drivers/gpu/drm/amd/display/dc/dcn10/dcn10_cm_common.c - linux - Git at Google

 /*
  * Copyright 2016 Advanced Micro Devices, Inc.
  *
  * Permission is hereby granted, free of charge, to any person obtaining a
  * copy of this software and associated documentation files (the "Software"),
  * to deal in the Software without restriction, including without limitation
  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
  * and/or sell copies of the Software, and to permit persons to whom the
  * Software is furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in
  * all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
  * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
  * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
  * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
  * OTHER DEALINGS IN THE SOFTWARE.
  *
  * Authors: AMD
  *
  */
 #include "dc.h"
 #include "reg_helper.h"
 #include "dcn10_dpp.h"

 #include "dcn10_cm_common.h"
 #include "custom_float.h"

 #define REG(reg) reg

 #define CTX \
 	ctx

 #undef FN
 #define FN(reg_name, field_name) \
 	reg->shifts.field_name, reg->masks.field_name

 void cm_helper_program_color_matrices(
 		struct dc_context *ctx,
 		const uint16_t *regval,
 		const struct color_matrices_reg *reg)
 {
 	uint32_t cur_csc_reg;
 	unsigned int i = 0;

 	for (cur_csc_reg = reg->csc_c11_c12;
 			cur_csc_reg <= reg->csc_c33_c34;
 			cur_csc_reg++) {

 		const uint16_t *regval0 = &(regval[2 * i]);
 		const uint16_t *regval1 = &(regval[(2 * i) + 1]);

 		REG_SET_2(cur_csc_reg, 0,
 				csc_c11, *regval0,
 				csc_c12, *regval1);

 		i++;
 	}

 }

 void cm_helper_program_xfer_func(
 		struct dc_context *ctx,
 		const struct pwl_params *params,
 		const struct xfer_func_reg *reg)
 {
 	uint32_t reg_region_cur;
 	unsigned int i = 0;

 	REG_SET_2(reg->start_cntl_b, 0,
 			exp_region_start, params->arr_points[0].custom_float_x,
 			exp_resion_start_segment, 0);
 	REG_SET_2(reg->start_cntl_g, 0,
 			exp_region_start, params->arr_points[0].custom_float_x,
 			exp_resion_start_segment, 0);
 	REG_SET_2(reg->start_cntl_r, 0,
 			exp_region_start, params->arr_points[0].custom_float_x,
 			exp_resion_start_segment, 0);

 	REG_SET(reg->start_slope_cntl_b, 0,
 			field_region_linear_slope, params->arr_points[0].custom_float_slope);
 	REG_SET(reg->start_slope_cntl_g, 0,
 			field_region_linear_slope, params->arr_points[0].custom_float_slope);
 	REG_SET(reg->start_slope_cntl_r, 0,
 			field_region_linear_slope, params->arr_points[0].custom_float_slope);

 	REG_SET(reg->start_end_cntl1_b, 0,
 			field_region_end, params->arr_points[1].custom_float_x);
 	REG_SET_2(reg->start_end_cntl2_b, 0,
 			field_region_end_slope, params->arr_points[1].custom_float_slope,
 			field_region_end_base, params->arr_points[1].custom_float_y);

 	REG_SET(reg->start_end_cntl1_g, 0,
 			field_region_end, params->arr_points[1].custom_float_x);
 	REG_SET_2(reg->start_end_cntl2_g, 0,
 			field_region_end_slope, params->arr_points[1].custom_float_slope,
 		field_region_end_base, params->arr_points[1].custom_float_y);

 	REG_SET(reg->start_end_cntl1_r, 0,
 			field_region_end, params->arr_points[1].custom_float_x);
 	REG_SET_2(reg->start_end_cntl2_r, 0,
 			field_region_end_slope, params->arr_points[1].custom_float_slope,
 		field_region_end_base, params->arr_points[1].custom_float_y);

 	for (reg_region_cur = reg->region_start;
 			reg_region_cur <= reg->region_end;
 			reg_region_cur++) {

 		const struct gamma_curve *curve0 = &(params->arr_curve_points[2 * i]);
 		const struct gamma_curve *curve1 = &(params->arr_curve_points[(2 * i) + 1]);

