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weston/tests/lcms_util.c
Pekka Paalanen 556272bae9 color-lcms: change stock sRGB to true power-2.2 
The sRGB expected display behavior uses the pure power-law with exponent
2.2, not the two-piece sRGB transfer function.
cmsCreate_sRGBProfileTHR() used the two-piece TF, now we use the proper
display TF.

This is particularly meaningful when implicit sRGB content is converted
to HDR formats, in order to maintain the stimuli reproduction near zero.

cmlcms_send_image_desc_info() is already sending this, it doesn't need
fixing.

Changing the curve also changes the error tolerances. The change is
theoretically a no-op, but the curve and its inverse and temporary
rounding add error. The new curve is more prone to error, so it is not
surprising we need to raise the tolerance. The color transformation does
end up as power-2.2 analytical form and I do not think it is ever
lowered to a LUT in alpha-blending test, so there is no obvious fix
improving the accuracy. The worst case point in alpha-blending still
occurs at the very same point as before.

The test reference images are updated for the same reason, they would
fail otherwise.

Both alpha-blending and color-icc-output contain the same sRGB-optical
sub-test, hence the same error tolerance.

It is surprising to have to increase the ICC roundtrip error tolerance
in color-icc-output test, given that the curves are passed as parametric
to LittleCMS, and adobeRGB case works with the old tolerance even. I did
not investigate further.

Signed-off-by: Pekka Paalanen <pekka.paalanen@collabora.com>
2025-06-03 15:47:20 +03:00

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/*
* Copyright 2021 Advanced Micro Devices, Inc.
* Copyright 2022 Collabora, Ltd.
* Copyright (c) 1998-2023 Marti Maria Saguer
*
* 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 (including the
* next paragraph) 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 AUTHORS OR COPYRIGHT HOLDERS
* 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.
*/
#include "config.h"
#include <math.h>
#include <lcms2.h>
#include <stdlib.h>
#include <libweston/linalg.h>
#include "shared/helpers.h"
#include "color_util.h"
#include "lcms_util.h"
#include "weston-test-assert.h"
static const cmsCIExyY wp_d65 = { 0.31271, 0.32902, 1.0 };
/*
* MPE tone curves can only use LittleCMS parametric curve types 6-8 and not
* inverses.
* type 6: Y = (aX + b)^g + c; params [g, a, b, c]
* type 7: Y = a log(bX^g + c) + d; params [g, a, b, c, d]
* type 8: Y = a b^(cX + d) + e; params [a, b, c, d, e]
* Additionally, type 0 is sampled segment.
*
* cmsCurveSegment.x1 is the breakpoint stored in ICC files, except for the
* last segment. First segment always begins at -Inf, and last segment always
* ends at Inf.
*/
static cmsToneCurve *
build_MPE_curve_sRGB(cmsContext ctx)
{
cmsCurveSegment segments[] = {
{
/* Constant zero segment */
.x0 = -HUGE_VAL,
.x1 = 0.0,
.Type = 6,
.Params = { 1.0, 0.0, 0.0, 0.0 },
},
{
/* Linear segment y = x / 12.92 */
.x0 = 0.0,
.x1 = 0.04045,
.Type = 0,
.nGridPoints = 2,
.SampledPoints = (float[]){ 0.0, 0.04045 / 12.92 },
},
{
/* Power segment y = ((x + 0.055) / 1.055)^2.4
* which is translated to
* y = (1/1.055 * x + 0.055 / 1.055)^2.4 + 0.0
*/
.x0 = 0.04045,
.x1 = 1.0,
.Type = 6,
.Params = { 2.4, 1.0 / 1.055, 0.055 / 1.055, 0.0 },
},
{
/* Constant one segment */
.x0 = 1.0,
.x1 = HUGE_VAL,
.Type = 6,
.Params = { 1.0, 0.0, 0.0, 1.0 },
}
};
return cmsBuildSegmentedToneCurve(ctx, ARRAY_LENGTH(segments), segments);
}
static cmsToneCurve *
build_MPE_curve_sRGB_inv(cmsContext ctx)
{
