int32_t overfetch = 0;  // Number of pixels need to be overfetched in left, right, top and bottom
                           // directions from source image for scaling.

   int32_t repeat = 0;     // Number of pixels need to be repeated in left, right, top and bottom
                           // directions for scaling.
 };

 struct HWPlane {
   int32_t init_phase_x = 0;
   int32_t phase_step_x = 0;
   int32_t init_phase_y = 0;
   int32_t phase_step_y = 0;
   HWPixelExtension left;
   HWPixelExtension top;
   HWPixelExtension right;
   HWPixelExtension bottom;
   uint32_t roi_width = 0;
   int32_t preload_x = 0;
   int32_t preload_y = 0;
   uint32_t src_width = 0;
   uint32_t src_height = 0;
 };

 struct HWScaleData {
   struct enable {
     uint8_t scale = 0;
     uint8_t direction_detection = 0;
     uint8_t detail_enhance = 0;
   } enable;
   uint32_t dst_width = 0;
   uint32_t dst_height = 0;
   HWPlane plane[MAX_PLANES];
   // scale_v2_data fields
   ScalingFilterConfig y_rgb_filter_cfg = kFilterEdgeDirected;
   ScalingFilterConfig uv_filter_cfg = kFilterEdgeDirected;
   HWAlphaInterpolation alpha_filter_cfg = kInterpolationPixelRepeat;
   HWBlendingFilter blend_cfg = kBlendFilterCircular;

   struct lut_flags {
     uint8_t lut_swap = 0;
     uint8_t lut_dir_wr = 0;
     uint8_t lut_y_cir_wr = 0;
     uint8_t lut_uv_cir_wr = 0;
     uint8_t lut_y_sep_wr = 0;
     uint8_t lut_uv_sep_wr = 0;
   } lut_flag;

   uint32_t dir_lut_idx = 0;
   /* for Y(RGB) and UV planes*/
   uint32_t y_rgb_cir_lut_idx = 0;
   uint32_t uv_cir_lut_idx = 0;
   uint32_t y_rgb_sep_lut_idx = 0;
   uint32_t uv_sep_lut_idx = 0;

   HWDetailEnhanceData detail_enhance;
 };

 struct HWDestScaleInfo {
   uint32_t mixer_width = 0;
   uint32_t mixer_height = 0;
   bool scale_update = false;
   HWScaleData scale_data = {};
 };

 typedef std::map<uint32_t, HWDestScaleInfo *> DestScaleInfoMap;

 struct HWAVRInfo {
   bool enable = false;                // Flag to Enable AVR feature
   HWAVRModes mode = kContinuousMode;  // Specifies the AVR mode
 };

 struct HWPipeInfo {
   uint32_t pipe_id = 0;
   HWSubBlockType sub_block_type = kHWSubBlockMax;
   LayerRect src_roi;
   LayerRect dst_roi;
   uint8_t horizontal_decimation = 0;
   uint8_t vertical_decimation = 0;
   HWScaleData scale_data;
   uint32_t z_order = 0;
   uint8_t flags = 0;
   bool valid = false;

   void Reset() { *this = HWPipeInfo(); }
 };

 struct HWLayerConfig {
   HWPipeInfo left_pipe;           // pipe for left side of output
   HWPipeInfo right_pipe;          // pipe for right side of output
   HWRotatorSession hw_rotator_session;
   float compression = 1.0f;

   void Reset() { *this = HWLayerConfig(); }
 };

 struct HWLayersInfo {
   LayerStack *stack = NULL;        // Input layer stack. Set by the caller.
   uint32_t app_layer_count = 0;    // Total number of app layers. Must not be 0.
   uint32_t gpu_target_index = 0;   // GPU target layer index. 0 if not present.