 		REG_SET_4(reg_region_cur, 0,
 				exp_region0_lut_offset, curve0->offset,
 				exp_region0_num_segments, curve0->segments_num,
 				exp_region1_lut_offset, curve1->offset,
 				exp_region1_num_segments, curve1->segments_num);

 		i++;
 	}

 }


 bool cm_helper_convert_to_custom_float(
 		struct pwl_result_data *rgb_resulted,
 		struct curve_points *arr_points,
 		uint32_t hw_points_num,
 		bool fixpoint)
 {
 	struct custom_float_format fmt;

 	struct pwl_result_data *rgb = rgb_resulted;

 	uint32_t i = 0;

 	fmt.exponenta_bits = 6;
 	fmt.mantissa_bits = 12;
 	fmt.sign = false;

 	if (!convert_to_custom_float_format(arr_points[0].x, &fmt,
 					    &arr_points[0].custom_float_x)) {
 		BREAK_TO_DEBUGGER();
 		return false;
 	}

 	if (!convert_to_custom_float_format(arr_points[0].offset, &fmt,
 					    &arr_points[0].custom_float_offset)) {
 		BREAK_TO_DEBUGGER();
 		return false;
 	}

 	if (!convert_to_custom_float_format(arr_points[0].slope, &fmt,
 					    &arr_points[0].custom_float_slope)) {
 		BREAK_TO_DEBUGGER();
 		return false;
 	}

 	fmt.mantissa_bits = 10;
 	fmt.sign = false;

 	if (!convert_to_custom_float_format(arr_points[1].x, &fmt,
 					    &arr_points[1].custom_float_x)) {
 		BREAK_TO_DEBUGGER();
 		return false;
 	}

 	if (fixpoint == true)
 		arr_points[1].custom_float_y = dal_fixed31_32_clamp_u0d14(arr_points[1].y);
 	else if (!convert_to_custom_float_format(arr_points[1].y, &fmt,
 		&arr_points[1].custom_float_y)) {
 		BREAK_TO_DEBUGGER();
 		return false;
 	}

 	if (!convert_to_custom_float_format(arr_points[1].slope, &fmt,
 					    &arr_points[1].custom_float_slope)) {
 		BREAK_TO_DEBUGGER();
 		return false;
 	}

 	if (hw_points_num == 0 || rgb_resulted == NULL || fixpoint == true)
 		return true;

 	fmt.mantissa_bits = 12;
 	fmt.sign = true;

 	while (i != hw_points_num) {
 		if (!convert_to_custom_float_format(rgb->red, &fmt,
 						    &rgb->red_reg)) {
 			BREAK_TO_DEBUGGER();
 			return false;
 		}

 		if (!convert_to_custom_float_format(rgb->green, &fmt,
 						    &rgb->green_reg)) {
 			BREAK_TO_DEBUGGER();
 			return false;
 		}

 		if (!convert_to_custom_float_format(rgb->blue, &fmt,
 						    &rgb->blue_reg)) {
 			BREAK_TO_DEBUGGER();
 			return false;
 		}

 		if (!convert_to_custom_float_format(rgb->delta_red, &fmt,
 						    &rgb->delta_red_reg)) {
 			BREAK_TO_DEBUGGER();
 			return false;
 		}

 		if (!convert_to_custom_float_format(rgb->delta_green, &fmt,
 						    &rgb->delta_green_reg)) {
 			BREAK_TO_DEBUGGER();
 			return false;
 		}

 		if (!convert_to_custom_float_format(rgb->delta_blue, &fmt,
 						    &rgb->delta_blue_reg)) {
 			BREAK_TO_DEBUGGER();
 			return false;
 		}

 		++rgb;
 		++i;
 	}

 	return true;
 }


 #define MAX_REGIONS_NUMBER 34
 #define MAX_LOW_POINT      25
 #define NUMBER_SEGMENTS    32

 bool cm_helper_translate_curve_to_hw_format(
 				const struct dc_transfer_func *output_tf,
 				struct pwl_params *lut_params, bool fixpoint)
 {
 	struct curve_points *arr_points;
 	struct pwl_result_data *rgb_resulted;
 	struct pwl_result_data *rgb;
 	struct pwl_result_data *rgb_plus_1;
 	struct fixed31_32 y_r;
 	struct fixed31_32 y_g;
 	struct fixed31_32 y_b;
 	struct fixed31_32 y1_min;
 	struct fixed31_32 y3_max;

 	int32_t segment_start, segment_end;
 	int32_t i;
 	uint32_t j, k, seg_distr[MAX_REGIONS_NUMBER], increment, start_index, hw_points;

 	if (output_tf == NULL || lut_params == NULL || output_tf->type == TF_TYPE_BYPASS)
 		return false;

