high_res_cube/eddy_flux/calcUVB2_ttcp.m

function m = calcUVB2_ttcp(ips, Spat, Tpat, Upat, Vpat, ilist, nlay, ne)

% Function m = calcTBave(ips, Spat, Tpat, Upat, Vpat, ilist, nlay, ne)
% 
%
% INPUTS
% ips      vector of IP values (last part of IP address)
% Tpat     string containing T-data file pattern
% Upat     string containing U-data file pattern
% Vpat     string containing V-data file pattern
% ilist    list of iteration values
% nlay     number of z layers
% ne       number of values alone each edge of each face
%
% OUTPUTS
% m        output array of dimension ns*nps

if nargin ~= 8
  disp('Error: wrong number of arguments')
  exit
end

deltatT = 1200;                % model time step size (s)
tavefreq = 259200;             % averaging period (s)
startDate = datenum(1992,1,1); % model integration starting date

oldyear = -1;
newyear = oldyear;

nps = 6 * ne*ne;
tx = 85;
ty = 85;
nt = ne*ne*6/(tx*ty);
cx = ne;
cy = ne;
nz = 1;

delR   = [ 
    10.00, 10.00, 10.00, 10.00, 10.00, 10.00, 10.00, 10.01, ...
    10.03, 10.11, 10.32, 10.80, 11.76, 13.42, 16.04 , 19.82, 24.85, ...
    31.10, 38.42, 46.50, 55.00, 63.50, 71.58, 78.90, 85.15, 90.18, ...
    93.96, 96.58, 98.25, 99.25,100.01,101.33,104.56,111.33,122.83, ...
    139.09,158.94,180.83,203.55,226.50,249.50,272.50,295.50,318.50, ...
    341.50,364.50,387.50,410.50,433.50,456.50 ];
R = cumsum(delR) - 0.5*delR;

vnam = [ 'U_'; 'V_'; 'T_'; 'S_'; 'B_'; 'B1'; ...
         'UT'; 'VT'; 'US'; 'VS'; 'UB'; 'VB' ];

lcstr = [ '! ( rm -f %s ; ttcp -r > %s ) > /dev/null 2>&1 &' ];
rcstr = [ '!ssh -x 10.12.2.%d ''( dd bs=6242400 skip=%d ' ...
          ' count=1 if=/home/edhill/%s' ...
          ' | ttcp -t 10.12.2.%d ) > /dev/null 2>&1''' ];

disp(['lcstr = "' lcstr '"']);
disp(['rcstr = "' rcstr '"']);

il = 1;
for il = 1:nlay
  
  a = sprintf('Slice: %g',il);
  %  disp(a);
  
  %  Zero the accumulators
  nm = 0;
  for io = 1:size(vnam,1)
    comm = sprintf('%s_acc = zeros(ne,ne,6);', vnam(io,:));
    eval(comm)
  end
  
  it = 1;
  for it = 1:length(ilist)
    
    iter = ilist(it);
    str = datestr(startDate + (iter*deltatT-tavefreq/2)/60/60/24);
    dv = datevec(startDate + (iter*deltatT-tavefreq/2)/60/60/24);
    newyear = dv(1);
    
    sfname = sprintf(Spat, ilist(it));
    tfname = sprintf(Tpat, ilist(it));
    ufname = sprintf(Upat, ilist(it));
    vfname = sprintf(Vpat, ilist(it));
    disp([ a '  ' str '  ' tfname ]);
    skip = il - 1;
    eval( sprintf(lcstr,         sfname, sfname) );
    eval( sprintf(rcstr, ips(2), skip,   sfname, ips(1)) );
    eval( sprintf(lcstr,         tfname, tfname) );
    eval( sprintf(rcstr, ips(3), skip,   tfname, ips(1)) );
    eval( sprintf(lcstr,         ufname, ufname) );
    eval( sprintf(rcstr, ips(4), skip,   ufname, ips(1)) );
    eval( sprintf(lcstr,         vfname, vfname) );
    eval( sprintf(rcstr, ips(5), skip,   vfname, ips(1)) );
    sfid = fopen(sfname, 'r', 'ieee-be');
    tfid = fopen(tfname, 'r', 'ieee-be');
    ufid = fopen(ufname, 'r', 'ieee-be');
    vfid = fopen(vfname, 'r', 'ieee-be');
    offset = (il - 1)*nps*4;
    
