def relation_to_span(g1, g2, relation, edges=False, attrs=False): """Convert a relation to a span.""" new_graph = type(g1)() left_h = dict() right_h = dict() for a, bs in relation.items(): for b in bs: new_node = str(a) + "_" + str(b) new_graph.add_node(new_node) if attrs: common_attrs = attrs_intersection(g1.get_node(a), g2.get_node(b)) new_graph.add_node_attrs(new_node, common_attrs) left_h[new_node] = a right_h[new_node] = b for n1 in new_graph.nodes(): for n2 in new_graph.nodes(): if (left_h[n1], left_h[n2]) in g1.edges() and\ (right_h[n1], right_h[n2]) in g2.edges(): new_graph.add_edge(n1, n2) common_attrs = attrs_intersection( g1.get_edge(left_h[n1], left_h[n2]), g2.get_edge(right_h[n1], right_h[n2]), ) new_graph.add_edge_attrs(n1, n2, common_attrs) return new_graph, left_h, right_h
def relation_to_span(g1, g2, relation, edges=False, attrs=False, directed=True): """Convert a relation to a span.""" if directed: new_graph = nx.DiGraph() else: new_graph = nx.Graph() left_h = dict() right_h = dict() for a, b in relation: new_node = str(a) + "_" + str(b) new_graph.add_node(new_node) if attrs: common_attrs = attrs_intersection(g1.node[a], g2.node[b]) add_node_attrs(new_graph, new_node, common_attrs) left_h[new_node] = a right_h[new_node] = b for n1 in new_graph.nodes(): for n2 in new_graph.nodes(): if (left_h[n1], left_h[n2]) in g1.edges() and\ (right_h[n1], right_h[n2]) in g2.edges(): new_graph.add_edge(n1, n2) common_attrs = attrs_intersection( g1.edge[left_h[n1]][left_h[n2]], g2.edge[right_h[n1]][right_h[n2]], ) add_edge_attrs(new_graph, n1, n2, common_attrs) return (new_graph, left_h, right_h)
def relation_to_span(g1, g2, relation, edges=False, attrs=False, directed=True): """Convert a relation to a span.""" if directed: new_graph = nx.DiGraph() else: new_graph = nx.Graph() left_h = dict() right_h = dict() for a, bs in relation.items(): for b in bs: new_node = str(a) + "_" + str(b) new_graph.add_node(new_node) if attrs: common_attrs = attrs_intersection( g1.node[a], g2.node[b] ) add_node_attrs(new_graph, new_node, common_attrs) left_h[new_node] = a right_h[new_node] = b for n1 in new_graph.nodes(): for n2 in new_graph.nodes(): if (left_h[n1], left_h[n2]) in g1.edges() and\ (right_h[n1], right_h[n2]) in g2.edges(): new_graph.add_edge(n1, n2) common_attrs = attrs_intersection( g1.adj[left_h[n1]][left_h[n2]], g2.adj[right_h[n1]][right_h[n2]], ) add_edge_attrs( new_graph, n1, n2, common_attrs ) return new_graph, left_h, right_h
def get_rule_projections(tx, hierarchy, graph_id, rule, instance, rhs_typing=None): """Execute the query finding rule liftings.""" if rhs_typing is None: rhs_typing = {} projections = {} if rule.is_relaxing(): if len(rule.lhs.nodes()) > 0: lhs_instance = { n: instance[n] for n in rule.lhs.nodes() } lhs_vars = { n: n for n in rule.lhs.nodes()} match_instance_vars = { v: lhs_instance[k] for k, v in lhs_vars.items() } # Match nodes query = "// Match nodes the instance of the rewritten graph \n" query += "MATCH {}".format( ", ".join([ "({}:{} {{id: '{}'}})".format(k, graph_id, v) for k, v in match_instance_vars.items() ]) ) query += "\n\n" carry_vars = list(lhs_vars.values()) for k, v in lhs_vars.items(): query += ( "OPTIONAL MATCH (n)<-[:typing*1..]-({})\n".format(v) + "WITH {} \n".format( ", ".join( carry_vars + ["collect(DISTINCT {{type:'node', origin: {}.id, id: n.id, graph:labels(n)[0], attrs: properties(n)}}) as {}_dict\n".format( v, v)]) ) ) carry_vars.append("{}_dict".format(v)) # Match edges for (u, v) in rule.p.edges(): edge_var = "{}_{}".format(lhs_vars[u], lhs_vars[v]) query += "OPTIONAL MATCH ({}_instance)-[{}:edge]->({}_instance)\n".format( lhs_vars[u], edge_var, lhs_vars[v]) query += "WHERE ({})<-[:typing*1..]