   std::vector<Layer> hw_layers = {};  // Layers which need to be programmed on the HW

   uint32_t index[kMaxSDELayers];   // Indexes of the layers from the layer stack which need to be
                                    // programmed on hardware.
   uint32_t roi_index[kMaxSDELayers] = {0};  // Stores the ROI index where the layers are visible.

   int sync_handle = -1;

   std::vector<LayerRect> left_frame_roi;   // Left ROI.
   std::vector<LayerRect> right_frame_roi;  // Right ROI.

   bool roi_split = false;          // Indicates separated left and right ROI

   bool use_hw_cursor = false;      // Indicates that HWCursor pipe needs to be used for cursor layer
   DestScaleInfoMap dest_scale_info_map = {};
 };

 struct HWLayers {
   HWLayersInfo info;
   HWLayerConfig config[kMaxSDELayers];
   float output_compression = 1.0f;
   uint32_t bandwidth = 0;
   uint32_t clock = 0;
   HWAVRInfo hw_avr_info = {};
 };

 struct HWDisplayAttributes : DisplayConfigVariableInfo {
   bool is_device_split = false;
   uint32_t v_front_porch = 0;  //!< Vertical front porch of panel
   uint32_t v_back_porch = 0;   //!< Vertical back porch of panel
   uint32_t v_pulse_width = 0;  //!< Vertical pulse width of panel
   uint32_t h_total = 0;        //!< Total width of panel (hActive + hFP + hBP + hPulseWidth)
   uint32_t v_total = 0;        //!< Total height of panel (vActive + vFP + vBP + vPulseWidth)
   std::bitset<32> s3d_config;  //!< Stores the bit mask of S3D modes

   void Reset() { *this = HWDisplayAttributes(); }

   bool operator !=(const HWDisplayAttributes &display_attributes) {
     return ((is_device_split != display_attributes.is_device_split) ||
             (x_pixels != display_attributes.x_pixels) ||
             (y_pixels != display_attributes.y_pixels) ||
             (x_dpi != display_attributes.x_dpi) ||
             (y_dpi != display_attributes.y_dpi) ||
             (fps != display_attributes.fps) ||
             (vsync_period_ns != display_attributes.vsync_period_ns) ||
             (v_front_porch != display_attributes.v_front_porch) ||
             (v_back_porch != display_attributes.v_back_porch) ||
             (v_pulse_width != display_attributes.v_pulse_width) ||
             (h_total != display_attributes.h_total) ||
             (is_yuv != display_attributes.is_yuv));
   }

   bool operator ==(const HWDisplayAttributes &display_attributes) {
     return !(operator !=(display_attributes));
   }
 };

 struct HWMixerAttributes {
   uint32_t width = 0;                                  // Layer mixer width
   uint32_t height = 0;                                 // Layer mixer height
   uint32_t split_left = 0;
   LayerBufferFormat output_format = kFormatRGB101010;  // Layer mixer output format

   bool operator !=(const HWMixerAttributes &mixer_attributes) {
     return ((width != mixer_attributes.width) ||
             (height != mixer_attributes.height) ||
             (output_format != mixer_attributes.output_format) ||
             (split_left != mixer_attributes.split_left));
   }

   bool operator ==(const HWMixerAttributes &mixer_attributes) {
     return !(operator !=(mixer_attributes));
   }

   bool IsValid() {
     return (width > 0 && height > 0);
   }
 };

 }  // namespace sdm

 #endif  // __HW_INFO_TYPES_H__
	/*
	* Copyright (c) 2015-2017, The Linux Foundation. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without modification, are permitted
	* provided that the following conditions are met:
	* * Redistributions of source code must retain the above copyright notice, this list of
	* conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright notice, this list of
	* conditions and the following disclaimer in the documentation and/or other materials provided
	* with the distribution.
	* * Neither the name of The Linux Foundation nor the names of its contributors may be used to
	* endorse or promote products derived from this software without specific prior written
	* permission.
	*
	* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
	* NON-INFRINGEMENT ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
	* OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
	* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#ifndef __HW_INFO_TYPES_H__
	#define __HW_INFO_TYPES_H__

