SUBROUTINE ALGSTB (IFIELD, SCRGRD, SCRWRK, DISKI, CNOSCI, DISKO, * CNOSCO, CHANEL, NCHAN, CATR, JBUFSZ, BUFF1, BUFF2, BUFF3, IRET) C----------------------------------------------------------------------- C! Interpolates model visibility from a grid and subtracts from uv data. C# UV Modeling AP-appl C----------------------------------------------------------------------- C; Copyright (C) 1995, 1997, 1999-2001, 2003, 2006, 2008-2010, 2012 C; Associated Universities, Inc. Washington DC, USA. C; C; This program is free software; you can redistribute it and/or C; modify it under the terms of the GNU General Public License as C; published by the Free Software Foundation; either version 2 of C; the License, or (at your option) any later version. C; C; This program is distributed in the hope that it will be useful, C; but WITHOUT ANY WARRANTY; without even the implied warranty of C; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the C; GNU General Public License for more details. C; C; You should have received a copy of the GNU General Public C; License along with this program; if not, write to the Free C; Software Foundation, Inc., 675 Massachusetts Ave, Cambridge, C; MA 02139, USA. C; C; Correspondence concerning AIPS should be addressed as follows: C; Internet email: aipsmail@nrao.edu. C; Postal address: AIPS Project Office C; National Radio Astronomy Observatory C; 520 Edgemont Road C; Charlottesville, VA 22903-2475 USA C----------------------------------------------------------------------- C ALGSTB interpolates model visibility data from a grid and subtracts C it from the observed visibilities. UV data may be in any sort order C If AP memory is large enough to hold all gridded model, ALGSTB runs C much faster. C Inputs: C IFIELD I Field number. C SCRGRD I /CFILES/ file number for grid file. C SCRWRK I /CFILES/ file number for work file C DISKI I Input file disk number for catalogd files, C .LE. 0 => /CFILES/ scratch file. C CNOSCI I Input file catalog slot number or /CFILES/ C scratch file number. C DISKO I Output file disk number for catalogd files, C .LE. 0 => /CFILES/ scratch file. C CNOSCO I Output file catalog slot number or /CFILES/ C scratch file number. C CHANEL I First channel number. C NCHAN I Number of channels to process. C CATR R(256) UV data catalog header record. C JBUFSZ I Size in bytes of buffers. Dimension of C BUFF1,2,3 must be at least 4096 words. C Inputs: from commons C LREC I length in words of vis record. C NVIS I number of vis records C FREQG D(*) Frequencies of IF and channels in same order C as occurs in the data. C Output: C BUFF1 R(*) Working buffer C BUFF2 R(*) Working buffer C BUFF3 R(*) Working buffer C IRET I Return code, 0 => ok, otherwise not. C