/* Write a single record of a keydata/keyinfo key set. */
static krb5_error_code
keyinfo_rec(struct rec_args *args, const char *name, int i, krb5_key_data *kd,
int dumpkeys)
{
int ret;
krb5_data data;
struct rechandle *h = args->rh;
if (startrec(h) < 0)
return errno;
if (writefield(h, "%s", name) < 0)
return errno;
if (writefield(h, "%d", i) < 0)
return errno;
if (writefield(h, "%d", kd->key_data_kvno) < 0)
return errno;
if (write_enctype(args, kd->key_data_type[0]) < 0)
return errno;
if (dumpkeys) {
data.length = kd->key_data_length[0];
data.data = (void *)kd->key_data_contents[0];
if (write_data(args, &data) < 0)
return errno;
}
ret = write_salttype(args, kd->key_data_type[1]);
if (ret)
return ret;
data.length = kd->key_data_length[1];
data.data = (void *)kd->key_data_contents[1];
if (write_data(args, &data) < 0)
return errno;
if (endrec(h) < 0)
return errno;
return 0;
}
/* Write a record corresponding to a single principal flag setting. */
static krb5_error_code
princflag_rec(struct rechandle *h, const char *name, const char *flagname,
int set)
{
if (startrec(h) < 0)
return errno;
if (writefield(h, "%s", name) < 0)
return errno;
if (writefield(h, "%s", flagname) < 0)
return errno;
if (writefield(h, "%d", set) < 0)
return errno;
if (endrec(h) < 0)
return errno;
return 0;
}
/*
* Write a header line if h->rectype is null. (If rectype is set, it will be
* prefixed to output lines, most likely in a mixed record type output file, so
* it doesn't make sense to output a header line in that case.)
*/
int
writeheader(struct rechandle *h, char * const *a)
{
int ret = 0;
char * const *p;
if (h->rectype != NULL)
return 0;
for (p = a; *p != NULL; p++) {
ret = writefield(h, "%s", *p);
if (ret < 0)
return ret;
}
ret = endrec(h);
return ret;
}
/* Write a principal's lockout data. */
static krb5_error_code
princ_lockout(struct rec_args *args, const char *name, krb5_db_entry *dbe)
{
struct rechandle *h = args->rh;
if (startrec(h) < 0)
return errno;
if (writefield(h, "%s", name) < 0)
return errno;
if (write_date(args, dbe->last_success) < 0)
return errno;
if (write_date(args, dbe->last_failed) < 0)
return errno;
if (writefield(h, "%d", dbe->fail_auth_count) < 0)
return errno;
if (endrec(h) < 0)
return errno;
return 0;
}
/* Write a principal's ticket policy. */
static krb5_error_code
princ_tktpolicy(struct rec_args *args, const char *name, krb5_db_entry *dbe)
{
struct rechandle *h = args->rh;
if (startrec(h) < 0)
return errno;
if (writefield(h, "%s", name) < 0)
return errno;
if (write_date(args, dbe->expiration) < 0)
return errno;
if (write_date(args, dbe->pw_expiration) < 0)
return errno;
if (writefield(h, "%d", dbe->max_life) < 0)
return errno;
if (writefield(h, "%d", dbe->max_renewable_life) < 0)
return errno;
if (endrec(h) < 0)
return errno;
return 0;
}
/* Write a principal's string attributes. */
static krb5_error_code
princ_stringattrs(struct rec_args *args, const char *name, krb5_db_entry *dbe)
{
int i, nattrs;
krb5_error_code ret;
krb5_string_attr *attrs;
struct rechandle *h = args->rh;
ret = krb5_dbe_get_strings(util_context, dbe, &attrs, &nattrs);
if (ret)
return ret;
for (i = 0; i < nattrs; i++) {
if (startrec(h) < 0) {
ret = errno;
goto cleanup;
}
if (writefield(h, "%s", name) < 0) {
ret = errno;
goto cleanup;
}
if (writefield(h, "%s", attrs[i].key) < 0) {
ret = errno;
goto cleanup;
}
if (writefield(h, "%s", attrs[i].value) < 0) {
ret = errno;
goto cleanup;
}
if (endrec(h) < 0) {
ret = errno;
goto cleanup;
}
}
cleanup:
krb5_dbe_free_strings(util_context, attrs, nattrs);
return ret;
}
/* Write a principal's metadata. */
static krb5_error_code
princ_meta(struct rec_args *args, const char *name, krb5_db_entry *dbe)
{
int got_adb = 0;
char *modby;
krb5_kvno mkvno;
const char *policy;
krb5_principal mod_princ = NULL;
krb5_timestamp mod_time, last_pwd;
krb5_error_code ret;
osa_princ_ent_rec adb;
struct rechandle *h = args->rh;
memset(&adb, 0, sizeof(adb));
if (startrec(h) < 0)
return errno;
if (writefield(h, "%s", name) < 0)
return errno;
ret = krb5_dbe_lookup_last_pwd_change(util_context, dbe, &last_pwd);
if (ret)
return ret;
ret = krb5_dbe_get_mkvno(util_context, dbe, &mkvno);
if (ret)
return ret;
ret = krb5_dbe_lookup_mod_princ_data(util_context, dbe, &mod_time,
&mod_princ);
if (ret)
return ret;
ret = krb5_unparse_name(util_context, mod_princ, &modby);
krb5_free_principal(util_context, mod_princ);
if (ret)
return ret;
ret = writefield(h, "%s", modby);
krb5_free_unparsed_name(util_context, modby);
if (ret < 0)
return errno;
if (write_date(args, mod_time) < 0)
return errno;
if (write_date(args, last_pwd) < 0)
return errno;
got_adb = get_adb(dbe, &adb);
if (got_adb && adb.policy != NULL)
policy = adb.policy;
else
policy = "";
ret = writefield(h, "%s", policy);
if (ret < 0) {
ret = errno;
goto cleanup;
}
if (writefield(h, "%d", mkvno) < 0) {
ret = errno;
goto cleanup;
}
if (writefield(h, "%d", adb.admin_history_kvno) < 0) {
ret = errno;
goto cleanup;
}
if (endrec(h) < 0)
ret = errno;
else
ret = 0;
cleanup:
kdb_free_entry(NULL, NULL, &adb);
return ret;
}
int main (int argc, char *argv[]) {
/*******/
/* i/o */
/*******/
FILE *fpimg, *fpout;
IFH ifh;
struct dsr hdr; /* ANALYZE hdr */
char imgroot[MAXL], imgfile[MAXL], outfile[MAXL];
char trailer[8] = ".4dint";
/****************/
/* image arrays */
/****************/
float *imgf, cscale = 1.0;
short int *imgi=NULL;
unsigned char *imgu=NULL;
float voxsiz[3];
int imgdim[4], vdim, orient, isbig;
int imin = 32767, imax = -32768;
char control = '\0';
short int origin[3]; /* used in SPM99 conversions */
/***********/
/* utility */
/***********/
int c, i, j, k;
char *str, command[MAXL], program[MAXL];
/*********/
/* flags */
/*********/
int uchar = 0;
int debug = 0;
int spm99 = 0;
int swab_flag = 0;
fprintf (stdout, "%s\n", rcsid);
setprog (program, argv);
/************************/
/* process command line */
/************************/
for (k = 0, i = 1; i < argc; i++) {
if (*argv[i] == '-') {
strcpy (command, argv[i]); str = command;
while ((c = *str++)) switch (c) {
case '8': uchar++; strcpy (trailer, "_8bit"); break;
case 'd': debug++; break;
case 'c': cscale = atof (str); *str = '\0'; break;
case 'S': if (!strcmp (str, "PM99")) spm99++; *str = '\0'; break;
case '@': control = *str++; *str = '\0'; break;
}
} else switch (k) {
case 0: getroot (argv[i], imgroot); k++; break;
}
}
if (k < 1) {
printf ("Usage:\t%s <(4dfp) filename>\n", program);
printf ("\toption\n");
printf ("\t-c<flt>\tscale output values by specified factor\n");
printf ("\t-8\toutput 8 bit unsigned char\n");
printf ("\t-SPM99\tinclude origin and scale in hdr (http:/wideman-one.com/gw/brain/analyze/format.doc)\n");
printf ("\t-@<b|l>\toutput big or little endian (default CPU endian)\n");
exit (1);
}
/*****************************/
/* get input 4dfp dimensions */
/*****************************/
if (get_4dfp_dimoe (imgroot, imgdim, voxsiz, &orient, &isbig)) errr (program, imgroot);
vdim = imgdim[0] * imgdim[1] * imgdim[2];
if (uchar) {
if (!(imgu = (unsigned char *) malloc (vdim * sizeof (char)))) errm (program);
} else {
if (!(imgi = (short *) malloc (vdim * sizeof (short)))) errm (program);
}
if (!(imgf = (float *) malloc (vdim * sizeof (float)))) errm (program);
/*************************/
/* open input and output */
/*************************/
sprintf (imgfile, "%s.4dfp.img", imgroot);
printf ("Reading: %s\n", imgfile);
if (!(fpimg = fopen (imgfile, "rb"))) errr (program, imgfile);
sprintf (outfile, "%s%s.img", imgroot, trailer);
if (!(fpout = fopen (outfile, "wb"))) errw (program, outfile);
printf ("Writing: %s\n", outfile);
/**********************/
/* process all frames */
/**********************/
for (k = 0; k < imgdim[3]; k++) {
if (eread (imgf, vdim, isbig, fpimg)) errr (program, imgfile);
switch (orient) {
case 4: flipx (imgf, imgdim + 0, imgdim + 1, imgdim + 2); /* sagittal */
case 3: flipz (imgf, imgdim + 0, imgdim + 1, imgdim + 2); /* coronal */
case 2: flipy (imgf, imgdim + 0, imgdim + 1, imgdim + 2); /* transverse */
break;
default:
fprintf (stderr, "%s: %s image orientation not recognized\n", program, imgfile);
exit (-1);
break;
}
for (i = 0; i < vdim; i++) {
j = nint (cscale*imgf[i]);
if (debug) printf ("%10.6f%10d\n", imgf[i], j);
if (uchar) {
if (j < 0) j = 0;
if (j > 255) j = 255;
imgu[i] = j;
} else {
imgi[i] = j;
}
if (j > imax) imax = j;
if (j < imin) imin = j;
}
if (uchar) {
if (fwrite ( imgu, sizeof (char), vdim, fpout) != vdim) errw (program, outfile);
} else {
if (gwrite ((char *) imgi, sizeof (short), vdim, fpout, control)) errw (program, outfile);
}
}
fclose (fpimg);
fclose (fpout);
/**************************/
/* create ANALYZE 7.5 hdr */
/**************************/
Inithdr (&hdr, imgdim, voxsiz, "");
if (uchar) {
hdr.dime.datatype = 2; /* unsigned char */
hdr.dime.bitpix = 8;
} else {
hdr.dime.datatype = 4; /* signed integer */
hdr.dime.bitpix = 16;
}
hdr.dime.glmax = imax;
hdr.dime.glmin = imin;
hdr.hist.orient = orient - 2;
swab_flag = ((CPU_is_bigendian() != 0) && (control == 'l' || control == 'L'))
|| ((CPU_is_bigendian() == 0) && (control == 'b' || control == 'B'));
if (spm99) {
if (Getifh (imgroot, &ifh)) errr (program, imgroot);
for (i = 0; i < 3; i++) origin[i] = 0.4999 + ifh.center[i]/ifh.mmppix[i];
/*************************************************/
/* flip 4dfp->analyze assuming transverse orient */
/*************************************************/
origin[1] = imgdim[1] + 1 - origin[1];
/*******************************************************************/
/* origin field officially text and so not affected by swab_hdr () */
