def opt(tree,root): if (script_tree.isLeaf(tree,script_tree.getChildren(tree,root)[0]) and script_tree.isLeaf(tree,script_tree.getChildren(tree,root)[1])): return [script_tree.getBootstrap(tree,root)] elif script_tree.isLeaf(tree,script_tree.getChildren(tree,root)[0]): return opt(tree,script_tree.getChildren(tree,root)[1])+[script_tree.getBootstrap(tree,root)] elif script_tree.isLeaf(tree,script_tree.getChildren(tree,root)[1]): return opt(tree,script_tree.getChildren(tree,root)[0])+[script_tree.getBootstrap(tree,root)] else: order1 = opt(tree,script_tree.getChildren(tree,root)[0]) order2 = opt(tree,script_tree.getChildren(tree,root)[1]) #print "level",len(order1)+len(order2),order1,order2 return mix(order1,order2) + [script_tree.getBootstrap(tree,root)]
def opt(tree, root): if (script_tree.isLeaf(tree, script_tree.getChildren(tree, root)[0]) and script_tree.isLeaf(tree, script_tree.getChildren(tree, root)[1])): return [script_tree.getBootstrap(tree, root)] elif script_tree.isLeaf(tree, script_tree.getChildren(tree, root)[0]): return opt(tree, script_tree.getChildren(tree, root)[1]) + [script_tree.getBootstrap(tree, root)] elif script_tree.isLeaf(tree, script_tree.getChildren(tree, root)[1]): return opt(tree, script_tree.getChildren(tree, root)[0]) + [script_tree.getBootstrap(tree, root)] else: order1 = opt(tree, script_tree.getChildren(tree, root)[0]) order2 = opt(tree, script_tree.getChildren(tree, root)[1]) # print "level",len(order1)+len(order2),order1,order2 return mix(order1, order2) + [script_tree.getBootstrap(tree, root)]
def maximum_distance(tree,root): c1 = script_tree.getChildren(tree,root)[0] c2 = script_tree.getChildren(tree,root)[1] name = script_tree.getBootstrap(tree,root) if script_tree.isLeaf(tree,c1) and script_tree.isLeaf(tree,c2): return [[name],[name]] elif script_tree.isLeaf(tree,c1): oo = maximum_distance(tree,c2) return [[name] + oo[0],[name] + oo[1]] elif script_tree.isLeaf(tree,c2): oo = maximum_distance(tree,c1) return [[name] + oo[0],[name] + oo[1]] else: orders1 = maximum_distance(tree,c1) orders2 = maximum_distance(tree,c2) return [[name] + orders1[0] + orders2[0],[name] + orders2[1] + orders1[1]]
def maximum_distance(tree, root): c1 = script_tree.getChildren(tree, root)[0] c2 = script_tree.getChildren(tree, root)[1] name = script_tree.getBootstrap(tree, root) if script_tree.isLeaf(tree, c1) and script_tree.isLeaf(tree, c2): return [[name], [name]] elif script_tree.isLeaf(tree, c1): oo = maximum_distance(tree, c2) return [[name] + oo[0], [name] + oo[1]] elif script_tree.isLeaf(tree, c2): oo = maximum_distance(tree, c1) return [[name] + oo[0], [name] + oo[1]] else: orders1 = maximum_distance(tree, c1) orders2 = maximum_distance(tree, c2) return [[name] + orders1[0] + orders2[0], [name] + orders2[1] + orders1[1]]
def order_from_tree(tree): order = [] nodes = script_tree.getNodes(tree) root = script_tree.getRoot(tree) for n in nodes: if not script_tree.isLeaf(tree,n): order.append(n) #print order order.sort(lambda x,y: cmp(script_tree.distanceFrom(tree,x,root),script_tree.distanceFrom(tree,y,root))) for i in range(len(order)): order[i] = script_tree.getBootstrap(tree,order[i]) return order
def tree_from_order(order): nodes = script_tree.getNodes(tree) for n in nodes: if not script_tree.isRoot(tree,n): if script_tree.isLeaf(tree,n): index = len(order) else: index = order.index(script_tree.getBootstrap(tree,n)) index_parent = order.index(script_tree.getBootstrap(tree,script_tree.getParent(tree,n))) script_tree.setLength(tree,n,index-index_parent) return script_tree.writeTree(tree,root,False)
def tree_from_order(order): nodes = script_tree.getNodes(tree) for n in nodes: if not script_tree.isRoot(tree, n): if script_tree.isLeaf(tree, n): index = len(order) else: index = order.index(script_tree.getBootstrap(tree, n)) index_parent = order.index(script_tree.getBootstrap(tree, script_tree.getParent(tree, n))) script_tree.setLength(tree, n, index - index_parent) return script_tree.writeTree(tree, root, False)
