def find_best_partition(self, x, y, avail_attrs, depth):
# Randomly select F features from the available ones
np.random.shuffle(avail_attrs)
feat_ixs = avail_attrs[:self.n_features]
# Compute the score for each attribute and keep the one with the highest score
best_score = -100
for feat_ix in feat_ixs:
score = self.compute_score(x[:, feat_ix], y)
if score > best_score:
best_feat_ix = feat_ix
best_score = score
# Annotate this feature as selected in the tree creation (To measure the feature importance in the forest)
self.feat_selected[best_feat_ix] = 1
# Remove the attribute from the list of available attributes
avail_attrs = [attr for attr in avail_attrs if attr != best_feat_ix]
# Create the Node and add a child per value of the selected attribute
out_node = Node(attribute=best_feat_ix,
avail_attrs=avail_attrs,
depth=depth,
children={})
for val in self.attr_vals[best_feat_ix]:
out_node.add_child(val,
np.argwhere(x[:, best_feat_ix] == val)[:, 0])
return out_node
def create_node(self, node_id="anode"):
node = Node(id=node_id)
node.lastContact = datetime.now()
node.status = Node.Status.IDLE
db.session.add(node)
db.session.commit()
return node
def expand_tree(self, tree, x, y, depth):
considered_insts = tree.get_instances()
for key, val in tree.children.items():
if len(set(y[val])) == 1:
# If there is only one class in this subset, set the child terminal value to this class
tree.children[key] = Node(terminal_value=y[val[0]],
depth=depth)
elif len(val) == 0:
# If the split left this branch empty, set the terminal value to the majority class of the parent subset
labels, counts = np.unique(y[considered_insts],
return_counts=True)
terminal_value = labels[np.argmax(counts)]
tree.children[key] = Node(terminal_value=terminal_value,
depth=depth)
elif self.min_samples_leaf > len(val) or depth == self.max_depth:
# If the number of samples at this leaf is lower than the minimum or maximum depth has been reached,
# set the terminal value to the majority class in the branch subset
labels, counts = np.unique(y[val], return_counts=True)
terminal_value = labels[np.argmax(counts)]
tree.children[key] = Node(terminal_value=terminal_value,
depth=depth)
else:
# Otherwise, find the best partition for this leaf and expand the subtree
tree.children[key] = self.find_best_partition(
x[val, :], y[val], tree.avail_attrs, depth)
self.expand_tree(tree.children[key], x[val], y[val], depth + 1)
return
def _process_break(self, action):
node1 = Node(action.label)
node2 = Node(action.label2)
self.stack.append(node1)
self.stack.append(node2)
self.buffer_indices.pop(0)
if len(self.buffer_indices) != 0:
self.current_token_index = self.buffer_indices[0]
def __init__(self, Name, Parent=None, Description=""):
"""
Model for the sink
:param Name: name of the model
:param Parent: parent model
:param Description: description of the model
:param data: parameters and other required data
"""
# Instantiate the Node
Node.__init__(self, Name, Parent=Parent, Description=Description)
def _make_named_entity(self, concept, literals):
wiki_tag = "_".join(literals)
wiki_node = Node(wiki_tag, tag=wiki_tag)
name_node = Node("name")
for i, literal in enumerate(literals):
literal_node = Node(literal, tag=literal)
name_node.add_child(literal_node, "op{}".format(i + 1))
concept_node = Node(concept)
concept_node.add_child(wiki_node, "wiki")
concept_node.add_child(name_node, "name")
return concept_node
def test_amr_print_with_reentrancy():
r: Node = Node('receive-01')
w: Node = Node('we')
t: Node = Node('thing')
r2: Node = Node('remind-01')
p: Node = Node('pay-01')