 	PERF_TRACE();

 	arr_points = lut_params->arr_points;
 	rgb_resulted = lut_params->rgb_resulted;
 	hw_points = 0;

 	memset(lut_params, 0, sizeof(struct pwl_params));
 	memset(seg_distr, 0, sizeof(seg_distr));

 	if (output_tf->tf == TRANSFER_FUNCTION_PQ) {
 		/* 32 segments
 		 * segments are from 2^-25 to 2^7
 		 */
 		for (i = 0; i < 32 ; i++)
 			seg_distr[i] = 3;

 		segment_start = -25;
 		segment_end   = 7;
 	} else {
 		/* 10 segments
 		 * segment is from 2^-10 to 2^0
 		 * There are less than 256 points, for optimization
 		 */
 		seg_distr[0] = 3;
 		seg_distr[1] = 4;
 		seg_distr[2] = 4;
 		seg_distr[3] = 4;
 		seg_distr[4] = 4;
 		seg_distr[5] = 4;
 		seg_distr[6] = 4;
 		seg_distr[7] = 4;
 		seg_distr[8] = 5;
 		seg_distr[9] = 5;

 		segment_start = -10;
 		segment_end = 0;
 	}

 	for (i = segment_end - segment_start; i < MAX_REGIONS_NUMBER ; i++)
 		seg_distr[i] = -1;

 	for (k = 0; k < MAX_REGIONS_NUMBER; k++) {
 		if (seg_distr[k] != -1)
 			hw_points += (1 << seg_distr[k]);
 	}

 	j = 0;
 	for (k = 0; k < (segment_end - segment_start); k++) {
 		increment = NUMBER_SEGMENTS / (1 << seg_distr[k]);
 		start_index = (segment_start + k + MAX_LOW_POINT) * NUMBER_SEGMENTS;
 		for (i = start_index; i < start_index + NUMBER_SEGMENTS; i += increment) {
 			if (j == hw_points - 1)
 				break;
 			rgb_resulted[j].red = output_tf->tf_pts.red[i];
 			rgb_resulted[j].green = output_tf->tf_pts.green[i];
 			rgb_resulted[j].blue = output_tf->tf_pts.blue[i];
 			j++;
 		}
 	}

 	/* last point */
 	start_index = (segment_end + MAX_LOW_POINT) * NUMBER_SEGMENTS;
 	rgb_resulted[hw_points - 1].red = output_tf->tf_pts.red[start_index];
 	rgb_resulted[hw_points - 1].green = output_tf->tf_pts.green[start_index];
 	rgb_resulted[hw_points - 1].blue = output_tf->tf_pts.blue[start_index];

 	arr_points[0].x = dal_fixed31_32_pow(dal_fixed31_32_from_int(2),
 					     dal_fixed31_32_from_int(segment_start));
 	arr_points[1].x = dal_fixed31_32_pow(dal_fixed31_32_from_int(2),
 					     dal_fixed31_32_from_int(segment_end));

 	y_r = rgb_resulted[0].red;
 	y_g = rgb_resulted[0].green;
 	y_b = rgb_resulted[0].blue;

 	y1_min = dal_fixed31_32_min(y_r, dal_fixed31_32_min(y_g, y_b));

 	arr_points[0].y = y1_min;
 	arr_points[0].slope = dal_fixed31_32_div(arr_points[0].y, arr_points[0].x);
 	y_r = rgb_resulted[hw_points - 1].red;
 	y_g = rgb_resulted[hw_points - 1].green;
 	y_b = rgb_resulted[hw_points - 1].blue;

