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Implement real::erf() with reasonable precision.

legacy
Sam Hocevar 7 anos atrás
pai
commit
6281145d9d
2 arquivos alterados com 65 adições e 3 exclusões
  1. +5
    -0
      src/lol/math/real.h
  2. +60
    -3
      src/math/real.cpp

+ 5
- 0
src/lol/math/real.h Ver arquivo

@@ -108,9 +108,12 @@ public:
/* Exponential and logarithmic functions */
template<typename U> friend Real<U> exp(Real<U> const &x);
template<typename U> friend Real<U> exp2(Real<U> const &x);
template<typename U> friend Real<U> erf(Real<U> const &x);
template<typename U> friend Real<U> log(Real<U> const &x);
template<typename U> friend Real<U> log2(Real<U> const &x);
template<typename U> friend Real<U> log10(Real<U> const &x);

/* Floating-point functions */
template<typename U> friend Real<U> frexp(Real<U> const &x, int64_t *exp);
template<typename U> friend Real<U> ldexp(Real<U> const &x, int64_t exp);
template<typename U> friend Real<U> modf(Real<U> const &x, Real<U> *iptr);
@@ -287,6 +290,7 @@ template<typename U> Real<U> cosh(Real<U> const &x);
template<typename U> Real<U> tanh(Real<U> const &x);
template<typename U> Real<U> exp(Real<U> const &x);
template<typename U> Real<U> exp2(Real<U> const &x);
template<typename U> Real<U> erf(Real<U> const &x);
template<typename U> Real<U> log(Real<U> const &x);
template<typename U> Real<U> log2(Real<U> const &x);
template<typename U> Real<U> log10(Real<U> const &x);
@@ -328,6 +332,7 @@ template<> real cosh(real const &x);
template<> real tanh(real const &x);
template<> real exp(real const &x);
template<> real exp2(real const &x);
template<> real erf(real const &x);
template<> real log(real const &x);
template<> real log2(real const &x);
template<> real log10(real const &x);


+ 60
- 3
src/math/real.cpp Ver arquivo

@@ -864,13 +864,19 @@ template<> real pow(real const &x, real const &y)
/* A fast factorial implementation for small numbers. An optional
* step argument allows to compute double factorials (i.e. with
* only the odd or the even terms. */
static real fast_fact(unsigned int x, unsigned int step = 1)
static real fast_fact(int x, int step = 1)
{
if (x < step)
return 1;

if (x == step)
return x;

unsigned int start = (x + step - 1) % step + 1;
real ret = start ? real(start) : real(step);
real ret(start);
uint64_t multiplier = 1;

for (unsigned int i = start, exponent = 0;;)
for (int i = start, exponent = 0;;)
{
if (i >= x)
return ldexp(ret * multiplier, exponent);
@@ -1072,6 +1078,57 @@ template<> real exp2(real const &x)
return x1;
}

template<> real erf(real const &x)
{
/* Strategy for erf(x):
* - if x<0, erf(x) = -erf(-x)
* - if x<7, erf(x) = sum((-1)^n×x^(2n+1)/((2n+1)×n!))/sqrt(pi/4)
* - if x≥7, erf(x) = 1+exp(-x²)/(x×sqrt(pi))×sum((-1)^n×(2n-1)!!/(2x²)^n
*
* FIXME: do not compute factorials at each iteration, accumulate
* them instead (see fast_exp_sub).
* FIXME: For a potentially faster implementation, see “Expanding the
* Error Function erf(z)” at:
* http://www.mathematica-journal.com/2014/11/on-burmanns-theorem-and-its-application-to-problems-of-linear-and-nonlinear-heat-transfer-and-diffusion/#more-39602/
*/
if (x.is_negative())
return -erf(-x);

real sum = real::R_0();
real x2 = x * x;

/* FIXME: this test is inefficient; the series converges slowly for x≥1 */
if (x < real(7))
{
real xn = x, xmul = x2;
for (int n = 0;; ++n, xn *= xmul)
{
real tmp = xn / (fast_fact(n) * (2 * n + 1));
real newsum = (n & 1) ? sum - tmp : sum + tmp;
if (newsum == sum)
break;
sum = newsum;
}
return sum * real::R_2_SQRTPI();
}
else
{
real xn = real::R_1(), xmul = inverse(x2 + x2);
/* FIXME: this does not converge well! We need to stop at 30
* iterations and sacrifice some accuracy. */
for (int n = 0; n < 30; ++n, xn *= xmul)
{
real tmp = xn * fast_fact(n * 2 - 1, 2);
real newsum = (n & 1) ? sum - tmp : sum + tmp;
if (newsum == sum)
break;
sum = newsum;
}

return real::R_1() - exp(-x2) / (x * sqrt(real::R_PI())) * sum;
}
}

template<> real sinh(real const &x)
{
/* We cannot always use (exp(x)-exp(-x))/2 because we'll lose


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