The AP grid file must contain the gridded UV model for this pass. C The UV points are read in and the model is subtracted from them. C----------------------------------------------------------------------- INTEGER IFIELD, SCRGRD, SCRWRK, DISKI, CNOSCI, DISKO, CNOSCO, * CHANEL, NCHAN, JBUFSZ, IRET REAL BUFF1(*), BUFF2(*), BUFF3(*) C INTEGER CJTBSZ, MINT, TPBFMX C CJTBSZ = conj. table size C MINT = Interpol. support size. C TPBFMX = Temp Buffer size PARAMETER (CJTBSZ=4000, MINT=11, TPBFMX=20000) INTEGER VISRED, NIOUT, IDISK, ICNOSC, INDS(3), NX, NY, ILENBU, * IUMIN, IUMAX, USTOP, USTRT, IU, U, IVIS, ICONJ, I, NIO, LENBU, * FLIST(22), CNJPTR(CJTBSZ), M, MO2, LOCHAN, NCHGRD, MSGINC, * NROGRD, MXROGD, KAP, CX, VIS, UV, LLREC, MM, WORK, INDEX, LROW, * FLAG, VISOFF, NS, APSIZE, MAXREC, CNT, IFACT, ITEMP1, ITEMP2, * INPTR, OUTPTR, JNPTR, KNPTR, LNPTR, NPOINT, JNCS, EXCESS, * LOGRID, JNCF, LRPARM, ROWSIZ, IDATA, MAXU, RPASS, NRPASS, * NROWS, NXO2, EROW, ERRCNT, IXTEMP(3), MSGSAV, HIC, LOC, J, K, * IUFMAX, IULO, IUHI, LSTRT, LSTOP, NROW, END1, LUMAX, LUMIN, * NEED, UCOUNT, UTARG LOGICAL ALLROW, ONCE, DOROT, DOFLAG REAL XTEMP(7), FACT2(2), CATR(256), ZSCLV, ZSCLW, ZSCLU, * SCALU, SCALV, FFRAC, FRSTU, UUMAX, VVMAX, UIN, VIN, UMIN, UMAX, * TEMPBF(TPBFMX), UUU, UMAT(3,3), PMAT(3,3), DDX(3), * RMAT(3,3), DMAT(3,3), RULO, RUHI, UVWS(3,TPBFMX) DOUBLE PRECISION GFACT, MAXFRQ, XRA, XDEC, MINFRQ, MXFACT, MNFACT CHARACTER CSTOK*1 INCLUDE 'INCS:PUVD.INC' INCLUDE 'INCS:DMSG.INC' INCLUDE 'INCS:DGDS.INC' INCLUDE 'INCS:DMPR.INC' INCLUDE 'INCS:DUVH.INC' INCLUDE 'INCS:DHDR.INC' INCLUDE 'INCS:DFIL.INC' INCLUDE 'INCS:DDCH.INC' INCLUDE 'INCS:DSCD.INC' INCLUDE 'INCS:DAPM.INC' SAVE ONCE, ERRCNT DATA ONCE /.FALSE./, ERRCNT /0/ C----------------------------------------------------------------------- IRET = 0 DOFLAG = ERRCNT.EQ.0 C Rotate? DOROT = (ABS (SSROT).GT.1.0E-10) .OR. (ABS (CCROT-1.0).GT.1.0E-4) APSIZE = PSAPNW * 1024 NX = ABS (FLDSZ(1,IFIELD) * OSFX) + 0.1 NY = ABS (FLDSZ(2,IFIELD) * OSFY) + 0.1 ZSCLU = SCLUG(IFIELD) * OSFX ZSCLV = SCLVG(IFIELD) * OSFY ZSCLW = SCLWG(IFIELD) NXO2 = NX / 2 C Set AP Pointers; IFACT=cellsiz IFACT = 2 LROW = NY ROWSIZ = IFACT * LROW C Set up for APIO CALL FILL (22, 0, FLIST) FLIST(1) = LUNS(4) FLIST(2) = SCRGRD FLIST(5) = ROWSIZ FLIST(6) = NXO2 + 1 FLIST(9) = 1 FLIST(11) = FLIST(5) FLIST(12) = 1 FLIST(13) = JBUFSZ C Get un-compressed UV increments IF (DATDIV) CALL PRMUPD IF (COMPDT) THEN ITEMP1 = LREC ITEMP2 = NRPARM LREC = SCLREC NRPARM = SCRPRM END IF C Correlator scaling table. MSGSAV = MSGSUP MSGSUP = 31900 CALL GETCTL (CATR, FACT2, IRET) MSGSUP = MSGSAV IF (IRET.NE.0) GO TO 999 CSTOK = MSGTXT(1:1) NS = NSTOK CALL UVINCS (INCS, INCF, INCIF, NRPARM, LREC, JNCS, JNCF, * LRPARM, LLREC) C