def main(args): #read in and rename arguments title1 = os.path.basename(args.input_dir_1) title2 = os.path.basename(args.input_dir_2) d1, n1 = scorefileparse.read_dec_nat(args.input_dir_1, [], args.scoretype1, True) d2, n2 = scorefileparse.read_dec_nat(args.input_dir_2, [], args.scoretype2, True) dec1 = scorefileparse.filter_pdbs_by_rmsd(d1, args.rmsd_cutoff) nat1 = scorefileparse.filter_pdbs_by_rmsd(n1, args.rmsd_cutoff) dec2 = scorefileparse.filter_pdbs_by_rmsd(d2, args.rmsd_cutoff) nat2 = scorefileparse.filter_pdbs_by_rmsd(n2, args.rmsd_cutoff) dec_norm1 = scorefileparse.norm_pdbs(dec1) nat_norm1 = scorefileparse.norm_pdbs(nat1,dec1) dec_norm2 = scorefileparse.norm_pdbs(dec2) nat_norm2 = scorefileparse.norm_pdbs(nat2,dec2) [dec_inter1, nat_inter1, dec_inter2, nat_inter2] = scorefileparse.pdbs_intersect([dec_norm1, nat_norm1, dec_norm2, nat_norm2]) [dec_inter1, dec_inter2] = scorefileparse.pdbs_scores_intersect([dec_inter1, dec_inter2]) [nat_inter1, nat_inter2] = scorefileparse.pdbs_scores_intersect([nat_inter1, nat_inter2]) dec_filt1 = scorefileparse.filter_norm_pdbs(dec_norm1) nat_filt1 = scorefileparse.filter_norm_pdbs(nat_norm1) dec_filt2 = scorefileparse.filter_norm_pdbs(dec_norm2) nat_filt2 = scorefileparse.filter_norm_pdbs(nat_norm2) [dec_finter1, dec_finter2] = scorefileparse.pdbs_scores_intersect([dec_filt1, dec_filt2]) [nat_finter1, nat_finter2] = scorefileparse.pdbs_scores_intersect([nat_filt1, nat_filt2]) fig, axarr = conv.create_ax(2, len(dec_inter1)) for x_ind,pdb in enumerate(sorted(dec_inter1.keys())): ax = axarr[x_ind, 0] plot(dec_inter1, dec_inter2, nat_inter1, nat_inter2, ax, pdb, title1, title2) ax = axarr[x_ind, 1] plot(dec_finter1, dec_finter2, nat_finter1, nat_finter2, ax, pdb, title1, title2)
def main(args): #read in and rename arguments inp_dir=args[1] scoretype=args[2] dec, nat = scorefileparse.read_dec_nat(inp_dir, [], scoretype) disc = discparse.read_dir(inp_dir) dec_norm = scorefileparse.norm_pdbs(dec) nat_norm = scorefileparse.norm_pdbs(nat,dec) [dec_inter, nat_inter, disc_inter] = scorefileparse.pdbs_intersect([dec_norm, nat_norm, disc]) #labels = ["Average","1.0","1.5","2.0","2.5","3.0","4.0","6.0"] labels = ["Average"] energy_gap = [[] for l in labels] avg_disc = [[] for l in labels] for pdb in dec_inter.keys(): for ind in xrange(0,len(labels)): lowest_dec = min([ e[0] for e in dec_inter[pdb].values() ]) lowest_nat = min([ n[0] for n in nat_inter[pdb].values() if n[1] < 2.0 ]) energy_gap[ind].append(lowest_nat - lowest_dec) avg_disc[ind].append(disc_inter[pdb][0]) fig, axarr = conv.create_ax(len(labels), 1) for x_ind,l in enumerate(labels): ax = axarr[0,x_ind] scatterplot.draw_actual_plot(ax, avg_disc[x_ind], energy_gap[x_ind], [], l,"Disc","Energy Gap") scatterplot.plot_regression(ax, avg_disc[x_ind], energy_gap[x_ind], False, False) title = os.path.basename(inp_dir) filename=inp_dir + "/test.txt" conv.save_fig(fig, filename, "disc_v_egap", len(labels)*3, 4)
def main(input_dir_1, scoretype1, input_dir_2, scoretype2, rmsd_cutoff, output_pre ): #read in and rename arguments title1 = os.path.basename(input_dir_1) title2 = os.path.basename(input_dir_2) d1, n1 = scorefileparse.read_dec_nat(input_dir_1, scoretype1, repl_orig=False) d2, n2 = scorefileparse.read_dec_nat(input_dir_2, scoretype2, repl_orig=False) dec1 = scorefileparse.filter_pdbs_by_rmsd(d1, rmsd_cutoff) nat1 = scorefileparse.filter_pdbs_by_rmsd(n1, rmsd_cutoff) dec2 = scorefileparse.filter_pdbs_by_rmsd(d2, rmsd_cutoff) nat2 = scorefileparse.filter_pdbs_by_rmsd(n2, rmsd_cutoff) dec_norm1 = scorefileparse.norm_pdbs(dec1) nat_norm1 = scorefileparse.norm_pdbs(nat1,dec1) dec_norm2 = scorefileparse.norm_pdbs(dec2) nat_norm2 = scorefileparse.norm_pdbs(nat2,dec2) [dec_inter1, nat_inter1, dec_inter2, nat_inter2] = scorefileparse.pdbs_intersect([dec_norm1, nat_norm1, dec_norm2, nat_norm2]) [dec_inter1, dec_inter2] = scorefileparse.pdbs_scores_intersect([dec_inter1, dec_inter2]) [nat_inter1, nat_inter2] = scorefileparse.pdbs_scores_intersect([nat_inter1, nat_inter2]) dec_filt1 = scorefileparse.filter_norm_pdbs(dec_norm1) nat_filt1 = scorefileparse.filter_norm_pdbs(nat_norm1) dec_filt2 = scorefileparse.filter_norm_pdbs(dec_norm2) nat_filt2 = scorefileparse.filter_norm_pdbs(nat_norm2) [dec_finter1, dec_finter2] = scorefileparse.pdbs_scores_intersect([dec_filt1, dec_filt2]) [nat_finter1, nat_finter2] = scorefileparse.pdbs_scores_intersect([nat_filt1, nat_filt2]) fig, axarr = conv.create_ax(2, len(dec_inter1)) line_plot_data = {} min_naive_by_pdb = {} for x_ind,pdb in enumerate(sorted(dec_inter1.keys())): ax = axarr[x_ind, 0] plot_r_v_r(dec_inter1, dec_inter2, nat_inter1, nat_inter2, ax, pdb, title1, title2) ax = axarr[x_ind, 1] min_naive = plot_pareto(dec_inter1, dec_inter2, nat_inter1, nat_inter2, ax, pdb, title1, title2) keys_to_include = ["Amber", "Rosetta","All","Pareto10"] for key, (rank1, rank2, rmsd) in min_naive.items(): #if key not in keys_to_include: # continue if line_plot_data.get(key) is None: line_plot_data[key] = ([],[]) line_plot_data[key][0].append(pdb) line_plot_data[key][1].append(rmsd) if min_naive_by_pdb.get(pdb) is None: min_naive_by_pdb[pdb] = {} min_naive_by_pdb[pdb][key] = rmsd #organize data indices = list(range(len(line_plot_data["All"][1]))) indices.sort(key=lambda x: line_plot_data["All"][1][x]) ranked_pdbs_by_rmsd_all = {} for i, x in enumerate(indices): ranked_pdbs_by_rmsd_all[line_plot_data["All"][0][x]] = i for label, (pdbs, rmsds) in line_plot_data.items(): line_plot_data[label] = tuple(zip(*sorted(zip(pdbs,rmsds), key=lambda x: ranked_pdbs_by_rmsd_all[x[0]] ))) filename = output_pre + "/" + title1 + "_" + title2 + ".txt" #suffix="rmsd_v_rmsd_{0}".format(rmsd_cutoff) #conv.save_fig(fig, filename, suffix, 7, len(dec_inter1)*3) #plot line plot all_pareto_labels = [] for initial in ["R","A"]: ordered_labels = ["All", "Amber", "Rosetta"] for i in range(1,11): ordered_labels.append("Pareto{0}{1}".format(initial,i)) all_pareto_labels.append("Pareto{0}{1}".format(initial,i)) lines = [ (line_plot_data[label][0], line_plot_data[label][1], label) for label in ordered_labels ] fig2, axarr2 = conv.create_ax(1, len(ordered_labels), shx=True, shy=True) for i, label in enumerate(ordered_labels): line.plot_series(axarr2[i,0], lines[0:i+1], "RMSD vs. pdb", "PDB", "RMSD", linestyle='') conv.add_legend(axarr2[i,0]) conv.save_fig(fig2, filename, "_line_{0}".format(initial), 10, len(ordered_labels)*5) #plot histogram plot hist_comp = [ ("Amber","All"), ("Rosetta", "All"), ("ParetoR10", "All"), ("ParetoA10", "All")] hist_comp.extend([ ("ParetoR{0}".format(ind),"Rosetta") for ind in range(1,11) ]) hist_comp.extend([ ("ParetoR{0}".format(ind),"Amber") for ind in range(1,11) ]) hist_comp.extend([ ("ParetoA{0}".format(ind),"Rosetta") for ind in range(1,11) ]) hist_comp.extend([ ("ParetoA{0}".format(ind), "Amber") for ind in range(1,11) ]) fig3, axarr3 = conv.create_ax(2, len(hist_comp), shx=False, shy=False) for ind, (top, bottom) in enumerate(hist_comp): gen_dist_plot(axarr3[ind,0], axarr3[ind,1], top, bottom, min_naive_by_pdb) conv.save_fig(fig3, filename, "_distdeltas", 7, len(hist_comp)*5, tight=False) #plot scatterplot fig4, axarr4 = conv.create_ax(10, 2) for i in range(1,11): gen_scatterplot(axarr4[0,i-1], "ParetoR{0}".format(i), "Rosetta", "Amber", min_naive_by_pdb) gen_scatterplot(axarr4[1,i-1], "ParetoA{0}".format(i), "Rosetta", "Amber", min_naive_by_pdb) conv.save_fig(fig4, filename, "_scattdeltas", 30, 6)
