godot/thirdparty/basis_universal/encoder/basisu_ssim.cpp

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// basisu_ssim.cpp
// Copyright (C) 2019 Binomial LLC. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "basisu_ssim.h"
#ifndef M_PI
#define M_PI 3.14159265358979323846
#endif
namespace basisu
{
float gauss(int x, int y, float sigma_sqr)
{
float pow = expf(-((x * x + y * y) / (2.0f * sigma_sqr)));
float g = (1.0f / (sqrtf((float)(2.0f * M_PI * sigma_sqr)))) * pow;
return g;
}
// size_x/y should be odd
void compute_gaussian_kernel(float *pDst, int size_x, int size_y, float sigma_sqr, uint32_t flags)
{
assert(size_x & size_y & 1);
if (!(size_x | size_y))
return;
int mid_x = size_x / 2;
int mid_y = size_y / 2;
double sum = 0;
for (int x = 0; x < size_x; x++)
{
for (int y = 0; y < size_y; y++)
{
float g;
if ((x > mid_x) && (y < mid_y))
g = pDst[(size_x - x - 1) + y * size_x];
else if ((x < mid_x) && (y > mid_y))
g = pDst[x + (size_y - y - 1) * size_x];
else if ((x > mid_x) && (y > mid_y))
g = pDst[(size_x - x - 1) + (size_y - y - 1) * size_x];
else
g = gauss(x - mid_x, y - mid_y, sigma_sqr);
pDst[x + y * size_x] = g;
sum += g;
}
}
if (flags & cComputeGaussianFlagNormalizeCenterToOne)
{
sum = pDst[mid_x + mid_y * size_x];
}
if (flags & (cComputeGaussianFlagNormalizeCenterToOne | cComputeGaussianFlagNormalize))
{
double one_over_sum = 1.0f / sum;
for (int i = 0; i < size_x * size_y; i++)
pDst[i] = static_cast<float>(pDst[i] * one_over_sum);
if (flags & cComputeGaussianFlagNormalizeCenterToOne)
pDst[mid_x + mid_y * size_x] = 1.0f;
}
if (flags & cComputeGaussianFlagPrint)
{
printf("{\n");
for (int y = 0; y < size_y; y++)
{
printf(" ");
for (int x = 0; x < size_x; x++)
{
printf("%f, ", pDst[x + y * size_x]);
}
printf("\n");
}
printf("}");
}
}
void gaussian_filter(imagef &dst, const imagef &orig_img, uint32_t odd_filter_width, float sigma_sqr, bool wrapping, uint32_t width_divisor, uint32_t height_divisor)
{
assert(odd_filter_width && (odd_filter_width & 1));
odd_filter_width |= 1;
vector2D<float> kernel(odd_filter_width, odd_filter_width);
compute_gaussian_kernel(kernel.get_ptr(), odd_filter_width, odd_filter_width, sigma_sqr, cComputeGaussianFlagNormalize);
const int dst_width = orig_img.get_width() / width_divisor;
const int dst_height = orig_img.get_height() / height_divisor;
const int H = odd_filter_width / 2;
const int L = -H;
dst.crop(dst_width, dst_height);
//#pragma omp parallel for
for (int oy = 0; oy < dst_height; oy++)
{
for (int ox = 0; ox < dst_width; ox++)
{
vec4F c(0.0f);
for (int yd = L; yd <= H; yd++)
{
int y = oy * height_divisor + (height_divisor >> 1) + yd;
for (int xd = L; xd <= H; xd++)
{
int x = ox * width_divisor + (width_divisor >> 1) + xd;
const vec4F &p = orig_img.get_clamped_or_wrapped(x, y, wrapping, wrapping);
float w = kernel(xd + H, yd + H);
c[0] += p[0] * w;
c[1] += p[1] * w;
c[2] += p[2] * w;
c[3] += p[3] * w;
}
}
dst(ox, oy).set(c[0], c[1], c[2], c[3]);
}
}
}
void pow_image(const imagef &src, imagef &dst, const vec4F &power)
{
dst.resize(src);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &p = src(x, y);
if ((power[0] == 2.0f) && (power[1] == 2.0f) && (power[2] == 2.0f) && (power[3] == 2.0f))
dst(x, y).set(p[0] * p[0], p[1] * p[1], p[2] * p[2], p[3] * p[3]);
else
dst(x, y).set(powf(p[0], power[0]), powf(p[1], power[1]), powf(p[2], power[2]), powf(p[3], power[3]));
}
}
}
void mul_image(const imagef &src, imagef &dst, const vec4F &mul)
{
dst.resize(src);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &p = src(x, y);
dst(x, y).set(p[0] * mul[0], p[1] * mul[1], p[2] * mul[2], p[3] * mul[3]);
}
}
}
void scale_image(const imagef &src, imagef &dst, const vec4F &scale, const vec4F &shift)
{
dst.resize(src);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &p = src(x, y);
vec4F d;
for (uint32_t c = 0; c < 4; c++)
d[c] = scale[c] * p[c] + shift[c];
dst(x, y).set(d[0], d[1], d[2], d[3]);
}
}
}
void add_weighted_image(const imagef &src1, const vec4F &alpha, const imagef &src2, const vec4F &beta, const vec4F &gamma, imagef &dst)