/*******************************************************************/
if (swab_flag) for (i = 0; i < 3; i++) swab2 ((char *) (origin + i));
memcpy ((char *) &hdr + 253, (char *) origin, 3*sizeof (short int));
memcpy ((char *) &hdr + 112, (char *) &cscale, sizeof (float));
hdr.hk.extents = 0;
}
if (swab_flag) swab_hdr (&hdr);
sprintf (outfile, "%s%s.hdr", imgroot, trailer);
printf ("Writing: %s\n", outfile);
if (!(fpout = fopen (outfile, "wb")) || fwrite (&hdr, sizeof (struct dsr), 1, fpout) != 1
|| fclose (fpout)) errw (program, outfile);
/*******************/
/* create rec file */
/*******************/
sprintf (outfile, "%s%s.img", imgroot, trailer);
startrece (outfile, argc, argv, rcsid, control);
sprintf (command, "Voxel values scaled by %f\n", cscale); printrec (command);
catrec (imgfile);
endrec ();
free (imgf);
if (uchar) {
free (imgu);
} else {
free (imgi);
}
exit (0);
}
int main (int argc, char *argv[]) {
FILE *imgfp; /* input file */
FILE *outfp; /* output file */
/*************/
/* image i/o */
/*************/
char *ptr, string[MAXL], program[MAXL], command[MAXL];
char imgroot[MAXL], imgfile[MAXL], ifhfile[MAXL];
char mskroot[MAXL], mskfile[MAXL];
char tmproot[MAXL], tmpfile[MAXL];
char trailer[MAXL] = "", outroot[MAXL], outfile[MAXL], recfile[MAXL];
/***************/
/* computation */
/***************/
float *imgv, *imgr, *imgm;
float v, frac, t, del2v, dmin;
float fndex[3], x[3], w[3], dvdx[3], d2vdx2[3];
float ctneg = 0.0, ctpos = 0.0;
float vtneg = 0.0, vtpos = 0.0;
float srad = 0.0, orad = 0;
int ix, iy, iz, dim, nx, ny, nz;
int c, i, j, k, l, jmin;
int isbig, isbigm;
char control = '\0';
/**************/
/* peak lists */
/**************/
EXTREMUM *ppos, *pneg, *pall, *pallN, ptmp[1];
int mpos = 0, mneg = 0, npos = 0, nneg = 0, nall, nallN, Nvoxcrit = 1;
int npos0, npos1, npos2;
int nneg0, nneg1, nneg2;
/*********/
/* flags */
/*********/
int mask = 0;
int status = 0;
int debug = 0;
int quiet = 0;
int forceblur = 0;
printf ("%s\n", rcsid);
if (!(ptr = strrchr (argv[0], '/'))) ptr = argv[0]; else ptr++;
strcpy (program, ptr);
/******************************/
/* get command line arguments */
/******************************/
for (k = 0, i = 1; i < argc; i++) {
if (*argv[i] == '-') {
strcpy (command, argv[i]); ptr = command;
while (c = *ptr++) switch (c) {
case 'q': quiet++; break;
case 'F': forceblur++; break;
case 's': srad = atof (ptr); *ptr = '\0'; break;
case 'd': dthresh = atof (ptr); *ptr = '\0'; break;
case 'n': ntop = atoi (ptr); *ptr = '\0'; break;
case 'N': Nvoxcrit = atoi (ptr); *ptr = '\0'; break;
case 'o': orad = atof (ptr); *ptr = '\0'; break;
case '@': control = *ptr++; *ptr = '\0'; break;
case 'c': getrange (ptr, &ctneg, &ctpos); *ptr = '\0'; break;
case 'v': getrange (ptr, &vtneg, &vtpos); *ptr = '\0'; break;
case 'm': getroot (ptr, mskroot); mask++; *ptr = '\0'; break;
case 'a': strncpy (trailer, ptr, MAXL - 1); *ptr = '\0'; break;
}
} else switch (k) {
case 0: getroot (argv[i], imgroot); k++; break;
}
}
if (k < 1) {
printf ("Usage: %s <file_4dfp>\n", program);
printf (" e.g., %s grand_average_222[.4dfp.img] -s10\n", program);
printf ("\toption\n");
printf ("\t-s<flt>\tpreblur with hard sphere kernel of specified radius\n");
printf ("\t-n<int>\tlimit initial pos and neg peak list lengths (default=%d)\n", NTOP);
printf ("\t-c<flt>[to<flt>] specify sign inverted curvature thresholds (default none)\n");
printf ("\t-v<flt>[to<flt>] specify peak value thresholds (default none)\n");
printf ("\t-d<flt>\tconsolidate extremum pairs closer than specified distance\n");
printf ("\t-o<flt>\toutput a fidl compatible 4dfp format ROI file with regions of specified radius\n");
printf ("\t-m<str>\tapply named mask file to output ROIs\n");
printf ("\t-N<int>\tspecify output ROI minimum voxel count (default = 1)\n");
printf ("\t-a<str>\tappend specified string to ROI output filename\n");
printf ("\t-q\tquiet mode (suppress rec file listing)\n");
printf ("\t-F\tforce preblur image creation even if hsphere_4dfp result exists\n");
printf ("\t-@<b|l>\toutput big or little endian (default input endian)\n");
printf ("N.B.:\toperations controlled by options -s, -n, -c, -v, -d, -o, -m, -N are applied serially in listed order\n");
printf ("N.B.:\tall distances are in mm\n");
printf ("N.B.:\toption -s<flt> creates a blurred image by invoking hsphere_4dfp\n");
printf ("N.B.:\toption -F is intended for use in iterative scripts and has no effect absent -s<flt>\n");
exit (1);
}
/************/
/* read ifh */
/************/
sprintf (imgfile, "%s.4dfp.img", imgroot);
if (srad > 0.0) {
sprintf (tmproot, "%s_%.0fmm", imgroot, srad);
} else {
strcpy (tmproot, imgroot);
}
sprintf (tmpfile, "%s.4dfp.img", tmproot);
sprintf (ifhfile, "%s.4dfp.ifh", imgroot);
fprintf (stdout, "Reading: %s\n", ifhfile);
if (Getifh (ifhfile, &imgifh)) errr (program, ifhfile);
isbig = strcmp (imgifh.imagedata_byte_order, "littleendian");
if (!control) control = (isbig) ? 'b' : 'l';
printf ("image dimensions \t%10d%10d%10d%10d\n",
imgifh.matrix_size[0], imgifh.matrix_size[1], imgifh.matrix_size[2], imgifh.matrix_size[3]);
printf ("image mmppix \t%10.6f%10.6f%10.6f\n",
imgifh.mmppix[0], imgifh.mmppix[1], imgifh.mmppix[2]);
printf ("image center \t%10.4f%10.4f%10.4f\n",
imgifh.center[0], imgifh.center[1], imgifh.center[2]);
printf ("image orientation\t%10d\n", imgifh.orientation);
/********************************************************************/
/* check that optionally specified mask is dimensionally consistent */
/********************************************************************/
if (mask) {
sprintf (mskfile, "%s.4dfp.img", mskroot);
sprintf (ifhfile, "%s.4dfp.ifh", mskroot);
fprintf (stdout, "Reading: %s\n", ifhfile);
if (Getifh (ifhfile, &mskifh)) errr (program, ifhfile);
isbigm = strcmp (mskifh.imagedata_byte_order, "littleendian");
status = imgifh.orientation - mskifh.orientation;
for (k = 0; k < 3; k++) {
status |= imgifh.matrix_size[k] - mskifh.matrix_size[k];
status |= (fabs ((double) (imgifh.mmppix[k] - mskifh.mmppix[k])) > 0.0001);
}
if (status) {
fprintf (stderr, "%s: %s %s dimension mismatch\n", program, imgroot, mskroot);
exit (-1);
}
}
dim = 1; for (k = 0; k < 3; k++) dim *= imgifh.matrix_size[k];
if (!(imgv = (float *) malloc (dim * sizeof (float)))) errm (program);
if (!(imgr = (float *) malloc (dim * sizeof (float)))) errm (program);
if (!(imgm = (float *) malloc (dim * sizeof (float)))) errm (program);
nx = imgifh.matrix_size[0];
ny = imgifh.matrix_size[1];
nz = imgifh.matrix_size[2];
/*****************************************/
/* virtual flip instead of x4dfp2ecat () */
/*****************************************/
vrtflip_ (&imgifh.orientation, imgifh.matrix_size, imgifh.center, imgifh.mmppix, centerr, mmppixr);
printf ("atlas mmppix \t%10.6f%10.6f%10.6f\n", mmppixr[0], mmppixr[1], mmppixr[2]);
printf ("atlas center \t%10.4f%10.4f%10.4f\n", centerr[0], centerr[1], centerr[2]);
/****************************************************/
/* read filtered image or create using hpshere_4dfp */
/****************************************************/
if (forceblur || access (tmpfile, R_OK)) {
sprintf (command, "hsphere_4dfp %s %.4f", imgfile, srad);
printf ("%s\n", command);
if (system (command)) errw (program, tmpfile);
}
printf ("Reading: %s\n", tmpfile);
if (!(imgfp = fopen (tmpfile, "rb")) || eread (imgv, dim, isbig, imgfp)
|| fclose (imgfp)) errr (program, tmpfile);
/************************************************************************************************/
/* intial extremum memory allocation (realloc on unassigned pointer => unpredictable core dump) */
/************************************************************************************************/
if (!(ppos = (EXTREMUM *) malloc ((mpos = MSIZE) * sizeof (EXTREMUM)))) errm (program);
if (!(pneg = (EXTREMUM *) malloc ((mneg = MSIZE) * sizeof (EXTREMUM)))) errm (program);
/*******************/
/* compile extrema */
/*******************/
printf ("peak value thresholds %10.4f to %10.4f\n", vtneg, vtpos);
printf ("peak curvature thresholds %10.4f to %10.4f\n", ctneg, ctpos);
printf ("compiling extrema slice");
for (iz = 1; iz < imgifh.matrix_size[2] - 1; iz++) {printf (" %d", iz + 1); fflush (stdout);
for (iy = 1; iy < imgifh.matrix_size[1] - 1; iy++) {
for (ix = 1; ix < imgifh.matrix_size[0] - 1; ix++) {
i = ix + nx*(iy + ny*iz);
dvdx[0] = 0.5*(-imgv[i - 1] + imgv[i + 1]);
dvdx[1] = 0.5*(-imgv[i - nx] + imgv[i + nx]);
dvdx[2] = 0.5*(-imgv[i - nx*ny] + imgv[i + nx*ny]);
d2vdx2[0] = -2.0*imgv[i] + imgv[i - 1] + imgv[i + 1];
d2vdx2[1] = -2.0*imgv[i] + imgv[i - nx] + imgv[i + nx];
d2vdx2[2] = -2.0*imgv[i] + imgv[i - nx*ny] + imgv[i + nx*ny];
for (k = 0; k < 3; k++) w[k] = -dvdx[k] / d2vdx2[k];
for (del2v = k = 0; k < 3; k++) del2v += d2vdx2[k] / (mmppixr[k] * mmppixr[k]);
fndex[0] = (float) (ix + 1) + w[0];
fndex[1] = (float) (iy + 1) + w[1];
fndex[2] = (float) (iz + 1) + w[2];
for (k = 0; k < 3; k++) x[k] = fndex[k] * mmppixr[k] - centerr[k];
if (imgv[i] > 0.0
&& del2v <= -ctpos
&& imgv[i] > imgv[i - 1] && imgv[i] > imgv[i + 1]
&& imgv[i] > imgv[i - nx] && imgv[i] > imgv[i + nx]
&& imgv[i] > imgv[i - nx*ny] && imgv[i] > imgv[i + nx*ny]) {
imgvalx_ (imgv, &nx, &ny, &nz, centerr, mmppixr, x, &t, &l);
if (l < 1) {printf ("undefined imgvalx point\n"); continue;}
if (t < vtpos) continue;
if (mpos <= npos) {
mpos += MSIZE;
if (!(ppos = (EXTREMUM *) realloc (ppos, mpos * sizeof (EXTREMUM)))) errm (program);
}
for (k = 0; k < 3; k++) ppos[npos].x[k] = x[k];
ppos[npos].v = t;
ppos[npos].del2v = del2v;
ppos[npos].weight = 1.0;
ppos[npos].nvox = ppos[npos].killed = 0;
