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Uploaded r11 from test tool shed.
| author | adam-novak |
|---|---|
| date | Tue, 22 Oct 2013 14:17:59 -0400 |
| parents | |
| children |
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function jstat(){} j = jstat; /* Simple JavaScript Inheritance * By John Resig http://ejohn.org/ * MIT Licensed. */ // Inspired by base2 and Prototype (function(){ var initializing = false, fnTest = /xyz/.test(function(){ xyz; }) ? /\b_super\b/ : /.*/; // The base Class implementation (does nothing) this.Class = function(){}; // Create a new Class that inherits from this class Class.extend = function(prop) { var _super = this.prototype; // Instantiate a base class (but only create the instance, // don't run the init constructor) initializing = true; var prototype = new this(); initializing = false; // Copy the properties over onto the new prototype for (var name in prop) { // Check if we're overwriting an existing function prototype[name] = typeof prop[name] == "function" && typeof _super[name] == "function" && fnTest.test(prop[name]) ? (function(name, fn){ return function() { var tmp = this._super; // Add a new ._super() method that is the same method // but on the super-class this._super = _super[name]; // The method only need to be bound temporarily, so we // remove it when we're done executing var ret = fn.apply(this, arguments); this._super = tmp; return ret; }; })(name, prop[name]) : prop[name]; } // The dummy class constructor function Class() { // All construction is actually done in the init method if ( !initializing && this.init ) this.init.apply(this, arguments); } // Populate our constructed prototype object Class.prototype = prototype; // Enforce the constructor to be what we expect Class.constructor = Class; // And make this class extendable Class.extend = arguments.callee; return Class; }; })(); /******************************************************************************/ /* Constants */ /******************************************************************************/ jstat.ONE_SQRT_2PI = 0.3989422804014327; jstat.LN_SQRT_2PI = 0.9189385332046727417803297; jstat.LN_SQRT_PId2 = 0.225791352644727432363097614947; jstat.DBL_MIN = 2.22507e-308; jstat.DBL_EPSILON = 2.220446049250313e-16; jstat.SQRT_32 = 5.656854249492380195206754896838; jstat.TWO_PI = 6.283185307179586; jstat.DBL_MIN_EXP = -999; jstat.SQRT_2dPI = 0.79788456080287; jstat.LN_SQRT_PI = 0.5723649429247; /******************************************************************************/ /* jstat Functions */ /******************************************************************************/ jstat.seq = function(min, max, length) { var r = new Range(min, max, length); return r.getPoints(); } jstat.dnorm = function(x, mean, sd, log) { if(mean == null) mean = 0; if(sd == null) sd = 1; if(log == null) log = false; var n = new NormalDistribution(mean, sd); if(!isNaN(x)) { // is a number return n._pdf(x, log); } else if(x.length) { var res = []; for(var i = 0; i < x.length; i++) { res.push(n._pdf(x[i], log)); } return res; } else { throw "Illegal argument: x"; } } jstat.pnorm = function(q, mean, sd, lower_tail, log) { if(mean == null) mean = 0; if(sd == null) sd = 1; if(lower_tail == null) lower_tail = true; if(log == null) log = false; var n = new NormalDistribution(mean, sd); if(!isNaN(q)) { // is a number return n._cdf(q, lower_tail, log); } else if(q.length) { var res = []; for(var i = 0; i < q.length; i++) { res.push(n._cdf(q[i], lower_tail, log)); } return res; } else { throw "Illegal argument: x"; } } jstat.dlnorm = function(x, meanlog, sdlog, log) { if(meanlog == null) meanlog = 0; if(sdlog == null) sdlog = 1; if(log == null) log = false; var n = new LogNormalDistribution(meanlog, sdlog); if(!isNaN(x)) { // is a number return n._pdf(x, log); } else if(x.length) { var res = []; for(var i = 0; i < x.length; i++) { res.push(n._pdf(x[i], log)); } return res; } else { throw "Illegal argument: x"; } } jstat.plnorm = function(q, meanlog, sdlog, lower_tail, log) { if(meanlog == null) meanlog = 0; if(sdlog == null) sdlog = 1; if(lower_tail == null) lower_tail = true; if(log == null) log = false; var n = new LogNormalDistribution(meanlog, sdlog); if(!isNaN(q)) { // is a number return n._cdf(q, lower_tail, log); } else if(q.length) { var res = []; for(var i = 0; i < q.length; i++) { res.push(n._cdf(q[i], lower_tail, log)); } return res; } else { throw "Illegal argument: x"; } } jstat.dbeta = function(x, alpha, beta, ncp, log) { if(ncp == null) ncp = 0; if(log == null) log = false; var b = new BetaDistribution(alpha, beta); if(!isNaN(x)) { // is a number return b._pdf(x, log); } else if(x.length) { var res = []; for(var i = 0; i < x.length; i++) { res.push(b._pdf(x[i], log)); } return res; } else { throw "Illegal argument: x"; } } jstat.pbeta = function(q, alpha, beta, ncp, lower_tail, log) { if(ncp == null) ncp = 0; if(log == null) log = false; if(lower_tail == null) lower_tail = true; var b = new BetaDistribution(alpha, beta); if(!isNaN(q)) { // is a number return b._cdf(q, lower_tail, log); } else if(q.length) { var res = []; for(var i = 0; i < q.length; i++) { res.push(b._cdf(q[i], lower_tail, log)); } return res; } else { throw "Illegal argument: x"; } } jstat.dgamma = function(x, shape, rate, scale, log) { if(rate == null) rate = 1; if(scale == null) scale = 1/rate; if(log == null) log = false; var g = new GammaDistribution(shape, scale); if(!isNaN(x)) { // is a number return g._pdf(x, log); } else if(x.length) { var res = []; for(var i = 0; i < x.length; i++) { res.push(g._pdf(x[i], log)); } return res; } else { throw "Illegal argument: x"; } } jstat.pgamma = function(q, shape, rate, scale, lower_tail, log) { if(rate == null) rate = 1; if(scale == null) scale = 1/rate; if(lower_tail == null) lower_tail = true; if(log == null) log = false; var g = new GammaDistribution(shape, scale); if(!isNaN(q)) { // is a number return g._cdf(q, lower_tail, log); } else if(q.length) { var res = []; for(var i = 0; i < q.length; i++) { res.push(g._cdf(q[i], lower_tail, log)); } return res; } else { throw "Illegal argument: x"; } } jstat.dt = function(x, df, ncp, log) { if(log == null) log = false; var t = new StudentTDistribution(df, ncp); if(!isNaN(x)) { // is a number return t._pdf(x, log); } else if(x.length) { var res = []; for(var i = 0; i < x.length; i++) { res.push(t._pdf(x[i], log)); } return res; } else { throw "Illegal argument: x"; } } jstat.pt = function(q, df, ncp, lower_tail, log) { if(lower_tail == null) lower_tail = true; if(log == null) log = false; var t = new StudentTDistribution(df, ncp); if(!isNaN(q)) { // is a number return t._cdf(q, lower_tail, log); } else if(q.length) { var res = []; for(var i = 0; i < q.length; i++) { res.push(t._cdf(q[i], lower_tail, log)); } return res; } else { throw "Illegal argument: x"; } } jstat.plot = function(x, y, options) { if(x == null) { throw "x is undefined in jstat.plot"; } if(y == null) { throw "y is undefined in jstat.plot"; } if(x.length != y.length) { throw "x and y lengths differ in jstat.plot"; } var flotOpt = { series: { lines: { }, points: { } } }; // combine x & y var series = []; if(x.length == undefined) { // single point series.push([x, y]); flotOpt.series.points.show = true; } else { // array for(var i = 0; i < x.length; i++) { series.push([x[i], y[i]]); } } var title = 'jstat graph'; // configure Flot options if(options != null) { // options = JSON.parse(String(options)); if(options.type != null) { if(options.type == 