 	/* see comment above, m_arrPoints[1].y should be the Y value for the
 	 * region end (m_numOfHwPoints), not last HW point(m_numOfHwPoints - 1)
 	 */
 	y3_max = dal_fixed31_32_max(y_r, dal_fixed31_32_max(y_g, y_b));

 	arr_points[1].y = y3_max;

 	arr_points[1].slope = dal_fixed31_32_zero;

 	if (output_tf->tf == TRANSFER_FUNCTION_PQ) {
 		/* for PQ, we want to have a straight line from last HW X point,
 		 * and the slope to be such that we hit 1.0 at 10000 nits.
 		 */
 		const struct fixed31_32 end_value =
 				dal_fixed31_32_from_int(125);

 		arr_points[1].slope = dal_fixed31_32_div(
 			dal_fixed31_32_sub(dal_fixed31_32_one, arr_points[1].y),
 			dal_fixed31_32_sub(end_value, arr_points[1].x));
 	}

 	lut_params->hw_points_num = hw_points;

 	i = 1;
 	for (k = 0; k < MAX_REGIONS_NUMBER && i < MAX_REGIONS_NUMBER; k++) {
 		if (seg_distr[k] != -1) {
 			lut_params->arr_curve_points[k].segments_num =
 					seg_distr[k];
 			lut_params->arr_curve_points[i].offset =
 					lut_params->arr_curve_points[k].offset + (1 << seg_distr[k]);
 		}
 		i++;
 	}

 	if (seg_distr[k] != -1)
 		lut_params->arr_curve_points[k].segments_num = seg_distr[k];

 	rgb = rgb_resulted;
 	rgb_plus_1 = rgb_resulted + 1;

 	i = 1;
 	while (i != hw_points + 1) {
 		if (dal_fixed31_32_lt(rgb_plus_1->red, rgb->red))
 			rgb_plus_1->red = rgb->red;
 		if (dal_fixed31_32_lt(rgb_plus_1->green, rgb->green))
 			rgb_plus_1->green = rgb->green;
 		if (dal_fixed31_32_lt(rgb_plus_1->blue, rgb->blue))
 			rgb_plus_1->blue = rgb->blue;

 		rgb->delta_red   = dal_fixed31_32_sub(rgb_plus_1->red,   rgb->red);
 		rgb->delta_green = dal_fixed31_32_sub(rgb_plus_1->green, rgb->green);
 		rgb->delta_blue  = dal_fixed31_32_sub(rgb_plus_1->blue,  rgb->blue);

 		if (fixpoint == true) {
 			rgb->delta_red_reg   = dal_fixed31_32_clamp_u0d10(rgb->delta_red);
 			rgb->delta_green_reg = dal_fixed31_32_clamp_u0d10(rgb->delta_green);
 			rgb->delta_blue_reg  = dal_fixed31_32_clamp_u0d10(rgb->delta_blue);
 			rgb->red_reg         = dal_fixed31_32_clamp_u0d14(rgb->red);
 			rgb->green_reg       = dal_fixed31_32_clamp_u0d14(rgb->green);
 			rgb->blue_reg        = dal_fixed31_32_clamp_u0d14(rgb->blue);
 		}

 		++rgb_plus_1;
 		++rgb;
 		++i;
 	}
 	cm_helper_convert_to_custom_float(rgb_resulted,
 						lut_params->arr_points,
 						hw_points, fixpoint);

 	return true;
 }
	/*
	* Copyright 2016 Advanced Micro Devices, Inc.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a
	* copy of this software and associated documentation files (the "Software"),
	* to deal in the Software without restriction, including without limitation
	* the rights to use, copy, modify, merge, publish, distribute, sublicense,
	* and/or sell copies of the Software, and to permit persons to whom the
	* Software is furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
	* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
	* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
	* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
	* OTHER DEALINGS IN THE SOFTWARE.
	*
	* Authors: AMD
	*
	*/
	#include "dc.h"
	#include "reg_helper.h"
	#include "dcn10_dpp.h"

	#include "dcn10_cm_common.h"
	#include "custom_float.h"

	#define REG(reg) reg

	#define CTX \
	ctx

	#undef FN
	#define FN(reg_name, field_name) \
	reg->shifts.field_name, reg->masks.field_name

	void cm_helper_program_color_matrices(
	struct dc_context *ctx,
	const uint16_t *regval,
	const struct color_matrices_reg *reg)
	{
	uint32_t cur_csc_reg;
	unsigned int i = 0;

	for (cur_csc_reg = reg->csc_c11_c12;
	cur_csc_reg <= reg->csc_c33_c34;
	cur_csc_reg++) {

	const uint16_t regval0 = &(regval[2 i]);
	const uint16_t regval1 = &(regval[(2 i) + 1]);