	#include <stdint.h>
	#include <core/display_interface.h>
	#include <core/core_interface.h>
	#include <vector>
	#include <map>
	#include <string>
	#include <bitset>

	namespace sdm {
	using std::string;

	const int kMaxSDELayers = 16; // Maximum number of layers that can be handled by hardware in a
	// given layer stack.
	#define MAX_PLANES 4

	#define MAX_DETAIL_ENHANCE_CURVE 3

	enum HWDeviceType {
	kDevicePrimary,
	kDeviceHDMI,
	kDeviceVirtual,
	kDeviceRotator,
	kDeviceMax,
	};

	enum HWBlockType {
	kHWPrimary,
	kHWHDMI,
	kHWWriteback0,
	kHWWriteback1,
	kHWWriteback2,
	kHWBlockMax
	};

	enum HWDisplayMode {
	kModeDefault,
	kModeVideo,
	kModeCommand,
	};

	enum PipeType {
	kPipeTypeUnused,
	kPipeTypeVIG,
	kPipeTypeRGB,
	kPipeTypeDMA,
	kPipeTypeCursor,
	};

	enum HWSubBlockType {
	kHWVIGPipe,
	kHWRGBPipe,
	kHWDMAPipe,
	kHWCursorPipe,
	kHWRotatorInput,
	kHWRotatorOutput,
	kHWWBIntfOutput,
	kHWDestinationScalar,
	kHWSubBlockMax,
	};

	enum HWAlphaInterpolation {
	kInterpolationPixelRepeat,
	kInterpolationBilinear,
	kInterpolationMax,
	};

	enum HWBlendingFilter {
	kBlendFilterCircular,
	kBlendFilterSeparable,
	kBlendFilterMax,
	};

	enum HWPipeFlags {
	kIGC = 0x01,
	kMultiRect = 0x02,
	kMultiRectParallelMode = 0x04,
	};

	enum HWAVRModes {
	kContinuousMode, // Mode to enable AVR feature for every frame.
	kOneShotMode, // Mode to enable AVR feature for particular frame.
	};

	typedef std::map<HWSubBlockType, std::vector<LayerBufferFormat>> FormatsMap;

	struct HWDynBwLimitInfo {
	uint32_t cur_mode = kBwDefault;
	uint32_t total_bw_limit[kBwModeMax] = { 0 };
	uint32_t pipe_bw_limit[kBwModeMax] = { 0 };
	};

	struct HWPipeCaps {
	PipeType type = kPipeTypeUnused;
	uint32_t id = 0;
	uint32_t max_rects = 1;
	};

	struct HWRotatorInfo {
	enum { ROT_TYPE_MDSS, ROT_TYPE_V4L2 };
	uint32_t type = ROT_TYPE_MDSS;
	uint32_t num_rotator = 0;
	bool has_downscale = false;
	std::string device_path = "";
	float min_downscale = 2.0f;
	bool downscale_compression = false;

	void Reset() { *this = HWRotatorInfo(); }
	};

	struct HWDestScalarInfo {
	uint32_t count = 0;
	uint32_t max_input_width = 0;
	uint32_t max_output_width = 0;
	uint32_t max_scale_up = 1;
	};

