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decuslib10-01
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43,50127/matrix.f4
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00010 C EXECUTIVE ROUTINE FOR MATRIX INTERPRETIVE PROGRAM
00020 INTEGER FREZ,FRET
��00030 INTEGER OPLIST(60),WORD(15),ERROR,WORD1,BLANK,SAVNM(2)
��00040 COMMON /FF/ NFMX,ITAPE,NWMX
��00050 COMMON /XX/ ERROR
��00060 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
���00070 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
�00080 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
���00090 INTEGER CHAR(0/9)
����00100 DIMENSION FNUMB(10)
00110 C * * * * * * * * * * * * * * LIST OF OPERATIONS * * *
00120 DATA (OPLIST(I),I=1,5)/'ZERO','REMAR','PRINT','MAP','ENVEL'/
����������������00130 DATA (OPLIST(I),I=6,10)/'LOAD','DUPL','DELET','SCALE','MSCAL'/
����00140 DATA OPLIST(11) /'SQREL'/
�00150 DATA (OPLIST(I),I=12,16)/'INVEL','LOG','ADD','SUB','TRANS'/
��00160 DATA (OPLIST(I),I=17,20)/'MULT','TRMPY','SYMCK','SYMNV'/
00170 DATA (OPLIST(I),I=21,24)/'INVRT','STODG','RMVDG','IDADD'/
����00180 DATA (OPLIST(I),I=25,28)/'DGADD','DGSUB','DGPRE','DGPST'/
����00190 DATA (OPLIST(I),I=29,32)/'DGMPY','FORMK','FORMD','MERGE'/
����00200 DATA (OPLIST(I),I=33,36)/'STOSM','ADDSM','RMVSM','DELRC'/
����00210 DATA (OPLIST(I),I=37,40)/'SELCT','CHOL1','CHOL2','CHOL3'/
�������������������������������������������������00220 DATA (OPLIST(I),I=41,44)/'EIGEN','FUNGN','RESPN','LIST'/
00230 DATA (OPLIST(I),I=45,48)/'EDIT','GET','SAVE','FEM'/
00240 DATA OPLIST(49) /'RANK'/
��00250 DATA (CHAR(I),I=0,9) /'0','1','2','3','4','5','6','7',
��00260 1 '8','9'/
�00270 DATA BLANK/' '/
�00280 EXTERNAL SUBERR
����00290 C * * * * * * * * * * * * * * INITIALIZE BY ZEROING ARRAY * * *
��00300 C SET PSIZE TO 44 AND MAXIMUM IN MLIST TO 30K FOR MATRXB
00310 CALL PSIZE(23)
��00320 C CALL PSIZE(44)
����00330 CALL EXSIZE(SUBERR)
00340 NNUM=10
��00350 NSIZE=0
����00360 NUM=0
�00370 DO 2 I=1,4
���������00380 IADDR=FREZ(10)
00390 2 NME(I)=IADDR
��00400 INC1=NME(1)-LOC(NAME)
���00410 INC2=NME(2)-LOC(NCOL)
���00420 INC3=NME(3)-LOC(NROW)
���00430 INC4=NME(4)-LOC(NN)
00440 NOPER=49
���00450 TYPE 4
00460 4 FORMAT(' MATRIX REV. 7 JULY 1969'///)
�00470 5 NF=0
�00480 NW=1
��00490 ITAPE=0
��00500 NFMX=10
��00510 NWMX=15
����00520 ERROR=0
����00530 DO 50 I=1,5
00540 WORD(I)=BLANK
���00550 FNUMB(I)=0
�00560 50 CONTINUE
�00570 DO 55 I=6,10
����00580 FNUMB(I)=0
�00590 55 CONTINUE
�00600 TYPE 6
00610 6 FORMAT(' *'$)
���������������������������00620 CALL FREAD(NW,WORD,NF,FNUMB)
���00630 WORD1=WORD(1)
���00640 I=1
���00650 8 IF(NOPER-I)9,10,10
��00660 9 TYPE 9001
�00670 9001 FORMAT(' ILLEGAL COMMAND'/)
00680 GO TO 5
����00690 10 IF(OPLIST(I).EQ.WORD1) GO TO 15
���00700 I=I+1
�00710 GO TO 8
����00720 15 IDITO=I
��00730 GO TO (100,5,120,140,160,180,200,220,240,260,280,300,
���00740 1 320,340,350,380,400,420,440,460,480,500,520,540,560,
��00750 2 580,600,620,640,660,680,700,720,740,760,780,800,
�00760 3 820,840,860,880,1000,1020,2000,190,2020,2040,2060,2080), IDITO
���00770 C * * * * * * ZEROS A MATRIX * * * * * *
����������������������00780 100 NAMA=WORD(2)
�00790 IF ((NW.NE.2).OR.(NF.NE.2)) GO TO 995
��00800 NR=FNUMB(1)
00810 NC=FNUMB(2)
00820 MPYTAG=0
���00830 CALL MLIST(NAMA)
00840 IF(ERROR.GT.0) GO TO 990
��00850 DO 110 I=1,NR*NC
00860 A(I+INCA)=0.0
���00870 110 CONTINUE
00880 GO TO 5
����00890 C * * * * * * * * * * * * * * MATRIX PRINT - PRINT* * *
00900 120 NAMA=WORD(2)
�00910 CALL MFIND(NAMA)
00920 IF(ERROR.GT.0) GO TO 990
��00930 CALL PRINT(NAMA)
00940 GO TO 5
����00950 C * * * * * * * * * * * * * * MATRIX MAP - MAP* * *
����00960 140 NAMA=WORD(2)
�00970 SCAL1=FNUMB(1)
��00980 CALL MFIND(NAMA)
���������������00990 IF(ERROR.GT.0) GO TO 990
��01000 CALL MTXMAP(SCAL1)
�01010 GO TO 5
����01020 C * * * * * * * * * * * * * * ENVELOPE VALUES OF MATRIC - ENVEL* * *
��01030 160 SCAL1=FNUMB(2)
����01040 IF(NF.EQ.1) TYPE 1601
01050 1601 FORMAT(' INTERVAL SCALAR OMITTED'/)
01060 IF ((NW.LT.2).OR.(NF.LT.2)) GO TO 995
��01070 NAMA=WORD(2)
����01080 KCOL=FNUMB(1)
���01090 CALL MFIND(NAMA)
01100 IF(ERROR.GT.0) GO TO 990
��01110 NA=INCA
��01120 IF(KCOL) 998,163,164
�01130 163 NRA=NR
��01140 NCA=NC
01150 GO TO 165
��01160 164 NCA=NR
���01170 NRA=NC
01180 165 NAMB=WORD(3)
���������������������01190 IF(NAMB.EQ.BLANK) GO TO 175
����01200 NR=1
��01210 NC=NRA
01220 CALL MLIST(NAMB)
01230 IF(ERROR.GT.0) GO TO 990
��01240 NBB=1
�01250 GO TO 176
��01260 175 NBB=0
���01270 176 NR=NRA
���01280 NC=NCA
���01290 CALL ENVEL(NA,NBB,SCAL1,KCOL)
����01300 GO TO 5
����01310 C * * * * * * * * * * * * * * LOAD MATRIX - LOAD * * *
�01320 180 IF (NW.LT.2.OR.NF.NE.2) GO TO 995
�01330 IF (NW.EQ.3) GO TO 184
��01340 NAMA=WORD(2)
��01350 GO TO 185
01360 184 IF (WORD(2).NE.'TAPE') GO TO 9
����01370 NAMA=WORD(3)
��01380 ITAPE=1
���������������������������01390 185 NR=FNUMB(1)
��01400 NC=FNUMB(2)
01410 CALL MLIST(NAMA)
01420 IF(ERROR.GT.0) GO TO 990
��01430 CALL LOAD
��01440 GO TO 5
����01450 C * * * * * * * EDIT AN ELEMENT OF A MATRIX * * * * * * * *
���01460 190 IF (NW.NE.2.OR.NF.NE.1) GO TO 995
�01470 NAMA=WORD(2)
��01480 CALL MFIND(NAMA)
���01490 IF (ERROR.GT.0) GO TO 990
����01500 NTIM=FNUMB(1)
�01510 IF (NTIM.LT.1) GO TO 996
01520 TYPE 1900
01530 1900 FORMAT(5X,'ROW-COL COORDINATES - VALUE'/)
���01540 DO 195 I=1,NTIM
����01550 NW=-3
����01560 NF=3
01570 NWMX=1
����������01580 NFMX=10
��01590 CALL FREAD(NW,WORD,NF,FNUMB)
�01600 NREL=FNUMB(1)
�01610 NCEL=FNUMB(2)
�01620 IF (NREL.GT.NR.OR.NCEL.GT.NC) GO TO 901
01630 NA=(NREL-1)*NC+NCEL+INCA
01640 A(NA)=FNUMB(3)
01650 195 CONTINUE
�01660 GO TO 5
��01670 C * * * * * * * * * * * * * * DUPLICATE MATRIX - DUPL * * *
�01680 200 NAMA=WORD(2)
�01690 IF (NW.NE.3) GO TO 995
��01700 NAMB=WORD(3)
����01710 IGO=1
�01720 CALL MFIND(NAMA)
01730 IF(ERROR.GT.0) GO TO 990
��01740 NB=INCA
��01750 CALL MLIST(NAMB)
01760 IF(ERROR.GT.0) GO TO 990
�����������������01770 NS=NR*NC
���01780 DO 210 I=1,NS
���01790 A(I+INCA)=A(I+NB)
����01800 210 CONTINUE
01810 GO TO 5
����01820 C * * * * * * * * * * * * * * DELETE MATRIX - DELETE * * *
��01830 220 NTIME=NW-3+1
�01840 DO 225 I=1,NTIME
01850 NAMA=WORD(2+I)
��01860 CALL DELETE(NAMA)
����01870 IF(ERROR.GT.0) GO TO 990
��01880 225 CONTINUE
01890 GO TO 5
����01900 C * * * * * * * * * * * * * * SCALAR MULTIPLICATION - SCALE * * *
01910 240 NAMA=WORD(2)
�01920 IF ((NW.NE.2).OR.(NF.NE.1)) GO TO 995
��01930 SCAL1=FNUMB(1)
��01940 241 CALL MFIND(NAMA)
��01950 IF(ERROR.GT.0) GO TO 990
��01960 DO 245 I=1,NR*NC
�����01970 A(I+INCA)=SCAL1*A(I+INCA)
�01980 245 CONTINUE
01990 GO TO 5
����02000 C * * * * * * * * * * * * * * MULTIPLY A*B(NR,NC) - MSCALE * * *
�02010 260 IFLAG=1
�02020 IF ((NW.NE.3).OR.(NF.NE.2)) GO TO 995
��02030 NAMA=WORD(2)
����02040 NAMB=WORD(3)
����02050 NR=FNUMB(1)
02060 NC=FNUMB(2)
02070 IF(NR*NC) 909,272,273
02080 272 NR=1
����02090 NC=1
��02100 273 NRB=NR
��02110 NCB=NC
02120 CALL MFIND(NAMB)
02130 IF(ERROR.GT.0) GO TO 990
��02140 IF((NRB.GT.NR).OR.(NCB.GT.NC)) GO TO 909
�02150 IF(NR*NC.EQ.0) GO TO 909
��02160 SCAL1=A(INCA+(NRB-1)*NC+NCB)
�02170 GO TO 241
�����������������02180 C * * * * * * * * * * * * * * SQUARE ROOT OF EACH ELEMENT - SQREL * * *
����02190 280 IFLAG=1
�02200 281 NAMA=WORD(2)
�02210 CALL MFIND(NAMA)
02220 IF(ERROR.GT.0) GO TO 990
��02230 CALL ELEMNT(IFLAG)
���02240 IF (ERROR.NE.0) GO TO 990
����02250 GO TO 5
����02260 C * * * * * * * * * * * * * * INVERSION OF EACH ELEMENT - INVEL * * *
�02270 300 IFLAG=2
�02280 GO TO 281
��02290 C * * * * * * * * * * * * * * LOG OF MATRIX - LOG * * *
02300 320 IFLAG=3
�02310 GO TO 281
��02320 C * * * * * * * * * * * * * * ADD OR SUBTRACT MATRICES - ADD , SUB * * *
���02330 340 TAG=1.0
�02340 GO TO 351
�������02350 350 TAG=-1.