    %  Convert the horrible JPL mdsio layout to six sane faces
    %fseek(sfid, offset, 'bof');
    scube = unmangleJPL1( ...
        reshape(fread(sfid, nps, 'real*4'),tx*nt,ty), ne, tx );
    
    %fseek(tfid, offset, 'bof');
    tcube = unmangleJPL1( ...
        reshape(fread(tfid, nps, 'real*4'),tx*nt,ty), ne, tx );

    %fseek(ufid, offset, 'bof');
    ucube = unmangleJPL1( ...
        reshape(fread(ufid, nps, 'real*4'),tx*nt,ty), ne, tx );
    
    %fseek(vfid, offset, 'bof');
    vcube = unmangleJPL1( ...
        reshape(fread(vfid, nps, 'real*4'),tx*nt,ty), ne, tx );

    fclose(sfid);
    fclose(tfid);
    fclose(ufid);
    fclose(vfid);
    
    %  Compute the density
    bcube   = zeros(size(scube));
    bcubem1 = zeros(size(scube));
    for icf = 1:6
      % pressure_for_eos.F :
      %   locPres(i,j) = -rhoConst*rC(k)*gravity*maskC(i,j,k,bi,bj)
      %   rhoConst = 9.997999999999999E+02  /* Ref density ( kg/m^3 ) */
      %   gravity  = 9.810000000000000E+00  /* Grav accel ( m/s^2 ) */
      p = 0.09998 * 9.81 * R(il);
      bcube(:,:,icf) = ...
          eh3densjmd95( squeeze(scube(:,:,icf)), ...
                        squeeze(tcube(:,:,icf)), p ) * -9.81 / 1000;
      if il > 1
        p = 0.09998 * 9.81 * R(il-1);
        bcubem1(:,:,icf) = ...
            eh3densjmd95( scube(:,:,icf), ...
                          tcube(:,:,icf), p ) * -9.81 / 1000;
      end
    end
    tmask   = double(tcube ~= 0.0);
    scube   = scube .* tmask;
    bcube   = bcube .* tmask;
    bcubem1 = bcubem1 .* tmask;

    %  Fill the (ne+1)*(ne+1) grid with T,S,B values
    ni = ne;    nip1 = ni + 1;
    nj = ne;    njp1 = nj + 1;
    ucubep1 = zeros( [ nip1 njp1 6 ] );
    vcubep1 = zeros( [ nip1 njp1 6 ] );
    for icf = 1:6
      ucubep1(2:nip1,2:njp1,icf) = ucube(:,:,icf);
      vcubep1(2:nip1,2:njp1,icf) = vcube(:,:,icf);
    end

    %  Do the upwind-edge U,V exchanges
    ucubep1(1,2:njp1,1) = cube(ni:-1:1,nj,5);   % - 
    ucubep1(2:nip1,1,1) = cube(1:ni,nj,6);      % -
    ucubep1(1,2:njp1,2) = cube(ni,1:nj,1);      % -
    ucubep1(2:nip1,1,2) = cube(ni,nj:-1:1,6);   % -
    ucubep1(1,2:njp1,3) = cube(ni:-1:1,nj,1);   % -
    ucubep1(2:nip1,1,3) = cube(1:ni,nj,2);      % -
    ucubep1(1,2:njp1,4) = cube(ni,1:nj,3);      % -
    ucubep1(2:nip1,1,4) = cube(ni,nj:-1:1,2);   % -
    ucubep1(1,2:njp1,5) = cube(ni:-1:1,nj,3);   % -
    ucubep1(2:nip1,1,5) = cube(1:ni,nj,4);      % -
    ucubep1(1,2:njp1,6) = cube(ni,1:nj,5);      % -
    ucubep1(2:nip1,1,6) = cube(ni,nj:-1:1,4);   % -