def order_from_tree(tree): order = [] nodes = script_tree.getNodes(tree) root = script_tree.getRoot(tree) for n in nodes: if not script_tree.isLeaf(tree, n): order.append(n) # print order order.sort(lambda x, y: cmp(script_tree.distanceFrom(tree, x, root), script_tree.distanceFrom(tree, y, root))) for i in range(len(order)): order[i] = script_tree.getBootstrap(tree, order[i]) return order
def distance_from(x, y): nodes = script_tree.getNodes(species_tree) for n in nodes: if script_tree.isLeaf(species_tree, n): name = script_tree.getName(species_tree, n) else: name = script_tree.getBootstrap(species_tree, n) if name == x: A = n if name == y: B = n return script_tree.distanceFrom(species_tree, A, B)
def distance_from(x,y): nodes = script_tree.getNodes(species_tree) for n in nodes: if script_tree.isLeaf(species_tree,n): name = script_tree.getName(species_tree,n) else: name = script_tree.getBootstrap(species_tree,n) if name == x: A = n if name == y: B = n return script_tree.distanceFrom(species_tree,A,B)
def receptor_search(t,n): if script_tree.isLeaf(t,n): result = [] else: annot = script_tree.getBootstrap(t,n) if annot.find("T@") >= 0: result = [] elif annot.split(".")[1][:2] == "D@": children = script_tree.getChildren(t,n) result = receptor_search(t,children[0]) + receptor_search(t,children[1]) else: result = [annot.split(".")[1]] #print result return result
def parent(x): #print x nodes = script_tree.getNodes(species_tree) for n in nodes: if script_tree.isLeaf(species_tree,n): name = script_tree.getName(species_tree,n) else: name = script_tree.getBootstrap(species_tree,n) if name == x: if script_tree.isRoot(species_tree,n): result = -1 else: result = script_tree.getBootstrap(species_tree,script_tree.getParent(species_tree,n)) return result
def random_order(tree, root): c1 = script_tree.getChildren(tree, root)[0] c2 = script_tree.getChildren(tree, root)[1] name = script_tree.getBootstrap(tree, root) if script_tree.isLeaf(tree, c1) and script_tree.isLeaf(tree, c2): return [name] elif script_tree.isLeaf(tree, c1): return [name] + random_order(tree, c2) elif script_tree.isLeaf(tree, c2): return [name] + random_order(tree, c1) else: order1 = random_order(tree, c1) order2 = random_order(tree, c2) # if script_tree.isRoot(tree,root): # print order1,order2 pos = range(len(order1) + len(order2)) for i in range(len(order2)): index = int(random.random() * (len(pos))) del pos[index] # if script_tree.isRoot(tree,root): # print pos order = [name] previous = 0 for i in pos: for j in range(i - previous): # if script_tree.isRoot(tree,root): # print order2,i,previous order.append(order2[0]) del order2[0] order.append(order1[0]) del order1[0] previous = i + 1 # if script_tree.isRoot(tree,root): # print order1,order2,order return order + order2
def receptor_search(t, n): if script_tree.isLeaf(t, n): result = [] else: annot = script_tree.getBootstrap(t, n) if annot.find("T@") >= 0: result = [] elif annot.split(".")[1][:2] == "D@": children = script_tree.getChildren(t, n) result = receptor_search(t, children[0]) + receptor_search( t, children[1]) else: result = [annot.split(".")[1]] #print result return result
def parent(x): #print x nodes = script_tree.getNodes(species_tree) for n in nodes: if script_tree.isLeaf(species_tree, n): name = script_tree.getName(species_tree, n) else: name = script_tree.getBootstrap(species_tree, n) if name == x: if script_tree.isRoot(species_tree, n): result = -1 else: result = script_tree.getBootstrap( species_tree, script_tree.getParent(species_tree, n)) return result
def random_order(tree,root): c1 = script_tree.getChildren(tree,root)[0] c2 = script_tree.getChildren(tree,root)[1] name = script_tree.getBootstrap(tree,root) if script_tree.isLeaf(tree,c1) and script_tree.isLeaf(tree,c2): return [name] elif script_tree.isLeaf(tree,c1): return [name] + random_order(tree,c2) elif script_tree.isLeaf(tree,c2): return [name] + random_order(tree,c1) else: order1 = random_order(tree,c1) order2 = random_order(tree,c2) #if script_tree.isRoot(tree,root): #print order1,order2 pos = range(len(order1)+len(order2)) for i in range(len(order2)): index = int(random.random()*(len(pos))) del pos[index] #if script_tree.isRoot(tree,root): #print pos order = [name] previous = 0 for i in pos: for j in range(i - previous): #if script_tree.isRoot(tree,root): #print order2,i,previous order.append(order2[0]) del order2[0] order.append(order1[0]) del order1[0] previous = i+1 #if script_tree.isRoot(tree,root): #print order1,order2,order return order + order2
