@@ -1399,71 +1399,6 @@ static void scale_gamma_dx(struct pwl_float_data *pwl_rgb,
pwl_rgb[i-1].b, 2), pwl_rgb[i-2].b);
}
-/* todo: all these scale_gamma functions are inherently the same but
- * take different structures as params or different format for ramp
- * values. We could probably implement it in a more generic fashion
- */
-static void scale_user_regamma_ramp(struct pwl_float_data *pwl_rgb,
- const struct regamma_ramp *ramp,
- struct dividers dividers)
-{
- unsigned short max_driver = 0xFFFF;
- unsigned short max_os = 0xFF00;
- unsigned short scaler = max_os;
- uint32_t i;
- struct pwl_float_data *rgb = pwl_rgb;
- struct pwl_float_data *rgb_last = rgb + GAMMA_RGB_256_ENTRIES - 1;
-
- i = 0;
- do {
- if (ramp->gamma[i] > max_os ||
- ramp->gamma[i + 256] > max_os ||
- ramp->gamma[i + 512] > max_os) {
- scaler = max_driver;
- break;
- }
- i++;
- } while (i != GAMMA_RGB_256_ENTRIES);
-
- i = 0;
- do {
- rgb->r = dc_fixpt_from_fraction(
- ramp->gamma[i], scaler);
- rgb->g = dc_fixpt_from_fraction(
- ramp->gamma[i + 256], scaler);
- rgb->b = dc_fixpt_from_fraction(
- ramp->gamma[i + 512], scaler);
-
- ++rgb;
- ++i;
- } while (i != GAMMA_RGB_256_ENTRIES);
-
- rgb->r = dc_fixpt_mul(rgb_last->r,
- dividers.divider1);
- rgb->g = dc_fixpt_mul(rgb_last->g,
- dividers.divider1);
- rgb->b = dc_fixpt_mul(rgb_last->b,
- dividers.divider1);
-
- ++rgb;
-
- rgb->r = dc_fixpt_mul(rgb_last->r,
- dividers.divider2);
- rgb->g = dc_fixpt_mul(rgb_last->g,
- dividers.divider2);
- rgb->b = dc_fixpt_mul(rgb_last->b,
- dividers.divider2);
-
- ++rgb;
-
- rgb->r = dc_fixpt_mul(rgb_last->r,
- dividers.divider3);
- rgb->g = dc_fixpt_mul(rgb_last->g,
- dividers.divider3);
- rgb->b = dc_fixpt_mul(rgb_last->b,
- dividers.divider3);
-}
-
/*
* RS3+ color transform DDI - 1D LUT adjustment is composed with regamma here
* Input is evenly distributed in the output color space as specified in
@@ -1663,106 +1598,6 @@ static bool calculate_interpolated_hardware_curve(
return true;
}
-/* The "old" interpolation uses a complicated scheme to build an array of
- * coefficients while also using an array of 0-255 normalized to 0-1
- * Then there's another loop using both of the above + new scaled user ramp
- * and we concatenate them. It also searches for points of interpolation and
- * uses enums for positions.
- *
- * This function uses a different approach:
- * user ramp is always applied on X with 0/255, 1/255, 2/255, ..., 255/255
- * To find index for hwX , we notice the following:
- * i/255 <= hwX < (i+1)/255 <=> i <= 255*hwX < i+1
- * See apply_lut_1d which is the same principle, but on 4K entry 1D LUT
- *
- * Once the index is known, combined Y is simply:
- * user_ramp(index) + (hwX-index/255)*(user_ramp(index+1) - user_ramp(index)
- *
- * We should switch to this method in all cases, it's simpler and faster
- * ToDo one day - for now this only applies to ADL regamma to avoid regression
- * for regular use cases (sRGB and PQ)
- */
-static void interpolate_user_regamma(uint32_t hw_points_num,
- struct pwl_float_data *rgb_user,
- bool apply_degamma,
- struct dc_transfer_func_distributed_points *tf_pts)
-{
- uint32_t i;
- uint32_t color = 0;
- int32_t index;
- int32_t index_next;
- struct fixed31_32 *tf_point;
- struct fixed31_32 hw_x;
- struct fixed31_32 norm_factor =
- dc_fixpt_from_int(255);
- struct fixed31_32 norm_x;
