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authorJörg Frings-Fürst <debian@jff-webhosting.net>2017-11-25 10:16:00 +0100
committerJörg Frings-Fürst <debian@jff-webhosting.net>2017-11-25 10:16:00 +0100
commitf6b8e0eae4374f339487a33e3e4fe5462d5816e1 (patch)
tree5f5f764fd6cda404b2ad6e85762c03fce3a335db /numlib/dhsx.c
parent615ab5513e79c4abc5bbe5c993587785b6a1738b (diff)
New upstream version 2.0.0upstream/2.0.0
Diffstat (limited to 'numlib/dhsx.c')
-rwxr-xr-x[-rw-r--r--]numlib/dhsx.c306
1 files changed, 225 insertions, 81 deletions
diff --git a/numlib/dhsx.c b/numlib/dhsx.c
index 180d15c..e9da0eb 100644..100755
--- a/numlib/dhsx.c
+++ b/numlib/dhsx.c
@@ -20,7 +20,9 @@
#undef DEBUG
-static void simplexinit(int di, double *cp, double *r,double **p);
+int dhsx_debug = 1;
+
+static void simplexinit(int di, double *cp, double **p, double *r, double sv, int ii);
static double trypoint(int di,double *cp, double **p, double *y, int hix, double hpfac,
double (*funk)(void *fdata, double *tp), void *fdata, double *tryp);
@@ -28,68 +30,98 @@ static double trypoint(int di,double *cp, double **p, double *y, int hix, double
#define ALPHA 0.7 /* Extrapolate hight point through oposite face factor */
#define GAMMA 1.4 /* Aditional extrapolation if ALPHA is good */
-#define BETA 0.4 /* One dimensional contraction factor */
+#define BETA 0.4 /* One dimensional contraction factor (smaller is more) */
+#define DELTA 0.5 /* Multi dimensional contraction factor (smaller is more) */
#define NONEXP 2 /* non expanding passes */
#else /* Standard tuning values */
-#define ALPHA 1.0 /* Extrapolate hight point through oposite face factor */
-#define GAMMA 2.0 /* Aditional extrapolation if ALPHA is good */
-#define BETA 0.5 /* One dimensional contraction factor */
-#define NONEXP 2 /* non expanding passes */
+#define ALPHA 1.0 /* [1.0] Extrapolate hight point through oposite face factor */
+#define GAMMA 2.0 /* [2.0] Aditional extrapolation if ALPHA is good */
+#define BETA 0.4 /* [0.5] One dimensional contraction factor (smaller is more) */
+#define DELTA 0.4 /* [0.5] Multi dimensional contraction factor (smaller is more) */
+#define NONEXP 3 /* [3] non expanding passes */
#endif
-
/* Down hill simplex function */
/* return 0 on sucess, 1 on failure due to excessive itterations */
/* Result will be in cp */
-/* Arrays start at 0 */
int dhsx(
double *rv, /* If not NULL, return the residual error */
int di, /* Dimentionality */
-double *cp, /* Initial starting point */
+double *cp, /* Initial starting point, return minimum */
double *s, /* Size of initial search area */
double ftol, /* Finishing tollerance of error change */
-double atol, /* Absolute return value tollerance */
+double athr, /* Absolute return value threshold. (Set high to not use) */
int maxit, /* Maximum iterations allowed */
double (*funk)(void *fdata, double *tp), /* Error function to evaluate */
void *fdata /* Data needed by function */
) {
+ int ii = 0; /* Initial simplex orientation */
int i, j;
- int lox, hix, nhix; /* Lowest point index, highest point, next highest point */
- int nsp = di+1; /* Number of simplex verticy points */
int nit; /* Number of iterations */
+ int nsp = di+1; /* Number of simplex verticy points */