	struct HWResourceInfo {
	uint32_t hw_version = 0;
	uint32_t hw_revision = 0;
	uint32_t num_dma_pipe = 0;
	uint32_t num_vig_pipe = 0;
	uint32_t num_rgb_pipe = 0;
	uint32_t num_cursor_pipe = 0;
	uint32_t num_blending_stages = 0;
	uint32_t num_control = 0;
	uint32_t num_mixer_to_disp = 0;
	uint32_t smp_total = 0;
	uint32_t smp_size = 0;
	uint32_t num_smp_per_pipe = 0;
	uint32_t max_scale_up = 1;
	uint32_t max_scale_down = 1;
	uint64_t max_bandwidth_low = 0;
	uint64_t max_bandwidth_high = 0;
	uint32_t max_mixer_width = 2048;
	uint32_t max_pipe_width = 2048;
	uint32_t max_cursor_size = 0;
	uint32_t max_pipe_bw = 0;
	uint32_t max_sde_clk = 0;
	float clk_fudge_factor = 1.0f;
	uint32_t macrotile_nv12_factor = 0;
	uint32_t macrotile_factor = 0;
	uint32_t linear_factor = 0;
	uint32_t scale_factor = 0;
	uint32_t extra_fudge_factor = 0;
	uint32_t amortizable_threshold = 0;
	uint32_t system_overhead_lines = 0;
	bool has_bwc = false;
	bool has_ubwc = false;
	bool has_decimation = false;
	bool has_macrotile = false;
	bool has_non_scalar_rgb = false;
	bool is_src_split = false;
	bool perf_calc = false;
	bool has_dyn_bw_support = false;
	bool separate_rotator = false;
	bool has_qseed3 = false;
	bool has_concurrent_writeback = false;
	bool has_ppp = false;
	uint32_t writeback_index = kHWBlockMax;
	HWDynBwLimitInfo dyn_bw_info;
	std::vector<HWPipeCaps> hw_pipes;
	FormatsMap supported_formats_map;
	HWRotatorInfo hw_rot_info;
	HWDestScalarInfo hw_dest_scalar_info;
	bool has_avr = false;
	bool has_hdr = false;

	void Reset() { *this = HWResourceInfo(); }
	};

	struct HWSplitInfo {
	uint32_t left_split = 0;
	uint32_t right_split = 0;

	bool operator !=(const HWSplitInfo &split_info) {
	return ((left_split != split_info.left_split) \|\| (right_split != split_info.right_split));
	}

	bool operator ==(const HWSplitInfo &split_info) {
	return !(operator !=(split_info));
	}
	};

	enum HWS3DMode {
	kS3DModeNone,
	kS3DModeLR,
	kS3DModeRL,
	kS3DModeTB,
	kS3DModeFP,
	kS3DModeMax,
	};

	struct HWColorPrimaries {
	uint32_t white_point[2] = {}; // White point
	uint32_t red[2] = {}; // Red color primary
	uint32_t green[2] = {}; // Green color primary
	uint32_t blue[2] = {}; // Blue color primary
	};

	struct HWPanelOrientation {
	bool rotation = false;
	bool flip_horizontal = false;
	bool flip_vertical = false;
	};

	struct HWPanelInfo {
	DisplayPort port = kPortDefault; // Display port
	HWDisplayMode mode = kModeDefault; // Display mode
	bool partial_update = false; // Partial update feature
	int left_align = 0; // ROI left alignment restriction
	int width_align = 0; // ROI width alignment restriction
	int top_align = 0; // ROI top alignment restriction
	int height_align = 0; // ROI height alignment restriction
	int min_roi_width = 0; // Min width needed for ROI
	int min_roi_height = 0; // Min height needed for ROI
	bool needs_roi_merge = false; // Merge ROI's of both the DSI's
	bool dynamic_fps = false; // Panel Supports dynamic fps
	bool dfps_porch_mode = false; // dynamic fps VFP or HFP mode
	bool ping_pong_split = false; // Supports Ping pong split
	uint32_t min_fps = 0; // Min fps supported by panel
	uint32_t max_fps = 0; // Max fps supported by panel
	bool is_primary_panel = false; // Panel is primary display
	bool is_pluggable = false; // Panel is pluggable
	HWSplitInfo split_info; // Panel split configuration
	char panel_name[256] = {0}; // Panel name
	HWS3DMode s3d_mode = kS3DModeNone; // Panel's current s3d mode.
	int panel_max_brightness = 0; // Max panel brightness
	uint32_t left_roi_count = 1; // Number if ROI supported on left panel
	uint32_t right_roi_count = 1; // Number if ROI supported on right panel
	bool hdr_enabled = false; // HDR feature supported
	uint32_t peak_luminance = 0; // Panel's peak luminance level
	uint32_t average_luminance = 0; // Panel's average luminance level
	uint32_t blackness_level = 0; // Panel's blackness level
	HWColorPrimaries primaries = {}; // WRGB color primaries
	HWPanelOrientation panel_orientation = {}; // Panel Orientation