-({}) AND ({})<-[:typing*1..]-({})\n".format( "{}_instance".format(lhs_vars[u]), lhs_vars[u], "{}_instance".format(lhs_vars[v]), lhs_vars[v]) query += ( "WITH {} \n".format( ", ".join(carry_vars + [ "collect({{type: 'edge', source: {}.id, target: {}.id, graph:labels({})[0], attrs: properties({})}}) as {}\n".format( "{}_instance".format(lhs_vars[u]), "{}_instance".format(lhs_vars[v]), "{}_instance".format(lhs_vars[u]), edge_var, edge_var) ]) ) ) carry_vars.append(edge_var) query += "RETURN {}".format( ", ".join( ["{}_dict as {}".format(v, v) for v in lhs_vars.values()] + ["{}_{}".format(lhs_vars[u], lhs_vars[v]) for u, v in rule.p.edges()])) result = tx.run(query) record = result.single() l_l_ts = {} l_nodes = {} l_edges = {} for k, v in record.items(): if len(v) > 0: if v[0]["type"] == "node": for el in v: l_node = keys_by_value(instance, el["origin"])[0] if el["graph"] not in l_nodes: l_nodes[el["graph"]] = {} l_l_ts[el["graph"]] = {} if el["id"] not in l_nodes[el["graph"]]: l_nodes[el["graph"]][el["id"]] = {} l_nodes[el["graph"]][el["id"]] = attrs_union( l_nodes[el["graph"]][el["id"]], attrs_intersection( generic.convert_props_to_attrs(el["attrs"]), get_node(rule.lhs, l_node))) l_l_ts[el["graph"]][l_node] = el["id"] else: for el in v: l_sources = keys_by_value(l_l_ts[el["graph"]], el["source"]) l_targets = keys_by_value(l_l_ts[el["graph"]], el["target"]) for l_source in l_sources: for l_target in l_targets: if exists_edge(rule.l, l_source, l_target): if el["graph"] not in l_edges: l_edges[el["graph"]] = {} if (el["source"], el["target"]) not in l_edges[el["graph"]]: l_edges[el["graph"]][(el["source"], el["target"])] = {} l_edges[el["graph"]][(el["source"], el["target"])] =\ attrs_union( l_edges[el["graph"]][(el["source"], el["target"])], attrs_intersection( generic.convert_props_to_attrs(el["attrs"]), get_edge(rule.lhs, l_source, l_target))) for graph, typing in hierarchy.get_descendants(graph_id).items(): if graph in l_nodes: nodes = l_nodes[graph] else: nodes = {} if graph in l_edges: edges = l_edges[graph] else: edges = {} l = nx.DiGraph() add_nodes_from(l, [(k, v) for k, v in nodes.items()]) if graph in l_edges: add_edges_from( l, [(s, t, v) for (s, t), v in edges.items()]) rhs, p_rhs, r_r_t = pushout( rule.p, l, rule.rhs, compose(rule.p_lhs, l_l_ts[graph]), rule.p_rhs) l_t_t = {n: n for n in nodes} # Modify P_T and R_T according to the controlling # relation rhs_typing if graph in rhs_typing.keys(): r_t_factorization = { r_r_t[k]: v for k, v in rhs_typing[graph].items() } added_t_nodes = set() for n in rhs.nodes(): if n in r_t_factorization.keys(): # If corresponding R_T node is specified in # the controlling relation add nodes of T # that type it to P t_nodes = r_t_factorization[n] for t_node in t_nodes: if t_node not in l_t_t.values() and\ t_node not in added_t_nodes: new_p_node = generate_new_id( l.nodes(), t_node) l.add_node(new_p_node) added_t_nodes.add(t_node) p_rhs[new_p_node] = n l_t_t[new_p_node] = t_node else: p_rhs[keys_by_value(l_t_t, t_node)[0]] = n projections[graph] = { "rule": Rule(p=l, rhs=rhs, p_rhs=p_rhs), "instance": l_t_t, "l_l_t": l_l_ts[graph], "p_p_t": {k: l_l_ts[graph][v] for k, v in rule.p_lhs.items()}, "r_r_t": r_r_t } return projections