'l') { flotOpt.series.lines.show = true; } else if (options.type == 'p') { flotOpt.series.lines.show = false; flotOpt.series.points.show = true; } } if(options.hover != null) { flotOpt.grid = { hoverable: options.hover } } if(options.main != null) { title = options.main; } } var now = new Date(); var hash = now.getMilliseconds() * now.getMinutes() + now.getSeconds(); $('body').append('<div title="' + title + '" style="display: none;" id="'+ hash +'"><div id="graph-' + hash + '" style="width:95%; height: 95%"></div></div>'); $('#' + hash).dialog({ modal: false, width: 475, height: 475, resizable: true, resize: function() { $.plot($('#graph-' + hash), [series], flotOpt); }, open: function(event, ui) { var id = '#graph-' + hash; $.plot($('#graph-' + hash), [series], flotOpt); } }) } /******************************************************************************/ /* Special Functions */ /******************************************************************************/ jstat.log10 = function(arg) { return Math.log(arg) / Math.LN10; } /* * */ jstat.toSigFig = function(num, n) { if(num == 0) { return 0; } var d = Math.ceil(jstat.log10(num < 0 ? -num: num)); var power = n - parseInt(d); var magnitude = Math.pow(10,power); var shifted = Math.round(num*magnitude); return shifted/magnitude; } jstat.trunc = function(x) { return (x > 0) ? Math.floor(x) : Math.ceil(x); } /** * Tests whether x is a finite number */ jstat.isFinite = function(x) { return (!isNaN(x) && (x != Number.POSITIVE_INFINITY) && (x != Number.NEGATIVE_INFINITY)); } /** * dopois_raw() computes the Poisson probability lb^x exp(-lb) / x!. * This does not check that x is an integer, since dgamma() may * call this with a fractional x argument. Any necessary argument * checks should be done in the calling function. */ jstat.dopois_raw = function(x, lambda, give_log) { /* x >= 0 ; integer for dpois(), but not e.g. for pgamma()! lambda >= 0 */ if (lambda == 0) { if(x == 0) { return(give_log) ? 0.0 : 1.0; //R_D__1 } return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0 } if (!jstat.isFinite(lambda)) return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; //R_D__0; if (x < 0) return(give_log) ? Number.NEGATIVE_INFINITY : 0.0; //R_D__0 if (x <= lambda * jstat.DBL_MIN) { return (give_log) ? -lambda : Math.exp(-lambda); // R_D_exp(-lambda) } if (lambda < x * jstat.DBL_MIN) { var param = -lambda + x*Math.log(lambda) -jstat.lgamma(x+1); return (give_log) ? param : Math.exp(param); // R_D_exp(-lambda + x*log(lambda) -lgammafn(x+1)) } var param1 = jstat.TWO_PI * x; // f var param2 = -jstat.stirlerr(x)-jstat.bd0(x,lambda); // x return (give_log) ? -0.5*Math.log(param1)+param2 : Math.exp(param2)/Math.sqrt(param1); // R_D_fexp(M_2PI*x, -stirlerr(x)-bd0(x,lambda)) //return(R_D_fexp( , -stirlerr(x)-bd0(x,lambda) )); } /** Evaluates the "deviance part" * bd0(x,M) := M * D0(x/M) = M*[ x/M * log(x/M) + 1 - (x/M) ] = * = x * log(x/M) + M - x * where M = E[X] = n*p (or = lambda), for x, M > 0 * * in a manner that should be stable (with small relative error) * for all x and M=np. In particular for x/np close to 1, direct * evaluation fails, and evaluation is based on the Taylor series * of log((1+v)/(1-v)) with v = (x-np)/(x+np). */ jstat.bd0 = function(x, np) { var ej, s, s1, v, j; if(!jstat.isFinite(x) || !jstat.isFinite(np) || np == 0.0) throw "illegal parameter in jstat.bd0"; if(Math.abs(x-np) > 0.1*(x+np)) { v = (x-np)/(x+np); s = (x-np)*v;/* s using v -- change by MM */ ej = 2*x*v; v = v*v; for (j=1; ; j++) { /* Taylor series */ ej *= v; s1 = s+ej/((j<<1)+1); if (s1==s) /* last term was effectively 0 */ return(s1); s = s1; } } /* else: | x - np | is not too small */ return(x*Math.log(x/np)+np-x); } /** Computes the log of the error term in Stirling's formula. * For n > 15, uses the series 1/12n - 1/360n^3 + ... * For n <=15, integers or half-integers, uses stored values. * For other n < 15, uses lgamma directly (don't use this to * write lgamma!) */ jstat.stirlerr= function(n) { var S0 = 0.083333333333333333333; var S1 = 0.00277777777777777777778; var S2 = 0.00079365079365079365079365; var S3 = 0.000595238095238095238095238; var S4 = 0.0008417508417508417508417508; var sferr_halves = [ 0.0, /* n=0 - wrong, place holder only */ 0.1534264097200273452913848, /* 0.5 */ 0.0810614667953272582196702, /* 1.0 */ 0.0548141210519176538961390, /* 1.5 */ 0.0413406959554092940938221, /* 2.0 */ 0.03316287351993628748511048, /* 2.5 */ 0.02767792568499833914878929, /* 3.0 */ 0.02374616365629749597132920, /* 3.5 */ 0.02079067210376509311152277, /* 4.0 */ 0.01848845053267318523077934, /* 4.5 */ 0.01664469118982119216319487, /* 5.0 */ 0.01513497322191737887351255, /* 5.5 */ 0.01387612882307074799874573, /* 6.0 */ 0.01281046524292022692424986, /* 6.5 */ 0.01189670994589177009505572, /* 7.0 */ 0.01110455975820691732662991, /* 7.5 */ 0.010411265261972096497478567, /* 8.0 */ 0.009799416126158803298389475, /* 8.5 */ 0.009255462182712732917728637, /* 9.0 */ 0.008768700134139385462952823, /* 9.5 */ 0.008330563433362871256469318, /* 10.0 */ 0.007934114564314020547248100, /* 10.5 */ 0.007573675487951840794972024, /* 11.0 */ 0.007244554301320383179543912, /* 11.5 */ 0.006942840107209529865664152, /* 12.0 */ 0.006665247032707682442354394, /* 12.5 */ 0.006408994188004207068439631, /* 13.0 */ 0.006171712263039457647532867, /* 13.5 */ 0.005951370112758847735624416, /* 14.0 */ 0.005746216513010115682023589, /* 14.5 */ 0.005554733551962801371038690 /* 15.0 */ ]; var nn; if (n <= 15.0) { nn = n + n; if (nn == parseInt(nn)) return(sferr_halves[parseInt(nn)]); return(jstat.lgamma(n + 1.0) - (n + 0.5)*Math.log(n) + n - jstat.LN_SQRT_2PI); } nn = n*n; if (n>500) return((S0-S1/nn)/n); if (n> 80) return((S0-(S1-S2/nn)/nn)/n); if (n> 35) return((S0-(S1-(S2-S3/nn)/nn)/nn)/n); /* 15 < n <= 35 : */ return((S0-(S1-(S2-(S3-S4/nn)/nn)/nn)/nn)/n); } /** The function lgamma computes log|gamma(x)|. The function * lgammafn_sign in addition assigns the sign of the gamma function * to the address in the second argument if this is not null. */ jstat.lgamma = function(x) { function lgammafn_sign(x, sgn) { var ans, y, sinpiy; var xmax = 2.5327372760800758e+305; var dxrel = 1.490116119384765696e-8; // if (xmax == 0) {/* initialize machine dependent constants _ONCE_ */ // xmax = jstat.DBL_MAX/Math.log(jstat.DBL_MAX);/* = 2.533 e305 for IEEE double */ // dxrel = Math.sqrt(jstat.DBL_EPSILON);/* sqrt(Eps) ~ 1.49 e-8 for IEEE double */ // } /* For IEEE double precision DBL_EPSILON = 2^-52 = 2.220446049250313e-16 : xmax = DBL_MAX / log(DBL_MAX) = 2^1024 / (1024 * log(2)) = 2^1014 / log(2) dxrel = sqrt(DBL_EPSILON) = 2^-26 = 5^26 * 1e-26 (is *exact* below !) */ if (sgn != null) sgn = 1; if(isNaN(x)) return x; if (x < 0 && (Math.floor(-x) % 2.0) == 0) if (sgn != null) sgn = -1; if (x <= 0 && x == jstat.trunc(x)) { /* Negative integer argument */ console.warn("Negative integer argument in lgammafn_sign"); return Number.POSITIVE_INFINITY;/* +Inf, since lgamma(x) = log|gamma(x)| */ } y = Math.abs(x); if(y <= 10) return Math.log(Math.abs(jstat.gamma(x))); // TODO: implement jstat.gamma if(y > xmax) { console.warn("Illegal arguement passed to lgammafn_sign"); return Number.POSITIVE_INFINITY; } if(x > 0) { if(x > 1e17) { return (x*(Math.log(x)-1.0)); } else if(x > 4934720.0) { return (jstat.LN_SQRT_2PI + (x-0.5) * Math.log(x) - x); } else { return jstat.LN_SQRT_2PI + (x-0.5) * Math.log(x) - x + jstat.lgammacor(x); // TODO: implement lgammacor } } sinpiy = Math.abs(Math.sin(Math.PI * y)); if(sinpiy == 0) { throw "Should