�02360 351 NAMA=WORD(2)
�02370 NAMB=WORD(3)
����02380 IF (NW.NE.3) GO TO 995
��02390 CALL MFIND(NAMA)
02400 IF(ERROR.GT.0) GO TO 990
��02410 NA=INCA
��02420 NRA=NR
02430 NCA=NC
02440 CALL MFIND(NAMB)
02450 IF(ERROR.GT.0) GO TO 990
��02460 IF ((NR.NE.NRA).OR.(NC.NE.NCA)) GO TO 901
���02470 NS=NR*NC
���02480 DO 360 I=1,NS
���02490 A(NA+I)=A(NA+I)+TAG*A(INCA+I)
02500 360 CONTINUE
02510 GO TO 5
����02520 C * * * * * * * * * * * * * * MATRIX TRANSPOSE - TRANS * * *
02530 380 NAMA=WORD(2)
�02540 IF (NW.NE.3) GO TO 995
��02550 NAMB=WORD(3)
���������02560 CALL MFIND(NAMA)
02570 IF(ERROR.GT.0) GO TO 990
��02580 NRA=NR
02590 NR=NC
�02600 NB=INCA
��02610 NC=NRA
02620 CALL MLIST(NAMB)
02630 IF(ERROR.GT.0) GO TO 990
��02640 CALL TRANS(NB)
02650 GO TO 5
����02660 C * * * * * * * * * * * * * * MATRIX RIGHT MULTIPLY - MULT * * *
�02670 400 MPYTAG=FNUMB(1)
���02680 ITRMPY=0
���02690 410 NAMA=WORD(2)
�02700 CALL MFIND(NAMA)
02710 IF(ERROR.GT.0) GO TO 990
��02720 NA=INCA
��02730 NRA=NR
02740 NCA=NC
02750 IF (NW.NE.4) GO TO 995
��02760 NAMB=WORD(3)
����02770 NAMC=WORD(4)
����02780 CALL MFIND(NAMB)
��������������������02790 IF(ERROR.GT.0) GO TO 990
��02800 NRB=NR
02810 NCB=NC
02820 NB=INCA
��02830 NR=NRA
02840 IF(ITRMPY.EQ.0) GO TO 411
�02850 NR=NCA
02860 NCA=NRA
����02870 411 IF (NCA.NE.NRB) GO TO 901
�02880 413 CALL MLIST(NAMC)
��02890 IF(ERROR.GT.0) GO TO 990
��02900 CALL MULT(NA,NB,NCA,NCB,ITRMPY)
02910 MPYTAG=0
���02920 ITRMPY=0
���02930 GO TO 5
����02940 C * * * * * * * * * * PREMULTIPLY BY TRANSPOSE (AND ADD) -TRMPY
����02950 420 MPYTAG=FNUMB(1)
���02960 ITRMPY=1
���02970 GO TO 410
��02980 C * * * * * * * * * * * * * * *SYMMETRY CHECK * * * *
����02990 440 L=1
03000 441 NAMA=WORD(2)
������03010 SCAL1=FNUMB(1)
��03020 442 CALL MFIND(NAMA)
��03030 IF(ERROR.GT.0) GO TO 990
��03040 IF (NR.NE.NC) GO TO 945
�03050 IF(SCAL1) 443,443,445
03060 443 SCAL1=ABS(A(INCA+1)*1.0E-06)
03070 445 IFLAG=0
�03080 CALL SYMCHK(SCAL1,IFLAG)
��03090 IF(IFLAG) 908,455,450
03100 450 IF(L-1) 908,5,901
�03110 455 GO TO (5,465,822,885), L
����03120 C * * * * * * * * * * * *INVERSION OF SYMETRIC MATRIX * *
03130 460 L=2
03140 GO TO 441
��03150 465 NA=INCA
�03160 NRA=NR
03170 467 NAMB=WORD(3)
�03180 IF(NAMB.EQ.BLANK) GO TO 470
����03190 CALL MFIND(NAMB)
03200 IF(ERROR.GT.0) GO TO 990
���������������������������03210 IF(NR.EQ.NRA) GO TO 470
���03220 ERROR=1
����03230 GO TO 990
��03240 470 NC=0
����03250 471 CALL SYMINV(NA,SCAL1)
���03260 IF(ERROR.GT.0) GO TO 990
��03270 GO TO 5
����03280 C * * * * * * * * * * * * * *MATRIX INVERSION * * *
�03290 480 NAMA=WORD(2)
�03300 SCAL1=FNUMB(1)
��03310 482 CALL MFIND(NAMA)
��03320 IF(ERROR.GT.0) GO TO 990
��03330 NA=INCA
����03340 NRA=NR
03350 IF (NR.NE.NC) GO TO 945
�03360 NAMB=WORD(3)
����03370 IF(NAMB.EQ.BLANK) GO TO 490
����03380 CALL MFIND(NAMB)
03390 IF(ERROR.GT.0) GO TO 990
��03400 IF(NR.EQ.NRA) GO TO 492
���03410 ERROR=1
������������������������03420 GO TO 990
��03430 490 NC=0
����03440 492 CALL INVERT(NA,SCAL1)
��03450 IF(ERROR.GT.0) GO TO 990
��03460 GO TO 5
����03470 C * * * * * * * * * * * * * STORE ROW (B) ON DIAGONAL OF (A) -STODG
03480 500 NAMA=WORD(2)
�03490 NAMB=WORD(3)
����03500 IF (NW.NE.3) GO TO 995
��03510 CALL MFIND(NAMA)
03520 IF(ERROR.GT.0) GO TO 990
��03530 K=INCA+1
���03540 IF (NR.NE.NC) GO TO 945
�03550 NCA=NC
03560 CALL MFIND(NAMB)
03570 IF(ERROR.GT.0) GO TO 990
��03580 IF (NR.NE.1) GO TO 901
��03590 IF (NC.NE.NCA) GO TO 901
03600 DO 510 I=1,NC
�03610 A(K)=A(I+INCA)
����������03620 K=K+NCA+1
��03630 510 CONTINUE
03640 GO TO 5
����03650 C * * * * * * *REMOVE ROW(B) FROM DIAGONAL OF (A) - RMVDG
03660 520 NAMA=WORD(2)
�03670 NAMB=WORD(3)
����03680 IF (NW.NE.3) GO TO 995
��03690 CALL MFIND(NAMA)
03700 IF(ERROR.GT.0) GO TO 990
��03710 IF (NR.NE.NC) GO TO 945
�03720 NR=1
��03730 CALL MLIST(NAMB)
03740 IF(ERROR.GT.0) GO TO 990
��03750 NB=INCA
��03760 CALL MFIND(NAMA)
03770 K=INCA+1
���03780 DO 525 I=1,NC
�03790 A(I+NB)=A(K)
��03800 K=K+NC+1
���03810 525 CONTINUE
03820 GO TO 5
����������������������������������������������������������������03830 C * * * * * *ADDITION OF SCALAR TIMES IDENTITY MATRIX - IDADD
�03840 540 NAMA=WORD(2)
�03850 IF ((NW.NE.2).OR.(NF.NE.1)) GO TO 995
��03860 SCAL1=FNUMB(1)
��03870 CALL MFIND(NAMA)
03880 IF(ERROR.GT.0) GO TO 990
��03890 IF (NR.NE.NC) GO TO 945
�03900 K=1+INCA
�03910 DO 545 I=1,NR
���03920 A(K)=A(K)+SCAL1
�03930 K=K+NC+1
�03940 545 CONTINUE
03950 GO TO 5
����03960 C * * * * ADDITION OR SUBTRACTION OF DIAGONAL MATRIX - DGADD,DGSUB
�03970 560 TAG=1.0
�03980 561 NAMA=WORD(2)
�03990 NAMB=WORD(3)
����04000 IF (NW.NE.3) GO TO 995
��04010 CALL MFIND(NAMA)
���������������04020 IF(ERROR.GT.0) GO TO 990
��04030 NA=INCA
��04040 IF (NR.NE.NC) GO TO 945
�04050 NCA=NC
04060 CALL MFIND(NAMB)
04070 IF(ERROR.GT.0) GO TO 990
��04080 IF (NR.NE.1) GO TO 901
��04090 IF (NC.NE.NCA) GO TO 901
04100 K=1+NA
���04110 DO 565 I=1,NC
�04120 A(K)=A(K)+TAG*A(I+INCA)
�04130 K=K+NC+1
���04140 565 CONTINUE
04150 GO TO 5
����04160 580 TAG=-1.0
04170 GO TO 561
��04180 C * * * *PREMULTIPLICATION BY DIAGONAL MATRIX - DGPRE * * *
���04190 600 IFLAG=1
�04200 601 NAMA=WORD(2)
�04210 NAMB=WORD(3)
����04220 IF (NW.NE.3) GO TO 995
������������04230 CALL MFIND(NAMA)
04240 IF(ERROR.GT.0) GO TO 990
��04250 NA=INCA
��04260 NRA=NR
04270 NCA=NC
04280 CALL MFIND(NAMB)
04290 IF(ERROR.GT.0) GO TO 990
��04300 IF (NR.NE.1) GO TO 901
��04310 GO TO (610,611,612),IFLAG
�04320 610 IF(NC-NRA) 901,615,901
�04330 611 IF(NC-NCA) 901,615,901
�04340 612 IF(NRA-1) 901,611,901
��04350 615 CALL DGMPY(NA,NRA,NCA,IFLAG)
�04360 GO TO 5
����04370 C * * * * * * * * *POSTMULTIPLICATION BY DIAGONAL MATRIX DGPST
04380 620 IFLAG=2
�04390 GO TO 601
��04400 C * * * * * * * * * *MULTIPLY TWO DIAGONAL MATRICES * * * *
���04410 640 IFLAG=3
���������������������04420 GO TO 601
��04430 C * * * *FORM TWO DIMENSIONAL BEAM STIFFNESS MATRIX(2X2,3X3,4X4)
���04440 660 NAMA=WORD(2)
�04450 IF ((NW.NE.2).OR.(NF.LT.1)) GO TO 995
��04460 NR=FNUMB(1)
04470 NC=FNUMB(2)
04480 IF((NR.LT.0).OR.(NR.GT.4)) GO TO 903
04490 IF(NR-1) 671,671,672
�04500 671 NR=2
����04510 672 NTYPE=NR
04520 IF(NC) 908,673,674
���04530 673 NC=1
����04540 674 N=NC
����04550 NR=N*NTYPE
�04560 NC=NR
�04570 CALL MLIST(NAMA)
04580 IF(ERROR.GT.0) GO TO 990
��04590 CALL FORMK(NTYPE,N)
��04600 IF(ERROR) 990,5,990
��04610 C * * * *FORM BEAM MATRIX FOR DIRECT STIFFNESS MERGING(4X4,6X6)
��������������04620 680 NAMA=WORD(2)
�04630 IF ((NW.NE.2).OR.(NF.NE.2)) GO TO 995
��04640 NTYPE=FNUMB(1)
��04650 N=FNUMB(2)
�04660 IF(.NOT.(NTYPE.EQ.4.OR.NTYPE.EQ.6.AND.N.GE.0)) GO TO 995
04670 IF(N.LE.0) N=1
��04680 NR=NTYPE
���04690 NC=NR
�04700 DO 685 I=1,5
����04710 NPLAC=I
����04720 CALL GET(NAMA,I,IC)
��04730 IF(IC.EQ.BLANK) GO TO 686
�04740 685 CONTINUE
04750 686 NDIG=1
��04760 IF(N.GE.10) NDIG=2
���04770 IF((NPLAC+NDIG).GT.5) NPLAC=6-NDIG
��04780 J=0
���04790 NEND=N
04800 NTIME=N/10
�04810 IF(NTIME.EQ.0) GO TO 688
�04820 NTIME=NTIME+1
���04830 NPLAC=NPLAC+1
���04840 687 J=J+1
�������������04850 CALL PUT(NAMA,NPLAC-1,CHAR(J-1))
����04860 NEND=N-(J-1)*10
�04870 IF(NEND.GT.9) NEND=9
�04880 IF(J.EQ.1) GO TO 688
�04890 CALL PUT(NAMA,NPLAC,CHAR(0))
���04900 CALL MLIST(NAMA)
04910 IF(ERROR.GT.0) GO TO 990
��04920 IF(NEND.EQ.0) GO TO 692
���04930 688 DO 690 I=1,NEND
���04940 ICHAR=CHAR(I)
���04950 CALL PUT(NAMA,NPLAC,ICHAR)
04960 CALL MLIST(NAMA)
04970 IF(ERROR.GT.0) GO TO 990
��04980 690 CONTINUE
04990 IF(NTIME.EQ.0) GO TO 692
��05000 IF(J-NTIME) 687,692,692
���05010 692 CALL FORMKD(NTYPE,N)
���05020 IF(ERROR)990,5,990
���05030 C * * * * * * * * * * * * * * * * *MATRIX MERGE * * *
���������05040 700 IF(.NOT.(NW.EQ.3.AND.NF.EQ.1)) GO TO 995
���05050 K=FNUMB(1)
�05060 NAMA=WORD(2)
����05070 NAMB=WORD(3)
����05080 IF(K.EQ.0) GO TO 903
�05090 CALL MFIND(NAMA)
05100 IF(ERROR.GT.0) GO TO 990
��05110 NA=INCA
����05120 NRA=NR
05130 NCA=NC
05140 CALL MFIND(NAMB)
05150 IF(ERROR.GT.0) GO TO 990
��05160 IF((NR.GT.100).OR.(NC.GT.100)) GO TO 901
�05170 CALL MERGE(NA,NRA,NCA,K)
05180 IF(ERROR) 990,5,990
��05190 C * * * * * * * * * * * * * STORE SUBMATRIX * * * * * *
��05200 720 NTAG=1
��05210 721 IF ((NW.NE.3).OR.(NF.NE.2)) GO TO 995
��05220 J=FNUMB(1)
�05230 K=FNUMB(2)
����������������05240 NAMB=WORD(3)
����05250 CALL MFIND(NAMB)
05260 IF(ERROR.GT.0) GO TO 990
��05270 GO TO 770
��05280 C * * * * * * * * * * * * * * * * ADD SUBMATRIX * * * *
��05290 740 NTAG=-1
�05300 GO TO 721
��05310 C * * * * * * * * * * * * * * * * * * REMOVE SUBMATRIX * * *
��05320 760 IF ((NW.NE.3).OR.(NF.NE.4)) GO TO 995
��05330 NAMB=WORD(3)
����05340 J=FNUMB(1)
�05350 K=FNUMB(2)
�05360 NR=FNUMB(3)
05370 NC=FNUMB(4)
05380 NTAG=0
05390 CALL MLIST(NAMB)
05400 IF(ERROR.GT.0) GO TO 990
��05410 770 NB=INCA
�05420 NRB=NR
05430 NCB=NC
05440 NAMA=WORD(2)
����05450 CALL MFIND(NAMA)
�������������������������05460 IF(ERROR.GT.0) GO TO 990
��05470 CALL STOSM(NB,NRB,NCB,J,K,NTAG)
05480 IF(ERROR.GT.0) GO TO 990
��05490 GO TO 5
����05500 C * * * * * DELETION OF NR ROWS AND NC COLUMNS FROM MATRIX *
��05510 780 IF(.NOT.(NW.EQ.3.AND.(NF.EQ.1.OR.NF.EQ.2))) GO TO 995
05520 NAMA=WORD(2)
����05530 NAMB=WORD(3)
����05540 NRD=FNUMB(1)
����05550 IF(NF.EQ.2) GO TO 790
05560 K=1
���05570 NCD=NRD
����05580 GO TO 795
��05590 790 NCD=FNUMB(2)
�05600 K=0
���05610 795 IF((NRD.GT.100).OR.(NCD.GT.100)) GO TO 901
�05620 CALL DELRC(NAMA,NRD,NCD,NAMB,K)
05630 IF(ERROR) 990,5,990
����������������������������������������������������05640 C * * * * * * * * SELECT EVERY NTH VALUE IN A ROW MATRIX
�05650 800 IF ((NW.NE.3).OR.(NF.LE.0)) GO TO 995
��05660 N=FNUMB(1)
�05670 M=FNUMB(2)
�05680 NAMA=WORD(2)
����05690 NAMB=WORD(3)
����05700 IF(N.LE.0.OR.M.LE.0) GO TO 908
�05710 CALL MFIND(NAMA)
05720 IF(ERROR.GT.0) GO TO 990
��05730 NA=INCA+M
05740 IF(NR-1) 901,813,811
�05750 811 IF (NC.NE.1) GO TO 901
��05760 NTMP=NR
����05770 NR=NC
�05780 NC=NTMP
����05790 813 NC=1+(NC-M)/N
05800 IF(NC.LT.M) GO TO 901
05810 CALL MLIST(NAMB)
05820 IF(ERROR.GT.0) GO TO 990
��05830 DO 815 I=1,NC
������������������������������������05840 A(I+INCA)=A(NA)
����05850 NA=NA+N
��05860 815 CONTINUE
05870 GO TO 5
����05880 C = = = = = = EIGENVALUE,RESPONSE,AND SUPPORTING OPERATIONS = = =
��05890 C * * * * CHOLESKI RIGHT DECOMPOSITION (UPPER TRIANGULAR) * * *
����05900 820 L=3
05910 IF (NW.NE.3) GO TO 995
��05920 NAMB=WORD(3)
����05930 GO TO 441
��05940 822 CALL MLIST(NAMB)
��05950 IF(ERROR.GT.0) GO TO 990
��05960 NB=INCA
����05970 CALL MFIND(NAMA)
05980 CALL DECOM(NB)
��05990 IF(ERROR) 990,5,990
��06000 C * * * * * * * * * * * * * * * * * * * CHOLESKI REDUCTION * * :
���06010 840 IFLAG=0
�������������������������������06020 841 IF(.NOT.(NW.EQ.2.OR.NW.EQ.3)) GO TO 995
06030 SCAL1=FNUMB(1)
��06040 NAMA=WORD(2)
����06050 CALL MFIND(NAMA)
06060 IF(ERROR.GT.0) GO TO 990
��06070 NA=INCA
����06080 IF (NR.NE.NC) GO TO 945
�06090 NRA=NR
06100 IF(NW.EQ.2) GO TO 845
06110 NAMB=WORD(3)
����06120 CALL MFIND(NAMB)
06130 IF(ERROR.GT.0) GO TO 990
��06140 IF (NRA.NE.NR) GO TO 901
06150 GO TO 846
��06160 845 NC=0
����06170 846 CALL CHSOLV(NA,IFLAG,SCAL1)
��06180 IF(ERROR)5,5,990
06190 C * * * * * * * * CHOLESKI BACK SUBSITUTION * * *
���06200 860 IFLAG=1
�06210 GO TO 841
�������������������������������������06220 C * * * * * * * EIGENVALUES AND EIGENVECTORS * * * * * * * * * * *
�06230 880 L=4
06240 IF ((NW.NE.5).OR.(NF.LE.0)) GO TO 995
��06250 M=FNUMB(1)
�06260 SCAL1=FNUMB(2)
��06270 NAMA=WORD(2)
����06280 GO TO 442
��06290 885 N=NR
����06300 NR=1
��06310 NC=N
��06320 NAMD=WORD(5)
����06330 CALL MLIST(NAMD)
06340 ND=INCA
��06350 IF(ERROR.GT.0) GO TO 990
��06360 NR=IABS(M)
�06370 NAMC=WORD(4)
����06380 CALL MLIST(NAMC)
06390 IF(ERROR.GT.0) GO TO 990
��06400 NE=INCA
����06410 CALL MFIND(NAMA)
06420 NA=INCA
����06430 NAMB=WORD(3)
����06440 CALL MFIND(NAMB)
�������������������������06450 IF(ERROR.GT.0) GO TO 990
��06460 IF (NR.NE.1) GO TO 901
��06470 IF (N.NE.NC) GO TO 901
��06480 CALL EIGEN(A(NA+1),A(NE+1),A(ND+1),N,M,N)
���06490 IF(ERROR) 5,5,990
����06500 C * * * * * * * * FUNCTION GENERATION * * * * * * * * *
��06510 1000 IF ((NW.NE.3).OR.(NF.NE.2)) GO TO 995
��06520 NAMA=WORD(2)
����06530 NAMB=WORD(3)
����06540 N=FNUMB(1)
�06550 SCAL1=FNUMB(2)
��06560 NR=1
��06570 NC=N
��06580 CALL MLIST(NAMB)
06590 IF(ERROR.GT.0) GO TO 990
��06600 NB=INCA
��06610 CALL MFIND(NAMA)
06620 IF(ERROR.GT.0) GO TO 990
��06630 IF (NC.NE.2) GO TO 901
�������06640 NS=NR*NC
���06650 CALL FUNGN(NB,N,NS,SCAL1)
����06660 IF(ERROR)5,5,990
06670 C * * * * * * * * * RESPONSE* * * * * * * * * * * * * * * * *
06680 1020 IF ((NW.NE.5).OR.(NF.NE.4)) GO TO 995
��06690 NAMA=WORD(2)
����06700 NAMB=WORD(3)
����06710 NAMC=WORD(4)
����06720 NAMD=WORD(5)
����06730 N=FNUMB(1)
�06740 K=FNUMB(2)
�06750 SCAL1=FNUMB(3)
��06760 SCAL2=FNUMB(4)
��06770 IF((K.LT.0).OR.(K.GT.2)) GO TO 995
��06780 CALL MFIND(NAMA)
06790 IF(ERROR.GT.0) GO TO 990
��06800 NA=INCA
��06810 M=NC
��06820 IF (NR.NE.1) GO TO 901
��06830 CALL MFIND(NAMC)
�������������������������06840 IF(ERROR.GT.0) GO TO 990
��06850 L=NC
06860 NTAG=1
���06870 IF (NR.EQ.1) NTAG=0
06880 NC=(NC-1)/N
06890 NR=M
��06900 NRA=INCA
�06910 CALL MLIST(NAMD)
06920 IF(ERROR.GT.0) GO TO 990
��06930 ND=INCA
����06940 CALL MFIND(NAMB)
06950 IF(ERROR.GT.0) GO TO 990
��06960 IF ((NC.NE.1).OR.(NR.NE.M)) GO TO 901
��06970 CALL RESPON(A(NA+1),A(NRA+1),A(ND+1),M,N,L,SCAL1,SCAL2,NTAG,K)
��06980 IF(ERROR) 5,5,990
����06990 C * * * * * * * * * * * * * LIST NAMES OF MATRICES
��07000 2000 NS=NSIZE
����07010 TYPE 2001, NUM,NS
�������������������������������������������������07020 2001 FORMAT(1X,I3,' MATRICES DEFINED, USING A TOTAL OF',
�07030 1 I6,' WORDS OF STORAGE'/)
�07040 IF (NUM.EQ.0) GO TO 5
���07050 DO 2010 I=1,NUM
�07060 NAMA=NAME(I+INC1)
����07070 CALL MFIND(NAMA)
07080 TYPE 2002,NAMA,NR,NC
�07090 2002 FORMAT(2X,A5,'(',I3,',',I3,')')
�07100 2010 CONTINUE
����07110 TYPE 2012
��07120 2012 FORMAT(/)
���07130 GO TO 5
����07140 C * * * * * * * * * * * GET MATRIX FILE * * * * * * * * * * *
07150 2020 IF ((NW.NE.2).OR.(NF.NE.0)) GO TO 995
��07160 CALL MGET(WORD(2))
�07170 IF (ERROR.NE.0) GO TO 990
����07180 GO TO 5
����������������������07190 C * * * * * * * * * SAVE ALL MATRICES * * * * * * * * * * * * *
����07200 2040 IF ((NW.EQ.3).AND.(NF.EQ.0)) GO TO 2050
07210 IF ((NW.EQ.2).AND.(NF.EQ.1)) GO TO 2042
07220 GO TO 995
07230 C * * * * * * * * SAVE "N" MATRICES * * * * * * * * * * *
07240 2042 NV=FNUMB(1)
���07250 CALL MSAVE(WORD(2),NV)
��07260 IF (ERROR.NE.0) GO TO 990
����07270 GO TO 5
��07280 2050 IF (WORD(2).NE.'ALL') GO TO 995
���07290 NV=NUM
���07300 CALL MSAVE(WORD(3),NV)