Set I/O visibility count ILENBU = ((MIN(JBUFSZ,TPBFMX*2) - 2 * NBPS) / 2) / LLREC - 2 ILENBU = MAX (ILENBU, 1) LENBU = ILENBU IDISK = DISKI ICNOSC = CNOSCI C Grab ap M = MINT MAXREC = 256 NEED = MAXREC*(LLREC+4) + 200*M + 30 + NCHAN + (NXO2+M)*ROWSIZ NEED = NEED / 1024 + 2 CALL QINIT (NEED, 0, KAP) IF ((KAP.EQ.0) .OR. (PSAPNW.EQ.0)) THEN IRET = 8 MSGTXT = 'ALGSTB UNABLE TO GET DESIRED MEMORY' CALL MSGWRT (8) GO TO 999 END IF APSIZE = 1024 * PSAPNW C Calc extra ap for interp func MAXREC = MIN (2048, (APSIZE/30)/(LLREC+4)) + 5 MAXREC = MAX (15, MAXREC) EXCESS = APSIZE - MAXREC*(LLREC+4) - 200*MINT - 30 - NCHAN C How big can interp func be? M = EXCESS / (ROWSIZ + 200) C M between mint/2 and mint M = MAX (MINT/2, MIN (M, MINT)) C M must be odd, round down M = (2 * ((M-1)/2)) + 1 MO2 = M / 2 C Extra ap goes to extra rows EXCESS = APSIZE - MAXREC*(LLREC+4) - 200*M - 30 - NCHAN MXROGD = (EXCESS/ROWSIZ) - 1 IF (MXROGD.LT.M) THEN IRET = 8 MSGTXT = 'ALGSTB UNABLE TO GET ENOUGH MEMORY' CALL MSGWRT (8) GO TO 999 END IF C Grid no more than all rows MXROGD = MIN (MXROGD, NXO2+M) C Set ap pointers LOGRID = APSIZE - ((MXROGD+1) * ROWSIZ) - 1 CX = LOGRID - (200 * (M+1)) - 1 MM = M FLAG = 1 IF ((KSTOK.EQ.3) .AND. (ICOR0.LE.0)) FLAG = -1 C model only IF (FACGRD(2).EQ.0.0) THEN UUU = 0.0 FACT2(1) = FACT2(1) * FACGRD(1) FACT2(2) = FACT2(2) * FACGRD(1) C Scale FACT2 by -FACGRD C data - model ELSE UUU = 1.0 FACT2(1) = -FACT2(1) * FACGRD(1) FACT2(2) = -FACT2(2) * FACGRD(1) END IF C If fft scale by 0.5 IF (DOFFT) THEN FACT2(1) = FACT2(1) * 0.5 FACT2(2) = FACT2(2) * 0.5 END IF C Prepare for bs loop DDX(1) = DXCG(IFIELD) DDX(2) = DYCG(IFIELD) DDX(3) = DZCG(IFIELD) CALL XYSHFT (RA, DEC, XSHIFT(IFIELD), YSHIFT(IFIELD), MAPROT, * XRA, XDEC) IF (DO3DIM) THEN CALL PRJMAT (RA, DEC, UVROT, XRA, XDEC, MAPROT, UMAT, PMAT) CALL RFILL (9, 0.0, RMAT) CALL RFILL (9, 0.0, DMAT) RMAT(1,1) = CCROT RMAT(1,2) = SSROT RMAT(2,1) = -SSROT RMAT(2,2) = CCROT RMAT(3,3) = 1 DO 20 I = 1,3 DO 15 J = 1,3 DO 10 K = 1,3 DMAT(I,J) = DMAT(I,J) + PMAT(I,K) * RMAT(K,J) 10 CONTINUE 15 CONTINUE 20 CONTINUE CALL PRJMUL (2, DDX, DMAT, DDX) ELSE CALL P2DMAT (RA, DEC, UVROT, XRA, XDEC, MAPROT, UMAT, PMAT) END IF C self defense DO 30 I = 1,3 DO 25 J = 1,3 IF (UMATS(I,J,1).NE.0.0) GO TO 35 25 CONTINUE 30 CONTINUE MSGTXT = 'ALGSTB: ROTATION MATRIX UMATS IS 0, FIELD 1' CALL MSGWRT (6) MSGTXT = 'ALGSTB: THIS IS A SERIOUS ERROR SINCE MFIELD > 1' IF (MFIELD.GT.1) CALL MSGWRT (7) CALL RCOPY (9, UMAT, UMATS) C Get maximum u 35 CALL UVPROT ('READ', IDISK, ICNOSC, LUNS(2), INDS(2), MFIELD, * UMATS, CCROT, SSROT, NVIS, LREC, ILENBU, JBUFSZ, BUFF1, NIO, * INPTR, FRSTU, DISKO, CNOSCO, IRET) IF (IRET.NE.0) GO TO 999 CALL ZCLOSE (LUNS(2), INDS(2), IRET) C