never happen!!"; } ans = jstat.LN_SQRT_PId2 + (x - 0.5) * Math.log(y) - x - Math.log(sinpiy) - jstat.lgammacor(y); if(Math.abs((x-jstat.trunc(x-0.5))* ans / x) < dxrel) { throw "The answer is less than half the precision argument too close to a negative integer"; } return ans; } return lgammafn_sign(x, null); } jstat.gamma = function(x) { var xbig = 171.624; var p = [ -1.71618513886549492533811, 24.7656508055759199108314,-379.804256470945635097577, 629.331155312818442661052,866.966202790413211295064, -31451.2729688483675254357,-36144.4134186911729807069, 66456.1438202405440627855 ]; var q = [ -30.8402300119738975254353, 315.350626979604161529144,-1015.15636749021914166146, -3107.77167157231109440444,22538.1184209801510330112, 4755.84627752788110767815,-134659.959864969306392456, -115132.259675553483497211 ]; var c = [ -.001910444077728,8.4171387781295e-4, -5.952379913043012e-4,7.93650793500350248e-4, -.002777777777777681622553,.08333333333333333331554247, .0057083835261 ]; var i,n,parity,fact,xden,xnum,y,z,yi,res,sum,ysq; parity = (0); fact = 1.0; n = 0; y=x; if(y <= 0.0) { /* ------------------------------------------------------------- Argument is negative ------------------------------------------------------------- */ y = -x; yi = jstat.trunc(y); res = y - yi; if (res != 0.0) { if (yi != jstat.trunc(yi * 0.5) * 2.0) parity = (1); fact = -Math.PI / Math.sin(Math.PI * res); y += 1.0; } else { return(Number.POSITIVE_INFINITY); } } /* ----------------------------------------------------------------- Argument is positive -----------------------------------------------------------------*/ if (y < jstat.DBL_EPSILON) { /* -------------------------------------------------------------- Argument < EPS -------------------------------------------------------------- */ if (y >= jstat.DBL_MIN) { res = 1.0 / y; } else { return(Number.POSITIVE_INFINITY); } } else if (y < 12.0) { yi = y; if (y < 1.0) { /* --------------------------------------------------------- EPS < argument < 1 --------------------------------------------------------- */ z = y; y += 1.0; } else { /* ----------------------------------------------------------- 1 <= argument < 12, reduce argument if necessary ----------------------------------------------------------- */ n = parseInt(y) - 1; y -= parseFloat(n); z = y - 1.0; } /* --------------------------------------------------------- Evaluate approximation for 1. < argument < 2. ---------------------------------------------------------*/ xnum = 0.0; xden = 1.0; for (i = 0; i < 8; ++i) { xnum = (xnum + p[i]) * z; xden = xden * z + q[i]; } res = xnum / xden + 1.0; if (yi < y) { /* -------------------------------------------------------- Adjust result for case 0. < argument < 1. -------------------------------------------------------- */ res /= yi; } else if (yi > y) { /* ---------------------------------------------------------- Adjust result for case 2. < argument < 12. ---------------------------------------------------------- */ for (i = 0; i < n; ++i) { res *= y; y += 1.0; } } } else { /* ------------------------------------------------------------- Evaluate for argument >= 12., ------------------------------------------------------------- */ if (y <= xbig) { ysq = y * y; sum = c[6]; for (i = 0; i < 6; ++i) { sum = sum / ysq + c[i]; } sum = sum / y - y + jstat.LN_SQRT_2PI; sum += (y - 0.5) * Math.log(y); res = Math.exp(sum); } else { return(Number.POSITIVE_INFINITY); } } /* ---------------------------------------------------------------------- Final adjustments and return ----------------------------------------------------------------------*/ if (parity) res = -res; if (fact != 1.0) res = fact / res; return res; } /** Compute the log gamma correction factor for x >= 10 so that * * log(gamma(x)) = .5*log(2*pi) + (x-.5)*log(x) -x + lgammacor(x) * * [ lgammacor(x) is called Del(x) in other contexts (e.g. dcdflib)] */ jstat.lgammacor = function(x) { var algmcs = [ +.1666389480451863247205729650822e+0, -.1384948176067563840732986059135e-4, +.9810825646924729426157171547487e-8, -.1809129475572494194263306266719e-10, +.6221098041892605227126015543416e-13, -.3399615005417721944303330599666e-15, +.2683181998482698748957538846666e-17, -.2868042435334643284144622399999e-19, +.3962837061046434803679306666666e-21, -.6831888753985766870111999999999e-23, +.1429227355942498147573333333333e-24, -.3547598158101070547199999999999e-26, +.1025680058010470912000000000000e-27, -.3401102254316748799999999999999e-29, +.1276642195630062933333333333333e-30 ]; var tmp; var nalgm = 5; var xbig = 94906265.62425156; var xmax = 3.745194030963158e306; if(x < 10) { return Number.NaN; } else if (x >= xmax) { throw "Underflow error in lgammacor"; } else if (x < xbig) { tmp = 10 / x; return jstat.chebyshev(tmp*tmp*2-1,algmcs,nalgm) / x; } return 1 / (x*12); } /* * Incomplete Beta function */ jstat.incompleteBeta = function(a, b, x) { /* * Used by incompleteBeta: Evaluates continued fraction for incomplete * beta function by modified Lentz's method. */ function betacf(a, b, x) { var MAXIT = 100; var EPS = 3.0e-12; var FPMIN = 1.0e-30; var m,m2,aa,c,d,del,h,qab,qam,qap; qab=a+b; qap=a+1.0; qam=a-1.0; c=1.0; d=1.0-qab*x/qap; if(Math.abs(d) < FPMIN) { d=FPMIN; } d = 1.0/d; h=d; for(m = 1; m <= MAXIT; m++) { m2=2*m; aa=m*(b-m)*x/((qam+m2)*(a+m2)); d=1.0+aa*d; if(Math.abs(d) < FPMIN) { d = FPMIN; } c=1.0+aa/c; if(Math.abs(c) < FPMIN) { c = FPMIN; } d=1.0/d; h *= d*c; aa = -(a+m)*(qab+m)*x/((a+m2) * (qap+m2)); d=1.0+aa*d; if(Math.abs(d) < FPMIN) { d = FPMIN; } c=1.0+aa/c; if(Math.abs(c) < FPMIN) { c=FPMIN; } d=1.0/d; del=d*c; h *= del; if(Math.abs(del-1.0) < EPS) { // are we done? break; } } if(m > MAXIT) { console.warn("a or b too big, or MAXIT too small in betacf: " + a + ", " + b + ", " + x + ", " + h); return h; } if(isNaN(h)) { console.warn(a + ", " + b + ", " + x); } return h; } var bt; if(x < 0.0 || x > 1.0) { throw "bad x in routine incompleteBeta"; } if(x == 0.0 || x == 1.0) { bt = 0.0; } else { bt = Math.exp(jstat.lgamma(a+b) - jstat.lgamma(a) - jstat.lgamma(b) + a * Math.log(x)+ b * Math.log(1.0-x)); } if(x < (a + 1.0)/(a+b+2.0)) { return bt * betacf(a,b,x)/a; } else { return 1.0-bt*betacf(b,a,1.0-x)/b; } } /** Evaluates the n-term Chebyshev series * "a" at "x". */ jstat.chebyshev = function(x, a, n) { var b0, b1, b2, twox; var i; if (n < 1 || n > 1000) return Number.NaN; if (x < -1.1 || x > 1.1) return Number.NaN; twox = x * 2; b2 = b1 = 0; b0 = 0; for (i = 1; i <= n; i++) { b2 = b1; b1 = b0; b0 = twox * b1 - b2 + a[n - i]; } return (b0 - b2) * 0.5; } jstat.fmin2 = function(x, y) { return (x < y) ? x : y; } jstat.log1p = function(x) { // http://kevin.vanzonneveld.net // + original by: Brett Zamir (http://brett-zamir.me) // % note 1: Precision 'n' can be adjusted as desired // * example 1: log1p(1e-15); // * returns 1: 9.999999999999995e-16 var ret = 0, n = 50; // degree of precision if (x <= -1) { return Number.NEGATIVE_INFINITY; // JavaScript style would be to return Number.NEGATIVE_INFINITY } if (x < 0 || x > 1) { return Math.log(1 + x); } for (var i = 1; i < n; i++) { if ((i % 2) === 0) { ret -= Math.pow(x, i) / i; } else { ret += Math.pow(x, i) / i; } } return ret; } jstat.expm1 = function(x) { var y, a = Math.abs(x); if(a < jstat.DBL_EPSILON) return x; if(a > 0.697) return Math.exp(x) - 1; /* negligable cancellation */ if(a > 1e-8) { y = Math.exp(x) - 1; } else { y = (x / 2 + 1) * x; } /* Newton step for solving log(1 + y) = x for y : */ /* WARNING: does not work for y ~ -1: bug in 1.5.0 */ y -= (1 + y) * (jstat.log1p(y) - x); return y; } jstat.logBeta = function(a, b) { var corr, p, q; p = q = a; if(b < p) p = b;/* := min(a,b) */ if(b > q) q = b;/* := max(a,b) */ /* both arguments must be >= 0 */ if (p < 0) { console.warn('Both arguements must be >= 0'); return Number.NaN; } else if (p == 0) { return Number.POSITIVE_INFINITY; } else if (!jstat.isFinite(q)) { /* q == +Inf */ return Number.NEGATIVE_INFINITY; } if (p >= 10) { /* p and q are big. */ corr = jstat.lgammacor(p) + jstat.lgammacor(q) - jstat.lgammacor(p + q); return Math.log(q) * -0.5 + jstat.LN_SQRT_2PI + corr + (p - 0.5) * Math.log(p / (p + q)) + q * jstat.log1p(-p / (p + q)); } else if (q >= 10) { /* p is small, but q is big. */ corr = jstat.lgammacor(q) - jstat.lgammacor(p + q); return jstat.lgamma(p) + corr + p - p * Math.log(p + q) + (q - 0.5) * jstat.log1p(-p / (p + q)); } else /* p and q are small: p <= q < 10. */ return Math.log(jstat.gamma(p) * (jstat.gamma(q) / jstat.gamma(p + q))); } jstat.dbinom_raw = function(x, n, p, q, give_log) { if(give_log == null) give_log = false; var lf, lc; if(p == 0) { if(x == 0) { // R_D__1 return (give_log) ? 