#for l in leaves: #species_under_origin.append(script_tree.getName(species_tree,l)) leaves = script_tree.getLeaves(tree, root) #species_present = [] #for l in leaves: #if script_tree.getName(tree,l).split("_")[0] not in species_present: #species_present.append(script_tree.getName(tree,l).split("_")[0]) if len( leaves ) > MINIMUM_FAMILY_SIZE: # and difference_symetrique(species_present,species_under_origin) < MAXIMUM_DIFFERENCE_WITH_PROFILE: #print script_tree.writeTree(tree,root,False) #print origination,len(leaves),len(species_present),len(species_under_origin), #output_distr.write(str(difference_symetrique(species_present,species_under_origin))+"\n") nodes = script_tree.getNodes(tree) for n in nodes: if script_tree.isLeaf(tree, n): annot = script_tree.getName(tree, n) else: annot = script_tree.getBootstrap(tree, n) #if script_tree.isLeaf(tree,n) and annot.find("T")>=0: #print annot # annot: evenement events = annot.split(".") if events[0] == "": del events[0] for e in events: if e[:2] == "T@": # on a touve un transfert #print e donnor = e[2:].split("->")[0] receptor = e[2:].split("->")[1]
for i in range(len(order)): order[i] = script_tree.getBootstrap(tree,order[i]) return order # useful variables degre_entrant = {} edge = {} graph = {} nodes = script_tree.getNodes(tree) leaves = script_tree.getLeavesNames(tree) root = script_tree.getRoot(tree) internal_nodes = [] # initialise from nodes for n in nodes: if (not script_tree.isLeaf(tree,n)): node = script_tree.getBootstrap(tree,n) graph[node] = [] degre_entrant[node] = [] internal_nodes.append(node) else: node = script_tree.getName(tree,n) graph[node] = [] # initialise from branches for n in nodes: if (not script_tree.isLeaf(tree,n)): if (not script_tree.isRoot(tree,n)): parent = script_tree.getBootstrap(tree,script_tree.getParent(tree,n)) child = script_tree.getBootstrap(tree,n) graph[parent].append(child)
return order # useful variables degre_entrant = {} edge = {} graph = {} nodes = script_tree.getNodes(tree) leaves = script_tree.getLeavesNames(tree) root = script_tree.getRoot(tree) # rootname = script_tree.getBootstrap(tree,root) internal_nodes = [] # initialise from nodes for n in nodes: if (not script_tree.isLeaf(tree, n)): node = script_tree.getBootstrap(tree, n) graph[node] = [] degre_entrant[node] = [] internal_nodes.append(node) else: node = script_tree.getName(tree, n) graph[node] = [] print "tree with ", len(internal_nodes), "internal nodes" # parse transfers # by_family = {} for line in constraints: # print line
#leaves = script_tree.getLeaves(species_tree,n) #species_under_origin = [] #for l in leaves: #species_under_origin.append(script_tree.getName(species_tree,l)) leaves = script_tree.getLeaves(tree,root) #species_present = [] #for l in leaves: #if script_tree.getName(tree,l).split("_")[0] not in species_present: #species_present.append(script_tree.getName(tree,l).split("_")[0]) if len(leaves) > MINIMUM_FAMILY_SIZE:# and difference_symetrique(species_present,species_under_origin) < MAXIMUM_DIFFERENCE_WITH_PROFILE: #print script_tree.writeTree(tree,root,False) #print origination,len(leaves),len(species_present),len(species_under_origin), #output_distr.write(str(difference_symetrique(species_present,species_under_origin))+"\n") nodes = script_tree.getNodes(tree) for n in nodes: if script_tree.isLeaf(tree,n): annot = script_tree.getName(tree,n) else: annot = script_tree.getBootstrap(tree,n) #if script_tree.isLeaf(tree,n) and annot.find("T")>=0: #print annot # annot: evenement events = annot.split(".") if events[0] == "": del events[0] for e in events: if e[:2] == "T@": # on a touve un transfert #print e donnor = e[2:].split("->")[0] receptor = e[2:].split("->")[1]