示例#1
0
static void do_variogram(int nvars, METHOD m) {
	int i, j;
	VARIOGRAM *vp = NULL;

	if (nvars == 0)
		return;

	for (i = 0; i < nvars; i++) {
		for (j = i; j >= 0; j--) {
			vp = get_vgm(LTI(i,j)); /* */
			vp->id1 = j;
			vp->id2 = i;
			if (m == COV)
				vp->ev->evt = (i != j) ? CROSSCOVARIOGRAM : COVARIOGRAM;
			else
				vp->ev->evt = (i != j) ? CROSSVARIOGRAM : SEMIVARIOGRAM;
			if (vp->fname != NULL || o_filename != NULL) {
				calc_variogram(vp, vp->fname ? vp->fname : o_filename);
				if (vp->n_models > 0 && gl_fit) {
					vp->ev->fit = fit_int2enum(gl_fit);
					if (fit_variogram(vp))
						pr_warning("error during variogram fit");
					else
						logprint_variogram(vp, 1);
				}
			}
		}
	}

	if (plotfile) {
		if (nvars > 1)
			ErrMsg(ER_IMPOSVAL, "plot file only works for single variable");
		if (vp->ev->map)
			ErrMsg(ER_IMPOSVAL, "cannot make plot file for variogram map");
		if (gl_jgraph)
			fprint_jgraph_variogram(plotfile, vp);
		else 
			fprint_gnuplot_variogram(plotfile, vp, "gnuplot.out", GNUPLOT, 0);
	}
}
示例#2
0
int ossfim(int argc, char *argv[]) {
	int c, n = 25, dx = 9, dy = 9, i, j, plot_vgm = 0;
	double b = 1, B = 10, s = 1, S = 10, blocksize, samplespacing, est[2],
		**table;
	DATA **d = NULL;
	DPOINT *block = NULL, where;
	char *vgm_str = "1Exp(10)", *map_name = NULL;
	VARIOGRAM *vgm;

	while ((c = getopt(argc, argv, "n:m:B:b:S:s:V:v:x:y:")) != EOF) {
		switch (c) {
			case 'n':
				if (read_int(optarg, &n) || n <= 0)
					ErrMsg(ER_ARGOPT, "n");
				break;
			case 'b':
				if (read_double(optarg, &b) || b < 0)
					ErrMsg(ER_ARGOPT, "b");
				break;
			case 'B':
				if (read_double(optarg, &B) || B <= 0)
					ErrMsg(ER_ARGOPT, "B");
				break;
			case 's':
				if (read_double(optarg, &s) || s <= 0)
					ErrMsg(ER_ARGOPT, "s");
				break;
			case 'S':
				if (read_double(optarg, &S) || S <= 0)
					ErrMsg(ER_ARGOPT, "S");
				break;
			case 'x':
				if (read_int(optarg, &dx) || dx <= 0)
					ErrMsg(ER_ARGOPT, "x");
				break;
			case 'y':
				if (read_int(optarg, &dy) || dy <= 0)
					ErrMsg(ER_ARGOPT, "y");
				break;
			case 'v':
				vgm_str = optarg;
				break;
			case 'V':
				plot_vgm = 1;
				vgm_str = optarg;
				break;
			case 'm':
				map_name = optarg;
				break;
			default:
				ErrClo(optopt);
				break;
		}
	}

	which_identifier("dummy grid");
	d = get_gstat_data();
	init_one_data(d[0]);
	d[0]->id = 0;
	d[0]->n_list = d[0]->n_max = 0;
	d[0]->mode = X_BIT_SET | Y_BIT_SET | V_BIT_SET;
	set_norm_fns(d[0]);
	vgm = get_vgm(0);
	if (read_variogram(vgm, vgm_str))
		ErrMsg(ER_SYNTAX, vgm_str);
	vgm->ev->evt = SEMIVARIOGRAM;
	vgm->id1 = vgm->id2 = d[0]->id;
	block = get_block_p();
	block->z = 0.0;
	block->x = block->y = -1.0;
	est[0] = 0.0;
	est[1] = -1.0;
	where.x = where.y = where.z = 0.0;
	where.X = (double *) emalloc(sizeof(double));
	where.X[0] = 1.0;

	if (plot_vgm)
		return fprint_gnuplot_variogram(stdout, vgm, "", GIF, 0);

	table = (double **) emalloc((dy + 1) * sizeof(double *));
	for (i = 0; i <= dy; i++)
		table[i] = (double *) emalloc((dx + 1) * sizeof(double));