npos++;
}
if (imgv[i] < 0.0
&& del2v >= -ctneg
&& imgv[i] < imgv[i - 1] && imgv[i] < imgv[i + 1]
&& imgv[i] < imgv[i - nx] && imgv[i] < imgv[i + nx]
&& imgv[i] < imgv[i - nx*ny] && imgv[i] < imgv[i + nx*ny]) {
imgvalx_ (imgv, &nx, &ny, &nz, centerr, mmppixr, x, &t, &l);
if (l < 1) {printf ("undefined imgvalx point\n"); continue;}
if (t > vtneg) continue;
if (mneg <= nneg) {
mneg += MSIZE;
if (!(pneg = (EXTREMUM *) realloc (pneg, mneg * sizeof (EXTREMUM)))) errm (program);
}
for (k = 0; k < 3; k++) pneg[nneg].x[k] = x[k];
pneg[nneg].v = t;
pneg[nneg].del2v = del2v;
pneg[nneg].weight = 1.0;
pneg[nneg].nvox = pneg[nneg].killed = 0;
nneg++;
}
}}}
printf ("\n"); fflush (stdout);
printf ("before sorting npos=%d nneg=%d\n", npos, nneg); npos0 = npos; nneg0 = nneg;
qsort ((void *) ppos, npos, sizeof (EXTREMUM), pcompare);
qsort ((void *) pneg, nneg, sizeof (EXTREMUM), pcompare);
printf ("positive peaks\n");
ntot = 0;
peaklist (stdout, ppos, npos, 0); npos1 = ntot;
if (dthresh > 0.0) consolidate (ppos, npos);
printf ("negative peaks\n");
ntot = 0;
peaklist (stdout, pneg, nneg, 0); nneg1 = ntot;
if (dthresh > 0.0) consolidate (pneg, nneg);
printf ("final peak list\n");
ntot = 0;
peaklist (stdout, ppos, npos, 0);
peaklist (stdout, pneg, nneg, 0);
/********************************************/
/* combine positive and negative peak lists */
/********************************************/
if (!(pall = (EXTREMUM *) malloc (ntot * sizeof (EXTREMUM)))) errm (program);
nall = 0;
for (npos2 = i = 0; i < ntop && i < npos; i++) if (!ppos[i].killed) {pall[nall++] = ppos[i]; npos2++;}
for (nneg2 = i = 0; i < ntop && i < nneg; i++) if (!pneg[i].killed) {pall[nall++] = pneg[i]; nneg2++;}
assert (ntot == nall);
free (ppos); free (pneg);
if (orad == 0.0) goto DONE;
/***************************/
/* create output ROI image */
/***************************/
printf ("Reading: %s\n", imgfile);
if (!(imgfp = fopen (imgfile, "rb")) || eread (imgv, dim, isbig, imgfp)
|| fclose (imgfp)) errr (program, imgfile);
if (mask) {
printf ("Reading: %s\n", mskfile);
if (!(imgfp = fopen (mskfile, "rb")) || eread (imgm, dim, isbigm, imgfp)
|| fclose (imgfp)) errr (program, mskfile);
}
/****************************/
/* count voxels in each ROI */
/****************************/
for (iz = 0; iz < imgifh.matrix_size[2]; iz++) {
for (iy = 0; iy < imgifh.matrix_size[1]; iy++) {
for (ix = 0; ix < imgifh.matrix_size[0]; ix++) {
i = ix + nx*(iy + ny*iz);
fndex[0] = (float) (ix + 1);
fndex[1] = (float) (iy + 1);
fndex[2] = (float) (iz + 1);
for (k = 0; k < 3; k++) ptmp[0].x[k] = fndex[k]*mmppixr[k] - centerr[k];
dmin = 1.e6;
for (j = 0; j < nall; j++) {
t = (float) pdist (ptmp, pall + j);
if (t < dmin) {
jmin = j;
dmin = t;
}
}
k = !mask || (fabs (imgm[i]) > 1.e-37);
if (k && (dmin < orad)) pall[jmin].nvox++;
}}}
/*******************************/
/* apply voxel count criterion */
/*******************************/
for (i = 0; i < ntot; i++) if (pall[i].nvox < Nvoxcrit) pall[i].killed = 1;
if (!(pallN = (EXTREMUM *) malloc (ntot * sizeof (EXTREMUM)))) errm (program);
for (nallN = i = 0; i < ntot; i++) if (!pall[i].killed) pallN[nallN++] = pall[i];
free (pall);
printf ("creating ROI slice");
for (iz = 0; iz < imgifh.matrix_size[2]; iz++) {printf (" %d", iz + 1); fflush (stdout);
for (iy = 0; iy < imgifh.matrix_size[1]; iy++) {
for (ix = 0; ix < imgifh.matrix_size[0]; ix++) {
i = ix + nx*(iy + ny*iz);
imgr[i] = 0.0;
fndex[0] = (float) (ix + 1);
fndex[1] = (float) (iy + 1);
fndex[2] = (float) (iz + 1);
for (k = 0; k < 3; k++) ptmp[0].x[k] = fndex[k]*mmppixr[k] - centerr[k];
dmin = 1.e6;
for (j = 0; j < nallN; j++) {
t = (float) pdist (ptmp, pallN + j);
if (t < dmin) {
jmin = j;
dmin = t;
}
}
k = !mask || (fabs (imgm[i]) > 1.e-37);
if (k && (dmin < orad)) imgr[i] = jmin + 2;
}}}
printf ("\n"); fflush (stdout);
if (!(ptr = strrchr (imgroot, '/'))) ptr = imgroot; else ptr++;
if (strlen (trailer)) {
sprintf (outroot, "%s_ROI_%s", ptr, trailer);
} else {
sprintf (outroot, "%s_ROI", ptr);
}
sprintf (outfile, "%s.4dfp.img", outroot);
printf ("Writing: %s\n", outfile);
if (!(outfp = fopen (outfile, "wb")) || ewrite (imgr, dim, control, outfp)
|| fclose (outfp)) errw (program, outfile);
/********************************************/
/* output ROI ifh and make analyze hdr file */
/********************************************/
if (Writeifh (program, outfile, &imgifh, control)) errw (program, outroot);
sprintf (outfile, "%s.4dfp.ifh", outroot);
if (!(outfp = fopen (outfile, "a"))) errw (program, outfile);
for (i = 0; i < nallN; i++) {
fprintf (outfp, "region names\t:= %-5droi_%+03d_%+03d_%+03d%10d\n", i,
nint (pallN[i].x[0]), nint (pallN[i].x[1]), nint (pallN[i].x[2]), pallN[i].nvox);
}
fclose (outfp);
/********************/
/* make analyze hdr */
/********************/
sprintf (command, "ifh2hdr %s -r%d", outroot, nallN + 1);
printf ("%s\n", command); status |= system (command);
/******************/
/* output ROI rec */
/******************/
sprintf (outfile, "%s.4dfp.img", outroot);
startrece (outfile, argc, argv, rcsid, control);
sprintf (recfile, "%s.rec", outfile);
if (!(outfp = fopen (recfile, "a"))) errw (program, recfile);
fprintf (outfp, "Peak value thresholds %10.4f to %10.4f\n", vtneg, vtpos);
fprintf (outfp, "Peak curvature thresholds %10.4f to %10.4f\n", ctneg, ctpos);
fprintf (outfp, "Peak counts before sorting pos=%d neg=%d\n", npos0, nneg0);
fprintf (outfp, "Peak counts after sorting pos=%d neg=%d\n", npos1, nneg1);
fprintf (outfp, "Peak counts after %.4f mm threshold consolidation pos=%d neg=%d\n", dthresh, npos2, nneg2);
ntot = 0; peaklist (outfp, pallN, nallN, 1);
free (pallN);
fprintf (outfp, "N.B.: indices count from 1 and include orientation specific 4dfptoanalyze flips\n");
fclose (outfp);
catrec (tmpfile);
if (mask) catrec (mskfile);
endrec ();
sprintf (command, "brec %s -2", recfile); if (!quiet) system (command);
DONE: free (imgv); free (imgr); free (imgm);
exit (status);
}
int main (int argc, char *argv[]) {
FILE *imgfp, *datfp;
char imgroot[MAXL], imgfile[MAXL], gfcfile[MAXL], ifhfile[MAXL];
char outroot[MAXL], outfile[MAXL], datfile[MAXL], volfile[MAXL], recfile[MAXL];
char program[MAXL], string[MAXL], command[MAXL], *ptr;
int isbig;
char control = '\0';
IFH ifh;
UCHAR ix, iy, iz;
XYZN xyzn;
int iv, iv0, jv, imgdim[3];
int ir, jr, nn;
int c, i, j, k, m, n;
double dela, delg, u1;
float vmin, vmax, fwhm = 0., alpha = ALPHA, *img_orig=NULL;
float maxfac = 0.0;
/**************/
/* gain field */
/**************/
int norder = NORDER, nterm = NTERM;
int niter = 0, limiter = LIMITER;
int eight = 8; /* field length for call to powstring_ () */
float a[NTERM], /* polynomial coefficients */
a0[NTERM];
float drms, diffcrit = DIFFCRIT;
float u1gfc[MAXR];
double sum0, sum, q, t;
/*********/
/* flags */
/*********/
int test = 0;
int status = 0;
int debug = 0;
int gfreeze = 0;
int verbose = 0;
int negdef = 0;
if (!(ptr = strrchr (argv[0], '/'))) ptr = argv[0]; else ptr++;
strcpy (program, ptr);
/************************/
/* process command line */
/************************/
for (k = 0, i = 1; i < argc; i++) if (*argv[i] == '-') {
strcpy (string, argv[i]); ptr = string;
while (c = *ptr++) switch (c) {
case 'v': verbose++; break;
case 'n': negdef++; break;
case 'g': gfreeze++; break;
case '@': control = *ptr++; *ptr = '\0'; break;
case 'b': g_bandwidth = atof (ptr); *ptr = '\0'; break;
case 'p': fwhm = atof (ptr); *ptr = '\0'; break;
case 'e': diffcrit = atof (ptr); *ptr = '\0'; break;
case 'i': g_sigma = atof (ptr); *ptr = '\0'; break;
case 'l': limiter = atoi (ptr); *ptr = '\0'; break;
case 'm': g_mr = atoi (ptr); *ptr = '\0'; break;
case 's': g_sconst = atof (ptr); *ptr = '\0'; break;
case 'z': g_zthresh = atof (ptr); *ptr = '\0'; break;
case 'M': maxfac = atof (ptr); *ptr = '\0'; break;
case 'r': getrange (ptr, &g_gfc_thresh, &g_gfc_ceil); *ptr = '\0'; break;
}
} else switch (k) {
case 0: getroot (argv[i], imgroot); k++; break;
}
if (k < 1) {
fprintf (stderr, "Usage:\t%s <imgroot>\n", program);
fprintf (stderr, " e.g.,\t%s vc1440_mpr_n4_111_t88.4dfp\n", program); /*??*/
fprintf (stderr, "\toption\n");
fprintf (stderr, "\t-g freeze initial gain field\n");
fprintf (stderr, "\t-n force negative definite quadratic gain field\n");
fprintf (stderr, "\t-v verbose mode\n");
fprintf (stderr, "\t-p<flt> pre-blur by specified FWHM in mm\n");
fprintf (stderr, "\t-b<flt>\tspecify bandwidth in intensity units (default=%.1f)\n", BANDWIDTH);
fprintf (stderr, "\t-e<flt>\tspecify drms convergence criterion (default=%f)\n", DIFFCRIT);
fprintf (stderr, "\t-i<flt>\tspecify sigma (default=%f)\n", SIGMA);
fprintf (stderr, "\t-l<int>\tspecify iteration limit (default=%d)\n", LIMITER);
fprintf (stderr, "\t-m<flt>\tspecify gfc computation region count (default=%d)\n", MR);
fprintf (stderr, "\t-s<flt>\tspecify space constant in mm (default=%f)\n", SCONST);
fprintf (stderr, "\t-z<flt>\tspecify background threshold (default=%.1f)\n", ZTHRESH);
fprintf (stderr, "\t-M<flt>\tspecify maximum correction factor\n");
fprintf (stderr, "\t-r<flt>[to<flt>]\tspecify gfc range (default=%.1fto%.1f)\n", GFC_THRESH, GFC_CEIL);
exit (1);
}
/*******************************************/
/* read/initialize gain field coefficients */
/*******************************************/
sprintf (gfcfile, "%s.4dfp.gfc", imgroot);
if (imgfp = fopen (gfcfile, "r")) {
printf ("Reading: %s\n", gfcfile);
for (k = 0; k < nterm; k++) fscanf (imgfp, "%f", a + k);
fclose (imgfp);
} else {
a[0] = 1.0;
for (k = 1; k < nterm; k++) a[k] = 0.0;
}