Find Max Frequency MAXFRQ = FREQG(CHANEL) MINFRQ = FREQG(CHANEL) DO 40 I = 2,NCHAN BUFF3(I-1) = 0.0 IF (FREQG(CHANEL+I-1).GT.0.0D0) THEN MAXFRQ = MAX (MAXFRQ, FREQG(CHANEL+I-1)) MINFRQ = MIN (MINFRQ, FREQG(CHANEL+I-1)) BUFF3(I-1) = FREQG(CHANEL+I-1)/FREQG(CHANEL+I-2) - 1.0D0 END IF 40 CONTINUE C Scale by Max Freq. to cells MAXU = ABS (FRSTU * MAXFRQ / FREQ * ZSCLU) + 0.99 C Limit u to max that will fit MAXU = MIN (MAXU, NXO2) C Calc number needed NROGRD = MAXU + M C Do all rows fit in ap? ALLROW = MXROGD.GE.NROGRD C Number of rows in a pass NROWS = MIN (NROGRD, MXROGD) C If all rows fit, 1 pass IF (ALLROW) THEN NRPASS = 1 WRITE (MSGTXT,1040) NROWS, MXROGD C Else, how many row passes? ELSE NRPASS = (MAXU + 1)/(NROWS - M + 1) IF (NRPASS*(NROWS-M+1).LT.(MAXU+1)) NRPASS = NRPASS + 1 WRITE (MSGTXT,1041) NROWS, NROGRD END IF IF (.NOT.ONCE) CALL MSGWRT (2) VISRED = 0 LOCHAN = 1 NCHGRD = NCHAN LOC = CHANEL + LOCHAN - 1 HIC = LOC + NCHGRD - 1 IF (MFIELD.LE.1) THEN WRITE (MSGTXT,1045) CSTOK, LOC, HIC ELSE WRITE (MSGTXT,1046) IFIELD, CSTOK, LOC, HIC END IF CALL MSGWRT (2) C Determine where data starts. FLIST(10) = MIN (MAXU+MO2+1, NXO2+1) C Get frequency scaling factors. FFRAC = (MINFRQ / FREQ) - 1.0D0 GFACT = 1.0D0 / ((1.0D0 + FFRAC) * ZSCLU) MNFACT = ZSCLU * MINFRQ / FREQ MXFACT = ZSCLU * MAXFRQ / FREQ FFRAC = (MAXFRQ / FREQ) - 1.0D0 SCALU = FFRAC * ZSCLU + ZSCLU SCALV = FFRAC * ZSCLV + ZSCLV C Set limits on u,v - don't get C Within mint/2+1 of edge. UUMAX = ABS (((NX/2) - (MINT/2+1)) / SCALU) VVMAX = ABS (((NY/2) - (MINT/2+1)) / SCALV) C Setup ap griding constants FFRAC = (FREQG(LOCHAN+CHANEL-1) / FREQ) - 1.0D0 XTEMP(1) = (ZSCLU + FFRAC * ZSCLU) XTEMP(2) = (ZSCLV + FFRAC * ZSCLV) XTEMP(3) = DDX(1) / ZSCLU XTEMP(4) = DDX(2) / ZSCLV XTEMP(5) = DDX(3) + DDX(3)*FFRAC XTEMP(6) = 0.0 XTEMP(7) = 0.0 IXTEMP(1) = 0 IXTEMP(2) = LOGRID IXTEMP(3) = CX CALL QPUT (XTEMP, 0, 7, 2) CALL QPUT (IXTEMP, 7, 3, 1) C Correlator scaling table. CALL QPUT (FACT2, 16, NS, 2) CALL QPUT (UUU, 15, 1, 2) C Frequency scaling table. BUFF3(NCHGRD) = 0.0 CALL QPUT (BUFF3, 20, NCHGRD, 2) C Set interpolation tables CALL INTPFN (CX, M, BUFF3, JBUFSZ, IRET) IF (IRET.NE.0) GO TO 999 C Save space for 4 word work array. MAXREC = (CX - 20 - NS - NCHGRD) / (LLREC+4) - 5 C No more recs than conj table. IF (MAXREC.GT.CJTBSZ) MAXREC = CJTBSZ C More ap pointers. WORK = 20 + NCHGRD UV = WORK + 4 + (MAXREC * 4) C Correction for stokes. VISOFF = LRPARM + ((CHANEL-1) + (LOCHAN-1))*JNCF + (VOFF / INCS) * * JNCS VIS = UV + VISOFF C Set location of data inp ap IDATA = UV IUMAX = MAXU RPASS = 0 LUMAX = 10 * MAXU LUMIN = LUMAX + 1 C Row pass loop point 50 RPASS = RPASS + 1 IUMIN = MAX (IUMAX - (NROWS-M), 0) IUFMAX = -1000 LSTRT = USTRT