��07310 GO TO 5
��07320 C * * * * * * * * GENERATION OF FIXED END MOMENTS MATRIX * * *
���������������07330 2060 IF(NW.NE.2.OR.NF.GT.1) GO TO 995
07340 IF(NF.EQ.0) FNUMB(1)=1.
���07350 NAMA=WORD(2)
����07360 NC=1
��07370 NTIME=FNUMB(1)
��07380 NR=4*NTIME
�07390 CALL MLIST(NAMA)
07400 IF(ERROR.GT.0) GO TO 990
��07410 CALL FIXEM(NTIME)
����07420 GO TO 5
����07430 C * * * * * * * * * * * RANK OF MATRIX * * * * * * * * * *
����07440 2080 IF(NW.NE.2) GO TO 995
�07450 NAMA=WORD(2)
����07460 SCAL1=-99999.
���07470 GO TO 482
��07480 C * * * * * * * * * * END OF COMMANDS FOR NOW * * : : * * *
��07490 C * * * * * * * * * * * *ERROR MESSAGES * * * * *
���07500 901 ERROR=1
�07510 GO TO 990
����������������������07520 903 ERROR=2
�07530 GO TO 990
��07540 908 ERROR=8
�07550 GO TO 990
��07560 909 ERROR=9
�07570 GO TO 990
��07580 945 TYPE 946, NAMA
����07590 946 FORMAT(2X,' MATRIX ',A5,' IS NOT SQUARE'/)
�07600 GO TO 5
����07610 990 CALL SUBERR
��07620 GO TO 5
����07630 995 TYPE 996
07640 996 FORMAT(2X,' ERROR IN COMMAND STRING'/)
07650 GO TO 5
����07660 998 TYPE 999
07670 999 FORMAT(2X,' ERROR IN MATRIX LOGIC, COMMAND STOPPED'/)
07680 GO TO 5
����07690 END
���
��00010 C***********************************************************************
00020 C FREE FORMAT READ SUBROUTINE
��������������������������������00030 C***********************************************************************
00040 SUBROUTINE FREAD(NA,ALPHA,NFLT,FNUMB)
����00050 COMMON /FF/ NFMX,IPT,NWMX
�00060 DIMENSION LINE(73),ALPHA(1),FNUMB(1)
00070 INTEGER A,BLANK,E,POINT,Z,COMMA,PLUS
00080 INTEGER ALPHA, ZERO
��00090 LOGICAL DIGIT
���00100 DATA A/'A'/
00110 DATA Z/'Z'/
00120 DATA E/'E'/
00130 DATA BLANK/' '/
�00140 DATA POINT/'.'/
�00150 DATA MINUS/'-'/
�00160 DATA COMMA/','/
�00170 DATA ZERO/'0'/
��00180 DATA NINE/'9'/
��00190 DATA PLUS/'+'/
��������������������������������00200 DIGIT(N) = N .GE. ZERO .AND. N .LE. NINE
�00210 IF (NFMX.EQ.0) NFMX=100
�00220 IF (NWMX.EQ.0) NWMX=5
���00230 8 NI=0
�00240 NF=0
�00250 10 I=0
���00260 IF(NA.GE.0.OR.IPT.GT.0) GO TO 120
���00270 TYPE 111
���00280 111 FORMAT('+#'$)
00290 120 CALL BCOUT(LINE,73)
����00300 ACCEPT 20, LINE
�00310 20 FORMAT(73A1)
��00320 1 SIGN=1.
����00330 PSIGN=1.0
��00340 X=0
���00350 15 I=I+1
����00360 IC=LINE(I)
�00370 IF(IC.EQ.BLANK.OR.IC.EQ.COMMA) GO TO 1000
00380 IF(IC.GE.A.AND.IC.LE.Z) GO TO 100
���00390 IF(DIGIT(IC)) GO TO 300
�������������00400 IF(IC.EQ.MINUS) GO TO 200
�00410 IF(IC.EQ.POINT) GO TO 350
�00420 11 IF(IPT.GT.0) GO TO 15
���00430 GO TO 1003
�00440 C ALPHA CHARACTER ENVOUNTERED - BUILD WORD (S)
�00450 100 IF(NA) 11,11,101
00460 101 J=I
���00470 NI=NI+1
����00480 102 I=I+1
�00490 IC=LINE(I)
�00500 IF(IC.EQ.BLANK.OR.IC.EQ.COMMA) GO TO 110
�00510 GO TO 102
��00520 110 K=I-1
�00530 JJ = 1
00540 DO 115 II = J,K
�00550 IF ((NI+JJ/5).GT.(NWMX+1)) GO TO 116
���00560 CALL PUT(ALPHA(NI),JJ,LINE(II))
00570 115 JJ = JJ+1
����00580 116 NI=NI+(K-J)/5
���00590 IF(ALPHA(1).EQ.'REMAR') GO TO 999
��������00600 GO TO 1000
�00610 C MINUS ENCOUNTERED - SET SIGN NEGATIVE
���00620 200 SIGN=-1.
���00630 I=I+1
�00640 IC=LINE(I)
�00650 IF(DIGIT(IC)) GO TO 300
���00660 IF(IC.EQ.POINT) GO TO 350
�00670 GO TO 11
���00680 300 IF(NFLT) 11,301,301
����00690 C DIGIT ENCOUNTERED - BUILD NUMBER
���00700 301 J=I
��00710 302 I=I+1
�00720 IC=LINE(I)
�00730 IF(DIGIT(IC)) GO TO 302
���00740 IF(IC.EQ.POINT) GO TO 324
�00750 IF(.NOT.(IC.EQ.BLANK.OR.IC.EQ. COMMA)) GO TO 11
����00760 IGOTO=1
����00770 GO TO 325
��00780 324 IGOTO=2
����00790 325 K=I-1
����������������00800 CALL ATSI(LINE,J,K,X)
00810 X=X*SIGN
���00820 GO TO (900,400),IGOTO
00830 350 X=0
���00840 I=I+1
�00850 IC=LINE(I)
�00860 GO TO 500
��00870 400 I=I+1
�00880 IC=LINE(I)
�00890 IF(IC.EQ.BLANK) GO TO 900
�00900 IF(IC.EQ.E) GO TO 700
00910 500 IF(.NOT.DIGIT(IC)) GO TO 11
����00920 J=I
���00930 502 I=I+1
�00940 IC=LINE(I)
�00950 IF(DIGIT(IC)) GO TO 502
���00960 IF(IC.EQ.E) GO TO 524
00970 IF(.NOT.(IC.EQ.BLANK.OR.IC.EQ.COMMA)) GO TO 11
00980 IGOTO=1
����00990 GO TO 525
��01000 524 IGOTO=2
�������������������01010 525 K=I-1
�01020 CALL ATSI(LINE,J,K,DEC)
���01030 X=X+SIGN*(DEC/10.**(K-J+1))
����01040 GO TO (900,700),IGOTO
01050 700 I=I+1
�01060 IC=LINE(I)
�01070 IF(IC.EQ.MINUS) GO TO 701
�01080 IF(IC.NE.PLUS) GO TO 720
��01090 I=I+1
�01100 IC=LINE(I)
�01110 GO TO 720
��01120 701 PSIGN=-1.