	/* do it: */
	for (i = 0; i <= dx; i++) { /* sample spacing loop */
		samplespacing = s + (i / (1.0 * dx)) * (S - s);
		generate_grid(d[0], samplespacing, n);
		select_at(d[0], &where);
		for (j = 0; j <= dy; j++) { /* block sizes loop */
			reset_block_discr();
			vgm_init_block_values(vgm);
			blocksize = b + (j / (1.0 * dy)) * (B - b);
			block->x = block->y = blocksize;
			if (blocksize == 0.0)
				SET_POINT(&where);
			else
				SET_BLOCK(&where);
			gls(d, 1, GLS_BLUP, &where, est);
			if (map_name)
				table[i][j] = sqrt(est[1]);
			else
				printlog("%g %g %g\n", samplespacing, blocksize, sqrt(est[1]));
		}
	}
	if (map_name)
		ossfim2map(table, map_name, s, S, b, B, dx, dy);
	return 0;
}
示例#3
0
文件: gls.c 项目: BenGraeler/gstat 
/*
 * n_vars is the number of variables to be considered,
 * d is the data array of variables d[0],...,d[n_vars-1],
 * pred determines which estimate is required: BLUE, BLUP, or BLP
 */
void gls(DATA **d /* pointer to DATA array */,
         int n_vars, /* length of DATA array (to consider) */
         enum GLS_WHAT pred, /* what type of prediction is requested */
         DPOINT *where, /* prediction location */
         double *est /* output: array that holds the predicted values and variances */)
{
    GLM *glm = NULL; /* to be copied to/from d */
    static MAT *X0 = MNULL, *C0 = MNULL, *MSPE = MNULL, *CinvC0 = MNULL,
                *Tmp1 = MNULL, *Tmp2 = MNULL, *Tmp3 = MNULL, *R = MNULL;
    static VEC *blup = VNULL, *tmpa = VNULL, *tmpb = VNULL;
    PERM *piv = PNULL;
    volatile unsigned int i, rows_C;
    unsigned int j, k, l = 0, row, col, start_i, start_j, start_X, global,
                       one_nbh_empty;
    VARIOGRAM *v = NULL;
    static enum GLS_WHAT last_pred = GLS_INIT; /* the initial value */
    double c_value, *X_ori;
    int info;

    if (d == NULL) { /* clean up */
        if (X0 != MNULL) M_FREE(X0);
        if (C0 != MNULL) M_FREE(C0);
        if (MSPE != MNULL) M_FREE(MSPE);
        if (CinvC0 != MNULL) M_FREE(CinvC0);
        if (Tmp1 != MNULL) M_FREE(Tmp1);
        if (Tmp2 != MNULL) M_FREE(Tmp2);
        if (Tmp3 != MNULL) M_FREE(Tmp3);
        if (R != MNULL) M_FREE(R);
        if (blup != VNULL) V_FREE(blup);
        if (tmpa != VNULL) V_FREE(tmpa);
        if (tmpb != VNULL) V_FREE(tmpb);
        last_pred = GLS_INIT;
        return;
    }

    if (DEBUG_COV) {
        printlog("we're at %s X: %g Y: %g Z: %g\n",
                 IS_BLOCK(where) ? "block" : "point",
                 where->x, where->y, where->z);
    }

    if (pred != UPDATE) /* it right away: */
        last_pred = pred;

    assert(last_pred != GLS_INIT);