for (k = 0; k < nterm; k++) fprintf (stdout, "%8.4f", a[k]); fprintf (stdout, "\n");
/******************************/
/* get input image dimensions */
/******************************/
if (Getifh (imgroot, &ifh) != 0) errr (program, imgroot);
isbig = strcmp (ifh.imagedata_byte_order, "littleendian");
if (!control) control = (isbig) ? 'b' : 'l';
for (k = 0; k < 3; k++) g_voxdim[k] = ifh.scaling_factor[k];
if (debug) printf ("%10.6f%10.6f%10.6f\n", g_voxdim[0], g_voxdim[1], g_voxdim[2]);
g_dimension = ((g_xdim = ifh.matrix_size[0])
*(g_ydim = ifh.matrix_size[1])
*(g_zdim = ifh.matrix_size[2]));
/************************************************/
/* check image index limits against XYZN typedef */
/*************************************************/
if (g_xdim > MAXD || g_ydim > MAXD || g_zdim > MAXD) {
fprintf (stderr, "%s: %s dimension exceeds %d\n", program, imgroot, MAXD);
exit (-1);
}
if (ifh.number_of_bytes_per_pixel != 4) {
printf ("%s: cannot process %d bytes per pixel", program, ifh.number_of_bytes_per_pixel);
exit (-1);
}
/************/
/* allocate */
/************/
if (!(g_img1 = (float *) malloc (g_dimension * sizeof (float)))
|| !(g_img0 = (float *) malloc (g_dimension * sizeof (float)))
|| !(g_imgg = (float *) malloc (g_dimension * sizeof (float)))
|| !(g_imgo = (short *) calloc (g_dimension, sizeof (short)))
|| !(g_imgb = (UCHAR *) calloc (g_dimension, sizeof (UCHAR)))) errm (program);
sprintf (imgfile, "%s.4dfp.img", imgroot);
printf ("Reading: %s\n", imgfile);
if (!(imgfp = fopen (imgfile, "rb")) || eread (g_img0, g_dimension, isbig, imgfp)
|| fclose (imgfp)) errr (program, imgfile);
/******************/
/* pre-blur image */
/******************/
if (!gfreeze && fwhm > 0) {
if (!(img_orig = (float *) malloc (g_dimension * sizeof (float)))) errm (program);
/*************************************/
/* img_orig will hold original image */
/*************************************/
memcpy (img_orig, g_img0, g_dimension*sizeof(float));
memcpy (g_img1, g_img0, g_dimension*sizeof(float));
printf ("blur FWHM = %.2f mm\n", fwhm);
imgdim[0] = g_xdim; imgdim[1] = g_ydim; imgdim[2] = g_zdim;
imgblur3d_ (&fwhm, &alpha, g_voxdim, g_img1, imgdim, g_img0); /* g_img1 returned unusable */
/************************************************************************/
/* g_img0 now points to blurred image to be used in further computation */
/************************************************************************/
}
/*******************/
/* compute outroot */
/*******************/
if (ptr = strrchr (imgroot, '/')) ptr++; else ptr = imgroot;
getroot (ptr, outroot);
/*********************/
/* apply initial gfc */
/*********************/
evalgain3d_ (g_imgg, &g_xdim, &g_ydim, &g_zdim, &norder, a);
for (sum = sum0 = i = 0; i < g_dimension; i++) {
sum0 += g_img0[i];
sum += (g_img1[i] = g_img0[i]/g_imgg[i]);
}
for (i = 0; i < g_dimension; i++) g_img1[i] *= (sum0/sum);
if (gfreeze) goto WRITE;
/****************/
/* open datfile */
/****************/
sprintf (datfile, "%s_gfc.dat", outroot);
if (!(datfp = fopen (datfile, "a"))) errw (program, datfile);
powstring_ (&norder, &eight, string);
fprintf (datfp, "#\t%s\n", string);
fprintf (datfp, "%d\t", niter);
for (k = 0; k < nterm; k++) fprintf (datfp, "%8.4f", a[k]);
fprintf (datfp, "%8.4f\n", 0.0); fflush (datfp);
/***********************/
/* clear region buffer */
/***********************/
memset (&g_region, '\0', MAXR * sizeof (REGION));
iv0 = ir = 0;
/***************************/
/* find contiguous regions */
/***************************/
CONTIG: while (ir < MAXR) {
for (iv = iv0; iv < g_dimension; iv++) if (!g_imgo[iv]) break;
if (iv == g_dimension) break;
iv0 = iv;
g_imgo[iv] = ir + 1;
g_region[ir].u1 = (floor (g_img1[iv] / g_bandwidth) + 0.5) * g_bandwidth;
k = iv;
j = g_dimension;
j /= g_zdim; iz = k / j; k -= iz * j;
j /= g_ydim; iy = k / j; k -= iy * j;
j /= g_xdim; ix = k / j; k -= ix * j;
xyzn.ix = ix; xyzn.iy = iy; xyzn.iz = iz; xyzn.nn = 0;
assign (ir, xyzn);
do {
m = g_region[ir].ne++;
iv = g_region[ir].xyzn[m].ix + g_xdim*(g_region[ir].xyzn[m].iy + g_ydim*g_region[ir].xyzn[m].iz);
for (j = 0; j < 6; j++) {
xyzn = g_region[ir].xyzn[m];
switch (j) {
case 0: k = -1; if (xyzn.ix < 1) continue; xyzn.ix--; break;
case 1: k *= -1; if (xyzn.ix > g_xdim - 2) continue; xyzn.ix++; break;
case 2: k *= -g_xdim; if (xyzn.iy < 1) continue; xyzn.iy--; break;
case 3: k *= -1; if (xyzn.iy > g_ydim - 2) continue; xyzn.iy++; break;
case 4: k *= -g_ydim; if (xyzn.iz < 1) continue; xyzn.iz--; break;
case 5: k *= -1; if (xyzn.iz > g_zdim - 2) continue; xyzn.iz++; break;
}
jv = iv + k;
if (g_imgo[jv] || g_img0[jv] < g_zthresh) continue;
dela = g_img1[jv] - g_region[ir].u1;
if (fabs (dela) < 0.5 * g_bandwidth) {
g_imgo[jv] = ir + 1;
assign (ir, xyzn);
}
}
if (verbose && !(g_region[ir].count % 1000)) {
xyzn = g_region[ir].xyzn[m];
printf ("checkr0: region=%4d unexa=%8d coords=%4d%4d%4d u1=%8.2f\n",
ir, g_region[ir].count - m, xyzn.ix, xyzn.iy, xyzn.iz, g_region[ir].u1);
}
} while (g_region[ir].count > g_region[ir].ne);
if (g_region[ir].count == 1) {
iv = g_region[ir].xyzn[0].ix + g_xdim*(g_region[ir].xyzn[0].iy + g_ydim*g_region[ir].xyzn[0].iz);
g_imgo[iv] = -1;
g_region[ir].count = g_region[ir].ne = 0;
} else {
ir++;
}
}
/************************/
/* sort regions by size */
/************************/
qsort ((void *) g_region, ir, sizeof (REGION), rcompare);
if (ir == MAXR) {
if (verbose) printf ("ir %d -> %d iv0=%10d ivmax=%d\n", ir, MAXR/2, iv0, g_dimension);
while (--ir > MAXR/2) {
for (m = 0; m < g_region[ir].count; m++) {
xyzn = g_region[ir].xyzn[m]; iv = xyzn.ix + g_xdim*(xyzn.iy + g_ydim*xyzn.iz);
g_imgo[iv] = 0;
}
g_region[ir].count = g_region[ir].ne = 0;
}
goto CONTIG;
}
g_nr = ir;
for (ir = g_nr; ir < MAXR; ir++) if (g_region[ir].xyzn) free (g_region[ir].xyzn);
test = 1;
ITER: getmean (); /* analyze g_img1 */
getxyzn0 (); /* analyze g_img1 */
/********************/
/* reassign regions */
/********************/
for (i = 0; i < g_dimension; i++) g_imgo[i] = 0;
printf ("total number of regions %d\n", g_nr);
for (ir = 0; ir < g_nr; ir++) {
g_region[ir].ne = g_region[ir].count = 0;
if (g_region[ir].u1 < g_gfc_thresh || g_region[ir].u1 > g_gfc_ceil) continue;
assign (ir, g_region[ir].xyzn0);
do {
m = g_region[ir].ne++;
xyzn = g_region[ir].xyzn[m];
iv = xyzn.ix + g_xdim*(xyzn.iy + g_ydim*xyzn.iz);
for (j = 0; j < 6; j++) {
xyzn = g_region[ir].xyzn[m];
switch (j) {
case 0: k = -1; if (xyzn.ix < 1) continue; xyzn.ix--; break;
case 1: k *= -1; if (xyzn.ix > g_xdim - 2) continue; xyzn.ix++; break;
case 2: k *= -g_xdim; if (xyzn.iy < 1) continue; xyzn.iy--; break;
case 3: k *= -1; if (xyzn.iy > g_ydim - 2) continue; xyzn.iy++; break;
case 4: k *= -g_ydim; if (xyzn.iz < 1) continue; xyzn.iz--; break;
case 5: k *= -1; if (xyzn.iz > g_zdim - 2) continue; xyzn.iz++; break;
}
jv = iv + k;
if (g_imgo[jv] || g_img0[jv] < g_zthresh) continue;
dela = g_img1[jv] - g_region[ir].u1;
delg = g_sconst * (g_img1[jv] - g_img1[iv]) / g_voxdim[j/2];
if (sqrt (dela*dela + delg*delg) < g_sigma*g_bandwidth) {
g_imgo[jv] = ir + 1;
assign (ir, xyzn);
}
}
if (verbose && !(g_region[ir].count % 1000)) {
xyzn = g_region[ir].xyzn[m];
printf ("checkr1: region=%4d unexa=%8d coords=%4d%4d%4d u1=%8.2f\n",
ir, g_region[ir].count - m, xyzn.ix, xyzn.iy, xyzn.iz, g_region[ir].u1);
}
} while (g_region[ir].count > g_region[ir].ne);
}
getmean (); getxyzn0 (); /* analyze g_img1 */
listreg (stdout);
if (g_region[0].u1 < g_bandwidth) {
fprintf (stderr, "%s: algorithmic failure\n", program);
exit (-1);
}
if (++niter > limiter || !test) goto COUNT;
fprintf (stdout, "%s: iteration %d\n", program, niter);
/***************/
/* compute gfc */
/***************/
for (ir = 0; ir < g_nr; ir++) u1gfc[ir] = g_region[ir].u1;
for (k = 0; k < nterm; k++) a0[k] = a[k];
fitgain3dd_ (g_img0, &g_xdim, &g_ydim, &g_zdim, g_imgo, u1gfc, &g_mr, &norder, a, &drms);
if (negdef) fnegdef_ (a);
printf ("niter=%d drms=%.6f diffcrit=%.6f\n", niter, drms, diffcrit);
fprintf (datfp, "%d\t", niter);
for (k = 0; k < nterm; k++) fprintf (datfp, "%8.4f", a[k]);
fprintf (datfp, "%8.4f\n", 100*drms); fflush (datfp);
evalgain3d_ (g_imgg, &g_xdim, &g_ydim, &g_zdim, &norder, a);
for (sum = i = 0; i < g_dimension; i++) sum += (g_img1[i] = g_img0[i]/g_imgg[i]);
for ( i = 0; i < g_dimension; i++) g_img1[i] *= (sum0/sum);
/********************/
/* convergence test */
/********************/
test = (drms > diffcrit);
goto ITER;
COUNT: fclose (datfp);
/*******************/
/* count neighbors */
/*******************/
for (ir = 0; ir < g_nr; ir++) {
for (g_nl = m = 0; m < g_region[ir].count; m++) {
ix = g_region[ir].xyzn[m].ix;
iy = g_region[ir].xyzn[m].iy;
iz = g_region[ir].xyzn[m].iz;
iv = ix + g_xdim*(iy + g_ydim*iz);
nn = 0;
k = -1; if (ix > 0) {if ((j = g_imgo[iv + k]) == ir + 1) nn++; else enter (j);}
k *= -1; if (ix < g_xdim - 1) {if ((j = g_imgo[iv + k]) == ir + 1) nn++; else enter (j);}
k *= -g_xdim; if (iy > 0) {if ((j = g_imgo[iv + k]) == ir + 1) nn++; else enter (j);}
k *= -1; if (iy < g_ydim - 1) {if ((j = g_imgo[iv + k]) == ir + 1) nn++; else enter (j);}
k *= -g_ydim; if (iz > 0) {if ((j = g_imgo[iv + k]) == ir + 1) nn++; else enter (j);}
k *= -1; if (iz < g_zdim - 1) {if ((j = g_imgo[iv + k]) == ir + 1) nn++; else enter (j);}
if (nn > g_region[ir].nnmax) g_region[ir].nnmax = nn;
g_imgb[iv] = g_region[ir].xyzn[m].nn = nn;
}
if (verbose) {
printf ("%5d%10d%10d%5d%2d |", ir, g_region[ir].count, k, j, g_region[ir].nnmax);
for (i = 0; i < g_nl; i++) printf (" %d", g_list[i]); printf ("\n");
}
}
/*********************************/
/* write gain field coefficients */
