211 lines
5.7 KiB
C
211 lines
5.7 KiB
C
/* pvalue.f -- translated by f2c (version 20030320).
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You must link the resulting object file with the libraries:
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-lf2c -lm (in that order)
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*/
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#include "f2c.h"
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/* DECK PVALUE */
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/* Subroutine */ int pvalue_(integer *l, integer *nder, real *x, real *yfit,
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real *yp, real *a)
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{
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/* System generated locals */
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integer i__1, i__2;
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/* Local variables */
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integer i__, n, k1, k2, k3, k4;
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real cc;
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integer ic, kc, in, k1i, lm1, lp1;
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real dif;
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integer k3p1, k4p1, ndo;
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real val;
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integer ilo, iup, ndp1, inp1, k3pn, k4pn, nord, maxord;
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/* ***BEGIN PROLOGUE PVALUE */
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/* ***PURPOSE Use the coefficients generated by POLFIT to evaluate the */
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/* polynomial fit of degree L, along with the first NDER of */
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/* its derivatives, at a specified point. */
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/* ***LIBRARY SLATEC */
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/* ***CATEGORY K6 */
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/* ***TYPE SINGLE PRECISION (PVALUE-S, DP1VLU-D) */
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/* ***KEYWORDS CURVE FITTING, LEAST SQUARES, POLYNOMIAL APPROXIMATION */
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/* ***AUTHOR Shampine, L. F., (SNLA) */
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/* Davenport, S. M., (SNLA) */
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/* ***DESCRIPTION */
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/* Written by L. F. Shampine and S. M. Davenport. */
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/* Abstract */
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/* The subroutine PVALUE uses the coefficients generated by POLFIT */
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/* to evaluate the polynomial fit of degree L , along with the first */
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/* NDER of its derivatives, at a specified point. Computationally */
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/* stable recurrence relations are used to perform this task. */
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/* The parameters for PVALUE are */
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/* Input -- */
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/* L - the degree of polynomial to be evaluated. L may be */
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/* any non-negative integer which is less than or equal */
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/* to NDEG , the highest degree polynomial provided */
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/* by POLFIT . */
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/* NDER - the number of derivatives to be evaluated. NDER */
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/* may be 0 or any positive value. If NDER is less */
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/* than 0, it will be treated as 0. */
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/* X - the argument at which the polynomial and its */
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/* derivatives are to be evaluated. */
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/* A - work and output array containing values from last */
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/* call to POLFIT . */
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/* Output -- */
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/* YFIT - value of the fitting polynomial of degree L at X */
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/* YP - array containing the first through NDER derivatives */
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/* of the polynomial of degree L . YP must be */
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/* dimensioned at least NDER in the calling program. */
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/* ***REFERENCES L. F. Shampine, S. M. Davenport and R. E. Huddleston, */
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/* Curve fitting by polynomials in one variable, Report */
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/* SLA-74-0270, Sandia Laboratories, June 1974. */
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/* ***ROUTINES CALLED XERMSG */
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/* ***REVISION HISTORY (YYMMDD) */
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/* 740601 DATE WRITTEN */
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/* 890531 Changed all specific intrinsics to generic. (WRB) */
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/* 890531 REVISION DATE from Version 3.2 */
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/* 891214 Prologue converted to Version 4.0 format. (BAB) */
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/* 900315 CALLs to XERROR changed to CALLs to XERMSG. (THJ) */
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/* 900510 Convert XERRWV calls to XERMSG calls. (RWC) */
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/* 920501 Reformatted the REFERENCES section. (WRB) */
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/* ***END PROLOGUE PVALUE */
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/* ***FIRST EXECUTABLE STATEMENT PVALUE */
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/* Parameter adjustments */
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--a;
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--yp;
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/* Function Body */
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if (*l < 0) {
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goto L12;
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}
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ndo = max(*nder,0);
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ndo = min(ndo,*l);
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maxord = a[1] + .5f;
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k1 = maxord + 1;
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k2 = k1 + maxord;
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k3 = k2 + maxord + 2;
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nord = a[k3] + .5f;