double tryy, ysave;
double tol;
- double **p; /* Simplex array */
- double *y; /* values of func at verticies */
+ double **p; /* Current simplex array */
+ double *y; /* Values of func at verticies */
+ double **p2; /* Trial simplex array */
+ double *y2; /* Trial values of func at verticies */
+ int lox, hix, nhix; /* Lowest point index, highest point, next highest point */
double *tryp; /* Temporary used by trypoint() */
/* Allocate array arrays */
- y = dvector(0, di); /* Value of function at verticies */
- tryp = dvector(0, di-1);
- p = dmatrix(0, di+1, 0, di); /* Vertex array of dimentions */
+ tryp = dvector(0, di-1); /* Trial value */
+ p = dmatrix(0, nsp-1, 0, di-1); /* Vertex array of dimentions */
+ y = dvector(0, nsp-1); /* Value of function at verticies */
+ p2 = dmatrix(0, nsp-1, 0, di-1); /* Trial vertex array of dimentions */
+ y2 = dvector(0, nsp-1); /* Trial value of function at verticies */
/* Init the search simplex */
- simplexinit(di, cp, s, p);
+ simplexinit(di, cp, p, s, 1.0, ii);
+
+ /* Compute initial y (function) values at simplex verticies */
+ for (i = 0; i < nsp; i++) /* For all verticies */
+ y[i] = (*funk)(fdata, p[i]); /* Compute error function */
- /* Compute current center point position */
- for (j = 0; j < di; j++) { /* For all dimensions */
+ /* Locate verticy with best value */
+ lox = 0;
+ for (i = 0; i < nsp; i++) {
+ if (y[i] < y[lox])
+ lox = i;
+ }
+ tryy = (*funk)(fdata, cp); /* Value at initial point */
+
+ /* If our initial point is better than any of the simplex verticies */
+ if (y[lox] > tryy) {
+ /* Move all the verticies to match moving lox to cp */
+ for (i = 0; i < nsp; i++) {
+ if (i == lox)
+ continue;
+ for (j = 0; j < di; j++)
+ p[i][j] += cp[j] - p[lox][j];
+ y[i] = (*funk)(fdata, p[i]); /* Compute error function */
+ }
+ /* Make lox be the input point */
+ for (j = 0; j < di; j++)
+ p[lox][j] = cp[j];
+ y[lox] = tryy;
+ }
+
+ /* Compute current center point location as sum of verticies. */
+ /* (We use this to compute moves) */
+ for (j = 0; j < di; j++) { /* For all dimensions */
double sum;
for (i = 0, sum = 0.0; i < nsp; i++) /* For all verticies */
sum += p[i][j];
cp[j] = sum;
}
- /* Compute initial y (function) values at verticies */
- for (i = 0; i < nsp; i++) /* For all verticies */
- y[i] = (*funk)(fdata,p[i]); /* Compute error function */
-
/* Untill we find a solution or give up */
- for (nit = 0; nit < maxit; nit++) {
- /* Find highest, next highest and lowest vertex */
+ for (nit = 0; ; nit++) {
+ /* Find highest, next highest and lowest vertex */
lox = nhix = hix = 0;
for (i = 0; i < nsp; i++) {
if (y[i] < y[lox])
@@ -104,82 +136,189 @@ void *fdata /* Data needed by function */
tol = y[hix] - y[lox];
-#ifdef DEBUG /* 2D */
- printf("Current vs = %f,%f %f,%f %f,%f\n",
- p[0].c[0],p[0].c[1],p[1].c[0],p[1].c[1],p[2].c[0],p[2].c[1]);
- printf("Current errs = %e %e %e\n",y[0],y[1],y[2]);
- printf("Current sxs = %d %d %d\n",sy[0]->no,sy[1]->no,sy[2]->no);
- printf("Current y[hix] = %e\n",y[hix]);
+#ifdef DEBUG
+ if (dhsx_debug) {
+ printf("Current vs =\n");
+ for (i = 0; i < nsp; i++)
+ printf(" %d: %s\n",i,debPdv(di, p[i]));
+ printf("Current errs = %s\n",debPdv(nsp,y));