0.0 : 1.0; } else { // R_D__0 return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; } } if(q == 0) { if(x == n) { // R_D__1 return (give_log) ? 0.0 : 1.0; } else { // R_D__0 return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; } } if (x == 0) { if(n == 0) return (give_log) ? 0.0 : 1.0; //R_D__1; lc = (p < 0.1) ? -jstat.bd0(n,n*q) - n*p : n*Math.log(q); return ( give_log ) ? lc : Math.exp(lc); //R_D_exp(lc) } if (x == n) { lc = (q < 0.1) ? -jstat.bd0(n,n*p) - n*q : n*Math.log(p); return ( give_log ) ? lc : Math.exp(lc); //R_D_exp(lc) } if (x < 0 || x > n) return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0; /* n*p or n*q can underflow to zero if n and p or q are small. This used to occur in dbeta, and gives NaN as from R 2.3.0. */ lc = jstat.stirlerr(n) - jstat.stirlerr(x) - jstat.stirlerr(n-x) - jstat.bd0(x,n*p) - jstat.bd0(n-x,n*q); /* f = (M_2PI*x*(n-x))/n; could overflow or underflow */ /* Upto R 2.7.1: * lf = log(M_2PI) + log(x) + log(n-x) - log(n); * -- following is much better for x << n : */ lf = Math.log(jstat.TWO_PI) + Math.log(x) + jstat.log1p(- x/n); return (give_log) ? lc - 0.5*lf : Math.exp(lc - 0.5*lf); // R_D_exp(lc - 0.5*lf); } jstat.max = function(values) { var max = Number.NEGATIVE_INFINITY; for(var i = 0; i < values.length; i++) { if(values[i] > max) { max = values[i]; } } return max; } /******************************************************************************/ /* Probability Distributions */ /******************************************************************************/ /** * Range class */ var Range = Class.extend({ init: function(min, max, numPoints) { this._minimum = parseFloat(min); this._maximum = parseFloat(max); this._numPoints = parseFloat(numPoints); }, getMinimum: function() { return this._minimum; }, getMaximum: function() { return this._maximum; }, getNumPoints: function() { return this._numPoints; }, getPoints: function() { var results = []; var x = this._minimum; var step = (this._maximum-this._minimum)/(this._numPoints-1); for(var i = 0; i < this._numPoints; i++) { results[i] = parseFloat(x.toFixed(6)); x += step; } return results; } }); Range.validate = function(range) { if( ! range instanceof Range) { return false; } if(isNaN(range.getMinimum()) || isNaN(range.getMaximum()) || isNaN(range.getNumPoints()) || range.getMaximum() < range.getMinimum() || range.getNumPoints() <= 0) { return false; } return true; } var ContinuousDistribution = Class.extend({ init: function(name) { this._name = name; }, toString: function() { return this._string; }, getName: function() { return this._name; }, getClassName: function() { return this._name + 'Distribution'; }, density: function(valueOrRange) { if(!isNaN(valueOrRange)) { // single value return parseFloat(this._pdf(valueOrRange).toFixed(15)); } else if (Range.validate(valueOrRange)) { // multiple values var points = valueOrRange.getPoints(); var result = []; // For each point in the range for(var i = 0; i < points.length; i++) { result[i] = parseFloat(this._pdf(points[i])); } return result; } else { // neither value or range throw "Invalid parameter supplied to " + this.getClassName() + ".density()"; } }, cumulativeDensity: function(valueOrRange) { if(!isNaN(valueOrRange)) { // single value return parseFloat(this._cdf(valueOrRange).toFixed(15)); } else if (Range.validate(valueOrRange)) { // multiple values var points = valueOrRange.getPoints(); var result = []; // For each point in the range for(var i = 0; i < points.length; i++) { result[i] = parseFloat(this._cdf(points[i])); } return result; } else { // neither value or range throw "Invalid parameter supplied to " + this.getClassName() + ".cumulativeDensity()"; } }, getRange: function(standardDeviations, numPoints) { if(standardDeviations == null) { standardDeviations = 5; } if(numPoints == null) { numPoints = 100; } var min = this.getMean() - standardDeviations * Math.sqrt(this.getVariance()); var max = this.getMean() + standardDeviations * Math.sqrt(this.getVariance()); if(this.getClassName() == 'GammaDistribution' || this.getClassName() == 'LogNormalDistribution') { min = 0.0; max = this.getMean() + standardDeviations * Math.sqrt(this.getVariance()); } else if(this.getClassName() == 'BetaDistribution') { min = 0.0; max = 1.0; } var range = new Range(min, max, numPoints); return range; }, getVariance: function(){}, getMean: function(){}, getQuantile: function(p) { var self = this; /* * Recursive function to find the closest match */ function findClosestMatch(range, p) { var ERR = 1.0e-5; var xs = range.getPoints(); var closestIndex = 0; var closestDistance = 999; for(var i=0; i<xs.length; i++) { var pp = self.cumulativeDensity(xs[i]); var distance = Math.abs(pp - p); if(distance < closestDistance) { // closer value found closestIndex = i; closestDistance = distance; } } if(closestDistance <= ERR) { // Acceptable - return value; return xs[closestIndex]; } else { // Calculate the new range var newRange = new Range(xs[closestIndex-1], xs[closestIndex+1],20); return findClosestMatch(newRange, p); } } var range = this.getRange(5, 20); return findClosestMatch(range, p); } }); /** * A normal distribution object */ var NormalDistribution = ContinuousDistribution.extend({ init: function(mean, sigma) { this._super('Normal'); this._mean = parseFloat(mean); this._sigma = parseFloat(sigma); this._string = "Normal ("+this._mean.toFixed(2)+", " + this._sigma.toFixed(2) + ")"; }, _pdf: function(x, give_log) { if(give_log == null) { give_log=false; } // default is false; var sigma = this._sigma; var mu = this._mean; if(!jstat.isFinite(sigma)) { return (give_log) ? Number.NEGATIVE_INFINITY : 0.0 } if(!jstat.isFinite(x) && mu == x) { return Number.NaN; } if(sigma<=0) { if(sigma < 0) { throw "invalid sigma in _pdf"; } return (x==mu)?Number.POSITIVE_INFINITY:(give_log)?Number.NEGATIVE_INFINITY:0.0; } x=(x-mu)/sigma; if(!jstat.isFinite(x)){ return (give_log)?Number.NEGATIVE_INFINITY:0.0; } return (give_log ? -(jstat.LN_SQRT_2PI + 0.5 * x * x + Math.log(sigma)) : jstat.ONE_SQRT_2PI * Math.exp(-0.5 * x * x) / sigma); }, _cdf: function(x, lower_tail, log_p) { if(lower_tail == null) lower_tail = true; if(log_p == null) log_p = false; function pnorm_both(x, cum, ccum, i_tail, log_p) { /* i_tail in {0,1,2} means: "lower", "upper", or "both" : if(lower) return *cum := P[X <= x] if(upper) return *ccum := P[X > x] = 1 - P[X <= x] */ var a = [ 