cmsCurveSegment segments[] = {
{
/* Constant zero segment */
.x0 = -HUGE_VAL,
.x1 = 0.0,
.Type = 6,
.Params = { 1.0, 0.0, 0.0, 0.0 },
},
{
/* Linear segment y = x * 12.92 */
.x0 = 0.0,
.x1 = 0.04045 / 12.92,
.Type = 0,
.nGridPoints = 2,
.SampledPoints = (float[]){ 0.0, 0.04045 },
},
{
/* Power segment y = 1.055 * x^(1/2.4) - 0.055
* which is translated to
* y = (1.055^2.4 * x + 0.0)^(1/2.4) - 0.055
*/
.x0 = 0.04045 / 12.92,
.x1 = 1.0,
.Type = 6,
.Params = { 1.0 / 2.4, pow(1.055, 2.4), 0.0, -0.055 },
},
{
/* Constant one segment */
.x0 = 1.0,
.x1 = HUGE_VAL,
.Type = 6,
.Params = { 1.0, 0.0, 0.0, 1.0 },
}
};
return cmsBuildSegmentedToneCurve(ctx, ARRAY_LENGTH(segments), segments);
}
static cmsToneCurve *
build_MPE_curve_power(cmsContext ctx, double exponent)
{
cmsCurveSegment segments[] = {
{
/* Constant zero segment */
.x0 = -HUGE_VAL,
.x1 = 0.0,
.Type = 6,
.Params = { 1.0, 0.0, 0.0, 0.0 },
},
{
/* Power segment y = x^exponent
* which is translated to
* y = (1.0 * x + 0.0)^exponent + 0.0
*/
.x0 = 0.0,
.x1 = 1.0,
.Type = 6,
.Params = { exponent, 1.0, 0.0, 0.0 },
},
{
/* Constant one segment */
.x0 = 1.0,
.x1 = HUGE_VAL,
.Type = 6,
.Params = { 1.0, 0.0, 0.0, 1.0 },
}
};
return cmsBuildSegmentedToneCurve(ctx, ARRAY_LENGTH(segments), segments);
}
cmsToneCurve *
build_MPE_curve(cmsContext ctx, enum transfer_fn fn)
{
switch (fn) {
case TRANSFER_FN_ADOBE_RGB_EOTF:
return build_MPE_curve_power(ctx, 563.0 / 256.0);
case TRANSFER_FN_ADOBE_RGB_EOTF_INVERSE:
return build_MPE_curve_power(ctx, 256.0 / 563.0);
case TRANSFER_FN_POWER2_2_EOTF:
return build_MPE_curve_power(ctx, 2.2);
case TRANSFER_FN_POWER2_2_EOTF_INVERSE:
return build_MPE_curve_power(ctx, 1.0 / 2.2);
case TRANSFER_FN_POWER2_4_EOTF:
return build_MPE_curve_power(ctx, 2.4);
case TRANSFER_FN_POWER2_4_EOTF_INVERSE:
return build_MPE_curve_power(ctx, 1.0 / 2.4);
case TRANSFER_FN_SRGB:
return build_MPE_curve_sRGB(ctx);
case TRANSFER_FN_SRGB_INVERSE:
return build_MPE_curve_sRGB_inv(ctx);
default:
test_assert_not_reached("unimplemented MPE curve");
}
return NULL;
}
cmsStage *
build_MPE_curve_stage(cmsContext context_id, enum transfer_fn fn)
{
cmsToneCurve *c;
cmsStage *stage;
c = build_MPE_curve(context_id, fn);
stage = cmsStageAllocToneCurves(context_id, 3,
(cmsToneCurve *[3]){ c, c, c });
test_assert_ptr_not_null(stage);
cmsFreeToneCurve(c);
return stage;
}
/* This function is taken from LittleCMS, pardon the odd style */
cmsBool
SetTextTags(cmsHPROFILE hProfile, const wchar_t* Description)
{
cmsMLU *DescriptionMLU, *CopyrightMLU;
cmsBool rc = FALSE;
cmsContext ContextID = cmsGetProfileContextID(hProfile);
DescriptionMLU = cmsMLUalloc(ContextID, 1);
CopyrightMLU = cmsMLUalloc(ContextID, 1);
if (DescriptionMLU == NULL || CopyrightMLU == NULL) goto Error;
if (!cmsMLUsetWide(DescriptionMLU, "en", "US", Description)) goto Error;
if (!cmsMLUsetWide(CopyrightMLU, "en", "US", L"No copyright, use freely")) goto Error;
if (!cmsWriteTag(hProfile, cmsSigProfileDescriptionTag, DescriptionMLU)) goto Error;
if (!cmsWriteTag(hProfile, cmsSigCopyrightTag, CopyrightMLU)) goto Error;
rc = TRUE;
Error:
if (DescriptionMLU)
cmsMLUfree(DescriptionMLU);
if (CopyrightMLU)
cmsMLUfree(CopyrightMLU);
return rc;
}
static void
test_roundtrip(uint8_t r, uint8_t g, uint8_t b, cmsPipeline *pip,
struct rgb_diff_stat *stat)
{
struct color_float in = { .rgb = { r / 255.0, g / 255.0, b / 255.0 } };
struct color_float out = {};
cmsPipelineEvalFloat(in.rgb, out.rgb, pip);
rgb_diff_stat_update(stat, &in, &out, &in);
}
/*
* Roundtrip verification tests that converting device -> PCS -> device
* results in the original color values close enough.