+ printf("Current y[lox] = %e, y[hix] = %e\n",y[lox], y[hix]);
+ }
+#endif /* DEBUG */
+
+ /* If we look like we are about to finish, */
+ /* see if we should re-start with a new simplex. */
+ if (tol < ftol && y[lox] < athr /* Found an adequate solution */
+ && nit < maxit) {
+ double scale = 0.0;
+ int lox2;
+
+#ifdef DEBUG
+ if (dhsx_debug) printf(" nit %d, tol %e\n",nit, tol);
+#endif /* DEBUG */
+
+ /* compute center location */
+ tryy = 1.0/nsp;
+ for (j = 0; j < di; j++) /* For all dimensions */
+ cp[j] *= tryy; /* Set cp to center point of simplex */
+
+ /* Compute scaled distance of vertexes from center */
+ for (i = 0; i < nsp; i++) {
+ double dist = 0.0;
+ for (j = 0; j < di; j++) {
+ double tt = (cp[j] - p[i][j])/s[j];
+ dist += tt * tt;
+ }
+ scale += sqrt(dist);
+ }
+ scale /= (double)nsp; /* Average scale compared to starting simplex */
+#ifdef DEBUG
+ if (dhsx_debug) printf(" ave scale = %f\n",scale);
+#endif /* DEBUG */
+
+ /* Enlarge search space, but not more than initial */
+ scale *= 10.0;
+ if (scale > 1.0)
+ scale = 1.0;
+
+ /* Compute trial simplex with different orientation */
+ if (++ii >= (di+1))
+ ii = 0;
+
+ /* Init the search simplex */
+ simplexinit(di, cp, p2, s, scale, ii);
+
+ /* Compute y (function) values at simplex verticies */
+ for (i = 0; i < nsp; i++) /* For all verticies */
+ y2[i] = (*funk)(fdata, p2[i]); /* Compute error function */
+
+ /* Locate verticy with best value */
+ lox2 = 0;
+ for (i = 0; i < nsp; i++) {
+ if (y2[i] < y2[lox2])
+ lox2 = i;
+ }
+#ifdef DEBUG
+ if (dhsx_debug) printf(" y2lox %f ylox %f\n",y2[lox2], y[lox]);
+#endif /* DEBUG */
+
+ /* If any of its vertexes are better than current best, switch */
+ /* to it and continue (i.e. re-start) */
+ if (y2[lox2] < y[lox]) {
+
+#ifdef DEBUG
+ if (dhsx_debug) printf(" restarting\n");
#endif /* DEBUG */
- if (tol < ftol && y[lox] < atol) { /* Found an adequate solution */
- /* (allow 10 x range for disambiguator) */
- /* set cp[] to best point, and return error value of that point */
- tryy = 1.0/(di+1);
+ for (i = 0; i < nsp; i++) {
+ for (j = 0; j < di; j++)
+ p[i][j] = p2[i][j];
+ y[i] = y2[i];
+ }
+
+ /* Compute current center point location as sum of verticies. */
+ /* (We use this to compute moves) */
+ for (j = 0; j < di; j++) { /* For all dimensions */
+ double sum;
+ for (i = 0, sum = 0.0; i < nsp; i++) /* For all verticies */
+ sum += p[i][j];
+ cp[j] = sum;
+ }
+
+ /* Find highest, next highest and lowest vertex */
+ lox = nhix = hix = 0;
+ for (i = 0; i < nsp; i++) {
+ if (y[i] < y[lox])
+ lox = i;
+ if (y[i] > y[hix]) {
+ nhix = hix;
+ hix = i;
+ } else if (y[i] > y[nhix]) {
+ nhix = i;
+ }
+ }
+
+ tol = y[hix] - y[lox];
+ }
+ }
+
+ if ((tol < ftol && y[lox] < athr) /* Found an adequate solution */
+ || ((nit+1) >= maxit)) { /* Or we are about to fail */
+
+ /* convert cp[] to center point location, */
+ /* and use best out of it and any simplex verticy. */
+ tryy = 1.0/nsp;
for (j = 0; j < di; j++) /* For all dimensions */
cp[j] *= tryy; /* Set cp to center point of simplex */
#ifdef DEBUG
- printf("C point = %f,%f\n",cp[0],cp[1]);
+ if (dhsx_debug) printf("C point = %s\n",debPdv(di,cp));
#endif
- tryy = (*funk)(fdata,cp); /* Compute error function */