2.2352520354606839287, 161.02823106855587881, 1067.6894854603709582, 18154.981253343561249, 0.065682337918207449113 ]; var b = [ 47.20258190468824187, 976.09855173777669322, 10260.932208618978205, 45507.789335026729956 ]; var c = [ 0.39894151208813466764, 8.8831497943883759412, 93.506656132177855979, 597.27027639480026226, 2494.5375852903726711, 6848.1904505362823326, 11602.651437647350124, 9842.7148383839780218, 1.0765576773720192317e-8 ]; var d = [ 22.266688044328115691, 235.38790178262499861, 1519.377599407554805, 6485.558298266760755, 18615.571640885098091, 34900.952721145977266, 38912.003286093271411, 19685.429676859990727 ]; var p = [ 0.21589853405795699, 0.1274011611602473639, 0.022235277870649807, 0.001421619193227893466, 2.9112874951168792e-5, 0.02307344176494017303 ]; var q = [ 1.28426009614491121, 0.468238212480865118, 0.0659881378689285515, 0.00378239633202758244, 7.29751555083966205e-5 ]; var xden, xnum, temp, del, eps, xsq, y, i, lower, upper; /* Consider changing these : */ eps = jstat.DBL_EPSILON * 0.5; /* i_tail in {0,1,2} =^= {lower, upper, both} */ lower = i_tail != 1; upper = i_tail != 0; y = Math.abs(x); if (y <= 0.67448975) { /* qnorm(3/4) = .6744.... -- earlier had 0.66291 */ if (y > eps) { xsq = x * x; xnum = a[4] * xsq; xden = xsq; for (i = 0; i < 3; ++i) { xnum = (xnum + a[i]) * xsq; xden = (xden + b[i]) * xsq; } } else { xnum = xden = 0.0; } temp = x * (xnum + a[3]) / (xden + b[3]); if(lower) cum = 0.5 + temp; if(upper) ccum = 0.5 - temp; if(log_p) { if(lower) cum = Math.log(cum); if(upper) ccum = Math.log(ccum); } } else if (y <= jstat.SQRT_32) { /* Evaluate pnorm for 0.674.. = qnorm(3/4) < |x| <= sqrt(32) ~= 5.657 */ xnum = c[8] * y; xden = y; for (i = 0; i < 7; ++i) { xnum = (xnum + c[i]) * y; xden = (xden + d[i]) * y; } temp = (xnum + c[7]) / (xden + d[7]); /* do_del */ xsq = jstat.trunc(x * 16) / 16; del = (x - xsq) * (x + xsq); if(log_p) { cum = (-xsq * xsq * 0.5) + (-del * 0.5) + Math.log(temp); if((lower && x > 0.) || (upper && x <= 0.)) ccum = jstat.log1p(-Math.exp(-xsq * xsq * 0.5) * Math.exp(-del * 0.5) * temp); } else { cum = Math.exp(-xsq * xsq * 0.5) * Math.exp(-del * 0.5) * temp; ccum = 1.0 - cum; } /* end do_del */ /* swap_tail */ if (x > 0.0) {/* swap ccum <--> cum */ temp = cum; if(lower) { cum = ccum; } ccum = temp; } /* end swap_tail */ } /* else |x| > sqrt(32) = 5.657 : * the next two case differentiations were really for lower=T, log=F * Particularly *not* for log_p ! * Cody had (-37.5193 < x && x < 8.2924) ; R originally had y < 50 * * Note that we do want symmetry(0), lower/upper -> hence use y */ else if((log_p && y < 1e170)|| (lower && -37.5193 < x && x < 8.2924) || (upper && -8.2924 < x && x < 37.5193)) { /* Evaluate pnorm for x in (-37.5, -5.657) union (5.657, 37.5) */ xsq = 1.0 / (x * x); /* (1./x)*(1./x) might be better */ xnum = p[5] * xsq; xden = xsq; for (i = 0; i < 4; ++i) { xnum = (xnum + p[i]) * xsq; xden = (xden + q[i]) * xsq; } temp = xsq * (xnum + p[4]) / (xden + q[4]); temp = (jstat.ONE_SQRT_2PI - temp) / y; /* do_del */ xsq = jstat.trunc(x * 16) / 16; del = (x - xsq) * (x + xsq); if(log_p) { cum = (-xsq * xsq * 0.5) + (-del * 0.5) + Math.log(temp); if((lower && x > 0.) || (upper && x <= 0.)) ccum = jstat.log1p(-Math.exp(-xsq * xsq * 0.5) * Math.exp(-del * 0.5) * temp); } else { cum = Math.exp(-xsq * xsq * 0.5) * Math.exp(-del * 0.5) * temp; ccum = 1.0 - cum; } /* end do_del */ /* swap_tail */ if (x > 0.0) {/* swap ccum <--> cum */ temp = cum; if(lower) { cum = ccum; } ccum = temp; } /* end swap_tail */ } else { /* large x such that probs are 0 or 1 */ if(x > 0) { cum = (log_p) ? 0.0 : 1.0; // R_D__1 ccum = (log_p) ? Number.NEGATIVE_INFINITY : 0.0; //R_D__0; } else { cum = (log_p) ? Number.NEGATIVE_INFINITY : 0.0; //R_D__0; ccum = (log_p) ? 0.0 : 1.0; // R_D__1 } } return [cum, ccum]; } var p, cp; var mu = this._mean; var sigma = this._sigma; var R_DT_0, R_DT_1; if(lower_tail) { if(log_p) { R_DT_0 = Number.NEGATIVE_INFINITY; R_DT_1 = 0.0; } else { R_DT_0 = 0.0; R_DT_1 = 1.0; } } else { if(log_p) { R_DT_0 = 0.0; R_DT_1 = Number.NEGATIVE_INFINITY; } else { R_DT_0 = 1.0; R_DT_1 = 0.0; } } if(!jstat.isFinite(x) && mu == x) return Number.NaN; if(sigma <= 0) { if(sigma < 0) { console.warn("Sigma is less than 0"); return Number.NaN; } return (x < mu) ? R_DT_0 : R_DT_1; } p = (x - mu) / sigma; if(!jstat.isFinite(p)) { return (x < mu) ? R_DT_0 : R_DT_1; } x = p; // pnorm_both(x, &p, &cp, (lower_tail ? 0 : 1), log_p); // result[0] == &p // result[1] == &cp var result = pnorm_both(x, p, cp, (lower_tail ? false : true), log_p); return (lower_tail ? result[0] : result[1]); }, getMean: function() { return this._mean; }, getSigma: function() { return this._sigma; }, getVariance: function() { return this._sigma*this._sigma; } }); /** * A Log-normal distribution object */ var LogNormalDistribution = ContinuousDistribution.extend({ init: function(location, scale) { this._super('LogNormal') this._location = parseFloat(location); this._scale = parseFloat(scale); this._string = "LogNormal ("+this._location.toFixed(2)+", " + this._scale.toFixed(2) + ")"; }, _pdf: function(x, give_log) { var y; var sdlog = this._scale; var meanlog = this._location; if(give_log == null) { give_log = false; } if(sdlog <= 0) throw "Illegal parameter in _pdf"; if(x <= 0) { return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; } y = (Math.log(x) - meanlog) / sdlog; return (give_log ? -(jstat.LN_SQRT_2PI + 0.5 * y * y + Math.log(x * sdlog)) : jstat.ONE_SQRT_2PI * Math.exp(-0.5 * y * y) / (x * sdlog)); }, _cdf: function(x, lower_tail, log_p) { var sdlog = this._scale; var meanlog = this._location; if(lower_tail == null) { lower_tail = true; } if(log_p == null) { log_p = false; } if(sdlog <= 0) { throw "illegal std in _cdf"; } if(x > 0) { var nd = new NormalDistribution(meanlog, sdlog); return nd._cdf(Math.log(x), lower_tail, log_p); } if(lower_tail) { return (log_p) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0 } else { return (log_p) ? 0.0 : 1.0; // R_D__1 } }, getLocation: function() { return this._location; }, getScale: function() { return this._scale; }, getMean: function() { return Math.exp((this._location + this._scale) / 2); }, getVariance: function() { var ans = (Math.exp(this._scale)-1)*Math.exp(2*this._location+this._scale); return ans; } }); /** * Gamma distribution object */ var GammaDistribution = ContinuousDistribution.extend({ init: function(shape, scale) { this._super('Gamma'); this._shape = parseFloat(shape); this._scale = parseFloat(scale); this._string = "Gamma ("+this._shape.toFixed(2)+", " + this._scale.toFixed(2) + ")"; }, _pdf: function(x, give_log) { var pr; var shape = this._shape; var scale = this._scale; if(give_log == null) { give_log = false; // default value } if(shape < 0 || scale <= 0) { throw "Illegal argument in _pdf"; } if(x < 0) { return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0 } if(shape == 0) { /* point mass at 0 */ return (x == 0) ? Number.POSITIVE_INFINITY : (give_log) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0 } if(x == 0) { if(shape < 1) return Number.POSITIVE_INFINITY; if(shape > 1) return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0 /* else */ return (give_log) ? -Math.log(scale) : 1/scale; } if(shape < 1) { pr = jstat.dopois_raw(shape, x/scale, give_log); return give_log ? pr + Math.log(shape/x) : pr*shape/x; } /* else shape >= 1 */ pr = jstat.dopois_raw(shape-1, x/scale, give_log); return give_log ? pr - Math.log(scale) : pr/scale; }, /** * This function computes the distribution function for the * gamma distribution with shape parameter alph and scale parameter * scale. This is also known as the incomplete gamma function. * See Abramowitz and Stegun (6.5.1) for example. */ _cdf: function(x, lower_tail, log_p) { /* define USE_PNORM */ function USE_PNORM() { pn1 = Math.sqrt(alph) * 3.0 * (Math.pow(x/alph,1.0/3.0) + 1.0 / (9.0 * alph) - 1.0); var norm_dist = new NormalDistribution(0.0, 1.0); return norm_dist._cdf(pn1, lower_tail, log_p); } /* Defaults */ if(lower_tail == null) lower_tail = true; if(log_p == null) log_p = false; var alph = this._shape; var scale = this._scale; var xbig = 1.0e+8; var xlarge = 1.0e+37; var alphlimit = 1e5; var pn1,pn2,pn3,pn4,pn5,pn6,arg,a,b,c,an,osum,sum,n,pearson; if(alph <= 0. || scale <= 0.) { console.warn('Invalid gamma params in _cdf'); return Number.NaN; } x/=scale; if(isNaN(x)) return x; if(x <= 0.0) { // R_DT_0 if(lower_tail) { // R_D__0 return (log_p) ? Number.NEGATIVE_INFINITY : 0.0; } else { // R_D__1 return (log_p) ? 