    if (d[0]->glm == NULL) { /* allocate and initialize: */
        glm = new_glm();
        d[0]->glm = (void *) glm;
    } else
        glm = (GLM *) d[0]->glm;

    glm->mu0 = v_resize(glm->mu0, n_vars);
    MSPE = m_resize(MSPE, n_vars, n_vars);
    if (pred == GLS_BLP || UPDATE_BLP) {
        X_ori = where->X;
        for (i = 0; i < n_vars; i++) { /* mu(0) */
            glm->mu0->ve[i] = calc_mu(d[i], where);
            blup = v_copy(glm->mu0, v_resize(blup, glm->mu0->dim));
            where->X += d[i]->n_X; /* shift to next x0 entry */
        }
        where->X = X_ori; /* ... and set back */
        for (i = 0; i < n_vars; i++) { /* Cij(0,0): */
            for (j = 0; j <= i; j++) {
                v = get_vgm(LTI(d[i]->id,d[j]->id));
                ME(MSPE, i, j) = ME(MSPE, j, i) = COVARIANCE0(v, where, where, d[j]->pp_norm2);
            }
        }
        fill_est(NULL, blup, MSPE, n_vars, est); /* in case of empty neighbourhood */
    }
    /* xxx */
    /*
    logprint_variogram(v, 1);
    */

    /*
     * selection dependent problem dimensions:
     */
    for (i = rows_C = 0, one_nbh_empty = 0; i < n_vars; i++) {
        rows_C += d[i]->n_sel;
        if (d[i]->n_sel == 0)
            one_nbh_empty = 1;
    }

    if (rows_C == 0 /* all selection lists empty */
            || one_nbh_empty == 1) { /* one selection list empty */
        if (pred == GLS_BLP || UPDATE_BLP)
            debug_result(blup, MSPE, pred);
        return;
    }

    for (i = 0, global = 1; i < n_vars && global; i++)
        global = (d[i]->sel == d[i]->list
                  && d[i]->n_list == d[i]->n_original
                  && d[i]->n_list == d[i]->n_sel);

    /*
     * global things: enter whenever (a) first time, (b) local selections or
     * (c) the size of the problem grew since the last call (e.g. simulation)
     */
    if (glm->C == NULL || !global || rows_C > glm->C->m) {
        /*
         * fill y:
         */
        glm->y = get_y(d, glm->y, n_vars);

        if (pred != UPDATE) {
            glm->C = m_resize(glm->C, rows_C, rows_C);
            if (gl_choleski == 0) /* use LDL' decomposition, allocate piv: */
                piv = px_resize(piv, rows_C);
            m_zero(glm->C);
            glm->X = get_X(d, glm->X, n_vars);
            M_DEBUG(glm->X, "X");
            glm->CinvX = m_resize(glm->CinvX, rows_C, glm->X->n);
            glm->XCinvX = m_resize(glm->XCinvX, glm->X->n, glm->X->n);
            glm->beta = v_resize(glm->beta, glm->X->n);
            for (i = start_X = start_i = 0; i < n_vars; i++) { /* row var */
                /* fill C, mu: */
                for (j = start_j = 0; j <= i; j++) { /* col var */
                    v = get_vgm(LTI(d[i]->id,d[j]->id));
                    for (k = 0; k < d[i]->n_sel; k++) { /* rows */
                        row = start_i + k;
                        for (l = 0, col = start_j; col <= row && l < d[j]->n_sel; l++, col++) {
                            if (pred == GLS_BLUP)
                                c_value = GCV(v, d[i]->sel[k], d[j]->sel[l]);
                            else
                                c_value = COVARIANCE(v, d[i]->sel[k], d[j]->sel[l]);
                            /* on the diagonal, if necessary, add measurement error variance */
                            if (d[i]->colnvariance && i == j && k == l)
                                c_value += d[i]->sel[k]->variance;
                            ME(glm->C, col, row) = c_value; /* fill upper */
                            if (col != row)
                                ME(glm->C, row, col) = c_value; /* fill all */
                        } /* for l */
                    } /* for k */
                    start_j += d[j]->n_sel;
                } /* for j */
                start_i += d[i]->n_sel;
                if (d[i]->n_sel > 0)
                    start_X += d[i]->n_X - d[i]->n_merge;
            } /* for i */