*
* This ensures that the two pipelines are probably built correctly, and we
* do not have problems with unexpected value clamping or with representing
* (inverse) EOTF curves.
*/
static void
roundtrip_verification(cmsPipeline *DToB, cmsPipeline *BToD, float tolerance)
{
unsigned r, g, b;
struct rgb_diff_stat stat = {};
cmsPipeline *pip;
pip = cmsPipelineDup(DToB);
cmsPipelineCat(pip, BToD);
/*
* Inverse-EOTF is known to have precision problems near zero, so
* sample near zero densely, the rest can be more sparse to run faster.
*/
for (r = 0; r < 256; r += (r < 15) ? 1 : 8) {
for (g = 0; g < 256; g += (g < 15) ? 1 : 8) {
for (b = 0; b < 256; b += (b < 15) ? 1 : 8)
test_roundtrip(r, g, b, pip, &stat);
}
}
cmsPipelineFree(pip);
rgb_diff_stat_print(&stat, "DToB->BToD roundtrip", 8);
test_assert_f32_lt(stat.two_norm.max, tolerance);
}
static const struct weston_vec3f PCS_BLACK = WESTON_VEC3F(
cmsPERCEPTUAL_BLACK_X,
cmsPERCEPTUAL_BLACK_Y,
cmsPERCEPTUAL_BLACK_Z
);
/* Whether BPC matrix applies never, after or before transformation */
enum bpc_dir {
BPC_DIR_NONE,
BPC_DIR_DTOB,
BPC_DIR_BTOD,
};
struct transform_sampler_context {
cmsHTRANSFORM t;
struct weston_mat4f bpc;
enum bpc_dir dir;
};
static cmsInt32Number
transform_sampler(const float src[], float dst[], void *cargo)
{
const struct transform_sampler_context *tsc = cargo;
struct weston_vec4f stmp = WESTON_VEC4F(src[0], src[1], src[2], 1.0);
struct weston_vec4f dtmp = WESTON_VEC4F(0.0, 0.0, 0.0, 1.0);
if (tsc->dir == BPC_DIR_BTOD)
stmp = weston_m4f_mul_v4f(tsc->bpc, stmp);
cmsDoTransform(tsc->t, stmp.el, dtmp.el, 1);
if (tsc->dir == BPC_DIR_DTOB)
dtmp = weston_m4f_mul_v4f(tsc->bpc, dtmp);
for (int i = 0; i < 3; i++)
dst[i] = dtmp.el[i];
return 1; /* Success. */
}
/*
* Black point compensation, copied from LittleCMS 2.16, cmscnvrt.c
* Adapted to Weston code base.
*/
static struct weston_mat4f
ComputeBlackPointCompensation(struct weston_vec3f src_bp,
struct weston_vec3f dst_bp)
{
struct weston_vec3f D50 = WESTON_VEC3F(cmsD50_XYZ()->X, cmsD50_XYZ()->Y, cmsD50_XYZ()->Z);
struct weston_vec3f a, b, t;
// Now we need to compute a matrix plus an offset m and of such of
// [m]*bpin + off = bpout
// [m]*D50 + off = D50
//
// This is a linear scaling in the form ax+b, where
// a = (bpout - D50) / (bpin - D50)
// b = - D50* (bpout - bpin) / (bpin - D50)
t.x = src_bp.x - D50.x;
t.y = src_bp.y - D50.y;
t.z = src_bp.z - D50.z;
a.x = (dst_bp.x - D50.x) / t.x;
a.y = (dst_bp.y - D50.y) / t.y;
a.z = (dst_bp.z - D50.z) / t.z;
b.x = - D50.x * (dst_bp.x - src_bp.x) / t.x;
b.y = - D50.y * (dst_bp.y - src_bp.y) / t.y;
b.z = - D50.z * (dst_bp.z - src_bp.z) / t.z;
return WESTON_MAT4F(
a.x, 0.0, 0.0, b.x,
0.0, a.y, 0.0, b.y,
0.0, 0.0, a.z, b.z,
0.0, 0.0, 0.0, 1.0
);
}
static cmsStage *
create_cLUT_from_transform(cmsContext context_id, const cmsHTRANSFORM t,
int dim_size,
enum bpc_dir dir)
{
struct transform_sampler_context tsc;
cmsStage *cLUT_stage;
test_assert_int_ne(dim_size, 0);
tsc.t = t;
tsc.dir = dir;
switch (tsc.dir) {
case BPC_DIR_NONE:
tsc.bpc = WESTON_MAT4F_IDENTITY;
break;