LSTOP = USTOP C Load ALL rows USTRT = MAX (IUMIN - MO2, 0) USTOP = MIN (IUMAX+MO2, NXO2) C move ones previously loaded IF ((RPASS.GT.1) .AND. (USTOP.GE.LSTRT)) THEN C wait for AP to FINISH CALL QWAIT C must move from top to bottom NROW = USTOP - LSTRT + 1 DO 60 I = 1,NROW END1 = LOGRID + ((NROW-I)*ROWSIZ) EROW = LOGRID + ((USTOP-(IUMIN-MO2))*ROWSIZ) CALL QVMOV (END1, 1, EROW, 1, ROWSIZ) CALL QWAIT USTOP = USTOP - 1 60 CONTINUE C clear rest for gridding CALL QVCLR (LOGRID, 1, EROW-LOGRID) CALL QWAIT END IF C Load grided uv values in ap CALL APLOAD (USTRT, USTOP, IUMIN-MO2, ROWSIZ, LOGRID, APSIZE, * FLIST, BUFF2, IRET) IF (IRET.NE.0) GO TO 999 C When near end of rows IF (IUMIN.EQ.0) THEN DO 90 IU = 1, MO2 C Convert to decreasing u U = MO2 - IU + 1 C U=0 at lrow/2 C U<0 rows from complex cong u>0 C Index points to end of u row INDEX = LOGRID + ((U+MO2+1)*ROWSIZ) - IFACT C Erow points to start of -u row EROW = LOGRID + ((MO2-U)*ROWSIZ) CALL QCVCON (INDEX, -IFACT, EROW+IFACT, IFACT, LROW-1) C Index points to start same u row INDEX = INDEX - ROWSIZ + IFACT C Conjugate a single pixel CALL QCVCON (INDEX, IFACT, EROW, IFACT, 1) 90 CONTINUE END IF C Set min and max this pass UMAX = (IUMAX + 0.5) * GFACT UMIN = (IUMIN - 0.5) * GFACT OUTPTR = 1 INPTR = 1 ILENBU = MIN (LENBU, MAXREC) C Set output file name. CALL UVPREP ('WRIT', DISKO, CNOSCO, LUNS(3), INDS(3), NVIS, * LREC, ILENBU, JBUFSZ, BUFF3, NIOUT, OUTPTR, FRSTU, IRET) IF (IRET.NE.0) GO TO 999 NIOUT = ILENBU ILENBU = MIN (LENBU, MAXREC) C Prepare to read through data CALL UVPREP ('READ', IDISK, ICNOSC, LUNS(2), INDS(2), NVIS, * LREC, ILENBU, JBUFSZ, BUFF1, NIO, INPTR, FRSTU, IRET) IF (IRET.NE.0) GO TO 999 C Reset input to output file. IDISK = DISKO ICNOSC = CNOSCO C Count points this pass NPOINT = 0 UCOUNT = NIO UTARG = 1 C Loop forever, read all uvdata 100 CONTINUE IF (UCOUNT.GT.UTARG) THEN WRITE (MSGTXT,1100) UTARG CALL MSGWRT (2) UTARG = UTARG + 50000 END IF C Rotate, save init u,v,w JNPTR = INPTR DO 110 I =1,NIO UVWS(1,I) = BUFF1(JNPTR+ILOCU) UVWS(2,I) = BUFF1(JNPTR+ILOCU+1) UVWS(3,I) = BUFF1(JNPTR+ILOCU+2) CALL PRJMUL (1, BUFF1(JNPTR+ILOCU), UMAT, * BUFF1(JNPTR+ILOCU)) JNPTR = JNPTR + LREC 110 CONTINUE C Start read from beginning of uvs JNPTR = INPTR C Put uvdata back at beginning KNPTR = INPTR C Use start of output buffer LNPTR = OUTPTR C Count points this buffer CNT = 0 C Do all points in buffer DO 200 IVIS = 1,NIO C Input u, v values UIN = ABS (BUFF1(JNPTR+ILOCU)) VIN = ABS (BUFF1(JNPTR+ILOCV)) IULO = MNFACT * UIN + 0.5 IUHI = MXFACT * UIN + 0.5 RULO = MNFACT * UIN RUHI = MXFACT * UIN C uv outside range. IF ((UIN.GT.UUMAX) .OR. (VIN.GT.VVMAX)) THEN CALL UVLIMT (0.0, 1.0E20, UUMAX, VVMAX, IVIS, * UIN, VIN, ERRCNT) C Reset u to within