h: Node = Node('hospital')
n: Node = Node('now')
a: Node = Node('already')
r.add_child(w, 'ARG0')
r.add_child(t, 'ARG1')
r.add_child(h, 'ARG2')
r.add_child(n, 'time')
r.add_child(a, 'time')
t.add_child(r2, 'ARG0-of')
r2.add_child(p, 'ARG1')
r2.add_child(w, 'ARG2')
p.add_child(w, 'ARG0')
generated_amr_str = r.amr_print_with_reentrancy()
expected_amr_str = """(r / receive-01~e.4
:ARG0 (w / we~e.0)
:ARG1 (t / thing~e.7
:ARG0-of~e.7 (r2 / remind-01~e.7
:ARG1 (p / pay-01~e.6
:ARG0 w)
:ARG2 w))
:ARG2~e.8 (h / hospital~e.10)
:time (n / now~e.2)
:time (a / already~e.3))"""
smatch = calculate_smatch(generated_amr_str, expected_amr_str)
assert smatch == 1
def test_amr_print_with_polarity():
b: Node = Node('bad')
neg: Node = Node('-')
i: Node = Node('imitate-01')
c: Node = Node('country')
d: Node = Node('develop-02')
m: Node = Node('most')
w: Node = Node('world')
r: Node = Node('real-04')
b.add_child(neg, 'polarity')
b.add_child(i, 'ARG1')
b.add_child(r, 'ARG1-of')
i.add_child(c, 'ARG1')
c.add_child(d, 'ARG1-of')
c.add_child(w, 'location')
d.add_child(m, 'degree')
generated_amr_str = b.amr_print()
generated_amr_no_spaces = ''.join(generated_amr_str.split())
expected_amr_str = """( d1 / bad
:polarity -
:ARG1 ( d1_1 / imitate-01
:ARG1 ( d1_1_1 / country
:ARG1-of ( d1_1_1_1 / develop-02
:degree ( d1_1_1_1_1 / most )
)
:location ( d1_1_1_2 / world )
)
)
:ARG1-of ( d1_2 / real-04 )
)"""
expected_amr_no_spaces = ''.join(expected_amr_str.split())
assert generated_amr_no_spaces == expected_amr_no_spaces, \
'expected \n' + expected_amr_str + '\ngot\n' + generated_amr_str + '\n'
def __init__(self, machine_manager, volume_manager, context):
self._driver = BTRFSDriver(context['node']['volume_path'])
self._from_etcd = None
self._machine_manager = machine_manager
self._volume_manager = volume_manager
self._node = Node(context['node'], self._driver)
self._work = []
self._volume_loop = self._machine_loop = None
self._max_error_count = context['max_error_count']
self._error_timeout = context['max_error_timeout']
self._delay = context['agent_ttl']
self._watch_timeout = context['watch_timeout']
self._started = False
def setUp(self):
self.lowestCommonAncestor = LowestCommonAncestor()
self.one = Node(1)
self.two = Node(2, self.one)
self.three = Node(3, self.one)
self.four = Node(4, self.two)
self.five = Node(5, self.two)
self.six = Node(6, self.three)
self.seven = Node(7, self.three)
self.eight = Node(8, self.four)
self.nine = Node(9, self.four)
def add_new_car(self, name, lane, intention):
from utils.utils import cars_cross_path
graph = self.get_graph()
leaf_cars = self.get_leaf_cars()
follow_list = list()
visited = set()
# list of nodes
to_visit = [graph[car] for car in leaf_cars]
# starts checking the leaves
while to_visit:
node = to_visit.pop(0)
if node.get_name() not in visited:
visited.add(node.get_name())
if cars_cross_path(lane, intention, node.get_lane(), node.get_intention()):
follow_list.append(node.get_name())
for car in node.get_follow_list():
visited.add(car)
else:
# If it doesn't collide then add the follow list of the node to to_visit list
to_visit = to_visit + [graph[car] for car in graph[node.get_name()].get_follow_list()]
for car in follow_list:
if car in self.get_leaf_cars():
leaf_cars.remove(car)
leaf_cars.add(name)
if name == self.get_name() and name in follow_list:
follow_list.remove(name)
graph[name] = Node(name=name, follow_list=follow_list, lane=lane, intention=intention)
return follow_list
def get_nodes(self, node_label_selector, retry_timer=5):
"""
Returns a list of KubeNodes that is matched to the label selector.