case BPC_DIR_DTOB:
tsc.bpc = ComputeBlackPointCompensation(WESTON_VEC3F_ZERO, PCS_BLACK);
break;
case BPC_DIR_BTOD:
tsc.bpc = ComputeBlackPointCompensation(PCS_BLACK, WESTON_VEC3F_ZERO);
break;
}
cLUT_stage = cmsStageAllocCLutFloat(context_id, dim_size, 3, 3, NULL);
cmsStageSampleCLutFloat(cLUT_stage, transform_sampler, &tsc, 0);
return cLUT_stage;
}
static void
vcgt_tag_add_to_profile(cmsContext context_id, cmsHPROFILE profile,
const double vcgt_exponents[COLOR_CHAN_NUM])
{
cmsToneCurve *vcgt_tag_curves[COLOR_CHAN_NUM];
unsigned int i;
if (!should_include_vcgt(vcgt_exponents))
return;
for (i = 0; i < COLOR_CHAN_NUM; i++)
vcgt_tag_curves[i] = cmsBuildGamma(context_id, vcgt_exponents[i]);
test_assert_true(cmsWriteTag(profile, cmsSigVcgtTag, vcgt_tag_curves));
cmsFreeToneCurveTriple(vcgt_tag_curves);
}
cmsHPROFILE
build_lcms_clut_profile_output(cmsContext context_id,
const struct lcms_pipeline *pipeline,
const double vcgt_exponents[COLOR_CHAN_NUM],
int clut_dim_size, float clut_roundtrip_tolerance)
{
enum transfer_fn inv_eotf_fn = pipeline->post_fn;
enum transfer_fn eotf_fn = transfer_fn_invert(inv_eotf_fn);
cmsHPROFILE hRGB;
cmsPipeline *DToB0, *BToD0;
cmsPipeline *DToB1, *BToD1;
cmsStage *stage;
cmsStage *stage_inv_eotf;
cmsStage *stage_eotf;
cmsToneCurve *identity_curves[3];
cmsHPROFILE linear_device;
cmsHPROFILE pcs;
cmsHTRANSFORM linear_device_to_pcs;
cmsHTRANSFORM pcs_to_linear_device;
identity_curves[0] = identity_curves[1] = identity_curves[2] =
cmsBuildGamma(context_id, 1.0);
linear_device = cmsCreateRGBProfileTHR(context_id, &wp_d65,
&pipeline->prim_output,
identity_curves);
test_assert_true(cmsIsMatrixShaper(linear_device));
cmsFreeToneCurve(identity_curves[0]);
pcs = cmsCreateXYZProfileTHR(context_id);
/*
* Since linear_device is a matrix-shaper profile, all rendering intents
* share the same device<->PCS transformations. We only need to pick
* an arbitrary rendering intent that allows to turn BPC both on and off.
*/
linear_device_to_pcs = cmsCreateTransformTHR(context_id,
linear_device, TYPE_RGB_FLT,
pcs, TYPE_XYZ_FLT,
INTENT_RELATIVE_COLORIMETRIC,
cmsFLAGS_NOOPTIMIZE);
pcs_to_linear_device = cmsCreateTransformTHR(context_id,
pcs, TYPE_XYZ_FLT,
linear_device, TYPE_RGB_FLT,
INTENT_RELATIVE_COLORIMETRIC,
cmsFLAGS_NOOPTIMIZE);
cmsCloseProfile(linear_device);
cmsCloseProfile(pcs);
hRGB = cmsCreateProfilePlaceholder(context_id);
cmsSetProfileVersion(hRGB, 4.3);
cmsSetDeviceClass(hRGB, cmsSigDisplayClass);
cmsSetColorSpace(hRGB, cmsSigRgbData);
cmsSetPCS(hRGB, cmsSigXYZData);
SetTextTags(hRGB, L"cLut profile");
stage_eotf = build_MPE_curve_stage(context_id, eotf_fn);
stage_inv_eotf = build_MPE_curve_stage(context_id, inv_eotf_fn);
/*
* Pipeline from PCS (optical) to device (electrical)
*/
/* Perceptual PCS black point is not zeros, so we need BPC */
BToD0 = cmsPipelineAlloc(context_id, 3, 3);
stage = create_cLUT_from_transform(context_id, pcs_to_linear_device,
clut_dim_size, BPC_DIR_BTOD);
cmsPipelineInsertStage(BToD0, cmsAT_END, stage);
cmsPipelineInsertStage(BToD0, cmsAT_END, cmsStageDup(stage_inv_eotf));