/*********************************/
if (!(imgfp = fopen (gfcfile, "w"))) errw (program, gfcfile);
printf ("Writing: %s\n", gfcfile);
for (k = 0; k < nterm; k++) fprintf (imgfp, "%8.4f", a[k]); fprintf (imgfp, "\n");
fclose (imgfp);
/*************************/
/* write corrected image */
/*************************/
WRITE: for (sum0 = sum = i = 0; i < g_dimension; i++) {
if (!gfreeze && fwhm > 0) g_img0[i] = img_orig[i];
sum0 += g_img0[i];
q = 1./g_imgg[i];
t = (maxfac > 0.0) ? 2.*maxfac*tanh(.5*q/maxfac) : q;
if (0) printf ("%10.6f %10.6f\n", q, t);
sum += (g_img1[i] = g_img0[i]*t);
}
for (i = 0; i < g_dimension; i++) g_img1[i] *= (sum0/sum);
vmin = FLT_MAX; vmax = -vmin;
for (i = 0; i < g_dimension; i++) {
if (g_img1[i] < vmin) vmin = g_img1[i];
if (g_img1[i] > vmax) vmax = g_img1[i];
}
sprintf (outfile, "%s_gfc.4dfp.img", outroot);
fprintf (stdout, "Writing: %s\n", outfile);
if (!(imgfp = fopen (outfile, "wb")) || ewrite (g_img1, g_dimension, control, imgfp)
|| fclose (imgfp)) errw (program, outfile);
/***************/
/* ifh and hdr */
/***************/
sprintf (ifhfile, "%s_gfc.4dfp.ifh", outroot);
if (Writeifh (program, ifhfile, &ifh, control)) errw (program, ifhfile);
sprintf (command, "ifh2hdr %s -r%.0f", ifhfile, vmax);
system (command);
/*******/
/* rec */
/*******/
startrece (outfile, argc, argv, g_rcsid, control);
sprintf (string, "%s gain field coefficients\n", imgroot); printrec (string);
powstring_ (&norder, &eight, string); printrec (string);
for (k = 0; k < nterm; k++) {sprintf (string, "%8.4f", a[k]); printrec (string);} printrec ("\n");
if (!gfreeze) {
sprintf (recfile, "%s_gfc.4dfp.img.rec", outroot);
if (!(imgfp = fopen (recfile, "a"))) errw (program, recfile); listreg (imgfp); fclose (imgfp);
}
catrec (imgfile);
endrec ();
if (gfreeze) goto FREE;
/*************************/
/* compute regions image */
/*************************/
for (i = 0; i < g_dimension; i++) g_img1[i] = 0;
for (ir = 0; ir < g_mr; ir++) {
for (m = 0; m < g_region[ir].count; m++) {
xyzn = g_region[ir].xyzn[m];
iv = xyzn.ix + g_xdim*(xyzn.iy + g_ydim*xyzn.iz);
g_img1[iv] = g_region[ir].u1;
}
}
/******************************/
/* write processing QA images */
/******************************/
sprintf (volfile, "%s_gfc_vols.4dfp.img", outroot);
printf ("Writing: %s\n", volfile);
if (!(imgfp = fopen (volfile, "w"))) errw (program, volfile);
/*****************/
/* regions image */
/*****************/
if (ewrite (g_img1, g_dimension, control, imgfp)) errw (program, volfile);
/****************/
/* border image */
/****************/
for (i = 0; i < g_dimension; i++) g_img1[i] = g_imgb[i];
if (ewrite (g_img1, g_dimension, control, imgfp)) errw (program, volfile);
/**************/
/* gain field */
/**************/
for (i = 0; i < g_dimension; i++) g_img1[i] = g_imgg[i];
if (ewrite (g_img1, g_dimension, control, imgfp)) errw (program, volfile);
fclose (imgfp);
/***************/
/* ifh and hdr */
/***************/
sprintf (ifhfile, "%s_gfc_vols.4dfp.ifh", outroot);
ifh.matrix_size[3] = 3;
if (Writeifh (program, ifhfile, &ifh, control)) errw (program, ifhfile);
sprintf (string, "ifh2hdr %s -r%.0f", ifhfile, vmax);
system (string);
/*******/
/* rec */
/*******/
startrece (volfile, argc, argv, g_rcsid, control);
sprintf (string, "%s_gfc QA (3 volumes)\n", imgroot); printrec (string);
catrec (outfile);
printrec ("Volume 1: regions\nVolume 2: border\nVolume 3: gain field\n");
endrec ();
/************/
/* clean up */
/************/
FREE: free (g_img1); free (g_img0); free (g_imgg);
free (g_imgo); free (g_imgb);
if (img_orig) free (img_orig);
for (ir = 0; ir < g_nr; ir++) free (g_region[ir].xyzn);
exit (status);
}
int
main(int argc, char **argv)
{
int ch, csv = 0, i, nf;
char **a, *rectype = NULL;
struct rechandle *h;
argv0 = argv[0];
while ((ch = getopt(argc, argv, "T:c")) != -1) {
switch (ch) {
case 'T':
rectype = optarg;
break;
case 'c':
csv = 1;
break;
default:
usage();
break;
}
}
argc -= optind;
argv += optind;
if (csv)
h = rechandle_csv(stdout, rectype);
else
h = rechandle_tabsep(stdout, rectype);
if (h == NULL)
exit(1);
if (*argv == NULL)
usage();
nf = atoi(*argv);
argc--;
argv++;
a = calloc(nf + 1, sizeof(*a));
if (a == NULL)
exit(1);
for (i = 0; argv[i] != NULL && i < nf; i++)
a[i] = argv[i];
if (i != nf)
usage();
argv += nf;
a[nf] = NULL;
if (rectype == NULL && writeheader(h, a) < 0)
exit(1);
free(a);
while (*argv != NULL) {
if (startrec(h) < 0)
exit(1);
for (i = 0; argv[i] != NULL && i < nf; i++) {
if (writefield(h, "%s", argv[i]) < 0)
exit(1);
}
if (i != nf)
usage();
argv += nf;
if (endrec(h) < 0)
exit(1);
}
exit(0);
}
int main (int argc, char *argv[]) {
FILE *fp;
IFH ifh;
char imgroot[2][MAXR][MAXL], Nmgroot[2][MAXL], lstfile[2][MAXL];
int nimg[2], isbig[2][MAXR], isbigN[2];
int orient, orient1, imgdim[4], imgdim1[4], dimension, vdim;
char outroot[MAXL] = "", imgfile[MAXL], outfile[MAXL];
float voxdim[3], voxdim1[3];
float amin = FLT_MAX, amax = -FLT_MAX;
float *img1, **imgN;
double **imgs, **imgv;
int **imgm, ngroup;
char control = '\0';
/***********/
/* utility */
/***********/
double u;
int c, i, j, k, m;
char *ptr, *str, command[MAXL];
char *srgv[MAXL]; /* string field pointers */
/*********/
/* flags */
/*********/
int defined;
int debug = 0;
int NaN_flag = 'E'; /* 'E' 1.e-37; 'Z' 0.0; 'N' NaN; */
int status = 0;
int saverec = 1;
printf ("%s\n", rcsid);
setprog (program, argv);
/************************/
/* process command line */
/************************/
k = 0; for (i = 1; i < argc; i++) {
if (*argv[i] == '-') {
strcpy (command, argv[i]); ptr = command;
while (c = *ptr++) switch (c) {
case 'R': saverec = 0; break;
case 'd': debug++; break;
case 'o': getroot (ptr, outroot); *ptr = '\0'; break;
case '@': control = *ptr++; *ptr = '\0'; break;
}
} else switch (k) {
case 0: strcpy (lstfile[0], argv[i]); k++; break;
case 1: getroot (argv[i], Nmgroot[0]); k++; break;
case 2: strcpy (lstfile[1], argv[i]); k++; break;
case 3: getroot (argv[i], Nmgroot[1]); k++; break;
}
}
if (k != 2 && k != 4) usage ();
ngroup = k/2;
/********************/
/* parse list files */
/********************/
for (k = 0; k < ngroup; k++) {
nimg[k] = 0;
if (!(fp = fopen (lstfile[k], "r"))) errr (program, lstfile[k]);
printf ("Reading: %s\n", lstfile[k]);
while (fgets (command, MAXL, fp)) {
if (nimg[k] >= MAXR) {
fprintf (stderr, "%s: maximum number of input images (%d) exceeded\n", program, MAXR);
exit (-1);
}
if (ptr = strchr (command, '#')) *ptr = '\0';
if (!strlen (command)) continue; /* skip blank lines */
if (ptr = strchr (command, '\n')) *ptr = '\0'; /* strip terminal nl */
i = m = 0; while (m < MAXL && i < MAXL) {
while (!isgraph ((int) command[i]) && command[i]) i++;
if (!command[i]) break;
srgv[m++] = command + i;
while (isgraph ((int) command[i])) i++;
if (!command[i]) break;
command[i++] = '\0';
}
getroot (srgv[0], imgroot[k][nimg[k]++]);
}
fclose (fp);
if (!nimg[k]) usage ();
/*********************************/
/* check dimensional consistency */
/*********************************/
for (i = 0; i < nimg[k]; i++) {
printf ("image %3d: %s\n", i + 1, imgroot[k][i]);
if (!i && !k) {
if (get_4dfp_dimoe (imgroot[k][i], imgdim, voxdim, &orient, isbig[k] + i)) exit (-1);
if (Getifh (imgroot[k][i], &ifh)) errr (program, imgroot[k][i]);
} else {
if (get_4dfp_dimoe (imgroot[k][i], imgdim1, voxdim1, &orient1, isbig[k] + i)) exit (-1);
status = (orient1 != orient);
for (j = 0; j < 4; j++) status |= (imgdim1[j] != imgdim[j]);
for (j = 0; j < 3; j++) status |= (fabs (voxdim1[j] - voxdim[j]) > 1.e-4);
}
if (status) {
fprintf (stderr, "%s: %s %s dimension mismatch\n", program, imgroot[0][0], imgroot[k][i]);
exit (-1);
}
}
if (get_4dfp_dimoe (Nmgroot[k], imgdim1, voxdim1, &orient1, isbigN + k)) exit (-1);
status = (orient1 != orient);
for (j = 0; j < 3; j++) status |= (imgdim1[j] != imgdim[j]);
for (j = 0; j < 3; j++) status |= (fabs (voxdim1[j] - voxdim[j]) > 1.e-4);
if (status) {
fprintf (stderr, "%s: %s %s dimension mismatch\n", program, imgroot[0][0], Nmgroot[k]);
exit (-1);
}
}
if (!control) control = (isbig[0][0]) ? 'b' : 'l';
vdim = imgdim[0]*imgdim[1]*imgdim[2];
dimension = vdim*imgdim[3];
if (!(img1 = (float *) calloc (dimension, sizeof (float)))) errm (program);
imgv = calloc_double2 (ngroup, dimension); /* variance accumulator */
imgs = calloc_double2 (ngroup, dimension); /* sum accumulator */
imgm = calloc_int2 (ngroup, dimension); /* voxel counter */
imgN = calloc_float2 (ngroup, vdim); /* input N image */
for (k = 0; k < ngroup; k++) {
/****************/
/* read N image */
/****************/
printf ("Reading: %s\n", Nmgroot[k]);
sprintf (imgfile, "%s.4dfp.img", Nmgroot[k]);
if (!(fp = fopen (imgfile, "rb")) || eread (imgN[k], vdim, isbigN[k], fp)
|| fclose (fp)) errr (program, imgfile);
/**********************************/
/* read and accumulate image data */
/**********************************/
for (j = 0; j < nimg[k]; j++) {
printf ("Reading: %s\n", imgroot[k][j]);
sprintf (imgfile, "%s.4dfp.img", imgroot[k][j]);
if (!(fp = fopen (imgfile, "rb")) || eread (img1, dimension, isbig[k][j], fp)
|| fclose (fp)) errr (program, imgfile);
for (i = 0; i < dimension; i++) {
defined = isnormal (img1[i]) && img1[i] != (float) 1.e-37;
if (!defined) continue;
imgm[k][i]++;
imgs[k][i] += img1[i];
imgv[k][i] += img1[i]*img1[i];
}
}
for (i = 0; i < dimension; i++) {
u = (imgs[k][i] /= imgm[k][i]);
imgv[k][i] -= u*u*imgm[k][i]; if (imgv[k][i] < 0.0) imgv[k][i] = 0.0;
imgv[k][i] /= (imgm[k][i] - 1);
}
/***************************************/
/* divide variance estimate by N image */
/***************************************/