0.0 : 1.0; } } if(alph > alphlimit) { return USE_PNORM(); } if(x > xbig * alph) { if(x > jstat.DBL_MAX * alph) { // R_DT_1 if(lower_tail) { // R_D__1 return (log_p) ? 0.0 : 1.0; } else { // R_D__0 return (log_p) ? Number.NEGATIVE_INFINITY : 0.0; } } else { return USE_PNORM(); } } if(x <= 1.0 || x < alph) { pearson = 1; /* use pearson's series expansion */ arg = alph * Math.log(x) - x - jstat.lgamma(alph + 1.0); c = 1.0; sum = 1.0; a = alph; do { a += 1.0; c *= x / a; sum += c; } while(c > jstat.DBL_EPSILON * sum); } else { /* x >= max( 1, alph) */ pearson = 0;/* use a continued fraction expansion */ arg = alph * Math.log(x) - x - jstat.lgamma(alph); a = 1. - alph; b = a + x + 1.; pn1 = 1.; pn2 = x; pn3 = x + 1.; pn4 = x * b; sum = pn3 / pn4; for (n = 1; ; n++) { a += 1.;/* = n+1 -alph */ b += 2.;/* = 2(n+1)-alph+x */ an = a * n; pn5 = b * pn3 - an * pn1; pn6 = b * pn4 - an * pn2; if (Math.abs(pn6) > 0.) { osum = sum; sum = pn5 / pn6; if (Math.abs(osum - sum) <= jstat.DBL_EPSILON * jstat.fmin2(1.0, sum)) break; } pn1 = pn3; pn2 = pn4; pn3 = pn5; pn4 = pn6; if (Math.abs(pn5) >= xlarge) { pn1 /= xlarge; pn2 /= xlarge; pn3 /= xlarge; pn4 /= xlarge; } } } arg += Math.log(sum); lower_tail = (lower_tail == pearson); if (log_p && lower_tail) return(arg); /* else */ /* sum = exp(arg); and return if(lower_tail) sum else 1-sum : */ if(lower_tail) { return Math.exp(arg); } else { if(log_p) { // R_Log1_Exp(arg); return (arg > -Math.LN2) ? Math.log(-jstat.expm1(arg)) : jstat.log1p(-Math.exp(arg)); } else { return -jstat.expm1(arg); } } }, getShape: function() { return this._shape; }, getScale: function() { return this._scale; }, getMean: function() { return this._shape * this._scale; }, getVariance: function() { return this._shape*Math.pow(this._scale,2); } }); /** * A Beta distribution object */ var BetaDistribution = ContinuousDistribution.extend({ init: function(alpha, beta) { this._super('Beta'); this._alpha = parseFloat(alpha); this._beta = parseFloat(beta); this._string = "Beta ("+this._alpha.toFixed(2)+", " + this._beta.toFixed(2) + ")"; }, _pdf: function(x, give_log) { if(give_log == null) give_log = false; // default; var a = this._alpha; var b = this._beta; var lval; if(a <= 0 || b <= 0) { console.warn('Illegal arguments in _pdf'); return Number.NaN; } if(x < 0 || x > 1) { // R_D__0 return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; } if(x == 0) { if(a > 1) { // R_D__0 return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; } if(a < 1) { return Number.POSITIVE_INFINITY; } /*a == 1 */ return (give_log) ? Math.log(b) : b; // R_D_val(b) } if(x == 1) { if(b > 1) { // R_D__0 return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; } if(b < 1) { return Number.POSITIVE_INFINITY; } /* b == 1 */ return (give_log) ? Math.log(a) : a; // R_D_val(a) } if(a<=2||b<=2) { lval = (a-1)*Math.log(x) + (b-1)*jstat.log1p(-x) - jstat.logBeta(a, b); } else { lval = Math.log(a+b-1) + jstat.dbinom_raw(a-1, a+b-2, x, 1-x, true); } //R_D_exp(lval) return (give_log) ? lval : Math.exp(lval); }, _cdf: function(x, lower_tail, log_p) { if(lower_tail == null) lower_tail = true; if(log_p == null) log_p = false; var pin = this._alpha; var qin = this._beta; if(pin <= 0 || qin <= 0) { console.warn('Invalid argument in _cdf'); return Number.NaN; } if(x <= 0) { //R_DT_0; if(lower_tail) { // R_D__0 return (log_p) ? Number.NEGATIVE_INFINITY : 0.0; } else { // R_D__1 return (log_p) ? 0.1 : 1.0; } } if(x >= 1){ // R_DT_1 if(lower_tail) { // R_D__1 return (log_p) ? 0.1 : 1.0; } else { // R_D__0 return (log_p) ? Number.NEGATIVE_INFINITY : 0.0; } } /* else */ return jstat.incompleteBeta(pin, qin, x); }, getAlpha: function() { return this._alpha; }, getBeta: function() { return this._beta; }, getMean: function() { return this._alpha / (this._alpha+ this._beta); }, getVariance: function() { var ans = (this._alpha * this._beta) / (Math.pow(this._alpha+this._beta,2)*(this._alpha+this._beta+1)); return ans; } }); var StudentTDistribution = ContinuousDistribution.extend({ init: function(degreesOfFreedom, mu) { this._super('StudentT'); this._dof = parseFloat(degreesOfFreedom); if(mu != null) { this._mu = parseFloat(mu); this._string = "StudentT ("+this._dof.toFixed(2)+", " + this._mu.toFixed(2)+ ")"; } else { this._mu = 0.0; this._string = "StudentT ("+this._dof.toFixed(2)+")"; } }, _pdf: function(x, give_log) { if(give_log == null) give_log = false; if(this._mu == null) { return this._dt(x, give_log); } else { var y = this._dnt(x, give_log); if(y > 1){ console.warn('x:' + x + ', y: ' + y); } return y; } }, _cdf: function(x, lower_tail, give_log) { if(lower_tail == null) lower_tail = true; if(give_log == null) give_log = false; if(this._mu == null) { return this._pt(x, lower_tail, give_log); } else { return this._pnt(x, lower_tail, give_log); } }, _dt: function(x, give_log) { var t,u; var n = this._dof; if (n <= 0){ console.warn('Invalid parameters in _dt'); return Number.NaN; } if(!jstat.isFinite(x)) { return (give_log) ? Number.NEGATIVE_INFINITY : 0.0; // R_D__0; } if(!jstat.isFinite(n)) { var norm = new NormalDistribution(0.0, 1.0); return norm.density(x, give_log); } t = -jstat.bd0(n/2.0,(n+1)/2.0) + jstat.stirlerr((n+1)/2.0) - jstat.stirlerr(n/2.0); if ( x*x > 0.2*n ) u = Math.log( 1+ x*x/n ) * n/2; else u = -jstat.bd0(n/2.0,(n+x*x)/2.0) + x*x/2.0; var p1 = jstat.TWO_PI *(1+x*x/n); var p2 = t-u; return (give_log) ? -0.5*Math.log(p1) + p2 : Math.exp(p2)/Math.sqrt(p1); // R_D_fexp(M_2PI*(1+x*x/n), t-u); }, _dnt: function(x, give_log) { if(give_log == null) give_log = false; var df = this._dof; var ncp = this._mu; var u; if(df <= 0.0) { console.warn("Illegal arguments _dnf"); return Number.NaN; } if(ncp == 0.0) { return this._dt(x, give_log); } if(!jstat.isFinite(x)) { // R_D__0 if(give_log) { return Number.NEGATIVE_INFINITY; } else { return 0.0; } } /* If infinite df then the density is identical to a normal distribution with mean = ncp. However, the formula loses a lot of accuracy around df=1e9 */ if(!isFinite(df) || df > 1e8) { var dist = new NormalDistribution(ncp, 1.); return dist.density(x, give_log); } /* Do calculations on log scale to stabilize */ /* Consider two cases: x ~= 0 or not */ if (Math.abs(x) > Math.sqrt(df * jstat.DBL_EPSILON)) { var newT = new StudentTDistribution(df+2, ncp); u = Math.log(df) - Math.log(Math.abs(x)) + Math.log(Math.abs(newT._pnt(x*Math.sqrt((df+2)/df), true, false) - this._pnt(x, true, false))); /* FIXME: the above still suffers from cancellation (but not horribly) */ } else { /* x ~= 0 : -> same value as for x = 0 */ u = jstat.lgamma((df+1)/2) - jstat.lgamma(df/2) - .5*(Math.log(Math.PI) + Math.log(df) + ncp*ncp); } return (give_log ? u : Math.exp(u)); }, _pt: function(x, lower_tail, log_p) { if(lower_tail == null) lower_tail = true; if(log_p == null) log_p = false; var val, nx; var n = this._dof; var DT_0, DT_1; if(lower_tail) { if(log_p) { DT_0 = Number.NEGATIVE_INFINITY; DT_1 = 1.; } else { DT_0 = 0.; DT_1 = 1.; } } else { if(log_p) { // not lower_tail but log_p DT_0 = 0.; DT_1 = Number.NEGATIVE_INFINITY; } else { // not lower_tail and not log_p DT_0 = 1.; DT_1 = 0.; } } if(n <= 0.0) { console.warn("Invalid T distribution _pt"); return Number.NaN; } var norm = new NormalDistribution(0,1); if(!jstat.isFinite(x)) { return (x < 0) ? DT_0 : DT_1; } if(!jstat.isFinite(n)) { return norm._cdf(x, lower_tail, log_p); } if (n > 4e5) { /*-- Fixme(?): test should depend on `n' AND `x' ! */ /* Approx. from Abramowitz & Stegun 26.7.8 (p.949) */ val = 1./(4.