def get_rule_liftings(tx, graph_id, rule, instance, p_typing=None): """Execute the query finding rule liftings.""" if p_typing is None: p_typing = {} liftings = {} if len(rule.lhs.nodes()) > 0: lhs_vars = { n: n for n in rule.lhs.nodes()} match_instance_vars = {lhs_vars[k]: v for k, v in instance.items()} # Match nodes query = "// Match nodes the instance of the rewritten graph \n" query += "MATCH {}".format( ", ".join([ "({}:{} {{id: '{}'}})".format(k, graph_id, v) for k, v in match_instance_vars.items() ]) ) query += "\n\n" carry_vars = list(lhs_vars.values()) for k, v in lhs_vars.items(): query += ( "OPTIONAL MATCH (n)-[:typing*1..]->({})\n".format(v) + "WITH {} \n".format( ", ".join(carry_vars + [ "collect({{type:'node', origin: {}.id, id: n.id, graph:labels(n)[0], attrs: properties(n)}}) as {}_dict\n".format( v, v)]) ) ) carry_vars.append("{}_dict".format(v)) # Match edges for (u, v) in rule.lhs.edges(): edge_var = "{}_{}".format(lhs_vars[u], lhs_vars[v]) query += "OPTIONAL MATCH ({}_instance)-[{}:edge]->({}_instance)\n".format( lhs_vars[u], edge_var, lhs_vars[v]) query += "WHERE ({})-[:typing*1..]->({}) AND ({})-[:typing*1..]->({})\n".format( "{}_instance".format(lhs_vars[u]), lhs_vars[u], "{}_instance".format(lhs_vars[v]), lhs_vars[v]) query += ( "WITH {} \n".format( ", ".join(carry_vars + [ "collect({{type: 'edge', source: {}.id, target: {}.id, attrs: properties({}), graph:labels({})[0]}}) as {}\n".format( "{}_instance".format(lhs_vars[u]), "{}_instance".format(lhs_vars[v]), edge_var, "{}_instance".format(lhs_vars[u]), edge_var) ]) ) ) carry_vars.append(edge_var) query += "RETURN {}".format( ", ".join( ["{}_dict as {}".format(v, v) for v in lhs_vars.values()] + ["{}_{}".format(lhs_vars[u], lhs_vars[v]) for u, v in rule.lhs.edges()])) result = tx.run(query) record = result.single() l_g_ls = {} lhs_nodes = {} lhs_edges = {} for k, v in record.items(): if len(v) > 0: if v[0]["type"] == "node": for el in v: if el["graph"] not in lhs_nodes: lhs_nodes[el["graph"]] = [] l_g_ls[el["graph"]] = {} l_g_ls[el["graph"]][el["id"]] = keys_by_value( instance, el["origin"])[0] # compute attr intersection attrs = attrs_intersection( generic.convert_props_to_attrs(el["attrs"]), get_node(rule.lhs, l_g_ls[el["graph"]][el["id"]])) lhs_nodes[el["graph"]].append((el["id"], attrs)) else: for el in v: if el["graph"] not in lhs_edges: lhs_edges[el["graph"]] = [] # compute attr intersection attrs = attrs_intersection( generic.convert_props_to_attrs(el["attrs"]), get_edge( rule.lhs, l_g_ls[el["graph"]][el["source"]], l_g_ls[el["graph"]][el["target"]])) lhs_edges[el["graph"]].append( (el["source"], el["target"], attrs) ) for graph, nodes in lhs_nodes.items(): lhs = nx.DiGraph() add_nodes_from(lhs, nodes) if graph in lhs_edges: add_edges_from( lhs, lhs_edges[graph]) p, p_lhs, p_g_p = pullback( lhs, rule.p, rule.lhs, l_g_ls[graph], rule.p_lhs) l_g_g = {n[0]: n[0] for n in nodes} # Remove controlled things from P_G if graph in p_typing.keys(): l_g_factorization = { keys_by_value(l_g_g, k)[0]: v for k, v in p_typing[graph].items() } p_g_nodes_to_remove = set() for n in p.nodes(): l_g_node = p_lhs[n] # If corresponding L_G node is specified in # the controlling relation, remove all # the instances of P nodes not mentioned # in this relations if l_g_node in l_g_factorization.keys(): p_nodes = l_g_factorization[l_g_node] if p_g_p[n] not in p_nodes: del p_g_p[n] del p_lhs[n] p_g_nodes_to_remove.add(n) for n in p_g_nodes_to_remove: p.remove_node(n) liftings[graph] = { "rule": Rule(p=p, lhs=lhs, p_lhs=p_lhs), "instance": l_g_g, "l_g_l": l_g_ls[graph], "p_g_p": p_g_p } else: query = generic.ancestors_query(graph_id, "graph", "homomorphism") result = tx.run(query) ancestors = [record["ancestor"] for record in result] for a in ancestors: liftings[a] = { "rule": Rule.identity_rule(), "instance": {}, "l_g_l": {}, "p_g_p": {} } return liftings