/* Foundation and miscellenea for the statistics modules. * * Contents: * 1. Summary statistics (means, variances) * 2. Special functions * 3. Standard statistical tests * 4. Data fitting. * 5. Unit tests. * 6. Test driver. * 7. Examples. * - driver for linear regression * - driver for G-test */ #include #include #include "easel.h" #include "esl_stats.h" /***************************************************************** * 1. Summary statistics calculations (means, variances) *****************************************************************/ /* Function: esl_stats_DMean() * Synopsis: Calculates mean and $\sigma^2$ for samples $x_i$. * * Purpose: Calculates the sample mean and $s^2$, the unbiased * estimator of the population variance, for a * sample of numbers , and optionally * returns either or both through and * . * * and do the same, * for float and integer vectors. * * Args: x - samples x[0]..x[n-1] * n - number of samples * opt_mean - optRETURN: sample mean * opt_var - optRETURN: sample variance * * Returns: on success. */ int esl_stats_DMean(const double *x, int n, double *opt_mean, double *opt_var) { double sum = 0.; double sqsum = 0.; int i; for (i = 0; i < n; i++) { sum += x[i]; sqsum += x[i]*x[i]; } if (opt_mean != NULL) *opt_mean = sum / (double) n; if (opt_var != NULL) *opt_var = (n > 1 ? fabs((sqsum - sum*sum/(double)n) / ((double)n-1)) : 0.); // fabs() avoids -epsilon result for zero variance. return eslOK; } int esl_stats_FMean(const float *x, int n, double *opt_mean, double *opt_var) { double sum = 0.; double sqsum = 0.; int i; for (i = 0; i < n; i++) { sum += x[i]; sqsum += x[i]*x[i]; } if (opt_mean != NULL) *opt_mean = sum / (double) n; if (opt_var != NULL) *opt_var = (n > 1 ? fabs((sqsum - sum*sum/(double)n) / ((double)n-1)) : 0.); // fabs() avoids -epsilon result for zero variance. return eslOK; } int esl_stats_IMean(const int *x, int n, double *opt_mean, double *opt_var) { double sum = 0.; double sqsum = 0.; int i; for (i = 0; i < n; i++) { sum += x[i]; sqsum += x[i]*x[i]; } if (opt_mean != NULL) *opt_mean = sum / (double) n; if (opt_var != NULL) *opt_var = (n > 1 ? fabs((sqsum - sum*sum/(double)n) / ((double)n-1)) : 0.); // fabs() avoids -epsilon result for zero variance. return eslOK; } /*--------------- end, summary statistics -----------------------*/ /***************************************************************** * 2. Special functions. *****************************************************************/ /* Function: esl_stats_LogGamma() * Synopsis: Calculates $\log \Gamma(x)$. * * Purpose: Returns natural log of $\Gamma(x)$, for $x > 0$. * * Credit: Adapted from a public domain implementation in the * NCBI core math library. Thanks to John Spouge and * the NCBI. (According to NCBI, that's Dr. John * "Gammas Galore" Spouge to you, pal.) * * Args: x : argument, x > 0.0 * ret_answer : RETURN: the answer * * Returns: Put the answer in ; returns . * * Throws: if $x <= 0$. */ int esl_stats_LogGamma(double x, double *ret_answer) { int i; double xx, tx; double tmp, value; static double cof[11] = { 4.694580336184385e+04, -1.560605207784446e+05, 2.065049568014106e+05, -1.388934775095388e+05, 5.031796415085709e+04, -9.601592329182778e+03, 8.785855930895250e+02, -3.155153906098611e+01, 2.908143421162229e-01, -2.319827630494973e-04, 1.251639670050933e-10 }; /* Protect against invalid x<=0 */ if (x <= 0.0) ESL_EXCEPTION(eslERANGE, "invalid x <= 0 in esl_stats_LogGamma()"); xx = x - 1.0; tx = tmp = xx + 11.0; value = 1.0; for (i = 10; i >= 0; i--) /* sum least significant terms first */ { value += cof[i] / tmp; tmp -= 1.0; } value = log(value); tx += 0.5; value += 0.918938533 + (xx+0.5)*log(tx) - tx; *ret_answer = value; return eslOK; } /* Function: esl_stats_Psi() * Synopsis: Calculates $\Psi(x)$ (the digamma function). * * Purpose: Computes $\Psi(x)$ (the "digamma" function), the * derivative of $\log \Gamma(x)$ for $x > 0$: * $d/dx \log \Gamma(x) = \frac{\Gamma'(x)}{\Gamma(x)} = \Psi(x)$. * * Implements J.M. Bernardo's "Algorithm AS 103", J Royal * Stat. Soc. C (Appl. Stat.) 25:315-317 (1976). * * Throws: if x <= 0 */ int esl_stats_Psi(double x, double *ret_answer) { double psi = 0.; double x2; if (x <= 0.0) ESL_EXCEPTION(eslERANGE, "invalid x <= 0 in esl_stats_Psi()"); else if (x <= 1e-5) { *ret_answer = -eslCONST_EULER - 1./x; return eslOK; } // For small x < S, Psi(x) ~= -0.5772 - 1/x + O(x), we're done. /* For medium x, use Psi(1+x) = \Psi(x) + 1/x to c.o.v. x, * big enough for Stirling approximation to work... */ while (x < 8.5) // This is bound C, which Bernardo sets to 8.5. { psi -= 1./x; x += 1.; } /* For large X, use Stirling approximation */ x2 = 1./x; psi += log(x) - 0.5 * x2; x2 = x2*x2; psi += (-1./12.)*x2 + (1./120.)*x2*x2 - (1./252.)