    vcubep1(1,2:njp1,1) = cube(ni:-1:1,nj,5);   % - 
    vcubep1(2:nip1,1,1) = cube(1:ni,nj,6);      % -
    vcubep1(1,2:njp1,2) = cube(ni,1:nj,1);      % -
    vcubep1(2:nip1,1,2) = cube(ni,nj:-1:1,6);   % -
    vcubep1(1,2:njp1,3) = cube(ni:-1:1,nj,1);   % -
    vcubep1(2:nip1,1,3) = cube(1:ni,nj,2);      % -
    vcubep1(1,2:njp1,4) = cube(ni,1:nj,3);      % -
    vcubep1(2:nip1,1,4) = cube(ni,nj:-1:1,2);   % -
    vcubep1(1,2:njp1,5) = cube(ni:-1:1,nj,3);   % -
    vcubep1(2:nip1,1,5) = cube(1:ni,nj,4);      % -
    vcubep1(1,2:njp1,6) = cube(ni,1:nj,5);      % -
    vcubep1(2:nip1,1,6) = cube(ni,nj:-1:1,4);   % -

    %  Get U,V values on the T grid points
    masku = 1.0 - abs(diff(double(tcubep1(2:nip1,:,:) == 0.0),1,2));
    maskv = 1.0 - abs(diff(double(tcubep1(:,2:nip1,:) == 0.0),1,1));
    diffu = 0.5*diff(tcubep1(2:nip1,:,:),1,2);
    diffv = 0.5*diff(tcubep1(:,2:nip1,:),1,1);
    tonu = tcube(:,:,:) + masku.*diffu;
    tonv = tcube(:,:,:) + maskv.*diffv;

    if ((newyear ~= oldyear) && (nm > 0)) || (it == length(ilist))

      %  Write if its a new year or the last of all entries
      disp(['  ==>  Writing files for ==> ' sprintf('%d',oldyear)]);
      for io = 1:size(vnam,1)
        comm = sprintf( ...
            '%s_ido = fopen(''%s_tave_%d'', ''a'', ''ieee-be'');', ...
            vnam(io,:), vnam(io,:), oldyear );
        eval(comm)
        comm = sprintf( '%s_acc = %s_acc ./ nm;',vnam(io,:), ...
                        vnam(io,:));
        eval(comm)
        comm = sprintf('fwrite(%s_ido, %s_acc, ''real*4'');', ...
                       vnam(io,:), vnam(io,:) );
        eval(comm)
        comm = sprintf( 'fclose(%s_ido);', vnam(io,:) );
        eval(comm)
        
        %  Re-zero the accumulators
        comm = sprintf('%s_acc = zeros(ne,ne,6);', vnam(io,:));
        eval(comm)
      end

      nm = 0;
      
    end
    
    %  Accumulate partial sums
    U__acc = U__acc + ucube;
    V__acc = V__acc + vcube;
    T__acc = T__acc + tcube;
    S__acc = S__acc + scube;
    B__acc = B__acc + bcube;
    B1_acc = B1_acc + bcubem1;
    
    UT_acc = UT_acc + tonu.*ucube;
    VT_acc = VT_acc + tonv.*vcube;
    US_acc = US_acc + sonu.*ucube;
    VS_acc = VS_acc + sonv.*vcube;
    UB_acc = UB_acc + bonu.*ucube;
    VB_acc = VB_acc + bonv.*vcube;

    nm = nm + 1;
    
    oldyear = newyear;
    