����01130 I=I+1
�01140 IC=LINE(I)
�01150 720 J=I
���01160 IF(IC.EQ.'+') GO TO 722
���01170 IF(.NOT.DIGIT(IC)) GO TO 11
����01180 722 I=I+1
�01190 IC=LINE(I)
�01200 IF(DIGIT(IC)) GO TO 722
���01210 IF(.NOT.(IC.EQ.BLANK.OR.IC.EQ.COMMA)) GO TO 11
����������01220 K=I-1
�01230 IF(K-J-1) 725,725,11
�01240 725 CALL ATSI(LINE,J,K,PW)
����01250 NP=PW*PSIGN
01260 X=X*10.**NP
01270 900 NF=NF+1
����01280 IF (NF.GT.NFMX) GO TO 1000
01290 FNUMB(NF)=X
01300 1000 IF(I-70) 1,1,1001
����01310 1001 IF(NF-NFLT) 1002,999,1005
�01320 1002 IF(IPT.GT.0) GO TO 10
�01330 1003 NLT=NFLT-NF
�01340 TYPE 1004, NF,NLT
����01350 1004 FORMAT(1X,I4,' VALUES STORED ** ENTER',I4,/)
��01360 GO TO 10
���01370 1005 IF(NA.GE.0.OR.IPT.GT.0) GO TO 999
����01380 NLT=NF-NFLT
01390 TYPE 1006, NLT
���������������������������������������������������������01400 1006 FORMAT(1X,I3,' TOO MANY VALUES ENTER & OMITTED'/)
���01410 999 NFLT=NF
����01420 NA=NI
�01430 NFMX=0
01440 NWMX=0
01450 RETURN
01460 END
���
��00010 SUBROUTINE ATSI(IN,IBEG,IEND,VALUE)
����00020 DIMENSION IN(73),NUM(10)
00030 DATA(NUM(I),I=1,5)/'1','2','3','4','5'/
00040 DATA(NUM(I),I=6,10)/'6','7','8','9','0'/
����00050 VALUE=0
��00060 IF(IEND.LT.IBEG) GO TO 200
���00070 DO 100 I=IBEG,IEND
�00080 IC=IN(I)
�00090 DO 10 J=1,10
��00100 IF(.NOT.IC.EQ.NUM(J)) GO TO 10
�������������������00110 IF(J-10)9,8,8
�00120 8 J=0
�00130 9 VALUE=VALUE*10+J
���00140 GO TO 100
00150 10 CONTINUE
�00160 100 CONTINUE
00170 GO TO 999
00180 200 VALUE=0
��00190 999 RETURN
��00200 END
���
��00010 C**********************************************************
���00020 C SUBROUTINE TO BLANK OUT INPUT ARRAY
����00030 C*************************************************************
00040 SUBROUTINE BCOUT(LINE,IC)
�00050 INTEGER BLANK
���00060 DIMENSION LINE(1)
����00070 DATA BLANK/' '/
�00080 DO 100 I=1,IC
���00090 LINE(I)=BLANK
���00100 100 CONTINUE
����������00110 RETURN
00120 END
���
��00010 SUBROUTINE MFIND(MM)
�00020 C***********************************************************************
00030 C SUBROUTINE TO FIND LOCATION AND SIZE OF MATRIX MM
��00040 C***********************************************************************
00050 INTEGER ERROR
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
00080 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
���00090 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00100 I=1
���00110 5 IF (NUM-I) 40,10,10
��00120 10 IF (NAME(I+INC1)-MM) 20,30,20
������������00130 20 I=I+1
�00140 GO TO 5
����00150 30 NR=NROW(I+INC3)
�00160 NC=NCOL(I+INC2)
�00170 NX=NN(I+INC4)
���00180 INCA=NX-LOC(A)
��00190 GO TO 101
��00200 40 ERROR=2
��00210 101 RETURN
00220 END
���
��00010 SUBROUTINE MLIST(MM)
�00020 C***********************************************************************
00030 C SUBROUTINE TO LIST MATRIX
�00040 C***********************************************************************
00050 INTEGER ERROR,FREZ
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
������������������������������00080 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
���00090 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00100 I=1
���00110 5 IF (NUM-I) 30,10,10
��00120 10 IF (NAME(I+INC1)-MM) 20,25,20
��00130 20 I=I+1
�00140 GO TO 5
����00150 C***********************************************************************
00160 C CHECK FOR POSSIBLE MULTIPLY AND ADD
�00170 C***********************************************************************
00180 25 IF(MPYTAG) 52,29,26
��00190 26 TYPE 100
�00200 IF(NR-NROW(I+INC3)) 54,27,54
���00210 27 IF(NC-NCOL(I+INC2)) 54,28,54
������������������00220 28 NX=NN(I+INC4)
���00230 GO TO 60
���00240 29 ERROR=4
��00250 GO TO 60
���00260 30 NUM=NUM+1
��00270 IF (NUM-101) 45,40,45
00280 40 ERROR=6
����00290 GO TO 60
���00300 45 NSIZE=NSIZE+NR*NC
����00310 C SET LIMIT TO 30K FOR MATRXB
��00320 C IF(30000-NSIZE) 50,65,65
�00330 IF (9000-NSIZE) 50,65,65
��00340 50 ERROR=5
����00350 NSIZE=NSIZE-NR*NC
����00360 NUM=NUM-1
��00370 GO TO 60
���00380 65 IF (NUM.LE.NNUM) GO TO 31
�00390 CALL MSTOR
�00400 31 NX=FREZ(NR*NC)
��00410 NROW(NUM+INC3)=NR
����00420 NCOL(NUM+INC2)=NC
��������������00430 NAME(NUM+INC1)=MM
����00440 NN(NUM+INC4)=NX
�00450 INCA=NX-LOC(A)
��00460 GO TO 60
���00470 MPYTAG=0
���00480 52 ERROR=8
��00490 GO TO 60
���00500 54 ERROR=1
��00510 GO TO 60
���00520 60 RETURN
00530 100 FORMAT(' THE MULTIPLICATION RESULT WILL BE ADDED TO THE MATRIX',
��00540 1' IN FIELD C'///)
����00550 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO FIND MAXIMUM VALUES IN ROWS ( OR COLUMNS) OF MATRIX
�00030 C***********************************************************************
����������00040 SUBROUTINE ENVEL(NA,NBB,SCAL1,KCOL)
�00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00080 DO 80 I=1,NR
����00090 AMAX=0.0
���00100 TIM =SCAL1
�00110 IF(KCOL) 10,10,15
����00120 10 K=(I-1)*NC+1
����00130 GO TO 20
���00140 15 K=I
���00150 20 DO 50 J=1,NC
����00160 XA=ABS(A(NA+K))
�00170 IF(AMAX-XA) 25,30,30
�00180 25 AMAX=XA
����00190 TMAX=TIM
���00200 30 IF(KCOL) 35,35,40
����00210 35 K=K+1
�00220 GO TO 50
���00230 40 K=K+NR
00240 50 TIM = TIM + SCAL1
�������������������00250 IF(NBB) 60,60,55
00260 55 A(INCA+I)=AMAX
��00270 60 IF(KCOL) 65,65,70
����00280 65 TYPE 100, I, TMAX, AMAX
���00290 GO TO 80
���00300 70 TYPE 101, I, TMAX, AMAX
���00310 80 CONTINUE
���00320 TYPE 102
���00330 102 FORMAT(/)
����00340 RETURN
00350 100 FORMAT(' ROW NUMBER',I4,3X,'INTERVAL = ',1PE12.5,3X,
�00360 1 'MAXIMUM VALUE = ',1PE12.5)
���00370 101 FORMAT(14H COLUMN NUMBER,I4,2X,10HINTERVAL = ,1PE11.4,2X,16HMAXIMU
00380 1M VALUE = ,1PE12.5)
��00390 END
���
��00010 SUBROUTINE DELETE(MM)
�����������������������������������������������������������������00020 C***********************************************************************
00030 C SUBROUTINE TO DELETE MATRIX MM
�00040 C***********************************************************************
00050 INTEGER ERROR,FRET
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
00080 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
���00090 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00100 I=1
���00110 5 IF (NUM-I) 60,10,10
��00120 10 IF ( NAME(I+INC1)-MM) 20,30,20
�00130 20 I=I+1
�00140 GO TO 5
����00150 30 NX=NN(I+INC4)
������������������00160 NUM=NUM-1
��00170 NS=NROW(I+INC3)*NCOL(I+INC2)
���00180 NSIZE=NSIZE-NS
��00190 IF (NUM.EQ.0) GO TO 50
����00200 IF (I.GT.NUM) GO TO 50
����00210 DO 40 J=I,NUM
���00220 NAME(J+INC1)=NAME(J+INC1+1)
����00230 NROW(J+INC3)=NROW(J+INC3+1)
����00240 NCOL(J+INC2)=NCOL(J+INC2+1)
����00250 40 NN(J+INC4)=NN(J+INC4+1)
���00260 50 CALL FRET(NS,NX)
00270 90 RETURN
00280 60 ERROR=2
����00290 GO TO 90
���00300 END
���
��00010 C***********************************************************************
00020 C MATRIX TRANSPOSE
��������������������00030 C***********************************************************************
00040 SUBROUTINE TRANS(NB)
�00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00080 K=1
���00090 DO 100 I=1,NR
���00100 L=I
���00110 DO 100 J=1,NC
���00120 A(K+INCA)=A(L+NB)
����00130 L=L+NR
00140 100 K=K+1
�00150 RETURN
00160 END
���
��00010 C***********************************************************************
00020 C MATRIX MULTIPLICATION
��������������������������������������������������������������������������������00030 C***********************************************************************
00040 SUBROUTINE MULT(NA,NB,NCA,NCB,ITRMPY)
����00050 INTEGER ERROR
���00060 COMMON /X/ ERROR
00070 COMMON /YY/ INCA
���00080 COMMON /Z/ A(1)
����00090 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
���00100 K=1
���00110 DO 200 I=1,NR
���00120 DO 200 J=1,NCB
��00130 MM=J
��00140 C***********************************************************************
00150 C CHECK FOR POSSIBLE PREMULTIPLICATION BY TRANSPOSE
��00160 C***********************************************************************
�����00170 IF(ITRMPY) 998,30,40
�00180 30 NN=(I-1)*NCA+1
��00190 GO TO 50
���00200 40 NN=I
��00210 C***********************************************************************
00220 C CHECK FOR POSSIBLE MULTIPLY AND ADD
�00230 C***********************************************************************
00240 50 IF(MPYTAG) 998,60,70
�00250 60 A(INCA+K)=0.0
���00260 70 DO 100 L=1,NCA
��00270 A(INCA+K)=A(INCA+K)+A(NA+NN)*A(NB+MM)
��00280 IF(ITRMPY) 998,80,90
�00290 80 NN=NN+1
����00300 GO TO 100
��00310 90 NN=NN+NR
���00320 100 MM=MM+NCB
��00330 200 K=K+1
���������������������00340 GO TO 999
��00350 998 ERROR=8
�00360 999 RETURN
��00370 END
���
��00010 SUBROUTINE SUBERR
����00020 C***********************************************************************
00030 C ERROR PRINT OUT SUBROUTINE
00040 C***********************************************************************
00050 INTEGER ERROR
���00060 COMMON /XX/ ERROR
����00070 COMMON /ZZ/ NUM
�00080 DATA NCT/0/
00090 IF (ERROR.EQ.0) GO TO 5
���00100 GO TO (1,2,3,4,5,6,7,8,9,10),ERROR
��00110 1 TYPE 101
��00120 GO TO 100
��00130 2 TYPE 102
���00140 GO TO 100
����������������������00150 3 TYPE 103
���00160 GO TO 100
��00170 4 TYPE 104
���00180 GO TO 100
��00190 5 TYPE 105
���00200 IF (NCT.NE.0) GO TO 60
����00210 NCT=NCT+1
��00220 TYPE 113
���00230 TYPE 111
���00240 CALL PSIZE(24)
��00250 GO TO 100
��00260 60 TYPE 112
���00270 STOP
��00280 6 TYPE 106
���00290 GO TO 100
��00300 7 TYPE 107
���00310 GO TO 100
��00320 8 TYPE 108
���00330 GO TO 100
��00340 9 TYPE 109
���00350 GO TO 100
��00360 10 TYPE 110
���00370 100 RETURN
00380 101 FORMAT (2X' MATRICES INCOMPATIBLE'/)
�����00390 102 FORMAT (2X' MATRIX UNDEFINED'/)
����00400 103 FORMAT (2X' OPERATION UNDEFINED'/)
�00410 104 FORMAT (2X' MATRIX PREVIOUSLY DEFINED'/)
�00420 105 FORMAT (2X'STORAGE EXCEEDED'/)
�00430 106 FORMAT (2X' OVER 100 MATRICES IN CORE'/ )
���00440 107 FORMAT (27H ILLEGAL TAPE USED )
�00450 108 FORMAT (2X' STRICTLY POSITIVE NUMBER HAS TAKEN ON NEGATIVE',
����00460 1 ' VALUE'/)
����00470 109 FORMAT (2X' SCALAR UNDEFINED'/)
00480 110 FORMAT(2X,' INVALID ARITHMETIC OPERATION ATTEMPTED'/)
���00490 111 FORMAT(2X,'PROTECT MATRICES WITH A "SAVE" '/)
�����������������������������������������00500 112 FORMAT(2X,'ERROR EXIT'/)
��00510 113 FORMAT(2X,'DELETE ALL MATRICES NOT IN USE IMMEDIATELY!')
00520 END
���
��00010 C***********************************************************************
00020 C PRINT OPERATION
�00030 C***********************************************************************
00040 SUBROUTINE PRINT(NAME)
����00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00080 DIMENSION NCOLL(5)
���00090 TYPE 102,NAME,NR,NC
��00100 DO 50 M=1,NC,5
��00110 NN=NC-M
����00120 IF (NN-4) 40,40,35
��������00130 35 NN=4
��00140 40 MM=NN+1
����00150 DO 45 N=1,MM
����00160 45 NCOLL(N)=M-1+N
��00170 TYPE 101, (NCOLL(N),N=1,MM)
����00180 DO 50 N=1,NR
����00190 NL=M+(N-1)*NC
���00200 NH=NL+NN
���00210 50 TYPE 100, N,(A(I+INCA),I=NL,NH)
00220 TYPE 103
���00230 RETURN
00240 100 FORMAT(I4,5(1X,1PE12.5))
��00250 101 FORMAT(/1X,I11,5I13/)
00260 102 FORMAT(2X,A5,'(',I3,',',I3,')')
��00270 103 FORMAT(//)
���00280 END
���
��00010 C*************************************************************
00020 C SUBROUTINE TO LOAD MATRIX
��������������������������������������������00030 C*****************************************************************
�00040 SUBROUTINE LOAD
�00050 COMMON /FF/ NFMX,ITAPE,NWMX
��00060 COMMON /YY/ INCA
���00070 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
�00080 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
���00090 TYPE 10
����00100 10 FORMAT(2X,' ENTER MATRIX BY ROWS'/)
����00110 K=1
���00120 DO 100 J=1,NR
���00130 NA=-NC
00140 NF=NC
����00150 NWMX=1
00160 NFMX=NC
��00170 CALL FREAD(NA,NA,NF,A(K+INCA))
�00180 K=K+NC
00190 100 CONTINUE
00200 RETURN
00210 END
���
����������������������00010 C***********************************************************************
00020 C SUBROUTINE TO PRINT MAP OF NON-ZERO ELEMENTS IN A MATRIX
00030 C***********************************************************************
00040 SUBROUTINE MTXMAP(SCAL1)
��00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00080 DIMENSION NCOLL(20)
��00090 DATA NULL/'.'/
��00100 DATA NZERO/'*'/
�00110 DO 50 M=1,NC,20
�00120 NN=NC-M
����00130 IF(NN-19) 40,40,35
���00140 35 NN=19
�00150 40 MM=NN+1
����00160 DO 41 N=1,MM
���������00170 41 NCOLL(N)=M-1+N
��00180 TYPE 101, (NCOLL(N),N=1,MM)
����00190 DO 50 I=1,NR
����00200 NL=M+(I-1)*NC
���00210 DO 45 J=1,MM
����00220 ND=NL+J-1
��00230 IF(ABS(A(INCA+ND))-SCAL1) 42,42,43
��00240 42 NCOLL(J)=NULL
���00250 GO TO 45
���00260 43 NCOLL(J)=NZERO
��00270 45 CONTINUE
���00280 50 TYPE 100, I,(NCOLL(J),J=1,MM)
��00290 TYPE 102
���00300 RETURN
00310 100 FORMAT(I5,20(2X,A1))
�00320 101 FORMAT(1H0,4X,20I3)
��00330 102 FORMAT(//)
���00340 END
���
����������������������������������������������������������������������������������00010 C***********************************************************************
00020 C SUBROUTINE TO PERFORM OPERATION ON EACH ELEMENT OF A MATRIX
��00030 C***********************************************************************
00040 SUBROUTINE ELEMNT(IFLAG)
��00050 INTEGER ERROR
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA
00080 COMMON /Z/ A(1)
�00090 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00100 NS=NR*NC
���00110 IF (IFLAG-2) 1,2,3
���00120 1 DO 11 I=1,NS
����00130 11 IF (A(I+INCA).LT.0) GO TO 13
���00140 GO TO 3
����00150 2 DO 21 I=1,NS
���������00160 21 IF (A(INCA+I).EQ.0) GO TO 13
���00170 3 DO 10 I=1,NS
����00180 IF(IFLAG-2) 4,6,8
����00190 4 A(I+INCA)=SQRT(A(I+INCA))
�00200 GO TO 10
���00210 6 A(I+INCA)=1.0/A(I+INCA)
���00220 GO TO 10
���00230 8 A(I+INCA)=ALOG(A(I+INCA))
�00240 10 CONTINUE
���00250 GO TO 15
���00260 13 ERROR=10
���00270 15 RETURN
00280 END
���
��00010 C***********************************************************************
00020 C SYMMETRICAL MATRIX INVERSION
���00030 C***********************************************************************
������������������������������00040 SUBROUTINE SYMINV(NA,SINGLR)
���00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NRA,NCB
00080 INTEGER FREZ,FRET
����00090 DIMENSION C(1),D(1)
��00100 C************************************************************
�00110 C GET FREE STORAGE FOR C AND D ARRAYS
����00120 C****************************************************************
��00130 LCPT=FREZ(2*NRA)
00140 LC=LCPT-LOC(C)
��00150 LD=LCPT+NRA-LOC(D)
���00160 DO 140 I=1,NRA
��00170 NR=(I-1)*NRA
����00180 DO 100 J=1,NRA
��00190 K=NR+J
���������������00200 100 C(J+LC)=A(K+NA)
�00210 DMAX=C(I+LC)
����00220 IF(SINGLR-ABS(DMAX)) 105,990,990
����00230 C***********************************************************************
00240 C DIVIDE ROW BY ELEMENT ON DIAGONAL
���00250 C***********************************************************************
00260 105 DO 110 J=1,NRA
��00270 110 D(J+LD)=-C(J+LC)/DMAX
00280 IF(NCB) 998,116,112
��00290 112 NLB=(I-1)*NCB+1
�00300 NHB=NLB+NCB-1
���00310 DO 115 K=NLB,NHB
00320 115 A(K+INCA)=A(K+INCA)/DMAX
��00330 116 L=1
�������������������������������������������������������������������������00340 C***********************************************************************
00350 C REDUCE REMAINING ROWS AND COLUMNS
���00360 C***********************************************************************
00370 DO 125 J=1,NRA
��00380 M=L
���00390 DO 120 K=J,NRA
��00400 A(L+NA)=A(L+NA)+C(J+LC)*D(K+LD)
00410 A(M+NA)=A(L+NA)
�00420 M=M+NRA
����00430 120 L=L+1
�00440 125 L=L+J
�00450 IF(NCB) 998,139,130
��00460 130 LB=1
��00470 TAG=-1.0
���00480 DO 135 J=1,NRA
��00490 IF(I-J) 132,131,132
��00500 131 LB=LB+NCB
��00510 TAG=1.0
�������������������00520 GO TO 135
��00530 132 DO 133 K=NLB,NHB
00540 A(LB+INCA)=A(LB+INCA)-TAG*C(J+LC)*A(K+INCA)
���00550 133 LB=LB+1
����00560 135 CONTINUE
���00570 139 D(I+LD)=-1.0/DMAX
����00580 M=I
���00590 C***********************************************************************
00600 C REPLACE ELEMENTS OF A WITH CALCULATED INVERSE ELEMENTS
��00610 C***********************************************************************
00620 DO 140 J=1,NRA
��00630 K=NR+J
00640 A(K+NA)=D(J+LD)
�00650 A(M+NA)=D(J+LD)
�00660 140 M=M+NRA
����00670 NS=NRA*NRA
�������������������������������00680 DO 150 J=1,NS
���00690 150 A(J+NA)=-A(J+NA)
00700 GO TO 999
��00710 990 TYPE 991
00720 991 FORMAT(' AN ACCURATE SINGLE PRECISION INVERSE CANNOT',
����00730 1 ' BE COMPUTED'/)
����00740 GO TO 999
��00750 998 ERROR=8
�00760 999 CALL FRET(2*NRA,LCPT)
00770 RETURN
00780 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO PERFORM VARIOUS DIAGONAL MATRIX MULTIPLICATIONS
00030 C***********************************************************************
00040 SUBROUTINE DGMPY(NA,N1,N2,IFLAG)
������������������������00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00080 DO 10 I=1,N1
����00090 DO 10 J=1,N2
����00100 K=(I-1)*N2+J+NA
�00110 IF(IFLAG-2) 4,6,8
����00120 4 A(K)=A(K)*A(I+INCA)
��00130 GO TO 10
���00140 6 A(K)=A(K)*A(J+INCA)
��00150 GO TO 10
���00160 8 A(J+NA)=A(J+NA)*A(J+INCA)
�00170 10 CONTINUE
���00180 RETURN
00190 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO CHECK ON SYMMETRY OF A MATRIX
��������������������������������������00030 C***********************************************************************
00040 SUBROUTINE SYMCHK(SCAL1,IFLAG)
�00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00080 DO 10 I=1,NR
����00090 DO 10 J=I,NR
����00100 IJ=(I-1)*NR+J
���00110 JI=(J-1)*NR+I
���00120 TEST=ABS(A(INCA+IJ)-A(INCA+JI))
00130 IF(TEST-SCAL1) 10,10,5
���00140 5 TYPE 100, I,J,A(INCA+IJ),J,I,A(INCA+JI)
��00150 IFLAG=1
����00160 10 CONTINUE
���00170 RETURN
00180 100 FORMAT(3X,'(',I3,',',I3,') =',
�������������������������������00190 1 1PE14.7,5X,'(',I3,',',I3,') =',1PE14.7/)
00200 END
���
��00010 C***********************************************************************
00020 C GENERAL MATRIX INVERSION SUBROUTINE
�00030 C***********************************************************************
00040 SUBROUTINE INVERT(NA,SINGLR)
���00050 INTEGER ERROR,FREZ,FRET
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA
00080 COMMON /Z/ A(1)
�00090 COMMON /ZZ/ NUM,NNUM,NX,N,NCB
��00100 DIMENSION M(1),C(1)
��00110 INTEGER RANK
����00120 LOGICAL IRANK
���00130 IRANK=.FALSE.