*x2*x2*x2; *ret_answer = psi; // Bernardo chose S,C bounds so rel error < 1e-10. return eslOK; } /* Function: esl_stats_Trigamma() * Synopsis: Compute $Psi'(x)$ (the trigamma function) * Incept: SRE, Wed 18 May 2022 * * Purpose: Computes $\Psi'(x)$, the "trigamma" function, the second * derivative of $\log \Gamma(x)$, for $x > 0$. Needed in * maximum likelihood fitting of Gamma distributions. * * Implements "Algorithm AS 121": B.E. Schneider, J. Royal * Stat. Soc. C (Appl. Stat.), 27:97-99 (1978). * * Throws: if x <= 0. */ int esl_stats_Trigamma(double x, double *ret_answer) { double trigam = 0.; double y; if (x <= 0.) ESL_EXCEPTION(eslERANGE, "invalid x <= 0 in esl_stats_Trigamma()"); else if (x <= 1.0e-4) { *ret_answer = 1.0 / (x*x); return eslOK; } // approximation for small value case x <= A; Schneider (1978) justifies the A=1e-4 choice while (x < 5.0) // B=5.0 is also a choice justified by Schneider (1978). { // For x >= B, we go straight on to a series approximation for large x trigam += 1. / (x*x); // For A < x < B, here we use the relation Psi'(x+1) = \Psi(x) - 1/x^2 to get Psi'(x) as a constant + Psi'(z) with z=x+i >= B x += 1.; } y = 1.0 / (x*x); trigam += 0.5 * y + (1. + y*((1./6.) + y*((1./30.)+ y*((1./42.)+ y*(1./30.))))) / x; // This is the series approximation, for large x >= B. // Schneider chose A,B so rel error of approximations is < 1e-8. *ret_answer = trigam; return eslOK; } /* Function: esl_stats_IncompleteGamma() * Synopsis: Calculates the incomplete Gamma function. * * Purpose: Returns $P(a,x)$ and $Q(a,x)$ where: * * \begin{eqnarray*} * P(a,x) & = & \frac{1}{\Gamma(a)} \int_{0}^{x} t^{a-1} e^{-t} dt \\ * & = & \frac{\gamma(a,x)}{\Gamma(a)} \\ * Q(a,x) & = & \frac{1}{\Gamma(a)} \int_{x}^{\infty} t^{a-1} e^{-t} dt\\ * & = & 1 - P(a,x) \\ * \end{eqnarray*} * * $P(a,x)$ is the CDF of a gamma density with $\lambda = 1$, * and $Q(a,x)$ is the survival function. * * For $x \simeq 0$, $P(a,x) \simeq 0$ and $Q(a,x) \simeq 1$; and * $P(a,x)$ is less prone to roundoff error. * * The opposite is the case for large $x >> a$, where * $P(a,x) \simeq 1$ and $Q(a,x) \simeq 0$; there, $Q(a,x)$ is * less prone to roundoff error. * * Method: Based on ideas from Numerical Recipes in C, Press et al., * Cambridge University Press, 1988. * * Args: a - for instance, degrees of freedom / 2 [a > 0] * x - for instance, chi-squared statistic / 2 [x >= 0] * ret_pax - RETURN: P(a,x) * ret_qax - RETURN: Q(a,x) * * Return: on success. * * Throws: if or is out of accepted range. * if approximation fails to converge. */ int esl_stats_IncompleteGamma(double a, double x, double *ret_pax, double *ret_qax) { int iter; /* iteration counter */ double pax; /* P(a,x) */ double qax; /* Q(a,x) */ int status; if (a <= 0.) ESL_EXCEPTION(eslERANGE, "esl_stats_IncompleteGamma(): a must be > 0"); if (x < 0.) ESL_EXCEPTION(eslERANGE, "esl_stats_IncompleteGamma(): x must be >= 0"); /* For x > a + 1 the following gives rapid convergence; * calculate Q(a,x) = \frac{\Gamma(a,x)}{\Gamma(a)}, * using a continued fraction development for \Gamma(a,x). */ if (x > a+1) { double oldp; /* previous value of p */ double nu0, nu1; /* numerators for continued fraction calc */ double de0, de1; /* denominators for continued fraction calc */ nu0 = 0.; /* A_0 = 0 */ de0 = 1.; /* B_0 = 1 */ nu1 = 1.; /* A_1 = 1 */ de1 = x; /* B_1 = x */ oldp = nu1; for (iter = 1; iter < 100; iter++) { /* Continued fraction development: * set A_j = b_j A_j-1 + a_j A_j-2 * B_j = b_j B_j-1 + a_j B_j-2 * We start with A_2, B_2. */ /* j = even: a_j = iter-a, b_j = 1 */ /* A,B_j-2 are in nu0, de0; A,B_j-1 are in nu1,de1 */ nu0 = nu1 + ((double)iter - a) * nu0; de0 = de1 + ((double)iter - a) * de0; /* j = odd: a_j = iter, b_j = x */ /* A,B_j-2 are in nu1, de1; A,B_j-1 in nu0,de0 */ nu1 = x * nu0 + (double) iter * nu1; de1 = x * de0 + (double) iter * de1; /* rescale */ if (de1 != 0.) { nu0 /= de1; de0 /= de1; nu1 /= de1; de1 = 1.; } /* check for convergence */ if (fabs((nu1-oldp)/nu1) < 1.e-7) { if ((status = esl_stats_LogGamma(a, &qax)) != eslOK) return status; qax = nu1 * exp(a * log(x) - x - qax); if (ret_pax != NULL) *ret_pax = 1 - qax; if (ret_qax != NULL) *ret_qax = qax; return eslOK; } oldp = nu1; } ESL_EXCEPTION(eslENOHALT, "esl_stats_IncompleteGamma(): fraction failed to converge"); } else /* x <= a+1 */ { double p; /* current sum */ double val; /* current value used in sum */ /* For x <= a+1 we use a convergent series instead: * P(a,x) = \frac{\gamma(a,x)}{\Gamma(a)}, * where * \gamma(a,x) = e^{-x}x^a \sum_{n=0}{\infty} \frac{\Gamma{a}}{\Gamma{a+1+n}} x^n * which looks appalling but the sum is in fact rearrangeable to * a simple series without the \Gamma functions: * = \frac{1}{a} + \frac{x}{a(a+1)} + \frac{x^2}{a(a+1)(a+2)} ... * and it's obvious that this should converge nicely for x <= a+1. */ p = val = 1. / a; for (iter = 1; iter < 10000; iter++) { val *= x / (a+(double)iter); p += val; if (fabs(val/p) < 1.e-7) { if ((status = esl_stats_LogGamma(a, &pax)) != eslOK) return status; pax = p * exp(a * log(x) - x - pax); if (ret_pax != NULL) *ret_pax = pax; if (ret_qax != NULL) *ret_qax = 1. - pax; return eslOK; } } ESL_EXCEPTION(eslENOHALT, "esl_stats_IncompleteGamma(): series failed to converge"); } /*NOTREACHED*/ return eslOK; } /* Function: esl_stats_erfc() * Synopsis: Complementary error function. * * Purpose: Calculate and return the complementary error function, * erfc(x). * * erfc(x) is mandated by the ANSI C99 standard but that * doesn't mean it's available on supposedly modern systems * (looking at you here, Microsoft). * * Used for cumulative distribution