  end
end

1	edhill	1.1	function m = calcUVB2_ttcp(ips, Spat, Tpat, Upat, Vpat, ilist, nlay, ne)
2
3			% Function m = calcTBave(ips, Spat, Tpat, Upat, Vpat, ilist, nlay, ne)
4			%
5			%
6			% INPUTS
7			% ips vector of IP values (last part of IP address)
8			% Tpat string containing T-data file pattern
9			% Upat string containing U-data file pattern
10			% Vpat string containing V-data file pattern
11			% ilist list of iteration values
12			% nlay number of z layers
13			% ne number of values alone each edge of each face
14			%
15			% OUTPUTS
16			% m output array of dimension ns*nps
17
18			if nargin ~= 8
19			disp('Error: wrong number of arguments')
20			exit
21			end
22
23			deltatT = 1200; % model time step size (s)
24			tavefreq = 259200; % averaging period (s)
25			startDate = datenum(1992,1,1); % model integration starting date
26
27			oldyear = -1;
28			newyear = oldyear;
29
30			nps = 6 * ne*ne;
31			tx = 85;
32			ty = 85;
33			nt = nene6/(tx*ty);
34			cx = ne;
35			cy = ne;
36			nz = 1;
37
38			delR = [
39			10.00, 10.00, 10.00, 10.00, 10.00, 10.00, 10.00, 10.01, ...
40			10.03, 10.11, 10.32, 10.80, 11.76, 13.42, 16.04 , 19.82, 24.85, ...
41			31.10, 38.42, 46.50, 55.00, 63.50, 71.58, 78.90, 85.15, 90.18, ...
42			93.96, 96.58, 98.25, 99.25,100.01,101.33,104.56,111.33,122.83, ...
43			139.09,158.94,180.83,203.55,226.50,249.50,272.50,295.50,318.50, ...
44			341.50,364.50,387.50,410.50,433.50,456.50 ];
45			R = cumsum(delR) - 0.5*delR;
46
47			vnam = [ 'U_'; 'V_'; 'T_'; 'S_'; 'B_'; 'B1'; ...
48			'UT'; 'VT'; 'US'; 'VS'; 'UB'; 'VB' ];
49
50			lcstr = [ '! ( rm -f %s ; ttcp -r > %s ) > /dev/null 2>&1 &' ];
51			rcstr = [ '!ssh -x 10.12.2.%d ''( dd bs=6242400 skip=%d ' ...
52			' count=1 if=/home/edhill/%s' ...
53			' \| ttcp -t 10.12.2.%d ) > /dev/null 2>&1''' ];
54
55			disp(['lcstr = "' lcstr '"']);
56			disp(['rcstr = "' rcstr '"']);
57
58			il = 1;
59			for il = 1:nlay
60
61			a = sprintf('Slice: %g',il);
62			% disp(a);
63
64			% Zero the accumulators
65			nm = 0;
66			for io = 1:size(vnam,1)
67			comm = sprintf('%s_acc = zeros(ne,ne,6);', vnam(io,:));
68			eval(comm)
69			end
70
71			it = 1;
72			for it = 1:length(ilist)
73
74			iter = ilist(it);
75			str = datestr(startDate + (iter*deltatT-tavefreq/2)/60/60/24);
76			dv = datevec(startDate + (iter*deltatT-tavefreq/2)/60/60/24);
77			newyear = dv(1);
78
79			sfname = sprintf(Spat, ilist(it));
80			tfname = sprintf(Tpat, ilist(it));
81			ufname = sprintf(Upat, ilist(it));
82			vfname = sprintf(Vpat, ilist(it));
83			disp([ a ' ' str ' ' tfname ]);
84			skip = il - 1;
85			eval( sprintf(lcstr, sfname, sfname) );
86			eval( sprintf(rcstr, ips(2), skip, sfname, ips(1)) );
87			eval( sprintf(lcstr, tfname, tfname) );