�������������00140 IF(SINGLR.GT.-99998.) GO TO 50
�00150 IRANK=.TRUE.
���00160 SINGLR=0.
��00170 50 DET=1.
���00180 MPT=FREZ(N)
00190 MC=MPT-LOC(M)
���00200 LCPT=FREZ(N)
����00210 LC=LCPT-LOC(C)
��00220 DO 90 I=1,N
00230 90 M(I+MC)=-I
�00240 DO 140 I=1,N
����00250 RANK=I
00260 C***********************************************************************
00270 C LOCATE LARGEST ELEMENT
����00280 C***********************************************************************
00290 D=0.0
�00300 DO 105 L=1,N
����00310 IF(M(L+MC)) 100,100,105
���00320 100 J=L
������������������00330 DO 104 K=1,N
����00340 IF(M(K+MC)) 101,101,103
���00350 101 IF (ABS(D)-ABS(A(J+NA))) 102,103,103
00360 102 LD=L
��00370 KD=K
��00380 D=A(J+NA)
��00390 103 J=J+N
�00400 104 CONTINUE
���00410 105 CONTINUE
���00420 IF(I-1) 998,107,110
��00430 107 IF(SINGLR) 998,108,109
�00440 108 SINGLR=ABS(D*1.0E-06)
00450 109 TYPE 992, SINGLR
00460 110 IF(SINGLR-ABS(D)) 111,990,990
��00470 C***********************************************************************
00480 C INTERCHANGE COLUMNS
��00490 C***********************************************************************
����������00500 111 TEMP=-M(LD+MC)
����00510 M(LD+MC)=M(KD+MC)
����00520 M(KD+MC)=TEMP
���00530 L=LD
��00540 K=KD
��00550 DO 114 J=1,N
����00560 C(J+LC)=A(L+NA)
�00570 A(L+NA)=A(K+NA)
�00580 A(K+NA)=C(J+LC)
�00590 L=L+N
�00600 114 K=K+N
�00610 C***********************************************************************
00620 C DIVIDE ROW BY LARGEST ELEMENT
��00630 C***********************************************************************
00640 DET=DET*D
��00650 NLA=(KD-1)*N+1
��00660 NHA=NLA+N-1
00670 DO 115 K=NLA,NHA
�����������������������������������00680 115 A(K+NA)=-A(K+NA)/D
���00690 IF(NCB) 998,120,116
��00700 116 NLB=(KD-1)*NCB+1
00710 NHB=NLB+NCB-1
���00720 DO 117 K=NLB,NHB
00730 117 A(K+INCA)=A(K+INCA)/D
00740 C***********************************************************************
00750 C REDUCE REMAINING ROWS AND COLUMNS
���00760 C***********************************************************************
00770 120 L=1
���00780 LB=1
��00790 DO 137 J=1,N
����00800 IF (J-KD) 130,125,130
00810 125 L=L+N
�00820 LB=LB+NCB
��00830 GO TO 137
��00840 130 DO 131 K=NLA,NHA
������������������������������00850 A(L+NA)=A(L+NA)+C(J+LC)*A(K+NA)
00860 131 L=L+1
�00870 IF(NCB) 998,137,132
��00880 132 IF(M(J+MC)) 134,134,133
���00890 133 TAG=-1.0
���00900 GO TO 135
��00910 134 TAG= 1.0
���00920 135 DO 136 K=NLB,NHB
00930 A(LB+INCA)=A(LB+INCA)-TAG*C(J+LC)*A(K+INCA)
���00940 136 LB=LB+1
����00950 137 CONTINUE
���00960 C***********************************************************************
00970 C REDUCE COLUMN
���00980 C***********************************************************************
00990 C(KD+LC)=1.0
����01000 J=KD
��01010 DO 139 K=1,N
�������������������01020 A(J+NA)=C(K+LC)/D
����01030 139 J=J+N
���01040 140 CONTINUE
01050 C***********************************************************************
01060 C INTERCHANGE ROWS
01070 C***********************************************************************
01080 DO 200 I=1,N
����01090 L=0
���01100 150 L=L+1
�01110 IF(M(L+MC)-I) 150,160,150
�01120 160 K=(L-1)*N+1
01130 J=(I-1)*N+1
01140 KB=(L-1)*NCB+1
��01150 JB=(I-1)*NCB+1
��01160 M(L+MC)=M(I+MC)
�01170 M(I+MC)=I
��01180 DO 170 LL=1,N
���01190 TEMP=A(K+NA)
����01200 A(K+NA)=A(J+NA)
�����������01210 A(J+NA)=TEMP
����01220 J=J+1
�01230 170 K=K+1
�01240 IF(NCB) 998,200,180
��01250 180 DO 190 LL=1,NCB
�01260 TEMP=A(KB+INCA)
�01270 A(KB+INCA)=A(JB+INCA)
01280 A(JB+INCA)=TEMP
�01290 JB=JB+1
����01300 190 KB=KB+1
����01310 200 CONTINUE
���01320 IF(IRANK) GO TO 995
��01330 TYPE 201, DET
���01340 201 FORMAT(' DETERMINANT =',1PE15.7/)
����01350 C***********************************************************************
01360 GO TO 999
��01370 C***********************************************************************
01380 990 IF(IRANK) GO TO 994
�������������������01390 TYPE 991, KD,LD,D
�01400 991 FORMAT(2X,' (',I3,',',I3,') =',1PE14.7,3X,'WILL NOT',
01410 1 ' PRODUCE'/' AN ACCURATE SINGLE PRECISION INVERSION'/)
����01420 992 FORMAT (9H SCALAR= 1PE15.7/)
��01430 GO TO 999
��01440 994 RANK=RANK-1
��01450 995 TYPE 996, RANK
����01460 996 FORMAT(' RANK =',I5/)
�01470 GO TO 999
��01480 998 ERROR=8
����01490 999 CALL FRET(N,MPT)
01500 CALL FRET(N,LCPT)
����01510 RETURN
01520 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO FORM MEMBER STIFFNESS MATRICES
������������00030 C***********************************************************************
00040 SUBROUTINE FORMK(NTYPE,N)
�00050 COMMON /FF/ NFMX,ITAPE,NWMX
����00060 COMMON /YY/ INCA
00070 COMMON /Z/ A(1)
�00080 DIMENSION DATA(5)
����00090 NRC=NTYPE*N
00100 NS=NRC*NRC
�00110 C***********************************************************************
00120 C INITIALIZE MATRIX, READ IN DATA, AND CALCULATE STIFFNESS CONSTANTS
00130 C***********************************************************************
00140 DO 1 I=1,NS
00150 1 A(INCA+I)=0.0
���00160 DO 2 I=1,5
����������������00170 DATA(I)=0.0
00180 2 CONTINUE
��00190 TYPE 100
���00200 100 FORMAT(' ENTER THE FOLLOWING DATA FOR EACH MEMBER'/)
�00210 IF(NTYPE.EQ.3) GO TO 10
���00220 TYPE 101
���00230 101 FORMAT(1X,' I ,SHEAR AREA, L , E'/)
���00240 NF=4
��00250 GO TO 11
���00260 10 TYPE 102
�00270 102 FORMAT(1X,' I,SHEAR AREA, L , E ,AREA'/)
���00280 NF=5
��00290 11 DO 50 I=1,N
���00300 NA=-NF
00310 NO=NF
�00320 NWMX=1
���00330 NFMX=5
���00340 CALL FREAD(NA,NA,NO,DATA)
�00350 XI=DATA(1)
�00360 ABAR=DATA(2)
����00370 XL=DATA(3)
�00380 E=DATA(4)
��00390 AREA=DATA(5)
����00400 G=E/2.4
�������������������00410 IF(ABAR) 98,15,20
����00420 15 BETA=0.0
���00430 GO TO 25
���00440 20 BETA=(6.0*E*XI)/((XL**2)*ABAR*G)
����00450 25 XKMM=(2.0*E*XI*(2.0+BETA))/(XL*(1.0+2.0*BETA))
00460 XKMV=(2.0*E*XI*(1.0-BETA))/(XL*(1.0+2.0*BETA))
00470 K=(I-1)*NTYPE*(NRC+1)+1+INCA
���00480 IF(NTYPE-3) 35,30,40
�00490 C***********************************************************************
00500 C 3 X 3 ELEMENT ( BENDING PLUS ONE AXIAL)
��00510 C***********************************************************************
00520 30 A(K)=AREA*E/XL
��00530 K=K+NRC+1
�������������������������������������00540 C***********************************************************************
00550 C 2 X 2 ELEMENT ( BENDING ONLY)
��00560 C***********************************************************************
00570 35 A(K)=XKMM
��00580 K=K+1
�00590 A(K)=XKMV
��00600 K=K+NRC-1
��00610 A(K)=XKMV
��00620 K=K+1
�00630 A(K)=XKMM
��00640 GO TO 50
���00650 C***********************************************************************
00660 C 4 X 4 ELEMENT ( BENDING AND TRANSVERSE SHEAR)
�00670 C***********************************************************************
�������������������������00680 40 XKVV=(12.0*E*XI)/((XL**3)*(1.0+2.0*BETA))
00690 XKVM=0.5*XL*XKVV
00700 A(K)=XKVV
��00710 L=K
���00720 K=K+1
�00730 A(K)=-XKVM
�00740 K=K+1
�00750 A(K)=-XKVV
�00760 K=K+1
�00770 A(K)=-XKVM
�00780 K=K+NRC-NTYPE+1
�00790 A(K)=-XKVM
�00800 K=K+1
�00810 A(K)=XKMM
��00820 K=K+1
�00830 A(K)=XKVM
��00840 K=K+1
�00850 A(K)=XKMV
��00860 K=K+NRC-NTYPE+1
�00870 A(K)=-XKVV
�00880 K=K+1
�00890 A(K)=XKVM
��00900 K=K+1
�00910 A(K)=XKVV
��00920 K=K+1
���������������������00930 A(K)=XKVM
��00940 K=K+NRC-NTYPE+1
�00950 A(K)=-XKVM
�00960 K=K+1
�00970 A(K)=XKMV
��00980 K=K+1
�00990 A(K)=XKVM
��01000 K=K+1
�01010 A(K)=XKMM
��01020 50 CONTINUE
���01030 GO TO 99
���01040 98 ERROR=8
��01050 99 RETURN
���01060 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO FORM COMPLETE MEMBER STIFFNESS MATRICES
���00030 C***********************************************************************
00040 SUBROUTINE FORMKD(NTYPE,N)
����������������������������������������00050 COMMON /FF/ NFMX,ITAPE,NWMX
����00060 COMMON /YY/ INCA, INC1
����00070 COMMON /Z/ A(1),NAME(1)
���00080 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00090 DIMENSION DATA(9)
����00100 NRC=NTYPE
��00110 NS=NRC*NRC
�00120 C***********************************************************************
00130 C INITIALIZE MATRIX, READ IN DATA, AND CALCULATE STIFFNESS CONSTANTS
00140 C***********************************************************************
00150 DO 2 I=1,9
�00160 DATA(I)=0.0
00170 2 CONTINUE
��00180 TYPE 100
���00190 100 FORMAT(' ENTER THE FOLLOWING DATA FOR EACH MEMBER'/)
�����������00200 IF(NTYPE.EQ.6) GO TO 6
����00210 TYPE 103
���00220 NF=6
��00230 GO TO 15
���00240 6 TYPE 101
��00250 101 FORMAT(3X,'I , SHEAR AREA,'$)
����00260 TYPE 103
���00270 103 FORMAT('+ E , CROSS-AREA, X1 , Y1 , X2 , Y2'//)
00280 NF=8
��00290 15 DO 90 I=1,N
���00300 NAMA=NAME(NUM-N+I+INC1)
���00310 CALL MFIND(NAMA)
00320 DO 18 J=1,NS
����00330 18 A(INCA+J)=0.0
�00340 NO=NF
�00350 NA=-NF
00360 NWMX=1
���00370 NFMX=9
���00380 CALL FREAD(NA,NA,NO,DATA)
�00390 IF(NTYPE.EQ.6) GO TO 20
���00400 XI=0
��00410 ABAR=0
00420 E=DATA(1)
��00430 AREA=DATA(2)
����00440 X1=DATA(3)
�����������00450 Y1=DATA(4)
�00460 X2=DATA(5)
�00470 Y2=DATA(6)
�00480 GO TO 25
���00490 20 XI=DATA(1)
����00500 ABAR=DATA(2)
����00510 E=DATA(3)
��00520 AREA=DATA(4)
����00530 X1=DATA(5)
�00540 Y1=DATA(6)
�00550 X2=DATA(7)
�00560 Y2=DATA(8)
�00570 25 G=E/2.4
��00580 DX=X2-X1
���00590 DY=Y2-Y1
���00600 XL=SQRT(DX**2+DY**2)
�00610 S=DY/XL
����00620 C=DX/XL
����00630 K=INCA+1
���00640 XKAA=AREA*E/XL
��00650 TYPE 105, XL
����00660 105 FORMAT(5X,'LENGTH =',1PE14.7//)
��00670 IF(NTYPE-4) 98,10,50
�����������������������������������������������������������������������00680 C***********************************************************************
00690 C 4 X 4 ELEMENT (AXIAL ONLY)
00700 C***********************************************************************
00710 10 A(K)=XKAA*C**2
��00720 L=K
���00730 K=K+1
�00740 A(K)=XKAA*C*S
���00750 LP1=L+1
����00760 K=K+1
�00770 A(K)=-A(L)
�00780 K=K+1
�00790 A(K)=-A(LP1)
����00800 K=K+1
�00810 A(K)=A(LP1)
00820 K=K+1
�00830 A(K)=XKAA*S**2
��00840 LPN1=LP1+NRC
����00850 K=K+1
�00860 A(K)=-A(LP1)
����00870 K=K+1
�00880 A(K)=-A(LPN1)
��������00890 GO TO 75
���00900 C***********************************************************************
00910 C 6 X 6 ELEMENT (BENDING, TRANSVERSE SHEAR, AND AXIAL)
����00920 C***********************************************************************
00930 50 IF(ABAR) 98,55,60
����00940 55 BETA=0.0
���00950 GO TO 65
���00960 60 BETA=(6.0*E*XI)/((XL**2)*ABAR*G)
����00970 65 XKVV=(12.0*E*XI)/((XL**3)*(1.0+2.0*BETA))
00980 XKVM=0.5*XL*XKVV
00990 XKMM=(2.0*E*XI*(2.0+BETA))/(XL*(1.0+2.0*BETA))
01000 XKMV=(2.0*E*XI*(1.0-BETA))/(XL*(1.0+2.0*BETA))
01010 A(K)=XKVV*S**2+XKAA*C**2
�������01020 L=K
���01030 K=K+1
�01040 A(K)=(-XKVV+XKAA)*C*S
01050 K=K+1
�01060 LP1=L+1