*n); return norm._cdf(x*(1. - val)/sqrt(1. + x*x*2.*val), lower_tail, log_p); } nx = 1 + (x/n)*x; /* FIXME: This test is probably losing rather than gaining precision, * now that pbeta(*, log_p = TRUE) is much better. * Note however that a version of this test *is* needed for x*x > D_MAX */ if(nx > 1e100) { /* <==> x*x > 1e100 * n */ /* Danger of underflow. So use Abramowitz & Stegun 26.5.4 pbeta(z, a, b) ~ z^a(1-z)^b / aB(a,b) ~ z^a / aB(a,b), with z = 1/nx, a = n/2, b= 1/2 : */ var lval; lval = -0.5*n*(2*Math.log(Math.abs(x)) - Math.log(n)) - jstat.logBeta(0.5*n, 0.5) - Math.log(0.5*n); val = log_p ? lval : Math.exp(lval); } else { /* val = (n > x * x) // ? pbeta (x * x / (n + x * x), 0.5, n / 2., 0, log_p) // : pbeta (1. / nx, n / 2., 0.5, 1, log_p); */ if(n > x * x) { var beta = new BetaDistribution(0.5, n/2.); return beta._cdf(x*x/ (n + x * x), false, log_p); } else { beta = new BetaDistribution(n / 2., 0.5); return beta._cdf(1. / nx, true, log_p); } } /* Use "1 - v" if lower_tail and x > 0 (but not both):*/ if(x <= 0.) lower_tail = !lower_tail; if(log_p) { if(lower_tail) return jstat.log1p(-0.5*Math.exp(val)); else return val - M_LN2; /* = log(.5* pbeta(....)) */ } else { val /= 2.; if(lower_tail) { return (0.5 - val + 0.5); } else { return val; } } }, _pnt: function(t, lower_tail, log_p) { var dof = this._dof; var ncp = this._mu; var DT_0, DT_1; if(lower_tail) { if(log_p) { DT_0 = Number.NEGATIVE_INFINITY; DT_1 = 1.; } else { DT_0 = 0.; DT_1 = 1.; } } else { if(log_p) { // not lower_tail but log_p DT_0 = 0.; DT_1 = Number.NEGATIVE_INFINITY; } else { // not lower_tail and not log_p DT_0 = 1.; DT_1 = 0.; } } var albeta, a, b, del, errbd, lambda, rxb, tt, x; var geven, godd, p, q, s, tnc, xeven, xodd; var it, negdel; /* note - itrmax and errmax may be changed to suit one's needs. */ var ITRMAX = 1000; var ERRMAX = 1.e-7; if(dof <= 0.0) { return Number.NaN; } else if (dof == 0.0) { return this._pt(t); } if(!jstat.isFinite(t)) { return (t < 0) ? DT_0 : DT_1; } if(t >= 0.) { negdel = false; tt = t; del = ncp; } else { /* We deal quickly with left tail if extreme, since pt(q, df, ncp) <= pt(0, df, ncp) = \Phi(-ncp) */ if(ncp >= 40 && (!log_p || !lower_tail)) { return DT_0; } negdel = true; tt = -t; del = -ncp; } if(dof > 4e5 || del*del > 2* Math.LN2 * (-(jstat.DBL_MIN_EXP))) { /*-- 2nd part: if del > 37.62, then p=0 below FIXME: test should depend on `df', `tt' AND `del' ! */ /* Approx. from Abramowitz & Stegun 26.7.10 (p.949) */ s=1./(4.*dof); var norm = new NormalDistribution(del, Math.sqrt(1. + tt*tt*2.*s)); var result = norm._cdf(tt*(1.-s), lower_tail != negdel, log_p); return result; } /* initialize twin series */ /* Guenther, J. (1978). Statist. Computn. Simuln. vol.6, 199. */ x = t * t; rxb = dof/(x + dof);/* := (1 - x) {x below} -- but more accurately */ x = x / (x + dof);/* in [0,1) */ if (x > 0.) {/* <==> t != 0 */ lambda = del * del; p = .5 * Math.exp(-.5 * lambda); if(p == 0.) { // underflow! console.warn("underflow in _pnt"); return DT_0; } q = jstat.SQRT_2dPI * p * del; s = .5 - p; if(s < 1e-7) { s = -0.5 * jstat.expm1(-0.5 * lambda); } a = .5; b = .5 * dof; /* rxb = (1 - x) ^ b [ ~= 1 - b*x for tiny x --> see 'xeven' below] * where '(1 - x)' =: rxb {accurately!} above */ rxb = Math.pow(rxb, b); albeta = jstat.LN_SQRT_PI + jstat.lgamma(b) - jstat.lgamma(.5 + b); /* TODO: change incompleteBeta function to accept lower_tail and p_log */ xodd = jstat.incompleteBeta(a, b, x); godd = 2. * rxb * Math.exp(a * Math.log(x) - albeta); tnc = b * x; xeven = (tnc < jstat.DBL_EPSILON) ? tnc : 1. - rxb; geven = tnc * rxb; tnc = p * xodd + q * xeven; /* repeat until convergence or iteration limit */ for(it = 1; it <= ITRMAX; it++) { a += 1.; xodd -= godd; xeven -= geven; godd *= x * (a + b - 1.) / a; geven *= x * (a + b - .5) / (a + .5); p *= lambda / (2 * it); q *= lambda / (2 * it + 1); tnc += p * xodd + q * xeven; s -= p; /* R 2.4.0 added test for rounding error here. */ if(s < -1.e-10) { /* happens e.g. for (t,df,ncp)=(40,10,38.5), after 799 it.*/ //console.write("precision error _pnt"); break; } if(s <= 0 && it > 1) break; errbd = 2. * s * (xodd - godd); if(Math.abs(errbd) < ERRMAX) break;/*convergence*/ } if(it == ITRMAX) { throw "Non-convergence _pnt"; } } else { tnc = 0.; } norm = new NormalDistribution(0,1); tnc += norm._cdf(-del, /*lower*/true, /*log_p*/ false); lower_tail = lower_tail != negdel; /* xor */ if(tnc > 1 - 1e-10 && lower_tail) { //console.warn("precision error _pnt"); } var res = jstat.fmin2(tnc, 1.); if(lower_tail) { if(log_p) { return Math.log(res); } else { return res; } } else { if(log_p) { return jstat.log1p(-(res)); } else { return (0.5 - (res) + 0.5); } } }, getDegreesOfFreedom: function() { return this._dof; }, getNonCentralityParameter: function() { return this._mu; }, getMean: function() { if(this._dof > 1) { var ans = (1/2)*Math.log(this._dof/2) + jstat.lgamma((this._dof-1)/2) - jstat.lgamma(this._dof/2) return Math.exp(ans) * this._mu; } else { return Number.NaN; } }, getVariance: function() { if(this._dof > 2) { var ans = this._dof * (1 + this._mu*this._mu)/(this._dof-2) - (((this._mu*this._mu * this._dof) / 2) * Math.pow(Math.exp(jstat.lgamma((this._dof - 1)/2)-jstat.lgamma(this._dof/2)), 2)); return ans; } else { return Number.NaN; } } }); /******************************************************************************/ /* jQuery Flot graph objects */ /******************************************************************************/ var Plot = Class.extend({ init: function(id, options) { this._container = '#' + String(id); this._plots = []; this._flotObj = null; this._locked = false; if(options != null) { this._options = options; } else { this._options = { }; } }, getContainer: function() { return this._container; }, getGraph: function() { return this._flotObj; }, setData: function(data) { this._plots = data; }, clear: function() { this._plots = []; //this.render(); }, showLegend: function() { this._options.legend = { show: true } this.render(); }, hideLegend: function() { this._options.legend = { show: false } this.render(); }, render: function() { this._flotObj = null; this._flotObj = $.plot($(this._container), this._plots, this._options); } }); var DistributionPlot = Plot.extend({ init: function(id, distribution, range, options) { this._super(id, options); this._showPDF = true; this._showCDF = false; this._pdfValues = []; // raw values for pdf this._cdfValues = []; // raw values for cdf this._maxY = 1; this._plotType = 'line'; // line, point, both this._fill = false; this._distribution = distribution; // underlying