	bool operator !=(const HWPanelInfo &panel_info) {
	return ((port != panel_info.port) \|\| (mode != panel_info.mode) \|\|
	(partial_update != panel_info.partial_update) \|\|
	(left_align != panel_info.left_align) \|\| (width_align != panel_info.width_align) \|\|
	(top_align != panel_info.top_align) \|\| (height_align != panel_info.height_align) \|\|
	(min_roi_width != panel_info.min_roi_width) \|\|
	(min_roi_height != panel_info.min_roi_height) \|\|
	(needs_roi_merge != panel_info.needs_roi_merge) \|\|
	(dynamic_fps != panel_info.dynamic_fps) \|\| (min_fps != panel_info.min_fps) \|\|
	(dfps_porch_mode != panel_info.dfps_porch_mode) \|\|
	(ping_pong_split != panel_info.ping_pong_split) \|\|
	(max_fps != panel_info.max_fps) \|\| (is_primary_panel != panel_info.is_primary_panel) \|\|
	(split_info != panel_info.split_info) \|\| (s3d_mode != panel_info.s3d_mode) \|\|
	(left_roi_count != panel_info.left_roi_count) \|\|
	(right_roi_count != panel_info.right_roi_count));
	}

	bool operator ==(const HWPanelInfo &panel_info) {
	return !(operator !=(panel_info));
	}
	};

	struct HWSessionConfig {
	LayerRect src_rect;
	LayerRect dst_rect;
	uint32_t buffer_count = 0;
	bool secure = false;
	uint32_t frame_rate = 0;
	LayerTransform transform;
	bool secure_camera = false;

	bool operator==(const HWSessionConfig& config) const {
	return (src_rect == config.src_rect &&
	dst_rect == config.dst_rect &&
	buffer_count == config.buffer_count &&
	secure == config.secure &&
	frame_rate == config.frame_rate &&
	transform == config.transform &&
	secure_camera == config.secure_camera);
	}

	bool operator!=(const HWSessionConfig& config) const {
	return !operator==(config);
	}
	};

	struct HWRotateInfo {
	int pipe_id = -1; // Not actual pipe id, but the relative DMA id
	int writeback_id = -1; // Writeback block id, but this is the same as DMA id
	LayerRect src_roi; // Source crop of each split
	LayerRect dst_roi; // Destination crop of each split
	bool valid = false;
	int rotate_id = -1; // Actual rotator session id with driver

	void Reset() { *this = HWRotateInfo(); }
	};

	struct HWRotatorSession {
	HWRotateInfo hw_rotate_info[kMaxRotatePerLayer];
	uint32_t hw_block_count = 0; // number of rotator hw blocks used by rotator session
	int session_id = -1; // A handle with Session Manager
	HWSessionConfig hw_session_config;
	LayerBuffer input_buffer; // Input to rotator
	LayerBuffer output_buffer; // Output of rotator, crop width and stride are same
	float input_compression = 1.0f;
	float output_compression = 1.0f;
	bool is_buffer_cached = false;
	};

	struct HWScaleLutInfo {
	uint32_t dir_lut_size = 0;
	uint32_t cir_lut_size = 0;
	uint32_t sep_lut_size = 0;
	uint64_t dir_lut = 0;
	uint64_t cir_lut = 0;
	uint64_t sep_lut = 0;
	};

	struct HWDetailEnhanceData : DisplayDetailEnhancerData {
	uint16_t prec_shift = 0;
	int16_t adjust_a[MAX_DETAIL_ENHANCE_CURVE] = {0};
	int16_t adjust_b[MAX_DETAIL_ENHANCE_CURVE] = {0};
	int16_t adjust_c[MAX_DETAIL_ENHANCE_CURVE] = {0};
	};

	struct HWPixelExtension {
	int32_t extension = 0; // Number of pixels extension in left, right, top and bottom directions
	// for all color components. This pixel value for each color component
	// should be sum of fetch and repeat pixels.