����01070 A(K)=XKVM*S
01080 K=K+1
�01090 A(K)=-A(L)
�01100 K=K+1
�01110 A(K)=-A(LP1)
����01120 K=K+1
�01130 A(K)=XKVM*S
01140 K=K+1
�01150 A(K)=A(LP1)
01160 K=K+1
�01170 A(K)=XKVV*C**2+XKAA*S**2
��01180 LPN1=LP1+NRC
����01190 K=K+1
�01200 A(K)=-XKVM*C
����01210 K=K+1
�01220 A(K)=-A(LP1)
����01230 K=K+1
�01240 A(K)=-A(LPN1)
���01250 K=K+1
�01260 A(K)=-XKVM*C
����01270 K=K+1
�����������01280 A(K)=XKVM*S
01290 K=K+1
�01300 A(K)=-XKVM*C
����01310 K=K+1
�01320 A(K)=XKMM
��01330 K=K+1
�01340 A(K)=-XKVM*S
����01350 K=K+1
�01360 A(K)=XKVM*C
01370 K=K+1
�01380 A(K)=XKMV
��01390 C***********************************************************************
01400 C DUPLICATE THE ROWS CORRESPONDING TO THE R1 AND R2 FREEDOMS
���01410 C***********************************************************************
01420 75 K=K+1
����01430 DO 80 J=1,2
01440 K=K+(J-1)*NRC
���01450 KPN=K+NTYPE-1
���01460 LL=L+(J-1)*NRC
������������01470 DO 80 JJ=K,KPN
��01480 A(JJ)=-A(LL)
����01490 80 LL=LL+1
����01500 IF(NTYPE-4) 98,90,85
�01510 85 K=K+(J-1)*NRC
���01520 A(K)=XKVM*S
01530 K=K+1
�01540 A(K)=-XKVM*C
����01550 K=K+1
�01560 A(K)=XKMV
��01570 K=K+1
�01580 A(K)=-XKVM*S
����01590 K=K+1
�01600 A(K)=XKVM*C
01610 K=K+1
�01620 A(K)=XKMM
��01630 90 CONTINUE
���01640 GO TO 99
���01650 98 ERROR=8
����01660 99 RETURN
01670 END
���
��00010 C***********************************************************************
�������������������������00020 C SUBROUTINE TO PERFORM DIRECT STIFFNESS MERGE
��00030 C***********************************************************************
00040 SUBROUTINE MERGE(NBIG,NRA,NCA,K)
����00050 INTEGER ERROR,FREZ,FRET
���00060 COMMON /FF/ NFMX,ITAPE,NWMX
����00070 COMMON /XX/ ERROR
����00080 COMMON /YY/ INCA
00090 COMMON /Z/ A(1)
�00100 COMMON /ZZ/ NUM,NNUM,NX,NRB,NCB
00110 DIMENSION NROW(1),NCOL(1),W1(1)
00120 C************************************************************
�00130 C GET FREE STORAGE
��00140 C*******************************************************
�����������00150 NS=3*NRB
���00160 NP=FREZ(NS)
00170 N1=NP-LOC(NROW)
�00180 N2=NP+NRB-LOC(NCOL)
��00190 N3=NP+2*NRB-LOC(W1)
��00200 C***********************************************************************
00210 C CHECK FOR SYMMETRICAL MERGE
����00220 C***********************************************************************
00230 IF(IABS(K)-1) 98,1,5
�00240 1 IF(NRB-NCB)91,2,91
��00250 2 TYPE 100
��00260 100 FORMAT(2X,' SYMMETRIC MERGE - ENTER ROW-COL COORDINATES'/)
00270 NF=NRB
00280 NA=-NF
00290 NFMX=NRB
���00300 NWMX=1
00310 CALL FREAD(NA,NA,NF,W1(N3+1))
�����������������00320 DO 3 I=1,NRB
����00330 NROW(I+N1)=W1(I+N3)
��00340 NCOL(I+N2)=W1(I+N3)
��00350 3 CONTINUE
��00360 GO TO 6
����00370 5 TYPE 101
��00380 101 FORMAT(2X,' ENTER ROW COORDINATES'/)
��00390 NF=NRB
00400 NA=-NF
00410 NFMX=NRB
���00420 NWMX=1
00430 CALL FREAD(NA,NA,NF,W1(N3+1))
��00440 DO 4 I=1,NRB
����00450 NROW(I+N1)=W1(I+N3)
��00460 4 CONTINUE
��00470 TYPE 102
���00480 102 FORMAT(2X,' ENTER COLUMN COORDINATES'/)
����00490 NF=NCB
00500 NA=-NF
00510 NFMX=NRB
���00520 NWMX=1
00530 CALL FREAD(NA,NA,NF,W1(N3+1))
��00540 DO 50 I=1,NCB
���00550 NCOL(I+N2)=W1(I+N3)
������������00560 50 CONTINUE
�00570 6 DO 8 I=1,NRB
���00580 IF(NRA-IABS(NROW(I+N1))) 91,8,8
00590 8 CONTINUE
���00600 DO 10 J=1,NCB
���00610 IF(NCA-IABS(NCOL(J+N2))) 91,10,10
���00620 10 CONTINUE
���00630 DO 21 I=1,NRB
���00640 IF(NROW(I+N1)) 11,21,12
���00650 11 TAGI=-1.0
��00660 NROW(I+N1)=IABS(NROW(I+N1))
����00670 GO TO 13
���00680 12 TAGI=1.0
���00690 13 DO 20 J=1,NCB
���00700 IF(NCOL(J+N2)) 14,20,15
���00710 14 IF(TAGI) 15,98,16
����00720 15 TAGJ=1.0
���00730 NCOL(J+N2) =IABS(NCOL(J+N2))
���00740 GO TO 17
����������������������������00750 16 TAGJ=-1.0
��00760 NCOL(J+N2) =IABS(NCOL(J+N2))
���00770 17 NNA=NCA*(NROW(I+N1)-1)+NCOL(J+N2)
���00780 NNB=NCB*(I-1)+J
�00790 IF(K) 18,98,19
��00800 18 A(NBIG+NNA)=TAGI*TAGJ*A(NNB+INCA)
���00810 GO TO 20
���00820 19 A(NNA+NBIG)=A(NNA+NBIG)+TAGI*TAGJ*A(INCA+NNB)
�00830 20 CONTINUE
���00840 21 CONTINUE
���00850 GO TO 99
���00860 91 ERROR=1
��00870 GO TO 99
���00880 98 ERROR=8
��00890 99 CALL FRET(NS,NP)
00900 RETURN
00910 END
���
��00010 C***********************************************************************
�����������������������������������00020 C SUBROUTINE TO STORE OR REMOVE A SUBMATRIX
00030 C***********************************************************************
00040 SUBROUTINE STOSM(NB,NRB,NCB,JJ,KK,NTAG)
��00050 INTEGER ERROR
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA
00080 COMMON /Z/ A(1)
�00090 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00100 IF (NR+1-JJ-NRB) 60,50,50
�00110 50 IF (NC+1-KK-NCB) 60,70,70
�00120 60 ERROR=1
��00130 GO TO 900
��00140 70 DO 100 I=1,NRB
��00150 K=(KK-1)+(JJ+I-2)*NC
�00160 L=(I-1)*NCB
00170 DO 100 J=1,NCB
��00180 N=K+J
���������������������00190 M=L+J
�00200 IF (NTAG) 75,90,80
���00210 75 A(INCA+N)=A(INCA+N)+A(NB+M)
����00220 GO TO 100
��00230 80 A(INCA+N)=A(NB+M)
����00240 GO TO 100
��00250 90 A(NB+M)=A(INCA+N)
����00260 100 CONTINUE
���00270 900 RETURN
��00280 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO DELETE ROWS AND/OR COLUMNS FROM A MATRIX
��00030 C***********************************************************************
00040 SUBROUTINE DELRC(NAMA,NRD,NCD,NAMB,K)
����00050 INTEGER ALPHA(1),ERROR,FREZ,FRET
��������������00060 COMMON /FF/ NFMX,ITAPE,NWMX
����00070 DIMENSION MROW(1),MCOL(1),W1(1)
00080 COMMON /XX/ ERROR
����00090 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
00100 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
���00110 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00120 C***********************************************************************
00130 C CHECK FOR SYMMETRICAL DELETION
�00140 C***********************************************************************
00150 NMX=MAX0(NRD,NCD)
����00160 NW1=FREZ(NMX)
���00170 IW1=NW1-LOC(W1)
�00180 NMR=FREZ(NRD+NCD)
���������00190 IMR=NMR-LOC(MROW)
����00200 IMC=NMR+NRD-LOC(MCOL)
00210 IF(K) 98,5,1
����00220 1 IF(NRD-NCD) 91,2,91
��00230 2 IF(NRD) 98,98,3
�00240 3 NF=NRD
����00250 NA=-NF
00260 TYPE 300
���00270 300 FORMAT(' ENTER ROWS-COLUMNS TO BE DELETED'/)
���00280 NFMX=NMX
���00290 NWMX=1
00300 CALL FREAD(NA,ALPHA,NF,W1(IW1+1))
���00310 DO 4 I=1,NRD
����00320 MROW(I+IMR)=W1(I+IW1)
00330 MCOL(I+IMC)=W1(I+IW1)
00340 4 CONTINUE
��00350 GO TO 10
���00360 5 IF(NRD)98,7,6
��00370 6 NF=NRD
����00380 NA=-NF
00390 TYPE 600
���00400 600 FORMAT(' ENTER ROWS TO BE DELETED'/)
����������������00410 NFMX=NMX
���00420 NWMX=1
00430 CALL FREAD(NA,ALPHA,NF,W1(IW1+1))
���00440 DO 70 I=1,NRD
���00450 MROW(I+IMR)=W1(I+IW1)
00460 70 CONTINUE
�00470 7 IF(NCD) 98,10,8
00480 8 NF=NCD
����00490 NA=-NF
00500 TYPE 800
���00510 800 FORMAT(' ENTER COLUMNS TO BE DELETED'/)
���00520 NFMX=NMX
���00530 NWMX=1
00540 CALL FREAD(NA,ALPHA,NF,W1(IW1+1))
���00550 DO 90 I=1,NCD
���00560 MCOL(I+IMC)=W1(I+IW1)
00570 90 CONTINUE
�00580 10 CALL MFIND(NAMA)
00590 IF(ERROR.GT.0) GO TO 99
���00600 NA=INCA+1
��00610 NRA=NR
00620 NCA=NC
00630 IF(NRD) 98,17,15
���������������00640 15 DO 16 I=1,NRD
���00650 IF(NRA-MROW(I+IMR)) 91,16,16
���00660 16 CONTINUE
���00670 17 IF(NCD) 98,20,18
00680 18 DO 19 J=1,NCD
���00690 IF(NCA-MCOL(J+IMC)) 91,19,19
���00700 19 CONTINUE
���00710 20 NR=NRA-NRD
�00720 NC=NCA-NCD
�00730 CALL MLIST(NAMB)
00740 IF(ERROR.GT.0) GO TO 99
���00750 NB=INCA+1
��00760 DO 30 II=1,NRA
��00770 DO 28 JJ=1,NCA
��00780 IF(NRD) 98,23,21
00790 21 DO 22 I=1,NRD
���00800 IF(II-MROW(I+IMR)) 22,29,22
����00810 22 CONTINUE
���00820 23 IF(NCD) 98,26,24
00830 24 DO 25 J=1,NCD
�����������������������00840 IF(JJ-MCOL(J+IMC)) 25,28,25
����00850 25 CONTINUE
���00860 26 A(NB)=A(NA)
00870 NB=NB+1
����00880 28 NA=NA+1
����00890 GO TO 30
���00900 29 NA=NA+NCA
��00910 30 CONTINUE
��00920 GO TO 99
��00930 91 ERROR=1
��00940 GO TO 99
���00950 98 ERROR=8
��00960 99 CALL FRET(NRD+NCD,NMR)
����00970 CALL FRET(NMX,NW1)
���00980 RETURN
00990 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO PERFORM CHOLESKI RIGHT DECOMPOSTITION
�����������������������������������������������������������������00030 C***********************************************************************
00040 SUBROUTINE DECOM(NB)
�00050 COMMON /YY/ INCA
00060 COMMON /Z/ A(1)
�00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC
��00080 NS=NR*NR
���00090 DO 1 I=1,NS
00100 1 A(I+NB)=0.0
00110 NU=1
��00120 SRA=A(INCA+NU)
��00130 IF(SRA.LT.0) GO TO 90
00140 A(NU+NB)=SQRT(SRA)
���00150 DO 2 K=2,NR
00160 2 A(K+NB)=A(K+INCA)/A(NU+NB)
00170 DO 10 I=2,NR
����00180 IP1=I+1
����00190 IM1=I-1
����00200 5 NU=(I-1)*NR+I
���00210 A(NU+NB)=A(NU+INCA)
��������������������������������00220 DO 6 II=1,IM1
���00230 NP=NU-II*NR
00240 6 A(NU+NB)=A(NU+NB)-(A(NP+NB)**2)
00250 SRA=A(NU+NB)
����00260 IF(SRA.LT.0) GO TO 90
00270 A(NU+NB)=SQRT(SRA)
���00280 IF(I-NR) 7,10,10
00290 7 NUSTR=NU
���00300 DO 9 J=IP1,NR
���00310 NU=NU+1
����00320 A(NU+NB)=A(NU+INCA)
��00330 DO 8 JJ=1,IM1
���00340 NP=NU-JJ*NR
00350 NNP=NUSTR-JJ*NR
�00360 8 A(NU+NB)=A(NU+NB)-A(NP+NB)*A(NNP+NB)
00370 9 A(NU+NB)=A(NU+NB)/A(NUSTR+NB)
��00380 10 CONTINUE
���00390 99 RETURN
���00400 90 TYPE 100
�������������������������������������������������������������00410 100 FORMAT(2X,' MATRIX IS NOT POSITIVE DEFINITE'/)
��00420 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO PERFORM FORWARD OR BACK SUBSTITUTION AND INVERSION
��00030 C***********************************************************************
00040 SUBROUTINE CHSOLV(NA,IFLAG,SINGLR)
��00050 INTEGER ERROR,FREZ,FRET
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA
00080 COMMON /Z/ A(1)
�00090 COMMON /ZZ/ NUM,NNUM,NX,N,M
����00100 DIMENSION C(1)
���������������������������������������������������������00110 C*************************************************
��00120 C GET FREE STORAGE FOR ARRAY C
���00130 C***************************************************
00140 NP=FREZ(N)
�00150 LC=NP-LOC(C)
����00160 NM1=N-1
����00170 DO 10 I=1,NM1
���00180 IP1=I+1
����00190 IF(IFLAG) 98,1,2
00200 1 II=I
��00210 GO TO 3
����00220 2 II=N-I+1
���00230 3 DO 10 J=IP1,N
���00240 IF(IFLAG) 98,6,7
00250 6 JJ=(II-1)*N+J
���00260 GO TO 8
����00270 7 JJ=II*N-J+1
00280 8 IF(ABS(A(JJ+NA))-SINGLR) 10,10,97
���00290 10 CONTINUE
�����������������������00300 DO 70 I=1,N
00310 IM1=I-1
����00320 IF(IFLAG) 98,12,13
���00330 12 II=I
��00340 GO TO 14
���00350 13 II=N-I+1
���00360 14 IF(IM1) 98,15,30
00370 15 K=(II-1)*N+II
���00380 IF(SINGLR) 98,16,17
��00390 16 SINGLR=ABS(A(K+NA)*1.0E-06)
����00400 17 TYPE 101, SINGLR
���00410 101 FORMAT(' SCALAR =',1PE14.7/)
���00420 IF(M) 98,25,18
��00430 18 JJ=(II-1)*M
00440 DO 20 J=1,M
00450 JJ=JJ+1
����00460 20 A(JJ+INCA)=A(JJ+INCA)/A(K+NA)