            /*
            if (d[0]->colnvmu)
            	glm->C = convert_vmuC(glm->C, d[0]);
            */
            if (d[0]->variance_fn) {
                glm->mu = get_mu(glm->mu, glm->y, d, n_vars);
                convert_C(glm->C, glm->mu, d[0]->variance_fn);
            }

            if (DEBUG_COV && pred == GLS_BLUP)
                printlog("[using generalized covariances: max_val - semivariance()]");
            M_DEBUG(glm->C, "Covariances (x_i, x_j) matrix C (upper triangle)");
            /*
             * factorize C:
             */
            CHfactor(glm->C, piv, &info);
            if (info != 0) { /* singular: */
                pr_warning("Covariance matrix singular at location [%g,%g,%g]: skipping...",
                           where->x, where->y, where->z);
                m_free(glm->C);
                glm->C = MNULL; /* assure re-entrance if global */
                P_FREE(piv);
                return;
            }
            if (piv == NULL)
                M_DEBUG(glm->C, "glm->C, Choleski decomposed:")
                else
                    M_DEBUG(glm->C, "glm->C, LDL' decomposed:")
                } /* if (pred != UPDATE) */
示例#4
0
/*
 * n_vars is the number of variables to be considered,
 * d is the data array of variables d[0],...,d[n_vars-1],
 * pred determines which estimate is required: BLUE, BLUP, or BLP
 */
void gls(DATA **d /* pointer to DATA array */,
		int n_vars, /* length of DATA array (to consider) */
		enum GLS_WHAT pred, /* what type of prediction is requested */
		DPOINT *where, /* prediction location */
		double *est /* output: array that holds the predicted values and variances */)
{
	GLM *glm = NULL; /* to be copied to/from d */
	static MAT *X0 = MNULL, *C0 = MNULL, *MSPE = MNULL, *CinvC0 = MNULL,
		*Tmp1 = MNULL, *Tmp2 = MNULL, *Tmp3, *R = MNULL;
	static VEC *blup = VNULL, *tmpa = VNULL, *tmpb = VNULL;
	volatile unsigned int i, rows_C;
	unsigned int j, k, l = 0, row, col, start_i, start_j, start_X, global;
	VARIOGRAM *v = NULL;
	static enum GLS_WHAT last_pred = GLS_INIT; /* the initial value */
	double c_value, *X_ori;

	if (d == NULL) { /* clean up */
		if (X0 != MNULL) M_FREE(X0); 
		if (C0 != MNULL) M_FREE(C0);
		if (MSPE != MNULL) M_FREE(MSPE);
		if (CinvC0 != MNULL) M_FREE(CinvC0);
		if (Tmp1 != MNULL) M_FREE(Tmp1);
		if (Tmp2 != MNULL) M_FREE(Tmp2);
		if (Tmp3 != MNULL) M_FREE(Tmp3);
		if (R != MNULL) M_FREE(R);
		if (blup != VNULL) V_FREE(blup);
		if (tmpa != VNULL) V_FREE(tmpa);
		if (tmpb != VNULL) V_FREE(tmpb);
		last_pred = GLS_INIT;
		return;
	}
#ifndef HAVE_SPARSE
	if (gl_sparse) {
		pr_warning("sparse matrices not supported: compile with --with-sparse");
		gl_sparse = 0;
	}
#endif

	if (DEBUG_COV) {
		printlog("we're at %s X: %g Y: %g Z: %g\n",
			IS_BLOCK(where) ? "block" : "point",
			where->x, where->y, where->z);
	}

	if (pred != UPDATE) /* it right away: */
		last_pred = pred;

	assert(last_pred != GLS_INIT);

	if (d[0]->glm == NULL) { /* allocate and initialize: */
		glm = new_glm();
		d[0]->glm = (void *) glm;
	} else
		glm = (GLM *) d[0]->glm;