{
dst.resize(src1);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &s1 = src1(x, y);
const vec4F &s2 = src2(x, y);
dst(x, y).set(
s1[0] * alpha[0] + s2[0] * beta[0] + gamma[0],
s1[1] * alpha[1] + s2[1] * beta[1] + gamma[1],
s1[2] * alpha[2] + s2[2] * beta[2] + gamma[2],
s1[3] * alpha[3] + s2[3] * beta[3] + gamma[3]);
}
}
}
void add_image(const imagef &src1, const imagef &src2, imagef &dst)
{
dst.resize(src1);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &s1 = src1(x, y);
const vec4F &s2 = src2(x, y);
dst(x, y).set(s1[0] + s2[0], s1[1] + s2[1], s1[2] + s2[2], s1[3] + s2[3]);
}
}
}
void adds_image(const imagef &src, const vec4F &value, imagef &dst)
{
dst.resize(src);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &p = src(x, y);
dst(x, y).set(p[0] + value[0], p[1] + value[1], p[2] + value[2], p[3] + value[3]);
}
}
}
void mul_image(const imagef &src1, const imagef &src2, imagef &dst, const vec4F &scale)
{
dst.resize(src1);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &s1 = src1(x, y);
const vec4F &s2 = src2(x, y);
vec4F d;
for (uint32_t c = 0; c < 4; c++)
{
float v1 = s1[c];
float v2 = s2[c];
d[c] = v1 * v2 * scale[c];
}
dst(x, y) = d;
}
}
}
void div_image(const imagef &src1, const imagef &src2, imagef &dst, const vec4F &scale)
{
dst.resize(src1);
//#pragma omp parallel for
for (int y = 0; y < (int)dst.get_height(); y++)
{
for (uint32_t x = 0; x < dst.get_width(); x++)
{
const vec4F &s1 = src1(x, y);
const vec4F &s2 = src2(x, y);
vec4F d;
for (uint32_t c = 0; c < 4; c++)
{
float v = s2[c];
if (v == 0.0f)
d[c] = 0.0f;
else
d[c] = (s1[c] * scale[c]) / v;
}
dst(x, y) = d;
}
}
}
vec4F avg_image(const imagef &src)
{
vec4F avg(0.0f);
for (uint32_t y = 0; y < src.get_height(); y++)
{
for (uint32_t x = 0; x < src.get_width(); x++)
{
const vec4F &s = src(x, y);
avg += vec4F(s[0], s[1], s[2], s[3]);
}
}
avg /= static_cast<float>(src.get_total_pixels());
return avg;
}
// Reference: https://ece.uwaterloo.ca/~z70wang/research/ssim/index.html
vec4F compute_ssim(const imagef &a, const imagef &b)
{
imagef axb, a_sq, b_sq, mu1, mu2, mu1_sq, mu2_sq, mu1_mu2, s1_sq, s2_sq, s12, smap, t1, t2, t3;
const float C1 = 6.50250f, C2 = 58.52250f;
pow_image(a, a_sq, vec4F(2));
pow_image(b, b_sq, vec4F(2));
mul_image(a, b, axb, vec4F(1.0f));
gaussian_filter(mu1, a, 11, 1.5f * 1.5f);
gaussian_filter(mu2, b, 11, 1.5f * 1.5f);
pow_image(mu1, mu1_sq, vec4F(2));
pow_image(mu2, mu2_sq, vec4F(2));
mul_image(mu1, mu2, mu1_mu2, vec4F(1.0f));
gaussian_filter(s1_sq, a_sq, 11, 1.5f * 1.5f);
add_weighted_image(s1_sq, vec4F(1), mu1_sq, vec4F(-1), vec4F(0), s1_sq);
gaussian_filter(s2_sq, b_sq, 11, 1.5f * 1.5f);
add_weighted_image(s2_sq, vec4F(1), mu2_sq, vec4F(-1), vec4F(0), s2_sq);
gaussian_filter(s12, axb, 11, 1.5f * 1.5f);
add_weighted_image(s12, vec4F(1), mu1_mu2, vec4F(-1), vec4F(0), s12);
scale_image(mu1_mu2, t1, vec4F(2), vec4F(0));
adds_image(t1, vec4F(C1), t1);
scale_image(s12, t2, vec4F(2), vec4F(0));
adds_image(t2, vec4F(C2), t2);
mul_image(t1, t2, t3, vec4F(1));
add_image(mu1_sq, mu2_sq, t1);
adds_image(t1, vec4F(C1), t1);
add_image(s1_sq, s2_sq, t2);
adds_image(t2, vec4F(C2), t2);
mul_image(t1, t2, t1, vec4F(1));
div_image(t3, t1, smap, vec4F(1));
return avg_image(smap);
}
vec4F compute_ssim(const image &a, const image &b, bool luma, bool luma_601)
{
image ta(a), tb(b);
if ((ta.get_width() != tb.get_width()) || (ta.get_height() != tb.get_height()))
{
debug_printf("compute_ssim: Cropping input images to equal dimensions\n");
const uint32_t w = minimum(a.get_width(), b.get_width());
const uint32_t h = minimum(a.get_height(), b.get_height());
ta.crop(w, h);
tb.crop(w, h);
}
if (!ta.get_width() || !ta.get_height())
{
assert(0);
return vec4F(0);
}
if (luma)
{
for (uint32_t y = 0; y < ta.get_height(); y++)
{
for (uint32_t x = 0; x < ta.get_width(); x++)
{
ta(x, y).set(ta(x, y).get_luma(luma_601), ta(x, y).a);
tb(x, y).set(tb(x, y).get_luma(luma_601), tb(x, y).a);
}
}
}
imagef fta, ftb;
fta.set(ta);
ftb.set(tb);
return compute_ssim(fta, ftb);
}
} // namespace basisu