def main(list_input_dirs, energies_names, output_pre): #read in and rename arguments inp_dir1=list_input_dirs[0][0] scoretype1=list_input_dirs[0][1] inp_dir2=list_input_dirs[1][0] scoretype2=list_input_dirs[1][1] title1 = os.path.basename(inp_dir1) title2 = os.path.basename(inp_dir2) column_dict = {} for c in energies_names: column_dict[c[0]] = c[1:] dec1, nat1 = scorefileparse.read_dec_nat(inp_dir1, energies_names[scoretype1], scoretype1) dec2, nat2 = scorefileparse.read_dec_nat(inp_dir2, energies_names[scoretype2], scoretype2) [dec_inter1, nat_inter1, dec_inter2, nat_inter2] = scorefileparse.pdbs_intersect([dec1, nat1, dec2, nat2]) sum_discs = Counter() fig, axarr = conv.create_ax(1, len(dec_inter1)+1, True,True) for x_ind, pdb in enumerate(sorted(dec_inter1.keys())): discs_per_pdb = {} for w_1 in xrange(-10,10,2): for w_2 in xrange(-10,10,2): weight_1 = 2 ** w_1 weight_2 = 2 ** w_2 weighted_1 = scorefileparse.weight_dict(dec_inter1[pdb], weight_1) weighted_2 = scorefileparse.weight_dict(dec_inter2[pdb], weight_2) merged = scorefileparse.merge_dicts([weighted_1, weighted_2]) ddata1 = scorefileparse.convert_disc(merged) disc_divs = [1.0,1.5,2.0,2.5,3.0,4.0,6.0] disc1, d, counts = disc.given_data_run_disc(ddata1, True, disc_divs) discs_per_pdb[(weight_1,weight_2)] = disc1 sorted_disc = sorted(discs_per_pdb.values()) max_title = [ t for t,v in discs_per_pdb.items() if v == sorted_disc[0] ] #header_string = "\t".join("{0:.3f}-{1:.3f}".format(x,y) for x,y in sorted(discs_per_pdb.keys())) + "\tMax_Weight" #values_string = "\t".join(format(x, "10.3f") for (w1,w2),x in sorted(discs_per_pdb.items())) + "\t{0:.3f}".format(max_title[0]) #print header_string #print values_string ax = axarr[x_ind, 0] #ax.set_xlim(-10, 600) #ax.set_ylim(-10, 600) ax.set_xscale('log', basex=2) ax.set_yscale('log', basey=2) x = [ w1 for (w1,w2) in sorted(discs_per_pdb.keys()) ] y = [ w2 for (w1,w2) in sorted(discs_per_pdb.keys()) ] d = [ v for k,v in sorted(discs_per_pdb.items()) ] min_y = min(discs_per_pdb.values()) max_y = max(discs_per_pdb.values()) #print min_y, max_y s = scatterplot.draw_actual_plot(ax, x, y, d, pdb, scoretype1, scoretype2, 'bwr') fig.colorbar(s,ax=ax) #ax.axhline(y=min_y) #ax.set_ylim(min_y-0.05,max_y+0.05) scatterplot.add_x_y_line(ax, 0,600) sum_discs.update(discs_per_pdb) #print "All PDBs {0}".format(len(dec_inter1)) #sorted_disc = sorted(sum_discs.values()) #max_title = [ t for t,v in sum_discs.items() if v == sorted_disc[0] ] #header_string = "\t".join(format(x, "10.3f") for x in sorted(sum_discs.keys())) + "\tMax_Weight" #values_string = "\t".join(format(x/len(dec_inter1), "10.3f") for key,x in sorted(sum_discs.items())) + "\t{0:.3f}".format(max_title[0]) #print header_string #print values_string ax = axarr[len(dec_inter1), 0] min_y = min(x/len(dec_inter1) for x in sum_discs.values()) max_y = max(x/len(dec_inter1) for x in sum_discs.values()) x = [ w1 for w1,w2 in sorted(sum_discs.keys()) ] y = [ w2 for w1,w2 in sorted(sum_discs.keys()) ] d = [ v/len(dec_inter1) for k,v in sorted(sum_discs.items()) ] #fix titles of axes ax.set_xscale('log', basex=2) ax.set_yscale('log', basey=2) s = scatterplot.draw_actual_plot(ax, x,y,d, "All", scoretype1, scoretype2, cm='bwr') fig.colorbar(s,ax=ax) scatterplot.add_x_y_line(ax, 0,600) #ax.axhline(y=min_y) conv.save_fig(fig, output_pre, "_weights_v_disc", 3, len(dec_inter1)*3)