	glm->mu0 = v_resize(glm->mu0, n_vars);
	MSPE = m_resize(MSPE, n_vars, n_vars);
	if (pred == GLS_BLP || UPDATE_BLP) {
		X_ori = where->X;
		for (i = 0; i < n_vars; i++) { /* mu(0) */
			glm->mu0->ve[i] = calc_mu(d[i], where);
			blup = v_copy(glm->mu0, v_resize(blup, glm->mu0->dim));
			where->X += d[i]->n_X; /* shift to next x0 entry */
		}
		where->X = X_ori; /* ... and set back */
		for (i = 0; i < n_vars; i++) { /* Cij(0,0): */
			for (j = 0; j <= i; j++) {
				v = get_vgm(LTI(d[i]->id,d[j]->id));
				MSPE->me[i][j] = MSPE->me[j][i] = COVARIANCE0(v, where, where, d[j]->pp_norm2);
			}
		}
		fill_est(NULL, blup, MSPE, n_vars, est); /* in case of empty neighbourhood */
	}
	/* xxx */
	/*
	logprint_variogram(v, 1);
	*/

/* 
 * selection dependent problem dimensions: 
 */
	for (i = rows_C = 0; i < n_vars; i++)
		rows_C += d[i]->n_sel;

	if (rows_C == 0) { /* empty selection list(s) */
		if (pred == GLS_BLP || UPDATE_BLP)
			debug_result(blup, MSPE, pred);
		return;
	}

	for (i = 0, global = 1; i < n_vars && global; i++)
		global = (d[i]->sel == d[i]->list && d[i]->n_list == d[i]->n_original);

/*
 * global things: enter whenever (a) first time, (b) local selections or
 * (c) the size of the problem grew since the last call (e.g. simulation)
 */
	if ((glm->C == NULL && glm->spC == NULL) || !global || rows_C > glm->C->m) {
/* 
 * fill y: 
 */
		glm->y = get_y(d, glm->y, n_vars);

		if (pred != UPDATE) {
			if (! gl_sparse) {
				glm->C = m_resize(glm->C, rows_C, rows_C);
				m_zero(glm->C);
			} 
#ifdef HAVE_SPARSE
			else {
				if (glm->C == NULL) {
					glm->spC = sp_get(rows_C, rows_C, gl_sparse);
					/* d->spLLT = spLLT = sp_get(rows_C, rows_C, gl_sparse); */
				} else {
					glm->spC = sp_resize(glm->spC, rows_C, rows_C);
					/* d->spLLT = spLLT = sp_resize(spLLT, rows_C, rows_C); */
				}
				sp_zero(glm->spC);
			} 
#endif
			glm->X = get_X(d, glm->X, n_vars);
			M_DEBUG(glm->X, "X");
			glm->CinvX = m_resize(glm->CinvX, rows_C, glm->X->n);
			glm->XCinvX = m_resize(glm->XCinvX, glm->X->n, glm->X->n);
			glm->beta = v_resize(glm->beta, glm->X->n);
			for (i = start_X = start_i = 0; i < n_vars; i++) { /* row var */
				/* fill C, mu: */
				for (j = start_j = 0; j <= i; j++) { /* col var */
					v = get_vgm(LTI(d[i]->id,d[j]->id));
					for (k = 0; k < d[i]->n_sel; k++) { /* rows */
						row = start_i + k;
						for (l = 0, col = start_j; col <= row && l < d[j]->n_sel; l++, col++) {
							if (pred == GLS_BLUP)
								c_value = GCV(v, d[i]->sel[k], d[j]->sel[l]);
							else
								c_value = COVARIANCE(v, d[i]->sel[k], d[j]->sel[l]);
							/* on the diagonal, if necessary, add measurement error variance */
							if (d[i]->colnvariance && i == j && k == l)
								c_value += d[i]->sel[k]->variance;
							if (! gl_sparse)
								glm->C->me[row][col] = c_value;
#ifdef HAVE_SPARSE
							else {
								if (c_value != 0.0)
									sp_set_val(glm->spC, row, col, c_value);
							} 
#endif
						} /* for l */
					} /* for k */
					start_j += d[j]->n_sel;
				} /* for j */
				start_i += d[i]->n_sel;
				if (d[i]->n_sel > 0)
					start_X += d[i]->n_X - d[i]->n_merge;
			} /* for i */