	REG_SET_2(cur_csc_reg, 0,
	csc_c11, *regval0,
	csc_c12, *regval1);

	i++;
	}

	}

	void cm_helper_program_xfer_func(
	struct dc_context *ctx,
	const struct pwl_params *params,
	const struct xfer_func_reg *reg)
	{
	uint32_t reg_region_cur;
	unsigned int i = 0;

	REG_SET_2(reg->start_cntl_b, 0,
	exp_region_start, params->arr_points[0].custom_float_x,
	exp_resion_start_segment, 0);
	REG_SET_2(reg->start_cntl_g, 0,
	exp_region_start, params->arr_points[0].custom_float_x,
	exp_resion_start_segment, 0);
	REG_SET_2(reg->start_cntl_r, 0,
	exp_region_start, params->arr_points[0].custom_float_x,
	exp_resion_start_segment, 0);

	REG_SET(reg->start_slope_cntl_b, 0,
	field_region_linear_slope, params->arr_points[0].custom_float_slope);
	REG_SET(reg->start_slope_cntl_g, 0,
	field_region_linear_slope, params->arr_points[0].custom_float_slope);
	REG_SET(reg->start_slope_cntl_r, 0,
	field_region_linear_slope, params->arr_points[0].custom_float_slope);

	REG_SET(reg->start_end_cntl1_b, 0,
	field_region_end, params->arr_points[1].custom_float_x);
	REG_SET_2(reg->start_end_cntl2_b, 0,
	field_region_end_slope, params->arr_points[1].custom_float_slope,
	field_region_end_base, params->arr_points[1].custom_float_y);

	REG_SET(reg->start_end_cntl1_g, 0,
	field_region_end, params->arr_points[1].custom_float_x);
	REG_SET_2(reg->start_end_cntl2_g, 0,
	field_region_end_slope, params->arr_points[1].custom_float_slope,
	field_region_end_base, params->arr_points[1].custom_float_y);

	REG_SET(reg->start_end_cntl1_r, 0,
	field_region_end, params->arr_points[1].custom_float_x);
	REG_SET_2(reg->start_end_cntl2_r, 0,
	field_region_end_slope, params->arr_points[1].custom_float_slope,
	field_region_end_base, params->arr_points[1].custom_float_y);

	for (reg_region_cur = reg->region_start;
	reg_region_cur <= reg->region_end;
	reg_region_cur++) {

	const struct gamma_curve curve0 = &(params->arr_curve_points[2 i]);
	const struct gamma_curve curve1 = &(params->arr_curve_points[(2 i) + 1]);

	REG_SET_4(reg_region_cur, 0,
	exp_region0_lut_offset, curve0->offset,
	exp_region0_num_segments, curve0->segments_num,
	exp_region1_lut_offset, curve1->offset,
	exp_region1_num_segments, curve1->segments_num);

	i++;
	}

	}



	bool cm_helper_convert_to_custom_float(
	struct pwl_result_data *rgb_resulted,
	struct curve_points *arr_points,
	uint32_t hw_points_num,
	bool fixpoint)
	{
	struct custom_float_format fmt;

	struct pwl_result_data *rgb = rgb_resulted;

	uint32_t i = 0;

	fmt.exponenta_bits = 6;
	fmt.mantissa_bits = 12;
	fmt.sign = false;

	if (!convert_to_custom_float_format(arr_points[0].x, &fmt,
	&arr_points[0].custom_float_x)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(arr_points[0].offset, &fmt,
	&arr_points[0].custom_float_offset)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(arr_points[0].slope, &fmt,
	&arr_points[0].custom_float_slope)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	fmt.mantissa_bits = 10;
	fmt.sign = false;

	if (!convert_to_custom_float_format(arr_points[1].x, &fmt,
	&arr_points[1].custom_float_x)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (fixpoint == true)
	arr_points[1].custom_float_y = dal_fixed31_32_clamp_u0d14(arr_points[1].y);
	else if (!convert_to_custom_float_format(arr_points[1].y, &fmt,
	&arr_points[1].custom_float_y)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(arr_points[1].slope, &fmt,
	&arr_points[1].custom_float_slope)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (hw_points_num == 0 \|\| rgb_resulted == NULL \|\| fixpoint == true)
	return true;