- struct fixed31_32 index_f;
- struct fixed31_32 lut1;
- struct fixed31_32 lut2;
- struct fixed31_32 delta_lut;
- struct fixed31_32 delta_index;
- const struct fixed31_32 one = dc_fixpt_from_int(1);
-
- i = 0;
- /* fixed_pt library has problems handling too small values */
- while (i != 32) {
- tf_pts->red[i] = dc_fixpt_zero;
- tf_pts->green[i] = dc_fixpt_zero;
- tf_pts->blue[i] = dc_fixpt_zero;
- ++i;
- }
- while (i <= hw_points_num + 1) {
- for (color = 0; color < 3; color++) {
- if (color == 0)
- tf_point = &tf_pts->red[i];
- else if (color == 1)
- tf_point = &tf_pts->green[i];
- else
- tf_point = &tf_pts->blue[i];
-
- if (apply_degamma) {
- if (color == 0)
- hw_x = coordinates_x[i].regamma_y_red;
- else if (color == 1)
- hw_x = coordinates_x[i].regamma_y_green;
- else
- hw_x = coordinates_x[i].regamma_y_blue;
- } else
- hw_x = coordinates_x[i].x;
-
- if (dc_fixpt_le(one, hw_x))
- hw_x = one;
-
- norm_x = dc_fixpt_mul(norm_factor, hw_x);
- index = dc_fixpt_floor(norm_x);
- if (index < 0 || index > 255)
- continue;
-
- index_f = dc_fixpt_from_int(index);
- index_next = (index == 255) ? index : index + 1;
-
- if (color == 0) {
- lut1 = rgb_user[index].r;
- lut2 = rgb_user[index_next].r;
- } else if (color == 1) {
- lut1 = rgb_user[index].g;
- lut2 = rgb_user[index_next].g;
- } else {
- lut1 = rgb_user[index].b;
- lut2 = rgb_user[index_next].b;
- }
-
- // we have everything now, so interpolate
- delta_lut = dc_fixpt_sub(lut2, lut1);
- delta_index = dc_fixpt_sub(norm_x, index_f);
-
- *tf_point = dc_fixpt_add(lut1,
- dc_fixpt_mul(delta_index, delta_lut));
- }
- ++i;
- }
-}
-
static void build_new_custom_resulted_curve(
uint32_t hw_points_num,
struct dc_transfer_func_distributed_points *tf_pts)
@@ -1784,29 +1619,6 @@ static void build_new_custom_resulted_curve(
}
}
-static void apply_degamma_for_user_regamma(struct pwl_float_data_ex *rgb_regamma,
- uint32_t hw_points_num, struct calculate_buffer *cal_buffer)
-{
- uint32_t i;
-
- struct gamma_coefficients coeff;
- struct pwl_float_data_ex *rgb = rgb_regamma;
- const struct hw_x_point *coord_x = coordinates_x;
-
- build_coefficients(&coeff, TRANSFER_FUNCTION_SRGB);
-
- i = 0;
- while (i != hw_points_num + 1) {
- rgb->r = translate_from_linear_space_ex(
- coord_x->x, &coeff, 0, cal_buffer);
- rgb->g = rgb->r;
- rgb->b = rgb->r;
- ++coord_x;
- ++rgb;
- ++i;
- }
-}
-
static bool map_regamma_hw_to_x_user(
const struct dc_gamma *ramp,
struct pixel_gamma_point *coeff128,
@@ -1855,125 +1667,6 @@ static bool map_regamma_hw_to_x_user(
#define _EXTRA_POINTS 3
-bool calculate_user_regamma_coeff(struct dc_transfer_func *output_tf,
- const struct regamma_lut *regamma,
- struct calculate_buffer *cal_buffer,
- const struct dc_gamma *ramp)
-{
- struct gamma_coefficients coeff;
- const struct hw_x_point *coord_x = coordinates_x;
- uint32_t i = 0;
-
- do {
- coeff.a0[i] = dc_fixpt_from_fraction(
- regamma->coeff.A0[i], 10000000);
- coeff.a1[i] = dc_fixpt_from_fraction(
- regamma->coeff.A1[i], 1000);
- coeff.a2[i] = dc_fixpt_from_fraction(
- regamma->coeff.A2[i], 1000);
- coeff.a3[i] = dc_fixpt_from_fraction(
- regamma->coeff.A3[i], 1000);
- coeff.user_gamma[i] = dc_fixpt_from_fraction(
- regamma->coeff.gamma[i], 1000);
-
- ++i;
- } while (i != 3);
-
- i = 0;
- /* fixed_pt library has problems handling too small values */
- while (i != 32) {