/* Media-relative colorimetric does not force BPC */
BToD1 = cmsPipelineAlloc(context_id, 3, 3);
stage = create_cLUT_from_transform(context_id, pcs_to_linear_device,
clut_dim_size, BPC_DIR_NONE);
cmsPipelineInsertStage(BToD1, cmsAT_END, stage);
cmsPipelineInsertStage(BToD1, cmsAT_END, cmsStageDup(stage_inv_eotf));
cmsWriteTag(hRGB, cmsSigBToD0Tag, BToD0);
cmsWriteTag(hRGB, cmsSigBToD1Tag, BToD1);
cmsLinkTag(hRGB, cmsSigBToD2Tag, cmsSigBToD0Tag);
cmsLinkTag(hRGB, cmsSigBToD3Tag, cmsSigBToD1Tag);
/*
* Pipeline from device (electrical) to PCS (optical)
*/
/* Perceptual PCS black point is not zeros, so we need BPC */
DToB0 = cmsPipelineAlloc(context_id, 3, 3);
cmsPipelineInsertStage(DToB0, cmsAT_END, cmsStageDup(stage_eotf));
stage = create_cLUT_from_transform(context_id, linear_device_to_pcs,
clut_dim_size, BPC_DIR_DTOB);
cmsPipelineInsertStage(DToB0, cmsAT_END, stage);
/* Media-relative colorimetric does not force BPC */
DToB1 = cmsPipelineAlloc(context_id, 3, 3);
cmsPipelineInsertStage(DToB1, cmsAT_END, cmsStageDup(stage_eotf));
stage = create_cLUT_from_transform(context_id, linear_device_to_pcs,
clut_dim_size, BPC_DIR_NONE);
cmsPipelineInsertStage(DToB1, cmsAT_END, stage);
cmsWriteTag(hRGB, cmsSigDToB0Tag, DToB0);
cmsWriteTag(hRGB, cmsSigDToB1Tag, DToB1);
cmsLinkTag(hRGB, cmsSigDToB2Tag, cmsSigDToB0Tag);
cmsLinkTag(hRGB, cmsSigDToB3Tag, cmsSigDToB1Tag);
vcgt_tag_add_to_profile(context_id, hRGB, vcgt_exponents);
roundtrip_verification(DToB0, BToD0, clut_roundtrip_tolerance);
roundtrip_verification(DToB1, BToD1, clut_roundtrip_tolerance);
cmsPipelineFree(BToD0);
cmsPipelineFree(DToB0);
cmsPipelineFree(BToD1);
cmsPipelineFree(DToB1);
cmsStageFree(stage_eotf);
cmsStageFree(stage_inv_eotf);
cmsDeleteTransform(linear_device_to_pcs);
cmsDeleteTransform(pcs_to_linear_device);
return hRGB;
}
cmsHPROFILE
build_lcms_matrix_shaper_profile_output(cmsContext context_id,
const struct lcms_pipeline *pipeline,
const double vcgt_exponents[COLOR_CHAN_NUM])
{
cmsToneCurve *arr_curves[3];
cmsHPROFILE hRGB;
int type_inverse_tone_curve;
double inverse_tone_curve_param[5];
find_tone_curve_type(pipeline->post_fn,
&type_inverse_tone_curve, inverse_tone_curve_param);
/*
* We are creating output profile and therefore we can use the following:
* calling semantics:
* cmsBuildParametricToneCurve(type_inverse_tone_curve, inverse_tone_curve_param)
* The function find_tone_curve_type sets the type of curve positive if it
* is tone curve and negative if it is inverse. When we create an ICC
* profile we should use a tone curve, the inversion is done by LCMS
* when the profile is used for output.
*/
arr_curves[0] = arr_curves[1] = arr_curves[2] =
cmsBuildParametricToneCurve(context_id,
(-1) * type_inverse_tone_curve,
inverse_tone_curve_param);
test_assert_ptr_not_null(arr_curves[0]);
hRGB = cmsCreateRGBProfileTHR(context_id, &wp_d65,
&pipeline->prim_output, arr_curves);
test_assert_ptr_not_null(hRGB);
vcgt_tag_add_to_profile(context_id, hRGB, vcgt_exponents);
cmsFreeToneCurve(arr_curves[0]);
return hRGB;
}
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