	fmt.mantissa_bits = 12;
	fmt.sign = true;

	while (i != hw_points_num) {
	if (!convert_to_custom_float_format(rgb->red, &fmt,
	&rgb->red_reg)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(rgb->green, &fmt,
	&rgb->green_reg)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(rgb->blue, &fmt,
	&rgb->blue_reg)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(rgb->delta_red, &fmt,
	&rgb->delta_red_reg)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(rgb->delta_green, &fmt,
	&rgb->delta_green_reg)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	if (!convert_to_custom_float_format(rgb->delta_blue, &fmt,
	&rgb->delta_blue_reg)) {
	BREAK_TO_DEBUGGER();
	return false;
	}

	++rgb;
	++i;
	}

	return true;
	}


	#define MAX_REGIONS_NUMBER 34
	#define MAX_LOW_POINT 25
	#define NUMBER_SEGMENTS 32

	bool cm_helper_translate_curve_to_hw_format(
	const struct dc_transfer_func *output_tf,
	struct pwl_params *lut_params, bool fixpoint)
	{
	struct curve_points *arr_points;
	struct pwl_result_data *rgb_resulted;
	struct pwl_result_data *rgb;
	struct pwl_result_data *rgb_plus_1;
	struct fixed31_32 y_r;
	struct fixed31_32 y_g;
	struct fixed31_32 y_b;
	struct fixed31_32 y1_min;
	struct fixed31_32 y3_max;

	int32_t segment_start, segment_end;
	int32_t i;
	uint32_t j, k, seg_distr[MAX_REGIONS_NUMBER], increment, start_index, hw_points;

	if (output_tf == NULL \|\| lut_params == NULL \|\| output_tf->type == TF_TYPE_BYPASS)
	return false;

	PERF_TRACE();

	arr_points = lut_params->arr_points;
	rgb_resulted = lut_params->rgb_resulted;
	hw_points = 0;

	memset(lut_params, 0, sizeof(struct pwl_params));
	memset(seg_distr, 0, sizeof(seg_distr));

	if (output_tf->tf == TRANSFER_FUNCTION_PQ) {
	/* 32 segments
	* segments are from 2^-25 to 2^7
	*/
	for (i = 0; i < 32 ; i++)
	seg_distr[i] = 3;

	segment_start = -25;
	segment_end = 7;
	} else {
	/* 10 segments
	* segment is from 2^-10 to 2^0
	* There are less than 256 points, for optimization
	*/
	seg_distr[0] = 3;
	seg_distr[1] = 4;
	seg_distr[2] = 4;
	seg_distr[3] = 4;
	seg_distr[4] = 4;
	seg_distr[5] = 4;
	seg_distr[6] = 4;
	seg_distr[7] = 4;
	seg_distr[8] = 5;
	seg_distr[9] = 5;

	segment_start = -10;
	segment_end = 0;
	}

	for (i = segment_end - segment_start; i < MAX_REGIONS_NUMBER ; i++)
	seg_distr[i] = -1;

	for (k = 0; k < MAX_REGIONS_NUMBER; k++) {
	if (seg_distr[k] != -1)
	hw_points += (1 << seg_distr[k]);
	}

	j = 0;
	for (k = 0; k < (segment_end - segment_start); k++) {
	increment = NUMBER_SEGMENTS / (1 << seg_distr[k]);
	start_index = (segment_start + k + MAX_LOW_POINT) * NUMBER_SEGMENTS;
	for (i = start_index; i < start_index + NUMBER_SEGMENTS; i += increment) {
	if (j == hw_points - 1)
	break;
	rgb_resulted[j].red = output_tf->tf_pts.red[i];
	rgb_resulted[j].green = output_tf->tf_pts.green[i];
	rgb_resulted[j].blue = output_tf->tf_pts.blue[i];
	j++;
	}
	}