			/*
			if (d[0]->colnvmu)
				glm->C = convert_vmuC(glm->C, d[0]);
			*/
			if (d[0]->variance_fn) {
				glm->mu = get_mu(glm->mu, glm->y, d, n_vars);
				convert_C(glm->C, glm->mu, d[0]->variance_fn);
			}

			if (DEBUG_COV && pred == GLS_BLUP)
				printlog("[using generalized covariances: max_val - semivariance()]");
			if (! gl_sparse) {
				M_DEBUG(glm->C, "Covariances (x_i, x_j) matrix C (lower triangle only)");
			}
#ifdef HAVE_SPARSE
			else {
				SM_DEBUG(glm->spC, "Covariances (x_i, x_j) sparse matrix C (lower triangle only)")
			}
#endif
/* check for singular C: */
			if (! gl_sparse && gl_cn_max > 0.0) {
				for (i = 0; i < rows_C; i++) /* row */ 
					for (j = i+1; j < rows_C; j++) /* col > row */
						glm->C->me[i][j] = glm->C->me[j][i]; /* fill symmetric */
				if (is_singular(glm->C, gl_cn_max)) {
					pr_warning("Covariance matrix (nearly) singular at location [%g,%g,%g]: skipping...",
						where->x, where->y, where->z);
					m_free(glm->C); glm->C = MNULL; /* assure re-entrance if global */
					return;
				}
			}
/* 
 * factorize C: 
 */
			if (! gl_sparse)
				LDLfactor(glm->C);
#ifdef HAVE_SPARSE
			else {
				sp_compact(glm->spC, 0.0);
				spCHfactor(glm->spC);
			}
#endif
		} /* if (pred != UPDATE) */
		if (pred != GLS_BLP && !UPDATE_BLP) { /* C-1 X and X'C-1 X, beta */
/* 
 * calculate CinvX: 
 */
    		tmpa = v_resize(tmpa, rows_C);
    		for (i = 0; i < glm->X->n; i++) {
				tmpa = get_col(glm->X, i, tmpa);
				if (! gl_sparse)
					tmpb = LDLsolve(glm->C, tmpa, tmpb);
#ifdef HAVE_SPARSE
				else
					tmpb = spCHsolve(glm->spC, tmpa, tmpb);
#endif
				set_col(glm->CinvX, i, tmpb);
			}
/* 
 * calculate X'C-1 X: 
 */
			glm->XCinvX = mtrm_mlt(glm->X, glm->CinvX, glm->XCinvX); /* X'C-1 X */
			M_DEBUG(glm->XCinvX, "X'C-1 X");
			if (gl_cn_max > 0.0 && is_singular(glm->XCinvX, gl_cn_max)) {
				pr_warning("X'C-1 X matrix (nearly) singular at location [%g,%g,%g]: skipping...",
					where->x, where->y, where->z);
				m_free(glm->C); glm->C = MNULL; /* assure re-entrance if global */
				return;
			}
			m_inverse(glm->XCinvX, glm->XCinvX);
/* 
 * calculate beta: 
 */
			tmpa = vm_mlt(glm->CinvX, glm->y, tmpa); /* X'C-1 y */
			glm->beta = vm_mlt(glm->XCinvX, tmpa, glm->beta); /* (X'C-1 X)-1 X'C-1 y */
			V_DEBUG(glm->beta, "beta");
			M_DEBUG(glm->XCinvX, "Cov(beta), (X'C-1 X)-1");
			M_DEBUG(R = get_corr_mat(glm->XCinvX, R), "Corr(beta)");
		} /* if pred != GLS_BLP */
	} /* if redo the heavy part */