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if (*l > nord) {
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goto L11;
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}
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k4 = k3 + *l + 1;
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if (*nder < 1) {
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goto L2;
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}
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i__1 = *nder;
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for (i__ = 1; i__ <= i__1; ++i__) {
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/* L1: */
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yp[i__] = 0.f;
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}
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L2:
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if (*l >= 2) {
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goto L4;
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}
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if (*l == 1) {
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goto L3;
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}
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/* L IS 0 */
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val = a[k2 + 1];
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goto L10;
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/* L IS 1 */
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L3:
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cc = a[k2 + 2];
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val = a[k2 + 1] + (*x - a[2]) * cc;
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if (*nder >= 1) {
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yp[1] = cc;
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}
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goto L10;
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/* L IS GREATER THAN 1 */
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L4:
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ndp1 = ndo + 1;
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k3p1 = k3 + 1;
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k4p1 = k4 + 1;
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lp1 = *l + 1;
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lm1 = *l - 1;
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ilo = k3 + 3;
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iup = k4 + ndp1;
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i__1 = iup;
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for (i__ = ilo; i__ <= i__1; ++i__) {
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/* L5: */
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a[i__] = 0.f;
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}
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dif = *x - a[lp1];
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kc = k2 + lp1;
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a[k4p1] = a[kc];
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a[k3p1] = a[kc - 1] + dif * a[k4p1];
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a[k3 + 2] = a[k4p1];
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/* EVALUATE RECURRENCE RELATIONS FOR FUNCTION VALUE AND DERIVATIVES */
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i__1 = lm1;
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for (i__ = 1; i__ <= i__1; ++i__) {
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in = *l - i__;
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inp1 = in + 1;
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k1i = k1 + inp1;
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ic = k2 + in;
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dif = *x - a[inp1];
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val = a[ic] + dif * a[k3p1] - a[k1i] * a[k4p1];
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if (ndo <= 0) {
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goto L8;
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}
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i__2 = ndo;
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for (n = 1; n <= i__2; ++n) {
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k3pn = k3p1 + n;
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k4pn = k4p1 + n;
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/* L6: */
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yp[n] = dif * a[k3pn] + n * a[k3pn - 1] - a[k1i] * a[k4pn];
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}
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/* SAVE VALUES NEEDED FOR NEXT EVALUATION OF RECURRENCE RELATIONS */
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i__2 = ndo;
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for (n = 1; n <= i__2; ++n) {
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k3pn = k3p1 + n;
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k4pn = k4p1 + n;
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a[k4pn] = a[k3pn];
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/* L7: */
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a[k3pn] = yp[n];
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}
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L8:
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a[k4p1] = a[k3p1];
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/* L9: */
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a[k3p1] = val;
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}
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/* NORMAL RETURN OR ABORT DUE TO ERROR */
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L10:
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*yfit = val;
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return 0;
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L11:
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return 0;
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/* WRITE (XERN1, '(I8)') L */
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/* WRITE (XERN2, '(I8)') NORD */
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/* CALL XERMSG ('SLATEC', 'PVALUE', */
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/* * 'THE ORDER OF POLYNOMIAL EVALUATION, L = ' // XERN1 // */
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/* * ' REQUESTED EXCEEDS THE HIGHEST ORDER FIT, NORD = ' // XERN2 // */
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/* * ', COMPUTED BY POLFIT -- EXECUTION TERMINATED.', 8, 2) */
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/* RETURN */
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L12:
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return 0;
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/* CALL XERMSG ('SLATEC', 'PVALUE', */
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/* + 'INVALID INPUT PARAMETER. ORDER OF POLYNOMIAL EVALUATION ' // */
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/* + 'REQUESTED IS NEGATIVE -- EXECUTION TERMINATED.', 2, 2) */
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/* RETURN */
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} /* pvalue_ */
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