function calculations * for the normal (Gaussian) distribution. See * module. * * erfc(-inf) = 2.0 * erfc(0) = 1.0 * erfc(inf) = 0.0 * erfc(NaN) = NaN * * Args: x : any real-numbered value -inf..inf * * Returns: erfc(x) * * Throws: (no abnormal error conditions) * * Source: * Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved. * Developed at SunPro, a Sun Microsystems, Inc. business. * Permission to use, copy, modify, and distribute this software is * freely granted, provided that this notice is preserved. * [as posted by eggcrook at stackexchange.com, 21 Dec 2012] * * Removed arcane incantations for runtime detection of endianness, * and for treating IEEE754 doubles as two adjacent uint32_t; * replaced with ANSI-compliant macros and compile-time detection * of endianness. [Apr 2015] */ double esl_stats_erfc(double x) { static const double erx = 8.45062911510467529297e-01; /* 0x3FEB0AC1, 0x60000000 */ /* * Coefficients for approximation to erf on [0,0.84375] */ static const double pp0 = 1.28379167095512558561e-01; /* 0x3FC06EBA, 0x8214DB68 */ static const double pp1 = -3.25042107247001499370e-01; /* 0xBFD4CD7D, 0x691CB913 */ static const double pp2 = -2.84817495755985104766e-02; /* 0xBF9D2A51, 0xDBD7194F */ static const double pp3 = -5.77027029648944159157e-03; /* 0xBF77A291, 0x236668E4 */ static const double pp4 = -2.37630166566501626084e-05; /* 0xBEF8EAD6, 0x120016AC */ static const double qq1 = 3.97917223959155352819e-01; /* 0x3FD97779, 0xCDDADC09 */ static const double qq2 = 6.50222499887672944485e-02; /* 0x3FB0A54C, 0x5536CEBA */ static const double qq3 = 5.08130628187576562776e-03; /* 0x3F74D022, 0xC4D36B0F */ static const double qq4 = 1.32494738004321644526e-04; /* 0x3F215DC9, 0x221C1A10 */ static const double qq5 = -3.96022827877536812320e-06; /* 0xBED09C43, 0x42A26120 */ /* * Coefficients for approximation to erf in [0.84375,1.25] */ static const double pa0 = -2.36211856075265944077e-03; /* 0xBF6359B8, 0xBEF77538 */ static const double pa1 = 4.14856118683748331666e-01; /* 0x3FDA8D00, 0xAD92B34D */ static const double pa2 = -3.72207876035701323847e-01; /* 0xBFD7D240, 0xFBB8C3F1 */ static const double pa3 = 3.18346619901161753674e-01; /* 0x3FD45FCA, 0x805120E4 */ static const double pa4 = -1.10894694282396677476e-01; /* 0xBFBC6398, 0x3D3E28EC */ static const double pa5 = 3.54783043256182359371e-02; /* 0x3FA22A36, 0x599795EB */ static const double pa6 = -2.16637559486879084300e-03; /* 0xBF61BF38, 0x0A96073F */ static const double qa1 = 1.06420880400844228286e-01; /* 0x3FBB3E66, 0x18EEE323 */ static const double qa2 = 5.40397917702171048937e-01; /* 0x3FE14AF0, 0x92EB6F33 */ static const double qa3 = 7.18286544141962662868e-02; /* 0x3FB2635C, 0xD99FE9A7 */ static const double qa4 = 1.26171219808761642112e-01; /* 0x3FC02660, 0xE763351F */ static const double qa5 = 1.36370839120290507362e-02; /* 0x3F8BEDC2, 0x6B51DD1C */ static const double qa6 = 1.19844998467991074170e-02; /* 0x3F888B54, 0x5735151D */ /* * Coefficients for approximation to erfc in [1.25,1/0.35] */ static const double ra0 = -9.86494403484714822705e-03; /* 0xBF843412, 0x600D6435 */ static const double ra1 = -6.93858572707181764372e-01; /* 0xBFE63416, 0xE4BA7360 */ static const double ra2 = -1.05586262253232909814e+01; /* 0xC0251E04, 0x41B0E726 */ static const double ra3 = -6.23753324503260060396e+01; /* 0xC04F300A, 0xE4CBA38D */ static const double ra4 = -1.62396669462573470355e+02; /* 0xC0644CB1, 0x84282266 */ static const double ra5 = -1.84605092906711035994e+02; /* 0xC067135C, 0xEBCCABB2 */ static const double ra6 = -8.12874355063065934246e+01; /* 0xC0545265, 0x57E4D2F2 */ static const double ra7 = -9.81432934416914548592e+00; /* 0xC023A0EF, 0xC69AC25C */ static const double sa1 = 1.96512716674392571292e+01; /* 0x4033A6B9, 0xBD707687 */ static const double sa2 = 1.37657754143519042600e+02; /* 0x4061350C, 0x526AE721 */ static const double sa3 = 4.34565877475229228821e+02; /* 0x407B290D, 0xD58A1A71 */ static const double sa4 = 6.45387271733267880336e+02; /* 0x40842B19, 0x21EC2868 */ static const double sa5 = 4.29008140027567833386e+02; /* 0x407AD021, 0x57700314 */ static const double sa6 = 1.08635005541779435134e+02; /* 0x405B28A3, 0xEE48AE2C */ static const double sa7 = 6.57024977031928170135e+00; /* 0x401A47EF, 0x8E484A93 */ static const double sa8 = -6.04244152148580987438e-02; /* 0xBFAEEFF2, 0xEE749A62 */ /* * Coefficients for approximation to erfc in [1/0.35,28] */ static const double rb0 = -9.86494292470009928597e-03; /* 0xBF843412, 0x39E86F4A */ static const double rb1 = -7.99283237680523006574e-01; /* 0xBFE993BA, 0x70C285DE */ static const double rb2 = -1.77579549177547519889e+01; /* 0xC031C209, 0x555F995A */ static const double rb3 = -1.60636384855821916062e+02; /* 0xC064145D, 0x43C5ED98 */ static const double rb4 = -6.37566443368389627722e+02; /* 0xC083EC88, 0x1375F228 */ static const double rb5 = -1.02509513161107724954e+03; /* 0xC0900461, 0x6A2E5992 */ static const double rb6 = -4.83519191608651397019e+02; /* 0xC07E384E, 0x9BDC383F */ static const double sb1 = 3.03380607434824582924e+01; /* 0x403E568B, 0x261D5190 */ static const double sb2 = 3.25792512996573918826e+02; /* 0x40745CAE, 0x221B9F0A */ static const double sb3 = 1.53672958608443695994e+03; /* 0x409802EB, 0x189D5118 */ static const double sb4 = 3.19985821950859553908e+03; /* 0x40A8FFB7, 0x688C246A */ static const double sb5 = 2.55305040643316442583e+03; /* 0x40A3F219, 0xCEDF3BE6 */ static const double sb6 = 4.74528541206955367215e+02; /* 0x407DA874, 0xE79FE763 */ static const double sb7 = -2.24409524465858183362e+01; /* 0xC03670E2, 0x42712D62 */ int hx,ix; double R,S,P,Q,s,y,z,r; ESL_GET_HIGHWORD(hx, x); // SRE: replaced original Sun incantation here. ix = hx & 0x7fffffff; if (ix>=0x7ff00000) /* erfc(nan)=nan; erfc(+-inf)=0,2 */ return (double)(((unsigned)hx>>31)<<1)+1.0/x; if (ix < 0x3feb0000) /* |x|<0.84375 */ { if (ix < 0x3c700000) return 1.0-x; /* |x|<2**-56 */ z = x*x; r = pp0+z*(pp1+z*(pp2+z*(pp3+z*pp4))); s = 1.0+z*(qq1+z*(qq2+z*(qq3+z*(qq4+z*qq5)))); y = r/s; if (hx < 0x3fd00000) /* x<1/4 */ { return 1.0-(x+x*y); } else { r = x*y; r += (x-0.5); return 0.5 - r ; } } if (ix < 0x3ff40000) /* 0.84375 <= |x| < 1.25 */ { s = fabs(x)-1.0; P = pa0+s*(pa1+s*(pa2+s*(pa3+s*(pa4+s*(pa5+s*pa6))))); Q = 1.0+s*(qa1+s*(qa2+s*(qa3+s*(qa4+s*(qa5+s*qa6))))); if (hx>=0) { z = 1.0-erx; return z - P/Q; } else { z = erx+P/Q; return 1.0+z; } } if (ix < 0x403c0000) /* |x|<28 */ { x = fabs(x); s = 1.0/(x*x); if (ix< 0x4006DB6D) /* |x| < 1/.35 ~ 2.857143*/ { R = ra0+s*(ra1+s*(ra2+s*(ra3+s*(ra4+s*(ra5+s*(ra6+s*ra7)))))); S = 1.0+s*(sa1+s*(sa2+s*(sa3+s*(sa4+s*(sa5+s*(sa6+s*(sa7+s*sa8))))))); } else /* |x| >= 1/.35 ~ 2.857143 */ { if (hx < 0 && ix >= 0x40180000) return 2.0; /* x < -6 */ R = rb0+s*(rb1+s*(rb2+s*(rb3+s*(rb4+s*(rb5+s*rb6))))); S = 1.0+s*(sb1+s*(sb2+s*(sb3+s*(sb4+s*(sb5+s*(sb6+s*sb7)))))); } z = x; ESL_SET_LOWWORD(z, 0); // SRE: replaced original Sun incantation here. r = exp(-z*z-0.5625) * exp((z-x)*(z+x)+R/S); if (hx>0) return r/x; else return 2.0-r/x; } else { if (hx>0) return 0.; else return 2.0; } } /*----------------- end, special functions ----------------------*/ /***************************************************************** * 3. Standard statistical tests. *****************************************************************/ /* Function: esl_stats_GTest() * Synopsis: Calculates a G-test on 2 vs. 1 binomials. * * Purpose: In experiment a, we've drawn successes in total * trials; in experiment b, we've drawn successes in * total trials. Are the counts different enough to * conclude that the two experiments are different? The * null hypothesis is that the successes in both experiments * were drawn from the same binomial distribution with * per-trial probability $p$. The tested hypothesis is that * experiments a,b have different binomial probabilities * $p_a,p_b$. The G-test is a log-likelihood-ratio statistic, * assuming maximum likelihood values for $p,p_a,p_b$. * $2G$ is distributed approximately as $X^2(1)$, * %"X" is "Chi" * which we use to calculate a P-value for the G statistic. * * Args: ca - number of positives in experiment a * na - total number in experiment a * cb - number of positives in experiment b * nb - total number in experiment b * ret_G - RETURN: G statistic, a log likelihood ratio, in nats * ret_P - RETURN: P-value for the G-statistic * * Returns: on success. * * Throws: (no abnormal error conditions) * * Xref: Archive1999/0906-sagescore/sagescore.c */ int esl_stats_GTest(int ca, int na, int cb, int nb, double *ret_G, double *ret_P) { double a,b,c,d,n; double G = 0.; a = (double) ca; b = (double) (na - ca); c = (double) cb; d = (double) (nb - cb); n = (double) na+nb; /* Yes, the calculation here is correct; algebraic * rearrangement of the log-likelihood-ratio with * p_a = ca/na, p_b = cb/nb, and p = (ca+cb)/(na+nb). * Guard against 0 probabilities; assume 0 log 0 => 0. */ if (a > 0.) G = a * log(a); if (b > 0.) G += b * log(b); if (c > 0.) G += c * log(c); if (d > 0.) G += d * log(d); if (n > 0.) G += n * log(n); if (a+b > 0.) G -= (a+b) * log(a+b); if (c+d > 0.) G -= (c+d) * log(c+d); if (a+c > 0.) G -= (a+c) * log(a+c); if (b+d > 0.) G -= (b+d) * log(b+d); *ret_G = G; return esl_stats_IncompleteGamma( 0.5, G, NULL, ret_P); } /* Function: esl_stats_ChiSquaredTest() * Synopsis: Calculates a $\chi^2$ P-value. * Incept: SRE, Tue Jul 19 11:39:32 2005 [St. Louis] * * Purpose: Calculate the probability that a chi-squared statistic * with degrees of freedom would exceed the observed * chi-squared value ; return it in . If * this probability is less than some small threshold (say, * 0.05 or 0.01), then we may reject the hypothesis we're * testing. * * Args: v - degrees of freedom * x - observed chi-squared value * ret_answer - RETURN: P(\chi^2 > x) * * Returns: on success. * * Throws: if or are out of valid range. * if iterative calculation fails. */ int esl_stats_ChiSquaredTest(int v, double x, double *ret_answer) { return esl_stats_IncompleteGamma((double)v/2., x/2., NULL, ret_answer); } /*----------------- end, statistical tests ---------------------*/ /***************************************************************** * 4. Data fitting. *****************************************************************/ /* Function: esl_stats_LinearRegression() * Synopsis: Fit data to a straight line. * Incept: SRE, Sat May 26 11:33:46 2007 [Janelia] * * Purpose: Fit points , to a straight line * $y = a + bx$ by linear regression. * * The $x_i$ are taken to be known, and the $y_i$ are taken * to be observed quantities associated with a sampling * error $\sigma_i$. If known, the standard deviations * $\sigma_i$ for $y_i$ are provided in the array. * If they are unknown, pass , and the * routine will proceed with the assumption that $\sigma_i * = 1$ for all $i$. * * The maximum likelihood estimates for $a$ and $b$ are * optionally returned in and . * * The estimated standard deviations of $a$ and $b$ and * their estimated covariance are optionally returned in * , , and . * * The Pearson correlation coefficient is optionally * returned in . * * The $\chi^2$ P-value for the regression fit is * optionally returned in . This P-value may only be * obtained when the $\sigma_i$ are known. If is * passed as and is requested, <*opt_Q> is * set to 1.0. * * This routine follows the description and algorithm in * \citep[pp.661-666]{Press93}. * * must be greater than 2; at least two x[i] must * differ; and if is provided, all must * be $>0$. If any of these conditions isn't met, the * routine throws . * * Args: x - x[0..n-1] * y - y[0..n-1] * sigma - sample error in observed y_i * n - number of data points * opt_a - optRETURN: intercept estimate * opt_b - optRETURN: slope estimate * opt_sigma_a - optRETURN: error in estimate of a * opt_sigma_b - optRETURN: error in estimate of b * opt_cov_ab - optRETURN: covariance of a,b estimates * opt_cc - optRETURN: Pearson correlation coefficient for x,y * opt_Q - optRETURN: X^2 P-value for linear fit * * Returns: on success. * * Throws: on allocation error; * if a contract condition isn't met; * if the chi-squared test fails. * In these cases, all optional return values are set to 0. */ int esl_stats_LinearRegression(const double *x, const double *y, const double *sigma, int n, double *opt_a, double *opt_b, double *opt_sigma_a, double *opt_sigma_b, double *opt_cov_ab, double *opt_cc, double *opt_Q) { int status; double *t = NULL; double S, Sx, Sy, Stt; double Sxy, Sxx, Syy; double a, b, sigma_a, sigma_b, cov_ab, cc, X2, Q; double xdev, ydev; double tmp; int i; /* Contract checks. */ if (n <= 2) ESL_XEXCEPTION(eslEINVAL, "n must be > 2 for linear regression fitting"); if (sigma != NULL) for (i = 0; i < n; i++) if (sigma[i] <= 0.) ESL_XEXCEPTION(eslEINVAL, "sigma[%d] <= 0", i); status = eslEINVAL; for (i = 0; i < n; i++) if (x[i] != 0.) { status = eslOK; break; } if (status != eslOK) ESL_XEXCEPTION(eslEINVAL, "all x[i] are 0."); /* Allocations */ ESL_ALLOC(t, sizeof(double) * n); /* S = \sum_{i=1}{n} \frac{1}{\sigma_i^2}. (S > 0.) */ if (sigma != NULL) { for (S = 0., i = 0; i < n; i++) S += 1./ (sigma[i] * sigma[i]); } else S = (double) n; /* S_x = \sum_{i=1}{n} \frac{x[i]}{ \sigma_i^2} (Sx real.) */ for (Sx = 0., i = 0; i < n; i++) { if (sigma == NULL) Sx += x[i]; else Sx += x[i] / (sigma[i] * sigma[i]); } /* S_y = \sum_{i=1}{n} \frac{y[i]}{\sigma_i^2} (Sy real.) */ for (Sy = 0., i = 0; i < n; i++) { if (sigma == NULL) Sy += y[i]; else Sy += y[i] / (sigma[i] * sigma[i]); } /* t_i = \frac{1}{\sigma_i} \left( x_i - \frac{S_x}{S} \right) (t_i real) */ for (i = 0; i < n; i++) { t[i] = x[i] - Sx/S; if (sigma != NULL) t[i] /= sigma[i]; } /* S_{tt} = \sum_{i=1}^n t_i^2 (if at least one x is != 0, Stt > 0) */ for (Stt = 0., i = 0; i < n; i++) { Stt += t[i] * t[i]; } /* b = \frac{1}{S_{tt}} \sum_{i=1}^{N} \frac{t_i y_i}{\sigma_i} */ for (b = 0., i = 0; i < n; i++) { if (sigma != NULL) { b += t[i]*y[i] / sigma[i]; } else { b += t[i]*y[i]; } } b /= Stt; /* a = \frac{ S_y - S_x b } {S} */ a = (Sy - Sx * b) / S; /* \sigma_a^2 = \frac{1}{S} \left( 1 + \frac{ S_x^2 }{S S_{tt}} \right) */ sigma_a = sqrt ((1. + (Sx*Sx) / (S*Stt)) / S); /* \sigma_b = \frac{1}{S_{tt}} */ sigma_b = sqrt (1. / Stt); /* Cov(a,b) = - \frac{S_x}{S S_{tt}} */ cov_ab = -Sx / (S * Stt); /* Pearson correlation coefficient */ Sxy = Sxx = Syy = 0.; for (i = 0; i < n; i++) { if (sigma != NULL) { xdev = (x[i] / (sigma[i] * sigma[i])) - (Sx / n); ydev = (y[i] / (sigma[i] * sigma[i])) - (Sy / n); } else { xdev = x[i] - (Sx / n); ydev = y[i] - (Sy / n); } Sxy += xdev * ydev; Sxx += xdev * xdev; Syy += ydev * ydev; } cc = Sxy / (sqrt(Sxx) * sqrt(Syy)); /* \chi^2 */ for (X2 = 0., i = 0; i < n; i++) { tmp = y[i] - a - b*x[i]; if (sigma != NULL) tmp /= sigma[i]; X2 += tmp*tmp; } /* We can calculate a goodness of fit if we know the \sigma_i */ if (sigma != NULL) { if (esl_stats_ChiSquaredTest(n-2, X2, &Q) != eslOK) { status = eslENORESULT; goto ERROR; } } else Q = 1.0; /* If we didn't use \sigma_i, adjust the sigmas for a,b */ if (sigma == NULL) { tmp = sqrt(X2 / (double)(n-2)); sigma_a *= tmp; sigma_b *= tmp; } /* Done. Set up for normal return. */ free(t); if (opt_a != NULL) *opt_a = a; if (opt_b != NULL) *opt_b = b; if (opt_sigma_a != NULL) *opt_sigma_a = sigma_a; if (opt_sigma_b != NULL) *opt_sigma_b = sigma_b; if (opt_cov_ab != NULL) *opt_cov_ab = cov_ab; if (opt_cc != NULL) *opt_cc = cc; if (opt_Q != NULL) *opt_Q = Q; return eslOK; ERROR: if (t != NULL) free(t); if (opt_a != NULL) *opt_a = 0.; if (opt_b != NULL) *opt_b = 0.; if (opt_sigma_a != NULL) *opt_sigma_a = 0.; if (opt_sigma_b != NULL) *opt_sigma_b = 0.; if (opt_cov_ab != NULL) *opt_cov_ab = 0.; if (opt_cc != NULL) *opt_cc = 0.; if (opt_Q != NULL) *opt_Q = 0.; return status; } /*------------------- end, data fitting -------------------------*/ /***************************************************************** * 5. Unit tests. *****************************************************************/ #ifdef eslSTATS_TESTDRIVE #include "esl_random.h" #include "esl_stopwatch.h" #ifdef HAVE_LIBGSL #include #endif static void utest_DMean(ESL_RANDOMNESS *rng) { char msg[] = "esl_stats:: DMean unit test failed"; double x[10000]; int n = 10000; int i; double mean, var; for (i = 0; i < n; i++) x[i] = esl_random(rng); esl_stats_DMean(x, n, &mean, &var); if (esl_DCompare(0.5, mean, 0., 0.01) != eslOK) esl_fatal(msg); // mean of U(0,1) = 0.5 if (esl_DCompare(1./12., var, 0., 0.01) != eslOK) esl_fatal(msg); // var of U(0,1) = 1/12 /* pathological case 1: all x[i] equal. */ for (i = 1; i < n; i++) x[i] = x[0]; esl_stats_DMean(x, n, &mean, &var); if (esl_DCompare(x[0], mean, 0., 1e-5) != eslOK) esl_fatal(msg); if (esl_DCompare(0.0, var, 0., 1e-5) != eslOK) esl_fatal(msg); // zero variance /* pathological case 2: n=1 */ esl_stats_DMean(x, 1, &mean, &var); if (esl_DCompare(x[0], mean, 0., 1e-5) != eslOK) esl_fatal(msg); if (esl_DCompare(0.0, var, 0., 1e-5) != eslOK) esl_fatal(msg); // zero variance } static void utest_FMean(ESL_RANDOMNESS *rng) { char msg[] = "esl_stats:: FMean unit test failed"; float x[10000]; int n = 10000; int i; double mean, var; for (i = 0; i < n; i++) x[i] = esl_random(rng); esl_stats_FMean(x, n, &mean, &var); // mean, var are in doubles if (esl_DCompare(0.5, mean, 0., 0.01) != eslOK) esl_fatal(msg); // mean of U(0,1) = 0.5 if (esl_DCompare(1./12., var, 0., 0.01) != eslOK) esl_fatal(msg); // var of U(0,1) = 1/12 /* pathological case 1: all x[i] equal. */ for (i = 1; i < n; i++) x[i] = x[0]; esl_stats_FMean(x, n, &mean, &var); if (esl_DCompare(x[0], mean, 0., 1e-5) != eslOK) esl_fatal(msg); if (esl_DCompare(0.0, var, 0., 1e-5) != eslOK) esl_fatal(msg); // zero variance /* pathological case 2: n=1 */ esl_stats_FMean(x, 1, &mean, &var); if (esl_DCompare(x[0], mean, 0., 1e-5) != eslOK) esl_fatal(msg); if (esl_DCompare(0.0, var, 0., 1e-5) != eslOK) esl_fatal(msg); // zero variance } static void utest_IMean(ESL_RANDOMNESS *rng) { char msg[] = "esl_stats:: IMean unit test failed"; int x[10000]; int n = 10000; int i; double mean, var; double mean0,var0; for (i = 0; i < n; i++) x[i] = esl_rnd_Roll(rng, 101); // U(0,100) mean0 = 100./2.; // mean of discrete U(a,b) = (a+b)/2 var0 = (101.0*101.0-1.)/12.; // variance of discrete U(a,b) = ((b-a+1)^2 -1)/12 esl_stats_IMean(x, n, &mean, &var); // mean, var are in doubles if (esl_DCompare(mean0, mean, 0.02, 0.02) != eslOK) esl_fatal(msg); if (esl_DCompare(var0, var, 0.02, 0.02) != eslOK) esl_fatal(msg); /* pathological case 1: all x[i] equal. */ for (i = 1; i < n; i++) x[i] = x[0]; esl_stats_IMean(x, n, &mean, &var); mean0 = (double) x[0]; var0 = 0.; if (esl_DCompare(mean0, mean, 0., 1e-5) != eslOK) esl_fatal(msg); if (esl_DCompare(var0, var, 0., 1e-5) != eslOK) esl_fatal(msg); // zero variance /* pathological case 2: n=1 */ esl_stats_IMean(x, 1, &mean, &var); if (esl_DCompare(mean0, mean, 0., 1e-5) != eslOK) esl_fatal(msg); if (esl_DCompare(var0, var, 0., 1e-5) != eslOK) esl_fatal(msg); // zero variance } /* Macros for treating IEEE754 double as two uint32_t halves, with * compile-time handling of endianness; see esl_stats.h. */ static void utest_doublesplitting(ESL_RANDOMNESS *rng) { char msg[] = "esl_stats:: doublesplitting unit test failed"; uint32_t ix0, ix1; double x; double x2; int iteration; // iteration 0 uses x = 2; iteration 1 uses random x = [0,1). for (iteration = 0; iteration < 2; iteration++) { x = (iteration == 0 ? 2.0 : esl_random(rng)); ESL_GET_WORDS(ix0, ix1, x); ESL_SET_WORDS(x2, ix0, ix1); if (x2 != x) esl_fatal(msg); ESL_GET_HIGHWORD(ix0, x); ESL_SET_HIGHWORD(x2, ix0); if (x2 != x) esl_fatal(msg); ESL_GET_LOWWORD(ix0, x); ESL_SET_LOWWORD(x2, ix0); if (iteration == 0 && ix0 != 0) esl_fatal(msg); if (x2 != x) esl_fatal(msg); } } /* The LogGamma() function is rate-limiting in hmmbuild, because it is * used so heavily in mixture Dirichlet calculations. * ./configure --with-gsl; [compile test driver] * ./stats_utest -v * runs a comparison of time/precision against GSL. * SRE, Sat May 23 10:04:41 2009, on home Mac: * LogGamma = 1.29u / N=1e8 = 13 nsec/call * gsl_sf_lngamma = 1.43u / N=1e8 = 14 nsec/call */ static void utest_LogGamma(ESL_RANDOMNESS *r, int N, int be_verbose) { char *msg = "esl_stats_LogGamma() unit test failed"; ESL_STOPWATCH *w = esl_stopwatch_Create(); double *x = malloc(sizeof(double) * N); double *lg = malloc(sizeof(double) * N); double *lg2 = malloc(sizeof(double) * N); int i; for (i = 0; i < N; i++) x[i] = esl_random(r) * 100.; esl_stopwatch_Start(w); for (i = 0; i < N; i++) if (esl_stats_LogGamma(x[i], &(lg[i])) != eslOK) esl_fatal(msg); esl_stopwatch_Stop(w); if (be_verbose) esl_stopwatch_Display(stdout, w, "esl_stats_LogGamma() timing: "); #ifdef HAVE_LIBGSL