+ tryy = (*funk)(fdata, cp); /* Compute error function */
if (tryy > y[lox]) { /* Center point is not the best */
+#ifdef DEBUG
+ if (dhsx_debug) printf("C point val %f is not best, using sx %d val %f instead\n",tryy,lox,y[lox]);
+#endif
tryy = y[lox];
for (j = 0; j < di; j++)
cp[j] = p[lox][j];
}
- free_dmatrix(p, 0, di+1, 0, di);
+ free_dvector(y2, 0, nsp-1);
+ free_dmatrix(p2, 0, nsp-1, 0, di-1);
+ free_dvector(y, 0, nsp-1);
+ free_dmatrix(p, 0, nsp-1, 0, di-1);
free_dvector(tryp, 0, di-1);
- free_dvector(y, 0, di);
-printf("~1 itterations = %d\n",nit);
+#ifdef DEBUG
+ if (dhsx_debug) printf("Total itterations = %d\n",nit);
+#endif
if (rv != NULL)
*rv = tryy;
+ if ((nit+1) >= maxit)
+ return 1; /* Failed */
return 0;
}
- if (nit > NONEXP) { /* Only try expanding after a couple of iterations */
+ /* Only try expanding after a couple of iterations */
+ if (nit > NONEXP) {
/* Try moving the high point through the oposite face by ALPHA */
#ifdef DEBUG
- printf("dhsx: try moving high point %d through oposite face",hix);
+ if (dhsx_debug) printf("dhsx: try moving high point %d through oposite face",hix);
#endif
tryy = trypoint(di, cp, p, y, hix, -ALPHA, funk, fdata, tryp);
}
+ /* If gave good result, continue on in that direction */
if (nit > NONEXP && tryy <= y[lox]) {
#ifdef DEBUG
- verbose(4,"dhsx: moving high through oposite face worked");
+ if (dhsx_debug) printf("dhsx: moving high through oposite face worked");
#endif
- /* Gave good result, so continue on in that direction */
- tryy=trypoint(di,cp,p,y,hix,GAMMA,funk,fdata,tryp);
+ tryy = trypoint(di, cp, p, y, hix, GAMMA, funk, fdata, tryp);
+ /* else if ALPHA move made things worse, do a one dimensional */
+ /* contraction by a factor BETA */
} else if (nit <= NONEXP || tryy >= y[nhix]) {
- /* else if ALPHA move made things worse, do a one dimensional */
- /* contraction by a factor BETA */
#ifdef DEBUG
- verbose(4,"dhsx: else try moving contracting point %d, y[ini] = %f",hix,y[hix]);
+ if (dhsx_debug) printf("dhsx: else try moving contracting point %d, y[ini] = %f",hix,y[hix]);
#endif
ysave = y[hix];
tryy = trypoint(di, cp, p, y, hix, BETA, funk, fdata, tryp);
if (tryy >= ysave) {
#ifdef DEBUG
- verbose(4,"dhsx: contracting didn't work, try contracting other points to low");
+ if (dhsx_debug) printf("dhsx: contracting didn't work, try contracting other points to low");
#endif
/* That still didn't help us, so move all the */
- /* other points towards the high point */
+ /* other points towards the low point */
for (i = 0; i < nsp; i++) { /* For all verts except low */
if (i != lox) {
- for (j = 0; j < di; j++) { /* For all dimensions */
- cp[j] = 0.5 * (p[i][j] + p[lox][j]);
- p[i][j] = cp[j];
- }
- /* Compute function value for new point */
- y[i] = (*funk)(fdata,p[i]); /* Compute error function */
+ for (j = 0; j < di; j++) /* For all dimensions */
+ p[i][j] = DELTA * p[i][j] + (1.0 - DELTA) * p[lox][j];
+ y[i] = (*funk)(fdata, p[i]); /* Compute function value for new point */
}
}
- /* Re-compute current center point value */
+ /* Re-compute current center point location */
for (j = 0; j < di; j++) {
double sum;
for (i = 0,sum = 0.0;i<nsp;i++)
@@ -188,22 +327,17 @@ printf("~1 itterations = %d\n",nit);
}
} else {
#ifdef DEBUG