- output_tf->tf_pts.red[i] = dc_fixpt_zero;
- output_tf->tf_pts.green[i] = dc_fixpt_zero;
- output_tf->tf_pts.blue[i] = dc_fixpt_zero;
- ++coord_x;
- ++i;
- }
- while (i != MAX_HW_POINTS + 1) {
- output_tf->tf_pts.red[i] = translate_from_linear_space_ex(
- coord_x->x, &coeff, 0, cal_buffer);
- output_tf->tf_pts.green[i] = translate_from_linear_space_ex(
- coord_x->x, &coeff, 1, cal_buffer);
- output_tf->tf_pts.blue[i] = translate_from_linear_space_ex(
- coord_x->x, &coeff, 2, cal_buffer);
- ++coord_x;
- ++i;
- }
-
- if (ramp && ramp->type == GAMMA_CS_TFM_1D)
- apply_lut_1d(ramp, MAX_HW_POINTS, &output_tf->tf_pts);
-
- // this function just clamps output to 0-1
- build_new_custom_resulted_curve(MAX_HW_POINTS, &output_tf->tf_pts);
- output_tf->type = TF_TYPE_DISTRIBUTED_POINTS;
-
- return true;
-}
-
-bool calculate_user_regamma_ramp(struct dc_transfer_func *output_tf,
- const struct regamma_lut *regamma,
- struct calculate_buffer *cal_buffer,
- const struct dc_gamma *ramp)
-{
- struct dc_transfer_func_distributed_points *tf_pts = &output_tf->tf_pts;
- struct dividers dividers;
-
- struct pwl_float_data *rgb_user = NULL;
- struct pwl_float_data_ex *rgb_regamma = NULL;
- bool ret = false;
-
- if (regamma == NULL)
- return false;
-
- output_tf->type = TF_TYPE_DISTRIBUTED_POINTS;
-
- rgb_user = kcalloc(GAMMA_RGB_256_ENTRIES + _EXTRA_POINTS,
- sizeof(*rgb_user),
- GFP_KERNEL);
- if (!rgb_user)
- goto rgb_user_alloc_fail;
-
- rgb_regamma = kcalloc(MAX_HW_POINTS + _EXTRA_POINTS,
- sizeof(*rgb_regamma),
- GFP_KERNEL);
- if (!rgb_regamma)
- goto rgb_regamma_alloc_fail;
-
- dividers.divider1 = dc_fixpt_from_fraction(3, 2);
- dividers.divider2 = dc_fixpt_from_int(2);
- dividers.divider3 = dc_fixpt_from_fraction(5, 2);
-
- scale_user_regamma_ramp(rgb_user, ®amma->ramp, dividers);
-
- if (regamma->flags.bits.applyDegamma == 1) {
- apply_degamma_for_user_regamma(rgb_regamma, MAX_HW_POINTS, cal_buffer);
- copy_rgb_regamma_to_coordinates_x(coordinates_x,
- MAX_HW_POINTS, rgb_regamma);
- }
-
- interpolate_user_regamma(MAX_HW_POINTS, rgb_user,
- regamma->flags.bits.applyDegamma, tf_pts);
-
- // no custom HDR curves!
- tf_pts->end_exponent = 0;
- tf_pts->x_point_at_y1_red = 1;
- tf_pts->x_point_at_y1_green = 1;
- tf_pts->x_point_at_y1_blue = 1;
-
- if (ramp && ramp->type == GAMMA_CS_TFM_1D)
- apply_lut_1d(ramp, MAX_HW_POINTS, &output_tf->tf_pts);
-
- // this function just clamps output to 0-1
- build_new_custom_resulted_curve(MAX_HW_POINTS, tf_pts);
-
- ret = true;
-
- kfree(rgb_regamma);
-rgb_regamma_alloc_fail:
- kfree(rgb_user);
-rgb_user_alloc_fail:
- return ret;
-}
-
bool mod_color_calculate_degamma_params(struct dc_color_caps *dc_caps,
struct dc_transfer_func *input_tf,
const struct dc_gamma *ramp, bool map_user_ramp)
@@ -115,15 +115,4 @@ bool mod_color_calculate_degamma_params(struct dc_color_caps *dc_caps,
struct dc_transfer_func *output_tf,
const struct dc_gamma *ramp, bool mapUserRamp);
-bool calculate_user_regamma_coeff(struct dc_transfer_func *output_tf,
- const struct regamma_lut *regamma,
- struct calculate_buffer *cal_buffer,
- const struct dc_gamma *ramp);
-
-bool calculate_user_regamma_ramp(struct dc_transfer_func *output_tf,
- const struct regamma_lut *regamma,
- struct calculate_buffer *cal_buffer,
- const struct dc_gamma *ramp);
-
-
#endif /* COLOR_MOD_COLOR_GAMMA_H_ */