��00470 25 A(K+NA)=1.0/A(K+NA)
��00480 GO TO 70
���00490 30 DO 35 J=1,I
�����������������������������������00500 IF(IFLAG) 98,32,33
���00510 32 JJ=(II-1)*N+J
���00520 GO TO 35
���00530 33 JJ=II*N-J+1
00540 35 C(J+LC)=A(JJ+NA)
00550 IF(SINGLR-ABS(C(I+LC))) 38,96,96
����00560 38 IF(M) 98,55,40
��00570 40 DO 50 J=1,M
00580 JJ=(II-1)*M+J
���00590 IF(IFLAG) 98,42,43
���00600 42 JL=J
��00610 GO TO 45
���00620 43 JL=(N-1)*M+J
����00630 45 DO 49 L=1,IM1
���00640 A(JJ+INCA)=A(JJ+INCA)-C(L+LC)*A(JL+INCA)
�00650 IF(IFLAG) 98,46,47
���00660 46 JL=JL+M
����00670 GO TO 49
���00680 47 JL=JL-M
����00690 49 CONTINUE
���������������������������������00700 50 A(JJ+INCA)=A(JJ+INCA)/C(I+LC)
��00710 55 K=(II-1)*N+II
���00720 A(K+NA)=1.0/C(I+LC)
��00730 DO 65 J=1,IM1
���00740 IF(IFLAG) 98,57,58
���00750 57 KK=(II-1)*N+J
���00760 GO TO 59
���00770 58 KK=II*N-J+1
00780 59 A(KK+NA)=0.0
����00790 DO 64 L=J,IM1
���00800 IF(IFLAG) 98,61,62
���00810 61 LL=(L-1)*N+J
����00820 GO TO 64
���00830 62 LL=N*N-N*(L-1)-J+1
���00840 64 A(KK+NA)=A(KK+NA)-C(L+LC)*A(LL+NA)
��00850 65 A(KK+NA)=A(KK+NA)/C(I+LC)
�00860 70 CONTINUE
���00870 GO TO 99
���00880 96 TYPE 102, II,II,C(I)
����00890 GO TO 99
�������������00900 97 ERROR=1
��00910 GO TO 99
���00920 98 ERROR=8
��00930 99 CALL FRET(N,NP)
����00940 RETURN
���00950 102 FORMAT(2X,' (',I3,',',I3,') =',1PE14.7,3X,'WILL NOT PRODUCE '
��00960 1 ,/' AN ACCURATE SINGLE PRECISION INVERSION'/)
00970 END
���
��00010 C***********************************************************************
00020 SUBROUTINE EIGEN(R,V,E,LP,M,NM)
00030 COMMON /YY/ INCA
00040 COMMON /Z/ A(1)
�00050 INTEGER FREZ,FRET
����00060 DIMENSION R(1),E(1),V(1),AA(1),B(1),W1(1),W2(1)
����00070 NAA=FREZ(LP)
����00080 NB=FREZ(LP)
���������������00090 NW1=FREZ(LP)
����00100 NW2=FREZ(LP)
����00110 INA=NAA-LOC(AA)+1
����00120 INB=NB-LOC(B)+1
�00130 IW1=NW1-LOC(W1)+1
����00140 IW2=NW2-LOC(W2)+1
����00150 IF(LP-1) 20,14,1
00160 1 DO 2 I=1,LP
00170 2 A(I+INCA)=1./(SQRT(A(I+INCA)))
�00180 DO 3 I=1,LP
00190 DO 3 J=1,LP
00200 JJ=I+(J-1)*NM
���00210 3 R(JJ)=A(I+INCA)*R(JJ)*A(J+INCA)
00220 C***********************************************************************
00230 C TRI-DIAGONALIZE MATRIX
����00240 C***********************************************************************
��������������������00250 4 CALL TRIDI(LP,NM,R,AA(INA),B(INB),W1(IW1),W2(IW2))
�00260 IF(ERROR) 20,40,20
���00270 C***********************************************************************
00280 C FIND EIGEN VALUES
��00290 C***********************************************************************
00300 40 CALL EIGVAL(LP,NM,M,E,AA(INA),B(INB),W1(IW1),W2(IW2))
�00310 IF (M) 5,14,5
���00320 C***********************************************************************
00330 C FIND EIGEN VECTORS
�00340 C***********************************************************************
00350 5 K=IABS(M)
��00360 J=1
�����������������������00370 DO 7 I=1,K
�00380 CALL EIGVEC(LP,NM,R,AA(INA),B(INB),E(I),V(J),W1(IW1),W2(IW2))
00390 7 J=J+NM
00400 C***********************************************************************
00410 C MODIFY EIGEN VECTORS
����00420 C***********************************************************************
00430 9 DO 15 I=1,LP
����00440 DO 15 J=1,K
00450 JJ=I+(J-1)*NM
���00460 15 V(JJ)=A(I+INCA)*V(JJ)
00470 GO TO 20
���00480 C***********************************************************************
00490 C SOLUTION FOR ORDER 1
���������������������������������������������������������������������00500 C***********************************************************************
00510 14 E(1)=R(1)/E(1)
��00520 V(1)=1.0
���00530 20 CALL FRET(LP,NAA)
����00540 CALL FRET(LP,NB)
00550 CALL FRET(LP,NW1)
����00560 CALL FRET(LP,NW2)
����00570 RETURN
00580 END
���
��00010 C***********************************************************************
00020 C TRI-DIAGONALIZATION SUBROUTINE DWM 1517-UB
�00030 C***********************************************************************
00040 C RETURN ORIGNAL R IN UPPER TRIANGULAR HALF INCLUDING DIAGONAL
������������������������00050 C RETURN MODIFIED W MATRICES IN LOWER HALF OF R MATRIX
��00060 C RETURN NEW DIAGONAL IN A
00070 C RETURN NEW FIRST OFF DIAGONAL IN B
00080 C***********************************************************************
00090 SUBROUTINE TRIDI(LP,NM,R,A,B,W,Q)
���00100 INTEGER ERROR
���00110 COMMON /XX/ ERROR
����00120 DIMENSION R(1),A(1),B(1),Q(1),W(1)
��00130 LP1=LP-1
���00140 LP2=LP1*NM+LP
���00150 LPP=LP2-NM
�00160 NM1=NM+1
���00170 C***********************************************************************
00180 C STORE ORIGINAL DIAGONAL
�����������������������������������������00190 C***********************************************************************
00200 L=0
���00210 DO 10 I=1,LP2,NM1
����00220 L=L+1
�00230 10 A(L)=R(I)
��00240 C***********************************************************************
00250 B(1)=0.
����00260 C***********************************************************************
00270 IF(LP-2)99,65,11
00280 11 SUM=0.
���00290 DO 12 I=1,LP-2
��00300 NR=(I-1)*LP
00310 DO 12 J=1,LP
����00320 IF((J-I).LT.2) GO TO 12
���00330 SUM=SUM+ABS(R(NR+J))
�00340 12 CONTINUE
�00350 IF(SUM.GT.0) GO TO 15
00360 SMALL=R(1)*1.E-8
���������������00370 IF(SMALL.EQ.0) SMALL=1.E-8
00380 R(LP)=SMALL
00390 R(LP*LP-LP+1)=SMALL
��00400 15 KK=0
��00410 DO 50 K=2,LP1
���00420 KL=KK+K
����00430 KU=KK+LP
���00440 KJ=K+1
00450 C***********************************************************************
00460 C MAKE SURE THERE IS AT LEAST ONE NON-ZERO ELEMENT IN THE FIRST ROW
���00470 C***********************************************************************
00480 IF(K-2) 99,16,19
00490 16 DO 17 J=2,KU
����00500 IF(R(J)-0.0) 19,17,19
00510 17 CONTINUE
���00520 18 TYPE 101
�00530 ERROR=-1
���00540 GO TO 99
������������������00550 C***********************************************************************
00560 C CALCULATE AND STORE MODIFIED COLUMN MATRIX W
00570 C***********************************************************************
00580 19 SUM=0.0
����00590 DO 20 J=KL,KU
���00600 20 SUM=SUM+R(J)**2
�00610 S=SQRT(SUM)
00620 B(K)=SIGN(S,-R(KL))
��00630 S=1./S
00640 W(K)=SQRT(ABS(R(KL))*S+1.)
00650 X=SIGN(S/W(K),R(KL))
�00660 R(KL)=W(K)
�00670 DO 30 I=KJ,LP
���00680 JJ=I+KK
����00690 W(I)=X*R(JJ)
����00700 30 R(JJ)=W(I)
���������������������������������������������������00710 C***********************************************************************
00720 C CALCULATE NEW R MATRIX WITH ROW K-1 NOW HAVING ZEROS OFF 2ND DIAGONAL
00730 C***********************************************************************
00740 DO 35 J=K,LP
����00750 JJ=J+1
00760 Q(J)=0.0
���00770 L=KK+J
00780 DO 33 I=K,J
00790 L=L+NM
00800 33 Q(J)=Q(J)+R(L)*W(I)
��00810 IF(JJ-LP)34,34,36
����00820 34 DO 35 I=JJ,LP
���00830 L=L+1
�00840 35 Q(J)=Q(J)+R(L)*W(I)
��00850 36 X=0.0
�00860 DO 40 J=K,LP
����00870 40 X=X+W(J)*Q(J)
���00880 X=.5*X
�����00890 DO 45 I=K,LP
����00900 45 Q(I)=X*W(I)-Q(I)
00910 LL=KK
�00920 KK=KK+NM
���00930 DO 50 I=K,LP
����00940 LL=LL+NM
���00950 DO 50 J=I,LP
����00960 L=LL+J
00970 50 R(L)=R(L)+Q(I)*W(J)+Q(J)*W(I)
��00980 C***********************************************************************
00990 C SORT OUTPUT
���01000 C***********************************************************************
01010 L=1
���01020 DO 60 I=1,LP
����01030 X=A(I)
01040 A(I)=R(L)
��01050 R(L)=X
01060 60 L=L+NM1
����01070 65 B(LP)=R(LPP)
����01080 99 RETURN
����������01090 101 FORMAT(48H4NO NON-ZERO OFF-DIAGONAL ELEMENTS IN FIRST ROW./
��01100 1' DIAGONAL ELEMENT IS AN EIGENVALUE--'/' NEED ONLY PERFORM EIGEN '
01110 2' OPERATION ON REMAINING SUBMATRIX'/)
����01120 END
���
��00010 C***********************************************************************
00020 C SUBROUTINE TO GENERATE EIGENVECTORS
�00030 C***********************************************************************
00040 SUBROUTINE EIGVEC (LP,NM,R,A,B,E,V,P,Q)
��00050 DIMENSION R(1),A(1),B(1),V(1),P(1),Q(1)
����������������������������������������������������������������������������������00060 C***********************************************************************
00070 C SET UP SIMULTANEOUS EQUATIONS FOR EIGEN VECTOR WITH EIGEN VALUE E
����00080 C***********************************************************************
00090 X=A(1)-E
���00100 Y=B(2)
00110 LP1=LP-1
���00120 DO 10 I=1,LP1
���00130 IF(ABS(X)-ABS(B(I+1))) 4,6,8
���00140 4 P(I)=B(I+1)
00150 Q(I)=A(I+1)-E
���00160 V(I)=B(I+2)
00170 Z=-X/P(I)
��00180 X=Z*Q(I)+Y
�00190 IF(LP1-I)5,10,5
�00200 5 Y=Z*V(I)
���00210 GO TO 10
���00220 6 IF(X)8,7,8
���������������������00230 7 X=1.0E-10
��00240 8 P(I)=X
00250 Q(I)=Y
00260 V(I)=0.
����00270 X=A(I+1)-(B(I+1)/X*Y+E)
���00280 Y=B(I+2)
���00290 10 CONTINUE
���00300 C***********************************************************************
00310 C SOLVE SIMULTANEOUS EQUATIONS FOR EIGEN VECTOR OF TRI-DIAGONAL MATRIX
�00320 C***********************************************************************
00330 20 IF(X) 21,28,21
��00340 21 V(LP)=1./X
�00350 22 I=LP1
�00360 V(I)=(1.-Q(I)*V(LP))/P(I)
�00370 X=V(LP)**2+V(I)**2
���00380 25 I=I-1
�00390 IF(I) 26,30,26
����������������������00400 26 V(I)=(1.-(Q(I)*V(I+1)+V(I)*V(I+2)))/P(I)
�00410 X=X+V(I)**2
00420 GO TO 25
���00430 28 V(LP)=1.0E10
����00440 GO TO 22
���00450 30 X=SQRT(X)
��00460 DO 31 I=1,LP
����00470 31 V(I)=V(I)/X
00480 C***********************************************************************
00490 C TRANSFORM EIGEN VECTOR TO SOLUTION OF ORIGINAL MATRIX
�00500 C***********************************************************************
00510 J=LP1*NM-NM
00520 K=LP
��00530 GO TO 42
���00540 32 K=K-1
�00550 J=J-NM
00560 Y=0.0
�00570 DO 35 I=K,LP
�������������������00580 L=J+I
�00590 35 Y=Y+V(I)*R(L)
���00600 DO 40 I=K,LP
����00610 L=J+I
�00620 40 V(I)=V(I)-Y*R(L)
00630 42 IF(J)32,44,32
���00640 44 RETURN
00650 END
���
��00010 C***********************************************************************
00020 C EIGEN VALUE SUBROUTINE FOR TRI-DIAGONAL MATRICES DWM 1517-UB
�00030 C***********************************************************************
00040 SUBROUTINE EIGVAL(LP,NM,M,E,A,B,F,W)
00050 DIMENSION E(1),A(1),B(1),F(1),W(1)
��00060 EQUIVALENCE (S1,IS1),(S2,IS2)
�����������������������������������������������00070 C***********************************************************************
00080 C FIND UPPER AND LOWER BOUNDS AND NORMALIZE INPUT
��00090 C***********************************************************************
00100 BD=ABS(A(1))
����00110 DO 5 I=2,LP
00120 5 BD=AMAX1(BD,ABS(A(I))+B(I)**2)
�00130 BD=BD+1.
���00140 DO 6 I=1,LP
00150 A(I)=A(I)/BD
����00160 B(I)=B(I)/BD
����00170 W(I)=1.
����00180 6 E(I)=-1.
