1 subroutine finsum ( timhrz, timesq, timvrt, hrzcmp, sqcmpn,
2 $ vrtcmp, ccmstr, rcmstr, output )
13 integer hrzcmp, sqcmpn, vrtcmp, output
15 integer ccmstr (*), rcmstr (*)
17 real timesq, timhrz, timvrt
21 if ( hrzcmp .gt. 0 )
then
22 write (output, 60000) hrzcmp, timhrz
23 call
fnrsum( 1, hrzcmp, ccmstr, rcmstr, output )
26 if ( sqcmpn .gt. 0 )
then
27 write (output, 61000) sqcmpn, timesq
28 call
fnrsum( hrzcmp + 1, hrzcmp + sqcmpn, ccmstr, rcmstr,
32 if ( vrtcmp .gt. 0 )
then
33 write (output, 62000) vrtcmp, timvrt
34 call
fnrsum( hrzcmp + sqcmpn + 1, hrzcmp + sqcmpn + vrtcmp,
35 $ ccmstr, rcmstr, output )
40 60000
format (/
'0fine decomposition of horizontal block (hr-hc)',
41 $ /
' number of connected components:', i10,
42 $ /
' time required:', 1pe10.1,
43 $ /
'0 component rows columns' )
45 61000
format (/
'0fine decomposition of square block (sr-sc)',
46 $ /
' number of strong components:', i10,
47 $ /
' time required:', 1pe10.1,
48 $ /
'0 component rows columns' )
50 62000
format (/
'0fine decomposition of vertical block (vr-vc)',
51 $ /
' number of connected components:', i10,
52 $ /
' time required:', 1pe10.1,
53 $ /
'0 component rows columns' )
subroutine finsum(timhrz, timesq, timvrt, hrzcmp, sqcmpn, vrtcmp, ccmstr, rcmstr, output)
subroutine fnrsum(fstcmp, lstcmp, ccmstr, rcmstr, output)
1.8.5