function [bonds,components] = rbg2abg(rbonds,rstrokes,rcomponents,rports,infofile) % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % %% Version control history % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % %% $Id$ % %% $Log$ % %% Revision 1.10 1997/03/17 13:45:42 peterg % %% Added more error info. % %% % %% Revision 1.9 1996/12/31 11:25:57 peterg % %% Clearer error messages for incorrect ports. % %% % %% Revision 1.8 1996/12/04 21:52:39 peterg % %% Now uses fopen. % %% % %% Revision 1.7 1996/11/01 18:01:57 peterg % %% Rationalised port ordering. % %% Fixed port bug. % %% % %% Revision 1.6 1996/08/25 08:27:14 peter % %% Now checks ports correctely - I hope. % %% % %% Revision 1.5 1996/08/24 19:21:26 peter % %% More specific error messages. % %% % %% Revision 1.4 1996/08/24 18:00:33 peter % %% Fixed bug with finding ports. % %% % %% Revision 1.3 1996/08/09 08:26:35 peter % %% Cosmetic tidy up. % %% % %% Revision 1.2 1996/08/04 18:37:57 peter % %% Fixed no causal strokes bug. % %% % %% Revision 1.1 1996/08/04 18:30:14 peter % %% Initial revision % %% % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if nargin<5 infofile='stdout'; else fnum = fopen(infofile, 'w'); end; % Xfig scaling factor scale = 1200.0/2.54546; % Rotation matrix rot = [0 -1; 1 0]; % Find number of strokes [n_strokes,columns] = size(rstrokes); if (columns ~= 4)&(n_strokes>0) error('Incorrect rstrokes matrix: must have 4 columns'); end; % Find number of bonds [n_bonds,columns] = size(rbonds); if (columns ~= 6)&(n_bonds>0) error('Incorrect rbonds matrix: must have 6 columns'); end; % Find number of components [n_components,columns] = size(rcomponents); % Find number of ports [n_ports,columns] = size(rports); % Determine coordinates of the arrow end of the bond and the other end other_end_1 = rbonds(:,1:2); arrow_end = rbonds(:,3:4); other_end_2 = rbonds(:,5:6); distance_1 = length2d(other_end_1 - arrow_end); distance_2 = length2d(other_end_2 - arrow_end); which_end = (distance_1>distance_2)*[1 1]; one = ones(size(which_end)); other_end = which_end.*other_end_1 + (one-which_end).*other_end_2; arrow_vector = ( which_end.*other_end_2 + (one-which_end).*other_end_1 ) - ... arrow_end; % Locate the bond end nearest to each port % col 1 of port_near_bond contains a signed bond number (+ for arrow end) % col 2 of port_near_bond contains the corresponding port number for i = 1:n_ports [i rports(i,1:2)/scale rports(i,3)] near_bond = adjbond(rports(i,1:2),arrow_end,other_end) [rows,cols]=size(near_bond); if rows>1 error(sprintf ... ("A port is near to more than one bond at coordinates %g,%g\n", ... rports(i,1)/scale, rports(i,2)/scale)); end; signed_bond = near_bond(1)*sign(1.5-near_bond(2)); port_near_bond(i,:) = [signed_bond, rports(i,3)]; end; % Locate the components at the ends of each bond % col 1 of comp_near_bond contain the component nearest to the arrow end % col 2 of comp_near_bond contain the component nearest to the other end for i = 1:n_bonds comp_near_bond(i,:) = adjcomp(arrow_end(i,:),other_end(i,:),rcomponents); end; % Produce a list of bonds on each component - sorted if explicit port numbers for i = 1:n_components % There are n bonds on this component with corresponding index [index,n] = getindex(comp_near_bond,i); % Error message in case we need it! port_error = sprintf(... 'Component at (%1.3f,%1.3f) has inconsistent port numbers', ... rcomponents(i,1)/scale, rcomponents(i,2)/scale); if index(1,1) ~= 0 % Then its a genuine component % Create the signed list of bonds on this component one = ones(n,1); bond_list = index(:,1); % bond at component bond_end = index(:,2); % which end of bond at component? direction = -sign(bond_end-1.5*one); signed_bond_list = bond_list.*direction; % Default sort of bonds (ie no change) sort_index = [1:n]'; if n_ports>0 % then there are some numbered ports % so find those associated with the bonds on this component. k=0; port_number=[]; for j = 1:n b = signed_bond_list(j); % Find the port label on component end of bond (if any) [port_index,m] = getindex(port_near_bond(:,1),b); if m==1 k=k+1; port_number(k,1) = port_near_bond(port_index,2); end; end; % Must have a lable for each port or non at all if k==n % Then a full set of port numbers [sorted,sort_index]=sort(port_number); %Check that all the numbers (1..n) are there if sum(sorted==[1:n]')~=n % There is something wrong mtt_info(port_error,fnum); mtt_info(sprintf('\t it must have consecutive ports labels from 1:%1.0f\n', n), ... fnum); port_str = sprintf('\t the port labels are: '); for kk=1:k port_str=sprintf('%s %1.0f', port_str, port_number(kk)); end; mtt_info(port_str, fnum); end; else if k~=0 mtt_info(port_error,fnum); mtt_info(sprintf('\t it must have 0 or %1.0f ports\n', n), fnum); port_str = sprintf('\t the port labels are: '); for kk=1:k port_str=sprintf('%s %1.0f', port_str, port_number(kk)); end; mtt_info(port_str, fnum); end; end; end; end; % Write out bond list sorted by port number (if any) for j = 1:length(sort_index) jj = sort_index(j); components(i,j) = signed_bond_list(jj); end; end; % Deduce causality from the strokes (if any). causality = zeros(n_bonds,2); if n_strokes>0 % Find out location of centre and ends of stroke. stroke_end_1 = [rstrokes(:,1) rstrokes(:,2)]; stroke_end_2 = [rstrokes(:,3) rstrokes(:,4)]; stroke_centre = (stroke_end_1 + stroke_end_2)/2; stroke_vector = (stroke_end_1 - stroke_end_2); stroke_length = length2d(stroke_vector); % Deduce bond causality from the strokes for i = 1:n_strokes stroke = [stroke_centre(i,:) stroke_end_1(i,:) stroke_end_2(i,:)]; % Find the nearest bond end. [index,distance] = adjbond(stroke(1,:),arrow_end,other_end); if (distance>2*stroke_length(i)) info = sprintf('Stroke at (%4.3f,%4.3f) is %4.3f away from the nearest bond\n', ... stroke(1,1)/scale, stroke(1,2)/scale, distance/scale); end; % Bond end coordinates j = index(1,1); which_end = index(1,2)==1; bond_end = arrow_end(j,:)*which_end + other_end(j,:)*(1-which_end); % Now decide which bit of the stroke is nearest stroke_index = adjbond(bond_end,stroke,zeros(size(stroke))); if stroke_index(1)==1 % uni-causal stroke causality(j,1:2) = (2*which_end-1)*[1 1]; else % bicausal stroke % Find out whether stroke is on flow side of bond stroke_direction = stroke(1,:) - stroke(stroke_index(1),:); flow_side = stroke_direction*arrow_vector(j,:)'>0; causality(j,1+flow_side) = 2*which_end-1; end; end; end; bonds = causality; fclose(fnum);