���00190 DO 50 K=1,LP
����00200 8 IF((W(K)-E(K))/AMAX1(ABS(W(K)),ABS(E(K)),1.0E-9)-1.0E-7) 50,50,10
�00210 10 X=(W(K)+E(K))*.5
��������������������00220 C***********************************************************************
00230 C FIND NUMBER OF EIGEN VALUES ,N, GREATER THAN OR EQUAL TO X
��00240 C***********************************************************************
00250 IS2=1
�00260 F(1)=A(1)-X
00270 IF(F(1))102,104,104
��00280 102 IS1=-1
00290 N=0
���00300 GO TO 105
��00310 104 IS1=1
�00320 N=1
���00330 105 DO 120 I=2,LP
���00340 IF(B(I))106,113,106
��00350 106 IF(B(I-1))107,114,107
00360 107 IF(ABS(F(I-1))+ABS(F(I-2))-1.0E-15) 110,112,112
����00370 110 F(I-1)=F(I-1)*1.0E15
��������������������������00380 F(I-2)=F(I-2)*1.0E15
�00390 112 F(I)=(A(I)-X)*F(I-1)-B(I)**2*F(I-2)
�00400 GO TO 115
��00410 113 F(I)=(A(I)-X)*SIGN(1.,S1)
�00420 GO TO 115
��00430 114 F(I)=(A(I)-X)*F(I-1)-SIGN(B(I)**2,S2)
����00440 115 S2=S1
�00450 IF(F(I))116,117,116
��00460 116 S1=SIGN(S1,F(I))
00470 IF(IS2+IS1)117,120,117
����00480 117 N=N+1
�00490 120 CONTINUE
���00500 C***********************************************************************
00510 C TRAP EIGEN VALUES IN SMALLER AND SMALLER BOUNDS
��00520 C***********************************************************************
��������������������00530 N=LP-N
00540 IF(N-K)20,12,12
�00550 12 DO 15 J=K,N
00560 15 W(J)=X
00570 20 N=N+1
�00580 IF(LP-N)8,24,24
�00590 24 DO 26 J=N,LP
����00600 IF(X-E(J))8,8,26
00610 26 E(J)=X
00620 GO TO 8
����00630 50 CONTINUE
���00640 C***********************************************************************
00650 C RESTORE INPUT AND ORDER EIGEN VALUES
���00660 C***********************************************************************
00670 DO 60 I=1,LP
����00680 A(I)=A(I)*BD
����00690 B(I)=B(I)*BD
����00700 60 F(I)=(W(I)+E(I))*BD*.5
����00710 J=LP
�������00720 K=1
���00730 DO 70 I=1,LP
����00740 IF(ABS(F(K))-ABS(F(J))) 63,63,65
����00750 63 E(I)=F(J)
��00760 J=J-1
�00770 GO TO 70
���00780 65 E(I)=F(K)
��00790 K=K+1
�00800 70 CONTINUE
���00810 IF(ISIGN(1,M)) 75,80,80
���00820 75 DO 77 I=1,LP
����00830 77 F(I)=E(I)
��00840 J=LP
��00850 DO 79 I=1,LP
����00860 E(I)=F(J)
��00870 79 J=J-1
�00880 80 CONTINUE
���00890 RETURN
00900 END
���
��00010 C***********************************************************************
������������������������������������������������������������00020 C SUBROUTINE TO GENERATE FUNCTION FROM DISCRETE DATA POINTS
����00030 C***********************************************************************
00040 SUBROUTINE FUNGN(NB,N,M,SCAL1)
�00050 INTEGER ERROR
���00060 COMMON /XX/ ERROR
����00070 COMMON /YY/ INCA
00080 COMMON /Z/ A(1)
�00090 K=1+NB
00100 L=1+INCA
���00110 TIM =A(L)
��00120 10 IF(M+INCA-L-3) 30,20,20
���00130 20 DT=A(L+2)-A(L)
��00140 DP=A(L+3)-A(L+1)
00150 L=L+2
�00160 IF (DT) 30,10,40
00170 30 ERROR=1
��00180 GO TO 70
���00190 40 SLOPE=DP/DT
����������������������������������������00200 50 IF (A(L)-TIM) 10,10,60
����00210 60 A(K)=A(L-1)+(TIM -A(L-2))*SLOPE
00220 TIM =TIM +SCAL1
�00230 K=K+1
�00240 IF(N+NB-K) 70,65,50
��00250 65 IF (A(L)-TIM) 10,66,60
����00260 66 A(K)=A(L+1)
00270 70 RETURN
00280 END
���
��00010 C***********************************************************************
00020 C RESPONSE PROGRAM
00030 C***********************************************************************
00040 SUBROUTINE RESPON(W,P,X,NM,NT,L,DAMP,DT,NTAG,NTYPE)
00050 COMMON /YY/ INCA
00060 COMMON /Z/ XM(1)
����������������������������������������00070 DIMENSION W(1),P(1),X(1)
��00080 NTYPE=NTYPE+1
���00090 K=1
���00100 C1=DT/2.
���00110 C2=C1*DT/3.
00120 C3=C2*2.
���00130 DO 160 N=1,NM
���00140 NOUT=NT+1
��00150 C4=W(N)**2
�00160 C5=2.*DAMP*W(N)
�00170 F=1.+C1*C5+C2*C4
00180 DISP=0.0
���00190 VEL=0.0
����00200 IL=L*(N-1)*NTAG+1
����00210 ACEL=P(IL)*XM(N+INCA)
00220 IL=IL+1
����00230 IH=IL+L-2
��00240 DO 160 I=IL,IH
��00250 A=VEL+C1*ACEL
���00260 B=DISP+DT*VEL+C3*ACEL
00270 ACEL=(P(I)*XM(N+INCA)-C5*A-C4*B)/F
����������������������00280 VEL=A+C1*ACEL
���00290 DISP=B+C2*ACEL
��00300 IF(NOUT-I) 160,150,160
����00310 150 GO TO (151,152,153),NTYPE
�00320 151 X(K)=DISP
��00330 GO TO 154
��00340 152 X(K)=VEL
���00350 GO TO 154
��00360 153 X(K)=ACEL
��00370 154 K=K+1
�00380 NOUT=NOUT+NT
����00390 160 CONTINUE
���00400 RETURN
00410 END
���
��00010 SUBROUTINE MSTOR
00020 INTEGER FREC,FRET,ERROR
�00030 COMMON /XX/ ERROR
����00040 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
���00050 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
����������������������������00060 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
00070 NNUM=NNUM+10
����00080 DO 10 I=1,4
00090 IADDR=NME(I)
����00100 ITMP=FREC(NNUM,IADDR)
00110 CALL FRET(NNUM-10,IADDR)
��00120 10 NME(I)=ITMP
���00130 INC1=NME(1)-LOC(NAME)
00140 INC2=NME(2)-LOC(NCOL)
00150 INC3=NME(3)-LOC(NROW)
00160 INC4=NME(4)-LOC(NN)
��00170 RETURN
00180 END
���
��00010 C * * * * *GETS MATRICES FROM DISK FILE * * * * *
���00020 SUBROUTINE MGET(NAM)
�00030 INTEGER FREZ,FRET,DISKIO,ERROR
�00040 COMMON /XX/ ERROR
����00050 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
��������������������������������������������������00060 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1),NME(4),NSIZE
���00070 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00080 DIMENSION FBUF(1),NFILN(2)
00090 DATA NFILN(2) /5H .MAT/
���00100 C * * * * * REQUEST FREE STORAGE * * * *
��00110 SLASH='//'
�00120 IPT=FREZ(128)
���00130 INC=IPT-LOC(FBUF)
����00140 NFILN(1)=NAM
����00150 NMB=0
�00160 NREC=1
00170 ISET=0
00180 NP=1
��00190 IERR=DISKIO(0,NFILN,NREC,FBUF(1+INC))
����00200 IF (IERR.NE.0) GO TO 50
���00210 10 IF ((NP+2).LT.129) GO TO 20
����00220 11 NREC=NREC+1
��������������������00230 IERR=DISKIO(0,NFILN,NREC,FBUF(INC+1))
����00240 IF (IERR.NE.0) GO TO 50
���00250 NP=1
��00260 IF (ISET.EQ.1) GO TO 45
���00270 C * * * * * LIST MATRIX * * * * *
����00280 20 DO 21 J=1,5
00290 CALL GET(FBUF(NP+INC),J,IC)
����00300 CALL PUT(NAMA,J,IC)
��00310 21 CONTINUE
���00320 NR=FBUF(NP+1+INC)
����00330 NC=FBUF(NP+2+INC)
����00340 NP=NP+2
����00350 NS=NR*NC
���00360 CALL MLIST(NAMA)
00370 IF (ERROR.EQ.0) GO TO 25
��00380 IF (ERROR.NE.4) GO TO 60
��00390 ERROR=0
����00400 NP=NP-2
����������������������������������00410 CALL DELETE(NAMA)
����00420 TYPE 22,NAMA
����00430 22 FORMAT(1H ,'MATRIX ',A5,' REPLACED'/)
����00440 GO TO 20
���00450 25 K=0
���00460 NMB=NMB+1
��00470 DO 30 I=1,NS
����00480 IF ((NP+I-K).LT.129) GO TO 40
��00490 NREC=NREC+1
00500 IERR=DISKIO(0,NFILN,NREC,FBUF(1+INC))
����00510 NP=1
��00520 K=I
���00530 40 A(I+INCA)=FBUF(INC+NP+I-K)
00540 30 CONTINUE
���00550 NP=NP+I-K+1
00560 IF (NP.LT.129) GO TO 45
���00570 ISET=1
00580 GO TO 11
���00590 C * * * IF THERE ARE MORE MATRICES, READ & LIST THEM * * *
��������������00600 45 ISET=0
00610 IF (FBUF(INC+NP).EQ.SLASH) GO TO 60
�00620 GO TO 10
���00630 50 TYPE 100,IERR
���00640 100 FORMAT(1H ,'ERROR ',I3/)
��00650 IF (IERR.EQ.2) TYPE 300,NFILN
��00660 300 FORMAT(1H ,'FILE ',2A5,' NOT FOUND'/)
����00670 IERR=0
00680 GO TO 70
���00690 60 IERR=DISKIO(2,NFILN,NREC,FBUF(INC+1))
����00700 IF (IERR.NE.0) GO TO 50
���00710 70 CALL FRET(128,IPT)
���00720 TYPE 200,NMB,NFILN
���00730 200 FORMAT(1H ,I3,' MATRICES RETRIEVED FROM DISK FILE ',2A5/)
����00740 RETURN
00750 END
���
������������������������������������������00010 C * * * * * * SUBROUTINE TO SAVE CURRENT MATRICES * * * * * *
�00020 SUBROUTINE MSAVE(NAM,NV)
��00030 INTEGER FREZ,FRET,DISKIO,ERROR,FRES
�00040 COMMON /FF/ NFMX,ITAPE,NWMX
����00050 COMMON /XX/ ERROR
����00060 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
00070 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1)
�00080 COMMON /ZZ/ NUM,NNUM,NX,NR,NC,MPYTAG
00090 DIMENSION NFILN(2),FBUF(1),NW(1),FNUMB(1)
00100 DATA NFILN(2) /5H .MAT/,IBL/' '/
����00110 IPT=FREZ(128)
���00120 INC=IPT-LOC(FBUF)
����00130 NREC=1
00140 NP=1
��������������������������������00150 NFILN(1)=NAM
����00160 IF (NV.EQ.NUM) GO TO 9
����00170 C * * * * * * SAVES "N" MATRICES * * * * * *
���00180 TYPE 1
00190 1 FORMAT(1H ,'ENTER MATRICES TO SAVE:'/)
���00200 NWP=FRES(NV,IBL)
00210 INW=NWP-LOC(NW)
�00220 3 NA=NV
�00230 NF=0
��00240 NWMX=NV
����00250 NFMX=1
00260 CALL FREAD(NA,NW(1+INW),NF,FNUMB)
���00270 IF ((NA.EQ.NV).AND.(NF.EQ.0)) GO TO 5
����00280 TYPE 4,NV
��00290 4 FORMAT(1H ,'ERROR. ENTER ',I3,' MATRICES TO BE SAVED.'/)
����00300 GO TO 3
����00310 5 DO 7 I=1,NV
00320 DO 6 J=1,NUM
��������������00330 6 IF (NAME(INC1+J).EQ.NW(I+INW)) GO TO 8
���00340 ERROR=2
����00350 GO TO 20
���00360 8 CALL SAVE(J,FBUF(INC+1),NFILN(1),NREC,NP)
00370 7 CONTINUE
���00380 GO TO 12
���00390 C * * * * * * SAVES ALL CURRENT MATRICES * * * * * *
00400 9 DO 10 I=1,NUM
���00410 CALL SAVE(I,FBUF(INC+1),NFILN(1),NREC,NP)
00420 10 CONTINUE
���00430 12 FBUF(INC+NP)='//'
����00440 NP=NP+1
����00450 IERR=DISKIO(-1,NFILN,NREC,FBUF(1+INC))
���00460 IF (IERR.NE.0) GO TO 30
���00470 IERR=DISKIO(-2,NFILN,NREC,FBUF(1+INC))
���00480 IF (IERR.NE.0) GO TO 30
�������������00490 TYPE 200,NV,NFILN
����00500 200 FORMAT(1H ,I3,' MATRICES STORED IN DISK FILE ',2A5/)
����00510 GO TO 20
���00520 30 TYPE 100,IERR
���00530 100 FORMAT(1H ,'ERROR ',I3)
���00540 20 IF (NV.NE.NUM) CALL FRET(NV,NWP)
����00550 22 CALL FRET(128,IPT)
���00560 RETURN
00570 END
���
��00010 C * * * * SAVES ONE MATRIX IN DISK FILE NFILN * * * *
����00020 SUBROUTINE SAVE(I,FBUF,NFILN,NREC,NP)
����00030 COMMON /YY/ INCA,INC1,INC2,INC3,INC4
00040 COMMON /Z/ A(1),NAME(1),NCOL(1),NROW(1),NN(1)
�00050 DIMENSION FBUF(1),NFILN(2)
00060 INTEGER DISKIO
�������00070 ISET=0
00080 IF ((NP+2).LT.129) GO TO 30
����00090 5 IERR=DISKIO(-1,NFILN,NREC,FBUF)
00100 IF (IERR.NE.0) GO TO 20
���00110 DO 10 J=1,128
���00120 10 FBUF(J)=0.0
00130 NREC=NREC+1
00140 NP=1
��00150 IF (ISET.EQ.1) GO TO 60
���00160 GO TO 30
���00170 20 TYPE 100,IERR
���00180 100 FORMAT(1H ,'I/O ERROR ',I3)
����00190 GO TO 60
���00200 C * * * * SAVE NAME, # OF ROWS, # OF COLS * * * *
��00210 30 DO 31 J=1,5
00220 CALL GET(NAME(I+INC1),J,IC)
����00230 CALL PUT(FBUF(NP),J,IC)
���00240 31 CONTINUE
���������������������������������00250 FBUF(NP+1)=NROW(I+INC3)
���00260 FBUF(NP+2)=NCOL(I+INC2)
���00270 INCA=NN(I+INC4)-LOC(A)
����00280 NP=NP+2
����00290 NS=NROW(I+INC3)*NCOL(I+INC2)
���00300 K=0
���00310 C * * * * SAVE MATRIX ELEMENTS * * * *
����00320 DO 50 J=1,NS
����00330 IF ((NP+J-K).LT.129) GO TO 40
��00340 IERR=DISKIO(-1,NFILN,NREC,FBUF)
00350 IF (IERR.NE.0) GO TO 20
���00360 DO 35 L=1,128
���00370 35 FBUF(L)=0.0
00380 NP=1
��00390 NREC=NREC+1
00400 K=J
���00410 40 FBUF(NP+J-K)=A(INCA+J)
����00420 50 CONTINUE
���00430 NP=NP+J-K+1
����������00440 IF (NP.LT.129) GO TO 60
���00450 ISET=1
00460 GO TO 5
����00470 60 ISET=0
00480 RETURN
00490 END
���
��00010 C SUBROUTINE FIXEM -FIXED END MOMENTS FOR MATRIX 20,11
����00020 SUBROUTINE FIXEM(NTIME)
���00030 COMMON /YY/ INCA
00040 COMMON /Z/ A(1)
�00050 DIMENSION DATA(3)
����00060 TYPE 10
����00070 10 FORMAT(2X,'LOAD,',1X,'LENGTH'/)
���00080 DO 100 I=1,NTIME
00090 20 NA=-2
����00100 NF=2
��00110 CALL FREAD(NA,NA,NF,DATA)
�00120 W=DATA(1)
��00130 XL=DATA(2)
�00140 MEMBR=(I-1)*4+INCA
���00150 WXL=W*XL/2.
00160 WXL2=W*XL**2./12.
������������������������00170 A(MEMBR+1)=-WXL
�00180 A(MEMBR+2)=WXL2
�00190 A(MEMBR+3)=-WXL
�00200 A(MEMBR+4)=-WXL2
00210 GO TO 100
��00220 GO TO 20
���00230 100 CONTINUE
00240 RETURN
00250 END
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