for (i = 0; i < vdim; i++) if (imgN[k][i]) for (j = 0; j < imgdim[3]; j++) {
imgv[k][j*vdim + i] /= imgN[k][i];
}
}
/***************************************************************************/
/* compute voxelwize t statistic (Welch's approximate t' when ngroup == 2) */
/***************************************************************************/
for (i = 0; i < dimension; i++) {
if (ngroup == 2) {
imgs[0][i] -= imgs[1][i];
imgv[0][i] += imgv[1][i];
}
if (isnormal (imgs[0][i]) && isnormal (imgv[0][i])) {
img1[i] = imgs[0][i] / sqrt (imgv[0][i]);
if (img1[i] > amax) amax = img1[i];
if (img1[i] < amin) amin = img1[i];
} else switch (NaN_flag) {
case 'Z': img1[i] = 0.0; break;
case 'E': img1[i] = (float) 1.e-37; break;
case 'N': img1[i] = rnan (); break;
}
}
if (!strlen (outroot)) {
/*******************/
/* compute outroot */
/*******************/
strcpy (command, lstfile[0]);
if (!(ptr = strrchr (command, '/'))) ptr = command; else ptr++;
if (str = strrchr (ptr, '.')) *str = '\0';
sprintf (outroot, "RFX_%s", ptr);
if (ngroup == 2) {
strcat (outroot, "_vs_");
strcpy (command, lstfile[1]);
if (!(ptr = strrchr (command, '/'))) ptr = command; else ptr++;
if (str = strrchr (ptr, '.')) *str = '\0';
strcat (outroot, ptr);
}
strcat (outroot, "_tmap");
}
sprintf (outfile, "%s.4dfp.img", outroot);
/****************/
/* write result */
/****************/
printf ("Writing: %s\n", outfile);
if (!(fp = fopen (outfile, "wb"))
|| ewrite (img1, dimension, control, fp)
|| fclose (fp)) errw (program, outfile);
/*******/
/* ifh */
/*******/
Writeifh (program, outfile, &ifh, control);
/*******/
/* hdr */
/*******/
sprintf (command, "ifh2hdr %s -r%.0fto%.0f", outroot, amin, amax);
printf ("%s\n", command);
status |= system (command);
/*******/
/* rec */
/*******/
startrecle (outfile, argc, argv, rcsid, control);
for (k = 0; k < ngroup; k++) {
sprintf (command, "imglist %d\n", k + 1);
printrec (command); catrec (lstfile[k]); printrec ("endimglist\n");
if (saverec) {
sprintf (imgfile, "%s.4dfp.img", Nmgroot[k]); catrec (imgfile);
for (j = 0; j < nimg[k]; j++) {
sprintf (imgfile, "%s.4dfp.img", imgroot[k][j]); catrec (imgfile);
}
}
}
endrec ();
free (img1); free_double2 (imgs); free_double2 (imgv); free_int2 (imgm); free_float2 (imgN);
exit (status);
}
int main (int argc, char *argv[]) {
/************/
/* 4dfp I/O */
/************/
FILE *fp_img, *fp_out;
IFH ifh;
char outfile[MAXL], imgfile[MAXL];
char imgroot[MAXL], outroot[MAXL] = "";
char control = '\0';
/****************/
/* image arrays */
/****************/
float *img1, *imgc;
float voxdim[3];
int imgdim[4], outdim[4], ix, iy, iz, index, vdim, isbig;
int ix0 = 1, ix1 = 0, iy0 = 1, iy1 = 0, iz0 = 1, iz1 = 0;
int vdim_crop, orient;
/***********/
/* utility */
/***********/
int c, i, j, k;
char *ptr, string[MAXL];
/*********/
/* flags */
/*********/
int doflip = 0;
int docrop = 1;
int scrollx = 0, scrolly = 0, scrollz = 0;
printf ("%s\n", rcsid);
setprog (program, argv);
/************************/
/* process command line */
/************************/
for (k = 0, i = 1; i < argc; i++) {
if (*argv[i] == '-') {
strcpy (string, argv[i]); ptr = string;
while (c = *ptr++) switch (c) {
case 'f': doflip++; break;
case 'Z': docrop = 0; break;
case '@': control = *ptr++; *ptr = '\0'; break;
case 'x': getirange (ptr, &ix0, &ix1); *ptr = '\0'; break;
case 'y': getirange (ptr, &iy0, &iy1); *ptr = '\0'; break;
case 'z': getirange (ptr, &iz0, &iz1); *ptr = '\0'; break;
case 's': switch (*ptr++) {
case 'x': scrollx = atoi (ptr); break;
case 'y': scrolly = atoi (ptr); break;
case 'z': scrollz = atoi (ptr); break;
} *ptr = '\0'; break;
}
}
else switch (k) {
case 0: getroot (argv[i], imgroot); k++; break;
case 1: getroot (argv[i], outroot); k++; break;
}
}
if (k < 1) {
printf ("Usage:\t%s <(4dfp) inroot> [(4dfp) outroot]\n", program);
printf ("\toption\n");
printf ("\t-<x|y|z><int>[to[<int>]\tspecify x y z crop limits\n");
printf ("\t-s<x|y|z><int>\tscroll specified axis by specified number of pixels\n");
printf ("\t-f\tinterpret specifications under 4dfp<->analyze flips\n");
printf ("\t-Z\tzero voxels instead of physically cropping\n");
printf ("\t-@<b|l>\toutput big or little endian (default input endian)\n");
printf ("N.B.:\tcrop limit indices count from 1\n");
printf ("N.B.:\tscrolling is done after cropping\n");
printf ("N.B.:\tdefault (4dfp) output root is <(4dfp) inroot>\"_crop\"\n");
exit (1);
}
sprintf (imgfile, "%s.4dfp.img", imgroot);
if (get_4dfp_dimoe (imgfile, imgdim, voxdim, &orient, &isbig) < 0
|| Getifh (imgfile, &ifh)) errr (program, imgfile);
if (!control) control = (isbig) ? 'b' : 'l';
printf ("input dimensions %10d%10d%10d%10d\n", imgdim[0], imgdim[1], imgdim[2], imgdim[3]);
printf ("voxel dimensions %10.6f%10.6f%10.6f\n", voxdim[0], voxdim[1], voxdim[2]);
if (ix1 > imgdim[0] || ix1 < 1) ix1 = imgdim[0];
if (iy1 > imgdim[1] || iy1 < 1) iy1 = imgdim[1];
if (iz1 > imgdim[2] || iz1 < 1) iz1 = imgdim[2];
if (ix0 > imgdim[0] || ix0 < 1) ix0 = 1;
if (iy0 > imgdim[1] || iy0 < 1) iy0 = 1;
if (iz0 > imgdim[2] || iz0 < 1) iz0 = 1;
if (ix1 < ix0) {k = ix1; ix1 = ix0; ix0 = k;}
if (iy1 < iy0) {k = iy1; iy1 = iy0; iy0 = k;}
if (iz1 < iz0) {k = iz1; iz1 = iz0; iz0 = k;}
printf ("crop limits x %3d to %3d\n", ix0, ix1);
printf ("crop limits y %3d to %3d\n", iy0, iy1);
printf ("crop limits z %3d to %3d\n", iz0, iz1);
printf ("scroll x %3d\n", scrollx);
printf ("scroll y %3d\n", scrolly);
printf ("scroll z %3d\n", scrollz);
outdim[0] = (docrop) ? ix1 - ix0 + 1 : imgdim[0];
outdim[1] = (docrop) ? iy1 - iy0 + 1 : imgdim[1];
outdim[2] = (docrop) ? iz1 - iz0 + 1 : imgdim[2];
outdim[3] = imgdim[3];
printf ("output dimensions %10d%10d%10d%10d\n", outdim[0], outdim[1], outdim[2], outdim[3]);
vdim = imgdim[0] * imgdim[1] * imgdim[2];
if (!(img1 = (float *) malloc (vdim * sizeof (float)))) errm (program);
if (!(fp_img = fopen (imgfile, "rb"))) errr (program, imgfile);
printf ("Reading: %s\n", imgfile);
if (!strlen (outroot)) sprintf (outroot, "%s_crop", imgroot);
sprintf (outfile, "%s.4dfp.img", outroot);
vdim_crop = outdim[0] * outdim[1] * outdim[2];
if (!(imgc = (float *) calloc (vdim_crop, sizeof (float)))) errm (program);
if (!(fp_out = fopen (outfile, "wb"))) errw (program, outfile);
printf ("Writing: %s\n", outfile);
/***********/
/* process */
/***********/
printf ("processing volume");
for (k = 0; k < imgdim[3]; k++) {printf (" %d", k + 1); fflush (stdout);
if (eread (img1, vdim, isbig, fp_img)) errr (program, imgfile);
if (doflip) {
if (x4dfp2analyze (img1, imgdim, ifh.orientation)) {
fprintf (stderr, "%s: invalid %s orientation\n", program, imgroot);
exit (-1);
}
}
i = 0;
for (iz = iz0 - 1; iz < iz1; iz++) {
for (iy = iy0 - 1; iy < iy1; iy++) {
for (ix = ix0 - 1; ix < ix1; ix++) {
index = ix + imgdim[0]*(iy + imgdim[1]*iz);
if (docrop) {
imgc[i++] = img1[index];
} else {
imgc[index] = img1[index];
}
}}}
if (scrollx) xscroll (img1, imgc, outdim, scrollx);
if (scrolly) yscroll (img1, imgc, outdim, scrolly);
if (scrollz) zscroll (img1, imgc, outdim, scrollz);
if (doflip) x4dfp2analyze (imgc, outdim, ifh.orientation);
if (ewrite (imgc, vdim_crop, control, fp_out)) errw (program, outfile);
} printf ("\n"); fflush (stdout);
fclose (fp_img);
fclose (fp_out);
/**************/
/* output ifh */
/**************/
if (docrop) {
if (writeifhe (program, outroot, outdim, voxdim, ifh.orientation, control)) errw (program, outroot);
} else {
Writeifh (program, outroot, &ifh, control);
}
/***************/
/* run ifh2hdr */
/***************/
sprintf (string, "ifh2hdr %s", outroot); status |= system (string);
/************/
/* rec file */
/************/
startrece (outfile, argc, argv, rcsid, control);
if (doflip) printrec ("indices subjected to 4dfp<->analyze orientation dependent flips\n");
if (!docrop) printrec ("voxels zeroed instead of physically cropped\n");
sprintf (string, "crop limits x %3d to %3d\n", ix0, ix1); printrec (string);
sprintf (string, "crop limits y %3d to %3d\n", iy0, iy1); printrec (string);
sprintf (string, "crop limits z %3d to %3d\n", iz0, iz1); printrec (string);
if (scrollx) {sprintf (string, "scroll x %3d\n", scrollx); printrec (string);}
if (scrolly) {sprintf (string, "scroll y %3d\n", scrolly); printrec (string);}
if (scrollz) {sprintf (string, "scroll z %3d\n", scrollz); printrec (string);}
catrec (imgfile);
endrec ();
/************/
/* clean up */
/************/
free (img1); free (imgc);
exit (status);
}
int main (int argc, char *argv[])
{
char ecatspec[MAXL], ecatname[MAXL];
char imgroot[MAXL], imgname[MAXL];
FILE *fptr;
struct Matval matval;
MatrixFile *mptr;
MatrixData *matrix;
MatDirNode *entry, **entries;
Image_subheader *ih;
float global_max, global_min;
int volume, plane, line, nframes, iframe, jframe, matnum, *missing, nmissing;
float scale_factor, calibration_factor/*, scan_time*/;
int cubic = CUBIC;
float *img;
short *ecat;
int i, j, k;
char string[MAXL], *ptr, c;
char control = '\0';
int isbig;
IFH ifh;
setprog (program, argv);
for (j = 0, i = 1; i < argc; i++)
if (*argv[i] == '-')
{
strncpy (string, argv[i], MAXL); ptr = string;
while (c = *ptr++) switch (c)
{
case '@': control = *ptr++; *ptr = '\0'; break;
}
}
else switch (j)
{
case 0: strncpy (ecatspec, argv[i], MAXL); j++; break;
case 1: getroot (argv[i], imgroot); j++; break;
}
if (j != 2)
{
fprintf (stderr, "Usage:\t%s <ecat> <(4dfp)image>\n", program);
fprintf (stderr, "\t-@<b|l>\toutput big or little endian (default input endian)\n");
exit (1);
}
/******** Get filenames and open ********/
matspec (ecatspec, ecatname, &matnum); /* matnum is unused */