range UIN = MAXU * GFACT UIN = MIN (UUMAX, UIN) * 0.99 C Put location back in buffer BUFF1(JNPTR+ILOCU) = UIN BUFF1(JNPTR+ILOCV) = 0.0 C Zero data CALL RFILL (LREC-VISOFF+2, 0.0, BUFF1(JNPTR+VISOFF-2)) END IF C If datum on current rows C IF (UIN.GT.UMIN .AND. (UIN.LE.UMAX.OR.RPASS.EQ.1)) THEN IF (((IUHI.LE.IUMAX) .OR. (RPASS.EQ.1)) .AND. * (IULO.GE.IUMIN) .AND. ((RPASS.EQ.1) .OR. * (IUHI.GT.LUMAX) .OR. (IULO.LT.LUMIN))) THEN C Keep count of number to process CNT = CNT + 1 C Store output point location CNJPTR(CNT) = LNPTR C If u neg. then flip IF (BUFF1(JNPTR+ILOCU).LT.0.0) THEN C Enter in cnjptr table. CNJPTR(CNT) = -LNPTR C Flip u, v, w, conjugate data. CALL UVCONJ (VISOFF, JNCF, NCHGRD, NSTOK, * JNCS, BUFF1(JNPTR)) C End if u < 0, conjugate END IF C If more than 1 pass IF (.NOT.ALLROW) THEN C Put data in buff for processing CALL COPY (LREC, BUFF1(JNPTR), BUFF1(KNPTR)) C Update output pointer KNPTR = KNPTR + LREC END IF C Else not in current rows ELSE IF (IULO.LT.IUMIN) IUFMAX = MAX (IUFMAX, IUHI) C Put in output buffer CALL COPY (LREC, BUFF1(JNPTR), BUFF3(LNPTR)) C End if on current rows END IF C Set new input and output pos JNPTR = JNPTR + LREC LNPTR = LNPTR + LREC C End for all vis recs read 200 CONTINUE C Keep track of total VISRED = VISRED + CNT C Count points in range each pass NPOINT = NPOINT + CNT C If points were found IF (CNT.GT.0) THEN C Wait for ap, then load into ap CALL QWR C Uncompress Vis and put in AP CALL BUFPUT (CNT, NRPARM, LREC, LLREC, IDATA, * BUFF1(INPTR), TEMPBF(1)) C Low row to ap IXTEMP(1) = IUMIN IXTEMP(2) = LOGRID CALL QPUT (IXTEMP, 7, 3, 1) CALL QWAIT CALL QUVIN (UV, VIS, WORK, LLREC, MM, LROW, NS, * JNCS, NCHGRD, JNCF, CNT, FLAG) CALL QWR C Read out interpolated data C If all data in ap IF (ALLROW) THEN C Get UVs from AP (maybe pack UV) CALL BUFGET (CNT, NRPARM, LREC, LLREC, IDATA, * BUFF3(OUTPTR), TEMPBF(1)) C Else get some data ELSE C Get UVs from AP (maybe pack UV) CALL BUFGET (CNT, NRPARM, LREC, LLREC, IDATA, * BUFF1(INPTR), TEMPBF(1)) JNPTR = INPTR C For all points DO 400 I = 1,CNT C Get output location of data LNPTR = ABS(CNJPTR(I)) C Move from input to output CALL COPY (LREC, BUFF1(JNPTR), BUFF3(LNPTR)) C Start location of next vis rec. JNPTR = JNPTR + LREC 400 CONTINUE C End if not all in ap END IF C For all points, conjugate DO 500 ICONJ = 1, CNT C If point was conjugated IF (CNJPTR(ICONJ).LT.0) THEN C Get position LNPTR = -CNJPTR(ICONJ) C Flip u, v, w, conjugate data. CALL UVCONJ (VISOFF, JNCF, NCHGRD, NSTOK, JNCS, * BUFF3(LNPTR)) END IF 500 CONTINUE C End if points this pass END IF C restore u,v,w JNPTR = OUTPTR DO 520 I = 1,NIO BUFF3(JNPTR+ILOCU) = UVWS(1,I) BUFF3(JNPTR+ILOCU+1) = UVWS(2,I) BUFF3(JNPTR+ILOCU+2) = UVWS(3,I) JNPTR = JNPTR + LREC 520 CONTINUE C Write all nio points read NIOUT = NIO C Write data to disk CALL UVDISK ('WRIT', LUNS(3), INDS(3), BUFF3, NIOUT, * OUTPTR, IRET) IF (IRET.NE.0) THEN WRITE (MSGTXT,1200) IRET GO TO 995 END IF C Read a new uvdata buffer CALL UVDISK ('READ', LUNS(2), INDS(2), BUFF1, NIO, INPTR, * IRET) IF (IRET.NE.0) THEN WRITE (MSGTXT,1300) IRET GO TO 995 END IF UCOUNT = UCOUNT + NIO C If more data, loop IF (NIO.GT.0) GO TO 100 C Jump here on end uv data C Write Diag messages ONLY once C Print only 10 Messages 675 IF (.NOT.ONCE) THEN WRITE(MSGTXT,1104,ERR=680) RPASS, IUMAX, IUMIN, NPOINT MSGINC = (NRPASS/10) + 1 680 IF (((RPASS/MSGINC)*MSGINC).EQ.RPASS) CALL MSGWRT (2) END IF C Finish write. NIOUT = 0 CALL UVDISK ('FLSH', LUNS(3), INDS(3), BUFF3, NIOUT, OUTPTR, * IRET) IF (IRET.NE.0) THEN WRITE (MSGTXT,1500) IRET, I GO TO 995 END IF C Close files CALL ZCLOSE (LUNS(2), INDS(2), IRET) CALL ZCLOSE (LUNS(3), INDS(3), IRET) LUMIN = IUMIN LUMAX = IUMAX C end of rows loop: do more? IF (IUFMAX.GT.0) THEN IUMAX = IUFMAX GO TO 50 END IF C Check that written all data read IF (NVIS.NE.VISRED) THEN WRITE (MSGTXT,1600) NVIS, VISRED CALL MSGWRT (8) END IF IF ((DOFLAG) .AND. (ERRCNT.GT.0)) THEN MSGTXT = '**************************************************' * // '*****' CALL MSGWRT (8) WRITE (MSGTXT,1601) ERRCNT CALL MSGWRT (8) MSGTXT = '**************************************************' * // '*****' CALL MSGWRT (8) END IF C re-set pointers to beginning C of the grid file. CALL APIO ('INIT', FLIST, LOGRID, BUFF2, IRET) IF (IRET.NE.0) THEN WRITE (MSGTXT,1400) IRET GO TO 995 END IF C Give up AP. CALL QRLSE C write diag messages once only C DEBUG C ONCE = .TRUE. C Close grid file. CALL APIO ('CLOS', FLIST, LOGRID, BUFF2, IRET) IF (COMPDT) THEN LREC = ITEMP1 NRPARM = ITEMP2 END IF GO TO 999 C Error 995 CALL MSGWRT (8) C 999 RETURN C----------------------------------------------------------------------- 1040 FORMAT ('ALGSTB: All ',I5,' Rows In AP (Max ',I5,')') 1041 FORMAT ('ALGSTB: Only',I5,' Rows In AP (Need ',I5,')') 1045 FORMAT ('ALGSTB: ',A1,'pol gridded model subtraction, chans',I5, * ' through',I5) 1046 FORMAT ('ALGSTB field',I5,1X,A1,'pol gridded model subtraction', * ' chns',I5,'-',I5) 1100 FORMAT ('ALGSTB: at visibility number',I12) 1104 FORMAT ('ALGSTB: Pass',I4,';',I5,'-',I4,' Cells, with',I9, * ' Pts') 1200 FORMAT ('ALGSTB: WRITE ERROR IN VISIBILITY FILE, IER=',I6) 1300 FORMAT ('ALGSTB: READ ERROR IN VISIBILITY FILE, IER=',I6) 1400 FORMAT ('ALGSTB: TROUBLE INIT GRID FILE, IER=',I5) 1500 FORMAT ('ALGSTB: ERROR',I5,' READING GRID ROW ',I5) 1600 FORMAT ('ALGSTB: WARNING! Misplaced Data, NVIS = ',I8, * ' WRITTEN =',I8) 1601 FORMAT ('ALGSTB:',I10,' POINTS FLAGGED FOR BEING OFF THE GRID') END