	/* last point */
	start_index = (segment_end + MAX_LOW_POINT) * NUMBER_SEGMENTS;
	rgb_resulted[hw_points - 1].red = output_tf->tf_pts.red[start_index];
	rgb_resulted[hw_points - 1].green = output_tf->tf_pts.green[start_index];
	rgb_resulted[hw_points - 1].blue = output_tf->tf_pts.blue[start_index];

	arr_points[0].x = dal_fixed31_32_pow(dal_fixed31_32_from_int(2),
	dal_fixed31_32_from_int(segment_start));
	arr_points[1].x = dal_fixed31_32_pow(dal_fixed31_32_from_int(2),
	dal_fixed31_32_from_int(segment_end));

	y_r = rgb_resulted[0].red;
	y_g = rgb_resulted[0].green;
	y_b = rgb_resulted[0].blue;

	y1_min = dal_fixed31_32_min(y_r, dal_fixed31_32_min(y_g, y_b));

	arr_points[0].y = y1_min;
	arr_points[0].slope = dal_fixed31_32_div(arr_points[0].y, arr_points[0].x);
	y_r = rgb_resulted[hw_points - 1].red;
	y_g = rgb_resulted[hw_points - 1].green;
	y_b = rgb_resulted[hw_points - 1].blue;

	/* see comment above, m_arrPoints[1].y should be the Y value for the
	* region end (m_numOfHwPoints), not last HW point(m_numOfHwPoints - 1)
	*/
	y3_max = dal_fixed31_32_max(y_r, dal_fixed31_32_max(y_g, y_b));

	arr_points[1].y = y3_max;

	arr_points[1].slope = dal_fixed31_32_zero;

	if (output_tf->tf == TRANSFER_FUNCTION_PQ) {
	/* for PQ, we want to have a straight line from last HW X point,
	* and the slope to be such that we hit 1.0 at 10000 nits.
	*/
	const struct fixed31_32 end_value =
	dal_fixed31_32_from_int(125);

	arr_points[1].slope = dal_fixed31_32_div(
	dal_fixed31_32_sub(dal_fixed31_32_one, arr_points[1].y),
	dal_fixed31_32_sub(end_value, arr_points[1].x));
	}

	lut_params->hw_points_num = hw_points;

	i = 1;
	for (k = 0; k < MAX_REGIONS_NUMBER && i < MAX_REGIONS_NUMBER; k++) {
	if (seg_distr[k] != -1) {
	lut_params->arr_curve_points[k].segments_num =
	seg_distr[k];
	lut_params->arr_curve_points[i].offset =
	lut_params->arr_curve_points[k].offset + (1 << seg_distr[k]);
	}
	i++;
	}

	if (seg_distr[k] != -1)
	lut_params->arr_curve_points[k].segments_num = seg_distr[k];

	rgb = rgb_resulted;
	rgb_plus_1 = rgb_resulted + 1;

	i = 1;
	while (i != hw_points + 1) {
	if (dal_fixed31_32_lt(rgb_plus_1->red, rgb->red))
	rgb_plus_1->red = rgb->red;
	if (dal_fixed31_32_lt(rgb_plus_1->green, rgb->green))
	rgb_plus_1->green = rgb->green;
	if (dal_fixed31_32_lt(rgb_plus_1->blue, rgb->blue))
	rgb_plus_1->blue = rgb->blue;

	rgb->delta_red = dal_fixed31_32_sub(rgb_plus_1->red, rgb->red);
	rgb->delta_green = dal_fixed31_32_sub(rgb_plus_1->green, rgb->green);
	rgb->delta_blue = dal_fixed31_32_sub(rgb_plus_1->blue, rgb->blue);

	if (fixpoint == true) {
	rgb->delta_red_reg = dal_fixed31_32_clamp_u0d10(rgb->delta_red);
	rgb->delta_green_reg = dal_fixed31_32_clamp_u0d10(rgb->delta_green);
	rgb->delta_blue_reg = dal_fixed31_32_clamp_u0d10(rgb->delta_blue);
	rgb->red_reg = dal_fixed31_32_clamp_u0d14(rgb->red);
	rgb->green_reg = dal_fixed31_32_clamp_u0d14(rgb->green);
	rgb->blue_reg = dal_fixed31_32_clamp_u0d14(rgb->blue);
	}

	++rgb_plus_1;
	++rgb;
	++i;
	}
	cm_helper_convert_to_custom_float(rgb_resulted,
	lut_params->arr_points,
	hw_points, fixpoint);

	return true;
	}