88			eval( sprintf(rcstr, ips(3), skip, tfname, ips(1)) );
89			eval( sprintf(lcstr, ufname, ufname) );
90			eval( sprintf(rcstr, ips(4), skip, ufname, ips(1)) );
91			eval( sprintf(lcstr, vfname, vfname) );
92			eval( sprintf(rcstr, ips(5), skip, vfname, ips(1)) );
93			sfid = fopen(sfname, 'r', 'ieee-be');
94			tfid = fopen(tfname, 'r', 'ieee-be');
95			ufid = fopen(ufname, 'r', 'ieee-be');
96			vfid = fopen(vfname, 'r', 'ieee-be');
97			offset = (il - 1)nps4;
98
99			% Convert the horrible JPL mdsio layout to six sane faces
100			%fseek(sfid, offset, 'bof');
101	edhill	1.2	scube = unmangleJPL1( ...
102			reshape(fread(sfid, nps, 'real4'),txnt,ty), ne, tx );
103	edhill	1.1
104			%fseek(tfid, offset, 'bof');
105	edhill	1.2	tcube = unmangleJPL1( ...
106			reshape(fread(tfid, nps, 'real4'),txnt,ty), ne, tx );
107	edhill	1.1
108			%fseek(ufid, offset, 'bof');
109	edhill	1.2	ucube = unmangleJPL1( ...
110			reshape(fread(ufid, nps, 'real4'),txnt,ty), ne, tx );
111	edhill	1.1
112			%fseek(vfid, offset, 'bof');
113	edhill	1.2	vcube = unmangleJPL1( ...
114			reshape(fread(vfid, nps, 'real4'),txnt,ty), ne, tx );
115	edhill	1.1
116			fclose(sfid);
117			fclose(tfid);
118			fclose(ufid);
119			fclose(vfid);
120
121			% Compute the density
122			bcube = zeros(size(scube));
123			bcubem1 = zeros(size(scube));
124			for icf = 1:6
125			% pressure_for_eos.F :
126			% locPres(i,j) = -rhoConstrC(k)gravity*maskC(i,j,k,bi,bj)
127			% rhoConst = 9.997999999999999E+02 /* Ref density ( kg/m^3 ) */
128			% gravity = 9.810000000000000E+00 /* Grav accel ( m/s^2 ) */
129			p = 0.09998 * 9.81 * R(il);
130			bcube(:,:,icf) = ...
131			eh3densjmd95( squeeze(scube(:,:,icf)), ...
132			squeeze(tcube(:,:,icf)), p ) * -9.81 / 1000;
133			if il > 1
134			p = 0.09998 * 9.81 * R(il-1);
135			bcubem1(:,:,icf) = ...
136			eh3densjmd95( scube(:,:,icf), ...
137			tcube(:,:,icf), p ) * -9.81 / 1000;
138			end
139			end
140			tmask = double(tcube ~= 0.0);
141			scube = scube .* tmask;
142			bcube = bcube .* tmask;
143			bcubem1 = bcubem1 .* tmask;
144
145			% Fill the (ne+1)*(ne+1) grid with T,S,B values
146			ni = ne; nip1 = ni + 1;
147			nj = ne; njp1 = nj + 1;
148	edhill	1.2	ucubep1 = zeros( [ nip1 njp1 6 ] );
149			vcubep1 = zeros( [ nip1 njp1 6 ] );
150	edhill	1.1	for icf = 1:6
151	edhill	1.2	ucubep1(2:nip1,2:njp1,icf) = ucube(:,:,icf);
152			vcubep1(2:nip1,2:njp1,icf) = vcube(:,:,icf);
153	edhill	1.1	end
154
155	edhill	1.2	% Do the upwind-edge U,V exchanges
156			ucubep1(1,2:njp1,1) = cube(ni:-1:1,nj,5); % -
157			ucubep1(2:nip1,1,1) = cube(1:ni,nj,6); % -
158			ucubep1(1,2:njp1,2) = cube(ni,1:nj,1); % -
159			ucubep1(2:nip1,1,2) = cube(ni,nj:-1:1,6); % -
160			ucubep1(1,2:njp1,3) = cube(ni:-1:1,nj,1); % -