esl_stopwatch_Start(w); for (i = 0; i < N; i++) lg2[i] = gsl_sf_lngamma(x[i]); esl_stopwatch_Stop(w); if (be_verbose) esl_stopwatch_Display(stdout, w, "gsl_sf_lngamma() timing: "); for (i = 0; i < N; i++) if (esl_DCompare_old(lg[i], lg2[i], 1e-2) != eslOK) esl_fatal(msg); #endif free(lg2); free(lg); free(x); esl_stopwatch_Destroy(w); } static void utest_psi(ESL_RANDOMNESS *rng) { char msg[] = "esl_stats:: psi unit test failed"; int ntrials = 5; // number of random x's to check int regime; // distribute our checks into all three regimes for esl_stats_Psi()'s approximations double x, psi_slow, psi, n; // those three regimes are 0 < x <= 1e-5; 1e-5 < x < 8.5; x >= 8.5 while (ntrials--) { regime = esl_rnd_Roll(rng, 3); // x <= S, S < x < C, x >= C regimes for esl_stats_Psi(); for if (regime == 0) x = 1.0e-5 * esl_rnd_UniformPositive(rng); // (0,1e-5); only rarely tests < 1e-6, won't test 1e-5 exactly, but fine else if (regime == 1) x = 8.5 * esl_rnd_UniformPositive(rng); // (0,8.5); rarely this'll be < 1e-4 but that's fine else x = 8.5 + 91.5*esl_random(rng); // [8.5,100) // Check against (slowly converging) series approximations eqn(3) and eqn(2) combined, from Bernardo (1976) // The esl_stats_Psi() function already uses eqn(2) for x<=1e-5, so it's sort of pointless to test x<=1e-5, but whatever, it's not nothing to check psi_slow = -eslCONST_EULER - 1./x; for (n = 1.; n < 500000.; n += 1.) psi_slow += x / (n*(n+x)); if (esl_stats_Psi(x, &psi) != eslOK) esl_fatal(msg); if (esl_DCompare(psi, psi_slow, 1e-4, 1e-4)) esl_fatal(msg); } } static void utest_trigamma(ESL_RANDOMNESS *rng) { char msg[] = "esl_stats:: trigamma unit test failed"; int ntrials = 5; // number of random x's to check int regime; // distribute our checks into all three regimes of esl_stats_Trigamma()'s approximations double x, trigam_slow, trigam, i; // those regimes are 0 < x <= 1e-4, 1e-4 < x < 5.0, x >= 5.0 while (ntrials--) { regime = esl_rnd_Roll(rng, 3); // x <= A, A < x < B, x >= B regimes for esl_stats_Trigamma() if (regime == 0) x = 1.0e-4 * esl_rnd_UniformPositive(rng); // (0,1e-4); only rarely tests < 1e-5, won't test 1e-4 exactly, but fine else if (regime == 1) x = 5.0 * esl_rnd_UniformPositive(rng); // (0,5); rarely this'll be < 1e-4 but that's fine else x = 5.0 + 95.*esl_random(rng); // [5,100) if (x <= 0. || x >= 100.) esl_fatal(msg); // this would probably mean a failure in the ranges of esl_random functions above // This is series approximation eqn(2) from Schneider (1978), // and boy he's not kidding that it's slowly converging trigam_slow = 0.; for (i = 0.; i < 1000000.; i += 1.0) trigam_slow += 1./((x+i)*(x+i)); if (esl_stats_Trigamma(x, &trigam) != eslOK) esl_fatal(msg); if (esl_DCompare(trigam, trigam_slow, 1e-4, 1e-4)) esl_fatal(msg); } } /* The test of esl_stats_LinearRegression() is a statistical test, * so we can't be too aggressive about testing results. * * Args: * r - a source of randomness * use_sigma - TRUE to pass sigma to the regression fit. * be_verbose - TRUE to print results (manual, not automated test mode) */ static void utest_LinearRegression(ESL_RANDOMNESS *r, int use_sigma, int be_verbose) { char msg[] = "linear regression unit test failed"; double a = -3.; double b = 1.; int n = 100; double xori = -20.; double xstep = 1.0; double setsigma = 1.0; /* sigma on all points */ int i; double *x = NULL; double *y = NULL; double *sigma = NULL; double ae, be, siga, sigb, cov_ab, cc, Q; if ((x = malloc(sizeof(double) * n)) == NULL) esl_fatal(msg); if ((y = malloc(sizeof(double) * n)) == NULL) esl_fatal(msg); if ((sigma = malloc(sizeof(double) * n)) == NULL) esl_fatal(msg); /* Simulate some linear data */ for (i = 0; i < n; i++) { sigma[i] = setsigma; x[i] = xori + i*xstep; y[i] = esl_rnd_Gaussian(r, a + b*x[i], sigma[i]); } if (use_sigma) { if (esl_stats_LinearRegression(x, y, sigma, n, &ae, &be, &siga, &sigb, &cov_ab, &cc, &Q) != eslOK) esl_fatal(msg); } else { if (esl_stats_LinearRegression(x, y, NULL, n, &ae, &be, &siga, &sigb, &cov_ab, &cc, &Q) != eslOK) esl_fatal(msg); } if (be_verbose) { printf("Linear regression test:\n"); printf("estimated intercept a = %8.4f [true = %8.4f]\n", ae, a); printf("estimated slope b = %8.4f [true = %8.4f]\n", be, b); printf("estimated sigma on a = %8.4f\n", siga); printf("estimated sigma on b = %8.4f\n", sigb); printf("estimated cov(a,b) = %8.4f\n", cov_ab); printf("correlation coeff = %8.4f\n", cc); printf("P-value = %8.4f\n", Q); } /* The following tests are statistical. */ if ( fabs(ae-a) > 2*siga ) esl_fatal(msg); if ( fabs(be-b) > 2*sigb ) esl_fatal(msg); if ( cc < 0.95) esl_fatal(msg); if (use_sigma) { if (Q < 0.001) esl_fatal(msg); } else { if (Q != 1.0) esl_fatal(msg); } free(x); free(y); free(sigma); } static void utest_erfc(ESL_RANDOMNESS *rng, int be_verbose) { char msg[] = "esl_stats:: erfc unit test failed"; double x; double result; int i; if (be_verbose) { printf("#--------------------------\n"); printf("# erfc unit testing...