- verbose(4,"dhsx: contracting point %d worked, tryy = %e, ysave = %e",hix,tryy,ysave);
+ if (dhsx_debug) printf("dhsx: contracting point %d worked, tryy = %e, ysave = %e",hix,tryy,ysave);
#endif
}
}
}
- free_dmatrix(p, 0, di+1, 0, di);
- free_dvector(tryp, 0, di-1);
- free_dvector(y, 0, di);
- if (rv != NULL)
- *rv = tryy;
- return 1; /* Failed */
}
/* Try moving the high point through the opposite face */
/* by a factor of fac, and replaces the high point if */
-/* that proves to be better. */
+/* that proves to be better. Return the failed or new */
+/* function value. */
static double trypoint(
int di, /* Dimentionality */
double *cp, /* nsp * center coord/Returned coordinate */
@@ -229,7 +363,7 @@ double *tryp /* temporary array of size di-1 */
/* If new high point pos. is better */
if (tryy < y[hix]) {
#ifdef DEBUG
- printf("Try gave improved %e from sx %d",tryy,lsxp->last_fwd->no);
+ if (dhsx_debug) printf("Try gave improved %e from sx %d",tryy,hix);
#endif
y[hix] = tryy; /* Replace func val of hi with trial */
@@ -239,8 +373,7 @@ double *tryp /* temporary array of size di-1 */
}
} else {
#ifdef DEBUG
- verbose(4,"Try gave worse %e from sx %d",tryy,
- lsxp->last_fwd == NULL ? -999 : lsxp->last_fwd->no);
+ if (dhsx_debug) printf("Try gave worse %e from sx %d",tryy,hix);
#endif
}
return tryy; /* Function value of trial point */
@@ -251,17 +384,19 @@ double *tryp /* temporary array of size di-1 */
static void
simplexinit(
int di, /* Dimentionality */
-double *cp, /* Initial solution values */
+double *cp, /* Initial solution location */
+double **p, /* Simplex to initialize */
double *s, /* initial radius for each dimention */
-double **p /* Simplex to initialize */
+double sv, /* Radius scaling value */
+int ii /* Coordinate to start with */
) {
double bb;
double hh = 0.5; /* Constant */
double rr = sqrt(3.0)/2.0; /* Constant */
- int i,j;
- for (i = 0; i <= di; i++) { /* For each vertex */
+ int i, j;
+ for (i = 0; i < (di+1); i++) { /* For each vertex */
/* The bounding points form a equalateral simplex */
- /* whose vertexes are on a spehere about the data */
+ /* whose vertexes are on a sphere about the data */
/* point center. The coordinate sequence is: */
/* B = sphere radius */
/* H = 0.5 */
@@ -287,16 +422,25 @@ double **p /* Simplex to initialize */
/* etc. */
bb = 1.0; /* Initial unscaled radius */
for (j = 0; j < di; j++) { /* For each coordinate in vertex */
- if (j > i)
- p[i][j] = cp[j] + s[j] * 0.0; /* If beyond last */
- else if (j == i) /* If last non-zero */
- p[i][j] = cp[j] + s[j] * bb;
- else if (i == di && j == (di-1)) /* If last of last */
- p[i][j] = cp[j] + s[j] * -1.0 * bb;
+ if (j > ii)
+ p[i][j] = cp[j] + sv * s[j] * 0.0; /* If beyond last */
+ else if (j == ii) /* If last non-zero */
+ p[i][j] = cp[j] + sv * s[j] * bb;
+ else if (ii == di && j == (di-1)) /* If last of last */
+ p[i][j] = cp[j] + sv * s[j] * -1.0 * bb;
else /* If before last */
- p[i][j] = cp[j] + s[j] * -hh * bb;
+ p[i][j] = cp[j] + sv * s[j] * -hh * bb;
bb *= rr;
}
+ /* Increment coordinate number with wrap around */
+ if (++ii >= (di+1))
+ ii = 0;
+ }
+#ifdef DEBUG
+ if (dhsx_debug) {
+ for (i = 0; i < (di+1); i++)
+ printf(" p[%d] = %s\n",i,debPdv(di,p[i]));
}
+#endif
}