/* * Copyright 2017 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkGaussFilter.h" #include #include "SkTypes.h" static constexpr double kPi = 3.14159265358979323846264338327950288; // The value when we can stop expanding the filter. The spec implies that 3% is acceptable, but // we just use 1%. static constexpr double kGoodEnough = 1.0 / 100.0; // Normalize the values of gauss to 1.0, and make sure they add to one. // NB if n == 1, then this will force gauss[0] == 1. static void normalize(int n, double* gauss) { // Carefully add from smallest to largest to calculate the normalizing sum. double sum = 0; for (int i = n-1; i >= 1; i--) { sum += 2 * gauss[i]; } sum += gauss[0]; // Normalize gauss. for (int i = 0; i < n; i++) { gauss[i] /= sum; } // The factors should sum to 1. Take any remaining slop, and add it to gauss[0]. Add the // values in such a way to maintain the most accuracy. sum = 0; for (int i = n - 1; i >= 1; i--) { sum += 2 * gauss[i]; } gauss[0] = 1 - sum; } static int calculate_bessel_factors(double sigma, double *gauss) { auto var = sigma * sigma; // The two functions below come from the equations in "Handbook of Mathematical Functions" // by Abramowitz and Stegun. Specifically, equation 9.6.10 on page 375. Bessel0 is given // explicitly as 9.6.12 // BesselI_0 for 0 <= sigma < 2. // NB the k = 0 factor is just sum = 1.0. auto besselI_0 = [](double t) -> double { auto tSquaredOver4 = t * t / 4.0; auto sum = 1.0; auto factor = 1.0; auto k = 1; // Use a variable number of loops. When sigma is small, this only requires 3-4 loops, but // when sigma is near 2, it could require 10 loops. The same holds for BesselI_1. while(factor > 1.0/1000000.0) { factor *= tSquaredOver4 / (k * k); sum += factor; k += 1; } return sum; }; // BesselI_1 for 0 <= sigma < 2. auto besselI_1 = [](double t) -> double { auto tSquaredOver4 = t * t / 4.0; auto sum = t / 2.0; auto factor = sum; auto k = 1; while (factor > 1.0/1000000.0) { factor *= tSquaredOver4 / (k * (k + 1)); sum += factor; k += 1; } return sum; }; // The following formula for calculating the Gaussian kernel is from // "Scale-Space for Discrete Signals" by Tony Lindeberg. // gauss(n; var) = besselI_n(var) / (e^var) auto d = std::exp(var); double b[SkGaussFilter::kGaussArrayMax] = {besselI_0(var), besselI_1(var)}; gauss[0] = b[0]/d; gauss[1] = b[1]/d; // The code below is tricky, and written to mirror the recursive equations from the book. // The maximum spread for sigma == 2 is guass[4], but in order to know to stop guass[5] // is calculated. At this point n == 5 meaning that gauss[0..4] are the factors, but a 6th // element was used to calculate them. int n = 1; // The recurrence relation below is from "Numerical Recipes" 3rd Edition. // Equation 6.5.16 p.282 while (gauss[n] > kGoodEnough) { b[n+1] = -(2*n/var) * b[n] + b[n-1]; gauss[n+1] = b[n+1] / d; n += 1; } normalize(n, gauss); return n; } static int calculate_gauss_factors(double sigma, double* gauss) { SkASSERT(0 <= sigma && sigma < 2); // From the SVG blur spec: 8.13 Filter primitive . // H(x) = exp(-x^2/ (2s^2)) / sqrt(2π * s^2) auto var = sigma * sigma; auto expGaussDenom = -2 * var; auto normalizeDenom = std::sqrt(2 * kPi) * sigma; // Use the recursion relation from "Incremental Computation of the Gaussian" by Ken // Turkowski in GPUGems 3. Page 877. double g0 = 1.0 / normalizeDenom; double g1 = std::exp(1.0 / expGaussDenom); double g2 = g1 * g1; gauss[0] = g0; g0 *= g1; g1 *= g2; gauss[1] = g0; int n = 1; while (gauss[n] > kGoodEnough) { g0 *= g1; g1 *= g2; gauss[n+1] = g0; n += 1; } normalize(n, gauss); return n; } SkGaussFilter::SkGaussFilter(double sigma, Type type) { SkASSERT(0 <= sigma && sigma < 2); if (type == Type::Bessel) { fN = calculate_bessel_factors(sigma, fBasis); } else { fN = calculate_gauss_factors(sigma, fBasis); } }