	int32_t overfetch = 0; // Number of pixels need to be overfetched in left, right, top and bottom
	// directions from source image for scaling.

	int32_t repeat = 0; // Number of pixels need to be repeated in left, right, top and bottom
	// directions for scaling.
	};

	struct HWPlane {
	int32_t init_phase_x = 0;
	int32_t phase_step_x = 0;
	int32_t init_phase_y = 0;
	int32_t phase_step_y = 0;
	HWPixelExtension left;
	HWPixelExtension top;
	HWPixelExtension right;
	HWPixelExtension bottom;
	uint32_t roi_width = 0;
	int32_t preload_x = 0;
	int32_t preload_y = 0;
	uint32_t src_width = 0;
	uint32_t src_height = 0;
	};

	struct HWScaleData {
	struct enable {
	uint8_t scale = 0;
	uint8_t direction_detection = 0;
	uint8_t detail_enhance = 0;
	} enable;
	uint32_t dst_width = 0;
	uint32_t dst_height = 0;
	HWPlane plane[MAX_PLANES];
	// scale_v2_data fields
	ScalingFilterConfig y_rgb_filter_cfg = kFilterEdgeDirected;
	ScalingFilterConfig uv_filter_cfg = kFilterEdgeDirected;
	HWAlphaInterpolation alpha_filter_cfg = kInterpolationPixelRepeat;
	HWBlendingFilter blend_cfg = kBlendFilterCircular;

	struct lut_flags {
	uint8_t lut_swap = 0;
	uint8_t lut_dir_wr = 0;
	uint8_t lut_y_cir_wr = 0;
	uint8_t lut_uv_cir_wr = 0;
	uint8_t lut_y_sep_wr = 0;
	uint8_t lut_uv_sep_wr = 0;
	} lut_flag;

	uint32_t dir_lut_idx = 0;
	/* for Y(RGB) and UV planes*/
	uint32_t y_rgb_cir_lut_idx = 0;
	uint32_t uv_cir_lut_idx = 0;
	uint32_t y_rgb_sep_lut_idx = 0;
	uint32_t uv_sep_lut_idx = 0;

	HWDetailEnhanceData detail_enhance;
	};

	struct HWDestScaleInfo {
	uint32_t mixer_width = 0;
	uint32_t mixer_height = 0;
	bool scale_update = false;
	HWScaleData scale_data = {};
	};

	typedef std::map<uint32_t, HWDestScaleInfo *> DestScaleInfoMap;

	struct HWAVRInfo {
	bool enable = false; // Flag to Enable AVR feature
	HWAVRModes mode = kContinuousMode; // Specifies the AVR mode
	};

	struct HWPipeInfo {
	uint32_t pipe_id = 0;
	HWSubBlockType sub_block_type = kHWSubBlockMax;
	LayerRect src_roi;
	LayerRect dst_roi;
	uint8_t horizontal_decimation = 0;
	uint8_t vertical_decimation = 0;
	HWScaleData scale_data;
	uint32_t z_order = 0;
	uint8_t flags = 0;
	bool valid = false;

	void Reset() { *this = HWPipeInfo(); }
	};

	struct HWLayerConfig {
	HWPipeInfo left_pipe; // pipe for left side of output
	HWPipeInfo right_pipe; // pipe for right side of output
	HWRotatorSession hw_rotator_session;
	float compression = 1.0f;

	void Reset() { *this = HWLayerConfig(); }
	};

	struct HWLayersInfo {
	LayerStack *stack = NULL; // Input layer stack. Set by the caller.
	uint32_t app_layer_count = 0; // Total number of app layers. Must not be 0.
	uint32_t gpu_target_index = 0; // GPU target layer index. 0 if not present.