if (!(mptr = matrix_open (ecatname, MAT_READ_ONLY, MAT_UNKNOWN_FTYPE)))
{
fprintf (stderr, "%s: cannot open %s as an ECAT image file\n", program, ecatname);
exit (-1);
}
if (mptr->mhptr->file_type != InterfileImage
&& mptr->mhptr->file_type != PetImage
&& mptr->mhptr->file_type != PetVolume
&& mptr->mhptr->file_type != ByteImage
&& mptr->mhptr->file_type != ByteVolume)
{
fprintf (stderr, "%s: filetype not supported\n", program);
exit (-1);
}
sprintf (imgname, "%s.4dfp.img", imgroot);
if (!(fptr = fopen (imgname, "w"))) errw (program, imgname);
if (!control) control = (CPU_is_bigendian ()) ? 'b' : 'l';
calibration_factor = mptr->mhptr->calibration_factor;
fprintf (stdout, "Calibration Factor := %10e\n", calibration_factor);
if (!(missing = (int *) calloc (mptr->mhptr->num_frames, sizeof (int)))
|| !(entries = (MatDirNode **) malloc (mptr->mhptr->num_frames * sizeof (MatDirNode *)))) errm (program);
sprintf (string, "%s.4dfp.img.rec", imgroot);
startrece (string, argc, argv, rcsid, control);
printrec ("Frame \t Length\t Midpoint\t Start\t Frame_Min\t Frame_Max\t Decay_Fac\tEcat_Frame\n");
for (nframes = 0, entry = mptr->dirlist->first; entry; entry = entry->next) entries[nframes++] = entry;
qsort (entries, nframes, sizeof (MatDirNode *), frame_cmp);
for (iframe = 1, jframe = 0, nmissing = 0/*, scan_time = 0*/; jframe < nframes; iframe++, jframe++)
{
entry = entries[jframe];
mat_numdoc (entry->matnum, &matval);
while (iframe < matval.frame) {
fprintf (stderr, "%s: %s frame %d not included\n", program, ecatname, iframe);
missing[nmissing++] = iframe++;
}
if (!(matrix = load_volume (mptr, matval.frame, cubic)))
{
fprintf (stderr, "%s: ecat frame %d not found\n", program, matval.frame);
exit (-1);
}
if ( matrix->data_type != SunShort && matrix->data_type != VAX_Ix2)
{
fprintf (stderr, "%s: only integer 2 images are currently supported\n", program);
exit(-1);
}
scale_factor = matrix->scale_factor * calibration_factor;
/* fprintf (stdout, "Scale Factor := %10e\tTotal Factor := %10e\n", matrix->scale_factor, scale_factor);
*/
if (jframe == 0)
{
ifh.scaling_factor[0] = ifh.scaling_factor[1] = 10 * matrix->pixel_size;
ifh.scaling_factor[2] = 10 * matrix->z_size;
ifh.matrix_size[0] = matrix->xdim;
ifh.matrix_size[1] = matrix->ydim;
ifh.matrix_size[2] = matrix->zdim;
line = ifh.matrix_size[0];
plane = ifh.matrix_size[1] * line;
volume = ifh.matrix_size[2] * plane;
if (!(img = (float *) malloc (volume * sizeof (float)))) errm (program);
global_min = matrix->data_min;
global_max = matrix->data_max;
}
else
{
if (matrix->data_min < global_min) global_min = matrix->data_min;
if (matrix->data_max > global_max) global_max = matrix->data_max;
}
/******** Flip Z, and write to output file ********/
ecat = (short *) matrix->data_ptr;
for (i = volume-plane; i >= 0; i -= plane)
/* for (j = 0; j < plane; j += line)
for (k = 0; k < line; k++, ecat++) img[i+j+k] = (*ecat) * scale_factor;
*/ for (j = 0; j < plane; j++, ecat++) img[i+j] = (*ecat) * scale_factor;
if (ewrite (img, volume, control, fptr)) errw (program, imgname);
ih = (Image_subheader*) matrix->shptr;
sprintf (string, "Frame_%-4d\t%10d\t%10.2f\t%10d\t%10d\t%10d\t%10.5f\t%10d\n", jframe+1,
ih->frame_duration,
(ih->frame_start_time + ih->frame_duration / 2.0) / 1000/*scan_time += ih->frame_duration / 1000*/,
ih->frame_start_time,
ih->image_min,
ih->image_max,
ih->decay_corr_fctr,
iframe);
printrec (string);
}
sprintf (string, "%s Missing Frames:", ecatname);
printrec (string);
for (i = 0; i < nmissing; i++)
{
sprintf (string, " %d", missing[i]);
printrec (string);
}
printrec ("\n");
endrec ();
/******** Write ifh, hdr, and rec files ********/
ifh.matrix_size[3] = nframes;
ifh.orientation = TRANSVERSE;
sprintf (string, "%s.4dfp.ifh", imgroot);
if (writeifhe (program, string, ifh.matrix_size, ifh.scaling_factor, ifh.orientation, control)) errw (program, string);
sprintf (string, "ifh2hdr %s -r%fto%f", imgroot, global_min, global_max);
system (string);
/******** Free, close and quit ********/
matrix_close (mptr);
fclose (fptr);
free (img);
exit (0);
}
int main (int argc, char *argv[]) {
/*************/
/* image I/O */
/*************/
FILE *fp_img, *fp_out;
IFH ifh;
char imgfile[MAXL], outfile[MAXL], imgroot[MAXL], outroot[MAXL];
char *str, command[MAXL], program[MAXL];
/**************/
/* processing */
/**************/
char control = '\0';
int dimension, c, i, j, k;
int imgdim[4], orient, isbig;
float voxdim[3], voxdimn[3];
float *imgz, *imgp;
double q;
/*********/
/* flags */
/*********/
int status = 0;
int p_flag = 0;
int two_sided = 0;
int defined;
int debug = 0;
printf ("%s\n", rcsid);
setprog (program, argv);
/************************/
/* process command line */
/************************/
for (k = 0, i = 1; i < argc; i++) {
if (*argv[i] == '-') {
strcpy (command, argv[i]); str = command;
while (c = *str++) switch (c) {
case 'd': debug++; break;
case 'p': p_flag++; break;
case '2': two_sided++; break;
case '@': control = *str++; *str = '\0'; break;
}
} else switch (k) {
case 0: getroot (argv[i], imgroot); k++; break;
}
}
if (k < 1) usage (program);
/**************************/
/* get input 4dfp z-image */
/**************************/
sprintf (imgfile, "%s.4dfp.img", imgroot);
if (get_4dfp_dimoe (imgfile, imgdim, voxdim, &orient, &isbig) < 0) errr (program, imgfile);
if (Getifh (imgfile, &ifh)) errr (program, imgfile);
if (!control) control = (isbig) ? 'b' : 'l';
dimension = imgdim[0] * imgdim[1] * imgdim[2];
if (!(imgz = (float *) malloc (dimension * sizeof (float)))) errm (program);
if (!(imgp = (float *) malloc (dimension * sizeof (float)))) errm (program);
/***************************/
/* prepare 4dfp read/write */
/***************************/
fprintf (stdout, "Reading: %s\n", imgfile);
if (!(fp_img = fopen (imgfile, "rb"))) errr (program, imgfile);
sprintf (outroot, "%s_%s", imgroot, (p_flag) ? "p" : "log10p");
sprintf (outfile, "%s.4dfp.img", outroot);
fprintf (stdout, "Writing: %s\n", outfile);
if (!(fp_out = fopen (outfile, "wb"))) errw (program, outfile);
/***********/
/* process */
/***********/
for (j = 0; j < imgdim[3]; j++) {
if (eread (imgz, dimension, isbig, fp_img)) errr (program, imgfile);
for (i = 0; i < dimension; i++) {
q = (double) imgz[i];
defined = !isnan (q) && imgz[i] != (float) 1.e-37 && finite (q);
if (defined) {
if (two_sided) {
q = fabs (q);
imgp[i] = (p_flag) ? 2.*p_z (q) : (-1./M_LN10)*(lnp_z (q) + M_LN2);
} else {
if (q > 0) {
imgp[i] = (p_flag) ? p_z (q) : (-1./M_LN10)*lnp_z (q);
} else {
imgp[i] = (p_flag) ? 1.0 : 0.0;
}
}
} else {
imgp[i] = 1.e-37;
}
}
if (ewrite (imgp, dimension, control, fp_out)) errw (program, outfile);
}
if (fclose (fp_img)) errr (program, imgfile);
if (fclose (fp_out)) errw (program, outfile);
/*******/
/* ifh */
/*******/
if (Writeifh (program, outfile, &ifh, control)) errw (program, outroot);
/*******/
/* hdr */
/*******/
sprintf (command, "ifh2hdr %s", outroot);
status |= system (command);
/*******/
/* rec */
/*******/
startrece (outfile, argc, argv, rcsid, control);
catrec (imgfile);
endrec ();
free (imgz); free (imgp);
exit (status);
}
int main (int argc, char *argv[]) {
FILE *anafp;
char in1root[MAXL];
char in2root[MAXL];
char outroot[MAXL];
char imgfile[MAXL];
char program[MAXL], string[MAXL], *ptr;
struct dsr hdr;
short *img1, *img2, *imgo;
int xdim, ydim, zdim, dimension;
int img1max = 0, img2max = 0;
int img1min = 0, img2min = 0;
int swab_img1 = 0, swab_img2 = 0, swab_imgo = 0;
char orient, control = '\0';
int nbin = NBIN;
int *hist, *mrg1, *mrg2;
int histmax = 0;
int range1, range2;
int binwid1, binwid2;
int grid1, grid2;
short valmax = 0;
float ftmp;
int c, i, j, k;
/*********/
/* flags */
/*********/
int status = 0;
int debug = 0;
int do_grid = 1;
if (ptr = strrchr (argv[0], '/')) ptr++; else ptr = argv[0];
strcpy (program, ptr);
printf ("%s\n", rcsid);
/************************/
/* process command line */
/************************/
for (k = 0, i = 1; i < argc; i++) if (*argv[i] == '-') {
strcpy (string, argv[i]); ptr = string;
while (c = *ptr++) switch (c) {
case 'd': debug++; break;
case 'g': do_grid = 0; break;
case '@': control = *ptr++; *ptr = '\0'; break;
case 'r': j = atoi (ptr++);
ptr++; /* skip over ":" */
switch (j) {
case 1: getrangei (ptr, &img1min, &img1max); break;
case 2: getrangei (ptr, &img2min, &img2max); break;
default: usage (program); break;
} *ptr = '\0'; break;
}
} else switch (k) {
case 0: getroot (argv[i], in1root); k++; break;
case 1: getroot (argv[i], in2root); k++; break;
case 2: getroot (argv[i], outroot); k++; break;
}
if (k < 3) usage (program);
fprintf (stdout, "img1: %s\nimg2: %s\n", in1root, in2root);
sprintf (imgfile, "%s.hdr", in1root);
if (!(anafp = fopen (imgfile, "rb")) || fread (&hdr, sizeof (struct dsr), 1, anafp) != 1
|| fclose (anafp)) errr (program, imgfile);
if (hdr.hk.sizeof_hdr != sizeof (struct dsr)) {
printf ("converting %s byte order\n", in1root);
swab_hdr (&hdr);
swab_img1++;
}
if (hdr.dime.bitpix != 16) erri (program, imgfile);
xdim = hdr.dime.dim[1];
ydim = hdr.dime.dim[2];
zdim = hdr.dime.dim[3];
orient = hdr.hist.orient;
dimension = xdim * ydim * zdim;
sprintf (imgfile, "%s.hdr", in2root);
if (!(anafp = fopen (imgfile, "rb")) || fread (&hdr, sizeof (struct dsr), 1, anafp) != 1
|| fclose (anafp)) errr (program, imgfile);
if (hdr.hk.sizeof_hdr != sizeof (struct dsr)) {
printf ("converting %s byte order\n", in2root);
swab_hdr (&hdr);
swab_img2++;
}
if (hdr.dime.bitpix != 16) erri (program, imgfile);
if (xdim != hdr.dime.dim[1] || ydim != hdr.dime.dim[2] || zdim != hdr.dime.dim[3] || orient != hdr.hist.orient) {