PDF // Range object for the plot if(range != null && Range.validate(range)) { this._range = range; } else { this._range = this._distribution.getRange(); // no range supplied, use distribution default } // render if(this._distribution != null) { this._maxY = this._generateValues(); // create the pdf/cdf values in the ctor } else { this._options.xaxis = { min: range.getMinimum(), max: range.getMaximum() } this._options.yaxis = { max: 1 } } this.render(); }, setHover: function(bool) { if(bool) { if(this._options.grid == null) { this._options.grid = { hoverable: true, mouseActiveRadius: 25 } } else { this._options.grid.hoverable = true, this._options.grid.mouseActiveRadius = 25 } function showTooltip(x, y, contents, color) { $('<div id="jstat_tooltip">' + contents + '</div>').css( { position: 'absolute', display: 'none', top: y + 15, 'font-size': 'small', left: x + 5, border: '1px solid ' + color[1], color: color[2], padding: '5px', 'background-color': color[0], opacity: 0.80 }).appendTo("body").show(); } var previousPoint = null; $(this._container).bind("plothover", function(event, pos, item) { $("#x").text(pos.x.toFixed(2)); $("#y").text(pos.y.toFixed(2)); if (item) { if (previousPoint != item.datapoint) { previousPoint = item.datapoint; $("#jstat_tooltip").remove(); var x = jstat.toSigFig(item.datapoint[0],2), y = jstat.toSigFig(item.datapoint[1], 2); var text = null; var color = item.series.color; if(item.series.label == 'PDF') { text = "P(" + x + ") = " + y; color = ["#fee", "#fdd", "#C05F5F"]; } else { // cdf text = "F(" + x + ") = " + y; color = ["#eef", "#ddf", "#4A4AC0"]; } showTooltip(item.pageX, item.pageY, text, color); } } else { $("#jstat_tooltip").remove(); previousPoint = null; } }); $(this._container).bind("mouseleave", function() { if($('#jstat_tooltip').is(':visible')) { $('#jstat_tooltip').remove(); previousPoint = null; } }); } else { // unbind if(this._options.grid == null) { this._options.grid = { hoverable: false } } else { this._options.grid.hoverable = false } $(this._container).unbind("plothover"); } this.render(); }, setType: function(type) { this._plotType = type; var lines = {}; var points = {}; if(this._plotType == 'line') { lines.show = true; points.show = false; } else if(this._plotType == 'points') { lines.show = false; points.show = true; } else if(this._plotType == 'both') { lines.show = true; points.show = true; } if(this._options.series == null) { this._options.series = { lines: lines, points: points } } else { if(this._options.series.lines == null) { this._options.series.lines = lines; } else { this._options.series.lines.show = lines.show; } if(this._options.series.points == null) { this._options.series.points = points; } else { this._options.series.points.show = points.show; } } this.render(); }, setFill: function(bool) { this._fill = bool; if(this._options.series == null) { this._options.series = { lines: { fill: bool } } } else { if(this._options.series.lines == null) { this._options.series.lines = { fill: bool } } else { this._options.series.lines.fill = bool; } } this.render(); }, clear: function() { this._super(); this._distribution = null; this._pdfValues = []; this._cdfValues = []; this.render(); }, _generateValues: function() { this._cdfValues = []; // reinitialize the arrays. this._pdfValues = []; var xs = this._range.getPoints(); this._options.xaxis = { min: xs[0], max: xs[xs.length-1] } var pdfs = this._distribution.density(this._range); var cdfs = this._distribution.cumulativeDensity(this._range); for(var i = 0; i < xs.length; i++) { if(pdfs[i] == Number.POSITIVE_INFINITY || pdfs[i] == Number.NEGATIVE_INFINITY) { pdfs[i] = null; } if(cdfs[i] == Number.POSITIVE_INFINITY || cdfs[i] == Number.NEGATIVE_INFINITY) { cdfs[i] = null; } this._pdfValues.push([xs[i], pdfs[i]]); this._cdfValues.push([xs[i], cdfs[i]]); } return jstat.max(pdfs); }, showPDF: function() { this._showPDF = true; this.render(); }, hidePDF: function() { this._showPDF = false; this.render(); }, showCDF: function() { this._showCDF = true; this.render(); }, hideCDF: function() { this._showCDF = false; this.render(); }, setDistribution: function(distribution, range) { this._distribution = distribution; if(range != null) { this._range = range; } else { this._range = distribution.getRange(); } this._maxY = this._generateValues(); this._options.yaxis = { max: this._maxY*1.1 } this.render(); }, getDistribution: function() { return this._distribution; }, getRange: function() { return this._range; }, setRange: function(range) { this._range = range; this._generateValues(); this.render(); }, render: function() { if(this._distribution != null) { if(this._showPDF && this._showCDF) { this.setData([{ yaxis: 1, data:this._pdfValues, color: 'rgb(237,194,64)', clickable: false, hoverable: true, label: "PDF" }, { yaxis: 2, data:this._cdfValues, clickable: false, color: 'rgb(175,216,248)', hoverable: true, label: "CDF" }]); this._options.yaxis = { max: this._maxY*1.1 } } else if(this._showPDF) { this.setData([{ data:this._pdfValues, hoverable: true, color: 'rgb(237,194,64)', clickable: false, label: "PDF" }]); this._options.yaxis = { max: this._maxY*1.1 } } else if(this._showCDF) { this.setData([{ data:this._cdfValues, hoverable: true, color: 'rgb(175,216,248)', clickable: false, label: "CDF" }]); this._options.yaxis = { max: 1.1 } } } else { this.setData([]); } this._super(); // Call the parent plot method } }); var DistributionFactory = {}; DistributionFactory.build = function(json) { /* if(json.name == null) { try{ json = JSON.parse(json); } catch(err) { throw "invalid JSON"; } // try to parse it }*/ /* if(json.name != null) { var name = json.name; } else { throw "Malformed JSON provided to DistributionBuilder " + json; } */ if(json.NormalDistribution) { if(json.NormalDistribution.mean != null && json.NormalDistribution.standardDeviation != null) { return new NormalDistribution(json.NormalDistribution.mean[0], json.NormalDistribution.standardDeviation[0]); } else { throw "Malformed JSON provided to DistributionBuilder " + json; } } else if (json.LogNormalDistribution) { if(json.LogNormalDistribution.location != null && json.LogNormalDistribution.scale != null) { return new LogNormalDistribution(json.LogNormalDistribution.location[0], json.LogNormalDistribution.scale[0]); } else { throw "Malformed JSON provided to DistributionBuilder " + json; } } else if (json.BetaDistribution) { if(json.BetaDistribution.alpha != null && json.BetaDistribution.beta != null) { return new BetaDistribution(json.BetaDistribution.alpha[0], json.BetaDistribution.beta[0]); } else { throw "Malformed JSON provided to DistributionBuilder " + json; } } else if (json.GammaDistribution) { if(json.GammaDistribution.shape != null && json.GammaDistribution.scale != null) { return new GammaDistribution(json.GammaDistribution.shape[0], json.GammaDistribution.scale[0]); } else { throw "Malformed JSON provided to DistributionBuilder " + json; } } else if (json.StudentTDistribution) { if(json.StudentTDistribution.degreesOfFreedom != null && json.StudentTDistribution.nonCentralityParameter != null) { return new StudentTDistribution(json.StudentTDistribution.degreesOfFreedom[0], json.StudentTDistribution.nonCentralityParameter[0]); } else if(json.StudentTDistribution.degreesOfFreedom != null) { return new StudentTDistribution(json.StudentTDistribution.degreesOfFreedom[0]); } else { throw "Malformed JSON provided to DistributionBuilder " + json; } } else { throw "Malformed JSON provided to DistributionBuilder " + json; } }