\n"); } result = esl_stats_erfc( eslNaN); if (! isnan(result)) esl_fatal(msg); if (esl_stats_erfc(-eslINFINITY) != 2.0) esl_fatal(msg); if (esl_stats_erfc( 0.0) != 1.0) esl_fatal(msg); if (esl_stats_erfc( eslINFINITY) != 0.0) esl_fatal(msg); for (i = 0; i < 42; i++) { x = esl_random(rng) * 10. - 5.; result = esl_stats_erfc(x); if (!isfinite(result)) esl_fatal(msg); #ifdef HAVE_ERFC if (esl_DCompare_old(result, erfc(x), 1e-6) != eslOK) esl_fatal(msg); if (be_verbose) printf("%15f %15f %15f\n", x, result, erfc(x)); #endif } if (be_verbose) printf("#--------------------------\n"); return; } #endif /*eslSTATS_TESTDRIVE*/ /*-------------------- end of unit tests ------------------------*/ /***************************************************************** * 6. Test driver. *****************************************************************/ #ifdef eslSTATS_TESTDRIVE /* gcc -g -Wall -o stats_utest -L. -I. -DeslSTATS_TESTDRIVE esl_stats.c -leasel -lm * gcc -DHAVE_LIBGSL -O2 -o stats_utest -L. -I. -DeslSTATS_TESTDRIVE esl_stats.c -leasel -lgsl -lm */ #include #include "easel.h" #include "esl_getopts.h" #include "esl_random.h" #include "esl_stats.h" static ESL_OPTIONS options[] = { /* name type default env range togs reqs incomp help docgrp */ {"-h", eslARG_NONE, FALSE, NULL, NULL, NULL, NULL, NULL, "show help and usage", 0}, {"-s", eslARG_INT, "42", NULL, NULL, NULL, NULL, NULL, "set random number seed to ", 0}, {"-v", eslARG_NONE, FALSE, NULL, NULL, NULL, NULL, NULL, "verbose: show verbose output", 0}, {"-N", eslARG_INT,"10000000", NULL, NULL, NULL, NULL, NULL, "number of trials in LogGamma test", 0}, { 0,0,0,0,0,0,0,0,0,0}, }; static char usage[] = "[-options]"; static char banner[] = "test driver for stats special functions"; int main(int argc, char **argv) { ESL_GETOPTS *go = esl_getopts_CreateDefaultApp(options, 0, argc, argv, banner, usage); ESL_RANDOMNESS *r = esl_randomness_Create(esl_opt_GetInteger(go, "-s")); int be_verbose = esl_opt_GetBoolean(go, "-v"); int N = esl_opt_GetInteger(go, "-N"); if (be_verbose) printf("seed = %" PRIu32 "\n", esl_randomness_GetSeed(r)); utest_DMean(r); utest_FMean(r); utest_IMean(r); utest_doublesplitting(r); utest_erfc(r, be_verbose); utest_LogGamma(r, N, be_verbose); utest_psi(r); utest_trigamma(r); utest_LinearRegression(r, TRUE, be_verbose); utest_LinearRegression(r, FALSE, be_verbose); esl_getopts_Destroy(go); esl_randomness_Destroy(r); exit(0); } #endif /*eslSTATS_TESTDRIVE*/ /*------------------- end of test driver ------------------------*/ /***************************************************************** * 7. Examples. *****************************************************************/ /* Compile: gcc -g -Wall -o example -I. -DeslSTATS_EXAMPLE esl_stats.c esl_random.c easel.c -lm * or gcc -g -Wall -o example -I. -L. -DeslSTATS_EXAMPLE esl_stats.c -leasel -lm */ #ifdef eslSTATS_EXAMPLE /*::cexcerpt::stats_example::begin::*/ /* gcc -g -Wall -o example -I. -DeslSTATS_EXAMPLE esl_stats.c esl_random.c easel.c -lm */ #include #include "easel.h" #include "esl_random.h" #include "esl_stats.h" int main(void) { ESL_RANDOMNESS *r = esl_randomness_Create(0); double a = -3.; double b = 1.; double xori = -20.; double xstep = 1.0; double setsigma = 1.0; /* sigma on all points */ int n = 100; double *x = malloc(sizeof(double) * n); double *y = malloc(sizeof(double) * n); double *sigma = malloc(sizeof(double) * n); int i; double ae, be, siga, sigb, cov_ab, cc, Q; /* Simulate some linear data, with Gaussian noise added to y_i */ for (i = 0; i < n; i++) { sigma[i] = setsigma; x[i] = xori + i*xstep; y[i] = esl_rnd_Gaussian(r, a + b*x[i], sigma[i]); } if (esl_stats_LinearRegression(x, y, sigma, n, &ae, &be, &siga, &sigb, &cov_ab, &cc, &Q) != eslOK) esl_fatal("linear regression failed"); printf("estimated intercept a = %8.4f [true = %8.4f]\n", ae, a); printf("estimated slope b = %8.4f [true = %8.4f]\n", be, b); printf("estimated sigma on a = %8.4f\n", siga); printf("estimated sigma on b = %8.4f\n", sigb); printf("estimated cov(a,b) = %8.4f\n", cov_ab); printf("correlation coeff = %8.4f\n", cc); printf("P-value = %8.4f\n", Q); free(x); free(y); free(sigma); esl_randomness_Destroy(r); exit(0); } /*::cexcerpt::stats_example::end::*/ #endif /* eslSTATS_EXAMPLE */ #ifdef eslSTATS_EXAMPLE2 #include #include "easel.h" #include "esl_getopts.h" #include "esl_stats.h" static ESL_OPTIONS options[] = { /* name type default env range toggles reqs incomp help docgroup*/ { "-h", eslARG_NONE, FALSE, NULL, NULL, NULL, NULL, NULL, "show brief help on version and usage", 0 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }, }; static char usage[] = "[-options] "; static char banner[] = "example from the stats module: using a G-test"; int main(int argc, char **argv) { ESL_GETOPTS *go = esl_getopts_CreateDefaultApp(options, 4, argc, argv, banner, usage); int ca = strtol(esl_opt_GetArg(go, 1), NULL, 10); int na = strtol(esl_opt_GetArg(go, 2), NULL, 10); int cb = strtol(esl_opt_GetArg(go, 3), NULL, 10); int nb = strtol(esl_opt_GetArg(go, 4), NULL, 10); double G, P; int status; if (ca > na || cb > nb) esl_fatal("argument order wrong? expect ca, na, cb, nb for ca/na, cb/nb"); if ( (status = esl_stats_GTest(ca, na, cb, nb, &G, &P)) != eslOK) esl_fatal("G-test failed?"); printf("%-10.3g %12.2f\n", P, G); exit(0); } #endif /* eslSTATS_EXAMPLE2 */ /*--------------------- end of examples -------------------------*/