fprintf (stderr, "%s: %s %s dimension/orientation mismatch\n", program, in1root, in2root);
exit (-1);
}
img1 = (short *) malloc (dimension * sizeof (short));
img2 = (short *) malloc (dimension * sizeof (short));
mrg1 = (int *) calloc (nbin, sizeof (int));
mrg2 = (int *) calloc (nbin, sizeof (int));
hist = (int *) calloc (nbin*nbin, sizeof (int));
imgo = (short *) malloc (nbin*nbin * sizeof (short));
if (!img1 || !img2 || !hist || !mrg1 || !mrg2 || !imgo) errm (program);
sprintf (imgfile, "%s.img", outroot); startrece (imgfile, argc, argv, rcsid, control);
sprintf (imgfile, "%s.img", in1root); catrec (imgfile);
printf ("Reading: %s\n", imgfile);
if (!(anafp = fopen (imgfile, "rb"))
|| fread (img1, sizeof (short), dimension, anafp) != dimension || fclose (anafp)) errr (program, imgfile);
if (swab_img1) for (i = 0; i < dimension; i++) swab2 ((char *) &img1[i]);
sprintf (imgfile, "%s.img", in2root); catrec (imgfile);
printf ("Reading: %s\n", imgfile);
if (!(anafp = fopen (imgfile, "rb"))
|| fread (img2, sizeof (short), dimension, anafp) != dimension || fclose (anafp)) errr (program, imgfile);
if (swab_img2) for (i = 0; i < dimension; i++) swab2 ((char *) &img2[i]);
if (!img1max && !img1min) {
img1max -32768; img1min = 32767;
for (i = 0; i < dimension; i++) {
if (img1[i] > img1max) img1max = img1[i];
if (img1[i] < img1min) img1min = img1[i];
}
} else {
for (i = 0; i < dimension; i++) {
if (img1[i] > img1max) img1[i] = img1max;
if (img1[i] < img1min) img1[i] = img1min;
}
}
range1 = img1max - img1min;
if (!img2max && !img2min) {
img2max -32768; img2min = 32767;
for (i = 0; i < dimension; i++) {
if (img2[i] > img2max) img2max = img2[i];
if (img2[i] < img2min) img2min = img2[i];
}
} else {
for (i = 0; i < dimension; i++) {
if (img2[i] > img2max) img2[i] = img2max;
if (img2[i] < img2min) img2[i] = img2min;
}
}
range2 = img2max - img2min;
fprintf (stdout, "img1: min=%6d\tmax=%6d\trange=%6d\n", img1min, img1max, range1);
fprintf (stdout, "img2: min=%6d\tmax=%6d\trange=%6d\n", img2min, img2max, range2);
sprintf (string, "before auto range adjust\n"); printrec (string);
sprintf (string, "img1: min=%6d\tmax=%6d\trange=%6d\n", img1min, img1max, range1); printrec (string);
sprintf (string, "img2: min=%6d\tmax=%6d\trange=%6d\n", img2min, img2max, range2); printrec (string);
for (i = 0; i < dimension; i++) {
k = (nbin * (img1[i] - img1min)) / range1;
if (k < nbin && k > 0) mrg1[k]++;
k = (nbin * (img2[i] - img2min)) / range2;
if (k < nbin && k > 0) mrg2[k]++;
}
for (k = 2; k < nbin; k++) {
mrg1[k] += mrg1[k - 1];
mrg2[k] += mrg2[k - 1];
}
if (debug) for (k = 0; k < nbin; k++) {
printf ("%6d %10.6f %10.6f\n", k,
(float) mrg1[k] / (float) mrg1[nbin - 1], (float) mrg2[k] / (float) mrg2[nbin - 1]);
}
for (i = 1; i < nbin; i++) if (((float) mrg1[i] / (float) mrg1[nbin - 1]) > CUM_D) break;
for (j = 1; j < nbin; j++) if (((float) mrg1[j] / (float) mrg1[nbin - 1]) > 1.0-CUM_D) break;
if (debug) printf ("img1: first_bin=%d\tlast_bin=%d\n", i, j);
img1min += (float) (range1 * i) / nbin;
range1 *= (float) (j - i) / nbin;
binwid1 = (float) range1 / nbin;
if (!binwid1) binwid1++;
range1 = binwid1 * nbin;
img1min += binwid1 - (img1min + range1) % binwid1;
for (i = 1; i < nbin; i++) if (((float) mrg2[i] / (float) mrg2[nbin - 1]) > CUM_D) break;
for (j = 1; j < nbin; j++) if (((float) mrg2[j] / (float) mrg2[nbin - 1]) > 1.0-CUM_D) break;
if (debug) printf ("img2: first_bin=%d\tlast_bin=%d\n", i, j);
img2min += (float) (range2 * i) / nbin;
range2 *= (float) (j - i) / nbin;
binwid2 = (float) range2 / nbin;
if (!binwid2) binwid2++;
range2 = binwid2 * nbin;
img2min += binwid2 - (img2min + range2) % binwid2;
fprintf (stdout, "img1: min=%6d\tmax=%6d\trange=%6d\tbinwidth=%d\n", img1min, img1min + range1, range1, binwid1);
fprintf (stdout, "img2: min=%6d\tmax=%6d\trange=%6d\tbinwidth=%d\n", img2min, img2min + range2, range2, binwid2);
sprintf (string, "after auto range adjust\n");
printrec (string);
sprintf (string, "img1: min=%6d\tmax=%6d\trange=%6d\tbinwidth=%d\n", img1min, img1min + range1, range1, binwid1);
printrec (string);
sprintf (string, "img2: min=%6d\tmax=%6d\trange=%6d\tbinwidth=%d\n", img2min, img2min + range2, range2, binwid2);
printrec (string);
if (!range1 || !range2) exit (-1);
for (k = 0; k < dimension; k++) {
i = (img1[k] - img1min) / binwid1;
j = (img2[k] - img2min) / binwid2;
if (i < 0 || i >= nbin || j < 0 || j >= nbin) continue;
hist[nbin * j + i]++;
if (!hist[nbin * j + i]) {
fprintf (stderr, "2Dhist: histogram bin overflow\n");
exit (-1);
}
if (hist[nbin * j + i] > histmax) histmax = hist[nbin * j + i];
}
fprintf (stdout, "maximum bin count=%d\n", histmax);
/***************************/
/* write histogram to imgo */
/***************************/
for (k = 0; k < nbin*nbin; k++) {
if (hist[k]) {
ftmp = 100 * log ((double) hist[k]);
imgo[k] = (short) ftmp;
} else imgo[k] = 0;
if (imgo[k] > valmax) valmax = imgo[k];
}
if (do_grid) {
grid1 = range1 / 10; grid1 /= 10; grid1 *= 10;
for (i = k = 0; i < nbin; k += grid1) {
i = (k - img1min) / binwid1;
if (i >= 0 && i < nbin) for (j = 0; j < nbin; j++) imgo[nbin * j + i] = valmax / 2;
}
sprintf (string, "img1: grid interval=%d\n", grid1); printrec (string);
grid2 = range2 / 10; grid2 /= 10; grid2 *= 10;
for (j = k = 0; j < nbin; k += grid2) {
j = (k - img2min) / binwid2;
if (j >= 0 && j < nbin) for (i = 0; i < nbin; i++) imgo[nbin * j + i] = valmax / 2;
}
sprintf (string, "img2: grid interval=%d\n", grid2); printrec (string);
}
swab_imgo = ((CPU_is_bigendian() != 0) && (control == 'l' || control == 'L'))
|| ((CPU_is_bigendian() == 0) && (control == 'b' || control == 'B'));
if (swab_imgo) for (i = 0; i < nbin*nbin; i++) swab2 ((char *) &imgo[i]);
sprintf (imgfile, "%s.img", outroot); fprintf (stdout, "Writing: %s\n", imgfile);
if (!(anafp = fopen (imgfile, "wb")) || fwrite (imgo, sizeof (short), nbin*nbin, anafp) != nbin*nbin
|| fclose (anafp)) errw (program, imgfile);
hdr.dime.dim[0] = 2;
hdr.dime.dim[1] = nbin;
hdr.dime.dim[2] = nbin;
hdr.dime.dim[3] = 1;
hdr.dime.datatype = 4;
hdr.dime.pixdim[1] = 1;
hdr.dime.pixdim[2] = 1;
hdr.dime.pixdim[3] = 1;
hdr.dime.glmax = valmax;
hdr.dime.glmin = 0;
hdr.hist.orient = 0;
if (swab_imgo) swab_hdr (&hdr);
sprintf (imgfile, "%s.hdr", outroot);
fprintf (stdout, "Writing: %s\n", imgfile);
if (!(anafp = fopen (imgfile, "wb"))
|| fwrite (&hdr, sizeof (struct dsr), 1, anafp) != 1 || fclose (anafp)) errw (program, imgfile);
free (img1); free (img2); free (imgo);
free (mrg1); free (mrg2);
free (hist);
endrec ();
exit (status);
}
int main (int argc, char **argv) {
/*************/
/* image I/O */
/*************/
FILE *fp_img, *fp_out;
IFH ifh;
char imgfile[MAXL], imgroot[MAXL];
char outfile[MAXL], outroot[MAXL] = "";
/**************/
/* processing */
/**************/
int imgdim[4], dimension, orient, isbig;
float voxdim[3];
float *imgr;
float thresh=0.0;
char control ='\0';
/***********/
/* utility */
/***********/
int c, i, k;
char *ptr, command[MAXL], program[MAXL];
/*********/
/* flags */
/*********/
int status = 0;
printf ("%s\n", rcsid);
setprog (program, argv);
/************************/
/* process command line */
/************************/
for (k = 0, i = 1; i < argc; i++) {
if (i > 1 && *argv[i] == '-') {
strcpy (command, argv[i]); ptr = command;
while ((c = *ptr++)) switch (c) {
case '@': control = *ptr++; *ptr = '\0'; break;
}
} else switch (k) {
case 0: thresh = atof (argv[i]); k++; break;
case 1: getroot (argv[i], imgroot); k++; break;
case 2: getroot (argv[i], outroot); k++; break;
}
}
if (k < 2) {
printf ("Usage: %s <flt> <file_4dfp> [outroot]\n", program);
printf (" option\n");
printf (" -@<b|l>\toutput big or little endian (default input endian)\n");
printf ("e.g., %s 90 pt349_study9to9\n", program);
printf ("e.g., %s 90 pt349_study9to9 pt349_study9to9z\n", program);
printf ("N.B.: default output 4dfp root is <file_4dfp>\"z\"\n");
exit (1);
}
sprintf (imgfile, "%s.4dfp.img", imgroot);
/***************************************/
/* create output filename if not given */
/***************************************/
if (!strlen (outroot)) sprintf (outroot, "%sz", imgroot);
sprintf (outfile, "%s.4dfp.img", outroot);
/*****************************/
/* get 4dfp input dimensions */
/*****************************/
if (get_4dfp_dimoe (imgfile, imgdim, voxdim, &orient, &isbig) < 0) errr (program, imgroot);
if (Getifh (imgfile, &ifh)) errr (program, imgroot);
if (!control) control = (isbig) ? 'b' : 'l';
dimension = imgdim[0] * imgdim[1] * imgdim[2];
/*****************/
/* alloc buffers */
/*****************/
if (!(imgr = (float *) malloc (dimension * sizeof (float)))) errm (program);
/***********/
/* process */
/***********/
if (!(fp_img = fopen (imgfile, "rb"))) errr (program, imgfile);
if (!(fp_out = fopen (outfile, "wb"))) errw (program, outfile);
fprintf (stdout, "Reading: %s\n", imgfile);
fprintf (stdout, "Writing: %s\n", outfile);
for (k = 0; k < imgdim[3]; k++) {
if (gread ((char *) imgr, sizeof (float), dimension, fp_img, isbig)) errr (program, imgfile);
for (i = 0; i < dimension; i++) if (imgr[i] < thresh) imgr[i] = 0.0;
if (gwrite ((char *) imgr, sizeof (float), dimension, fp_out, control)) errw (program, outfile);
}
fclose (fp_img);
fclose (fp_out);
/***************/
/* ifh and hdr */
/***************/
if (Writeifh (program, outfile, &ifh, control)) errw (program, outfile);
sprintf (command, "ifh2hdr %s", outroot); printf ("%s\n", command);
status = system (command);
/*******************/
/* create rec file */
/*******************/
startrece (outfile, argc, argv, rcsid, control);
catrec (imgfile);
endrec ();
free (imgr);
exit (status);
}