	std::vector<Layer> hw_layers = {}; // Layers which need to be programmed on the HW

	uint32_t index[kMaxSDELayers]; // Indexes of the layers from the layer stack which need to be
	// programmed on hardware.
	uint32_t roi_index[kMaxSDELayers] = {0}; // Stores the ROI index where the layers are visible.

	int sync_handle = -1;

	std::vector<LayerRect> left_frame_roi; // Left ROI.
	std::vector<LayerRect> right_frame_roi; // Right ROI.

	bool roi_split = false; // Indicates separated left and right ROI

	bool use_hw_cursor = false; // Indicates that HWCursor pipe needs to be used for cursor layer
	DestScaleInfoMap dest_scale_info_map = {};
	};

	struct HWLayers {
	HWLayersInfo info;
	HWLayerConfig config[kMaxSDELayers];
	float output_compression = 1.0f;
	uint32_t bandwidth = 0;
	uint32_t clock = 0;
	HWAVRInfo hw_avr_info = {};
	};

	struct HWDisplayAttributes : DisplayConfigVariableInfo {
	bool is_device_split = false;
	uint32_t v_front_porch = 0; //!< Vertical front porch of panel
	uint32_t v_back_porch = 0; //!< Vertical back porch of panel
	uint32_t v_pulse_width = 0; //!< Vertical pulse width of panel
	uint32_t h_total = 0; //!< Total width of panel (hActive + hFP + hBP + hPulseWidth)
	uint32_t v_total = 0; //!< Total height of panel (vActive + vFP + vBP + vPulseWidth)
	std::bitset<32> s3d_config; //!< Stores the bit mask of S3D modes

	void Reset() { *this = HWDisplayAttributes(); }

	bool operator !=(const HWDisplayAttributes &display_attributes) {
	return ((is_device_split != display_attributes.is_device_split) \|\|
	(x_pixels != display_attributes.x_pixels) \|\|
	(y_pixels != display_attributes.y_pixels) \|\|
	(x_dpi != display_attributes.x_dpi) \|\|
	(y_dpi != display_attributes.y_dpi) \|\|
	(fps != display_attributes.fps) \|\|
	(vsync_period_ns != display_attributes.vsync_period_ns) \|\|
	(v_front_porch != display_attributes.v_front_porch) \|\|
	(v_back_porch != display_attributes.v_back_porch) \|\|
	(v_pulse_width != display_attributes.v_pulse_width) \|\|
	(h_total != display_attributes.h_total) \|\|
	(is_yuv != display_attributes.is_yuv));
	}

	bool operator ==(const HWDisplayAttributes &display_attributes) {
	return !(operator !=(display_attributes));
	}
	};

	struct HWMixerAttributes {
	uint32_t width = 0; // Layer mixer width
	uint32_t height = 0; // Layer mixer height
	uint32_t split_left = 0;
	LayerBufferFormat output_format = kFormatRGB101010; // Layer mixer output format

	bool operator !=(const HWMixerAttributes &mixer_attributes) {
	return ((width != mixer_attributes.width) \|\|
	(height != mixer_attributes.height) \|\|
	(output_format != mixer_attributes.output_format) \|\|
	(split_left != mixer_attributes.split_left));
	}

	bool operator ==(const HWMixerAttributes &mixer_attributes) {
	return !(operator !=(mixer_attributes));
	}

	bool IsValid() {
	return (width > 0 && height > 0);
	}
	};

	} // namespace sdm

	#endif // __HW_INFO_TYPES_H__