161			ucubep1(2:nip1,1,3) = cube(1:ni,nj,2); % -
162			ucubep1(1,2:njp1,4) = cube(ni,1:nj,3); % -
163			ucubep1(2:nip1,1,4) = cube(ni,nj:-1:1,2); % -
164			ucubep1(1,2:njp1,5) = cube(ni:-1:1,nj,3); % -
165			ucubep1(2:nip1,1,5) = cube(1:ni,nj,4); % -
166			ucubep1(1,2:njp1,6) = cube(ni,1:nj,5); % -
167			ucubep1(2:nip1,1,6) = cube(ni,nj:-1:1,4); % -
168
169			vcubep1(1,2:njp1,1) = cube(ni:-1:1,nj,5); % -
170			vcubep1(2:nip1,1,1) = cube(1:ni,nj,6); % -
171			vcubep1(1,2:njp1,2) = cube(ni,1:nj,1); % -
172			vcubep1(2:nip1,1,2) = cube(ni,nj:-1:1,6); % -
173			vcubep1(1,2:njp1,3) = cube(ni:-1:1,nj,1); % -
174			vcubep1(2:nip1,1,3) = cube(1:ni,nj,2); % -
175			vcubep1(1,2:njp1,4) = cube(ni,1:nj,3); % -
176			vcubep1(2:nip1,1,4) = cube(ni,nj:-1:1,2); % -
177			vcubep1(1,2:njp1,5) = cube(ni:-1:1,nj,3); % -
178			vcubep1(2:nip1,1,5) = cube(1:ni,nj,4); % -
179			vcubep1(1,2:njp1,6) = cube(ni,1:nj,5); % -
180			vcubep1(2:nip1,1,6) = cube(ni,nj:-1:1,4); % -
181	edhill	1.1
182	edhill	1.2	% Get U,V values on the T grid points
183	edhill	1.1	masku = 1.0 - abs(diff(double(tcubep1(2:nip1,:,:) == 0.0),1,2));
184			maskv = 1.0 - abs(diff(double(tcubep1(:,2:nip1,:) == 0.0),1,1));
185			diffu = 0.5*diff(tcubep1(2:nip1,:,:),1,2);
186			diffv = 0.5*diff(tcubep1(:,2:nip1,:),1,1);
187			tonu = tcube(:,:,:) + masku.*diffu;
188			tonv = tcube(:,:,:) + maskv.*diffv;
189
190			if ((newyear ~= oldyear) && (nm > 0)) \|\| (it == length(ilist))
191
192			% Write if its a new year or the last of all entries
193			disp([' ==> Writing files for ==> ' sprintf('%d',oldyear)]);
194			for io = 1:size(vnam,1)
195			comm = sprintf( ...
196			'%s_ido = fopen(''%s_tave_%d'', ''a'', ''ieee-be'');', ...
197			vnam(io,:), vnam(io,:), oldyear );
198			eval(comm)
199			comm = sprintf( '%s_acc = %s_acc ./ nm;',vnam(io,:), ...
200			vnam(io,:));
201			eval(comm)
202			comm = sprintf('fwrite(%s_ido, %s_acc, ''real*4'');', ...
203			vnam(io,:), vnam(io,:) );
204			eval(comm)
205			comm = sprintf( 'fclose(%s_ido);', vnam(io,:) );
206			eval(comm)
207
208			% Re-zero the accumulators
209			comm = sprintf('%s_acc = zeros(ne,ne,6);', vnam(io,:));
210			eval(comm)
211			end
212
213			nm = 0;
214
215			end
216
217			% Accumulate partial sums
218			U__acc = U__acc + ucube;
219			V__acc = V__acc + vcube;
220			T__acc = T__acc + tcube;
221			S__acc = S__acc + scube;
222			B__acc = B__acc + bcube;
223			B1_acc = B1_acc + bcubem1;
224
225			UT_acc = UT_acc + tonu.*ucube;
226			VT_acc = VT_acc + tonv.*vcube;
227			US_acc = US_acc + sonu.*ucube;
228			VS_acc = VS_acc + sonv.*vcube;
229			UB_acc = UB_acc + bonu.*ucube;
230			VB_acc = VB_acc + bonv.*vcube;
231
232			nm = nm + 1;
233
234			oldyear = newyear;
235
236			end
237			end
238