"""
while True:
try:
api_client = client.CoreV1Api()
if node_label_selector:
ret = api_client.list_node(
label_selector=node_label_selector)
else:
ret = api_client.list_node()
kubenodes = [
Node.from_kubernetes_client(node_json=node)
for node in ret.items
]
kubenodes = sorted(kubenodes, key=lambda k: k.name)
return kubenodes
except ApiException as e:
error_dict = json.loads(e.body)
self.logger.error("{}: {}".format(error_dict['status'],
error_dict['message']))
time.sleep(retry_timer)
def _update_nodes(self):
try:
nodes = []
for device in self._devices:
node = Node(device)
nodes.append(node)
hub = self._get_hub(nodes)
if hub is None or hub.neighbors is None:
_LOGGER.error("No hub found")
return
for node in nodes:
self._update_edges(node, nodes)
for hop in range(len(nodes)):
if not self._update_hop(hop, nodes):
break
for node in nodes:
self._update_relation_type(node, nodes)
self._nodes = nodes
except Exception as ex:
trace_back = sys.exc_info()[2]
line = trace_back.tb_lineno
_LOGGER.error(
f"Failed to update nodes due to error: {ex} [LN: {line}]")
def GET(self,id):
page=int(web.input().get('page','1'))
item=Node.objects(ID=int(id)).first()
#todo 分页 or ajax
comments=Tweet.objects(Q(SubjectID=int(id))&Q(flag__ne=1)).order_by("-ID")
#flag=1 means share
next=None
if Auth.is_login():
user=User.objects(id=Auth.uid()).first()
mycollect=user.nodes_follow
if item.ID in mycollect:
collected=True
else:
collected=False
else:
user=None
collected=False
if item and item.creatorID:
creator=User.objects(ID=item.creatorID).first()
else:
creator =None
datalist=[]
for comment in comments:
datalist.append((User.objects(ID=comment.AutherID).first(),comment))
if user==creator :
editble=True
else:
editble=False
if user and ( user.email=="*****@*****.**" or user.email=="*****@*****.**" ):
editble=True
return render.item(editble=editble,user=user,creator=creator,item=item,datalist=datalist,collected=collected)
def __init__(self, mode, values):
if mode == GenMode.BST and values is not None:
leaves = [Node(val=value) for value in values]
root = leaves[0]
self.root_node = root
for leaf in leaves[1:]:
self.build_bst(root, leaf)
def getSingleResult(self, results):
for result in results:
node = Node(result['_id'], result['name'], result['timestamp'],
result['desc'], result['logEntryRef'],
result['logCreator'], "", result['icon'],
result['source'], result['visible'])
return node
def GET(self,uid):
myuid=Auth.uid()
page=int(web.input().get("page","1"))
thisguy=User.objects(ID=int(uid)).first()
if not thisguy:
return render.notfound()
thisguy.tweet_count=Tweet.objects(AutherID=thisguy.ID).count()
counts = thisguy.followings_count,thisguy.followed_count,thisguy.tweet_count
#update count
if page*20<counts[2]:
next=page+1
elif page*20-counts[2]>20 :
return web.notfound()
else:
next=None
if Auth.is_login():
me=User.objects(id=Auth.uid()).first()
else:
me=None
if not me:
relation=None
elif me==thisguy:
relation="self"
elif thisguy.ID in me.followings:
relation="ifollowhim"
else:
relation=None
# do i follow that people?
datalist=[]
posts=Tweet.objects(AutherID=thisguy.ID).order_by("-ID")[(page-1)*20:page*20]
for p in posts:
if p.SubjectID>0:
if p.flag==1:
datalist.append(("share" ,Node.objects(ID=p.SubjectID).first(),p, friendly_time(p.created).decode("utf-8")))
elif p.flag==-1:
pass
else:
datalist.append(("comment" ,Node.objects(ID=p.SubjectID).first(),p, friendly_time(p.created).decode("utf-8")))
elif p.flag==-1:
pass
else:
datalist.append(("say",p,friendly_time(p.created).decode("utf-8")))
return render.user(user=me,thisguy=thisguy,counts=counts,next=next,datalist=datalist,relation=relation)
async def update_node(self,
hostname: str,
ip_address: str,
acquire: bool = False) -> None:
"""Updates the given node or creates a new one if it does not yet exist.
:param str hostname: Hostname of the node
:param str ip_address: IP Address of the node
:param bool acquire: True, if the node should get acquired
"""
# search by hostname since IPs can change
node = self.config.node_repository.get_node_by_hostname(hostname)
# create or update the node
if node is None:
node = Node(name=hostname,
online=True,
ip_address=ip_address,
hostname=hostname)
await self.config.node_repository.add_node(node)
self.log(node, 'added to registry')
elif node.ip_address != ip_address:
node.ip_address = ip_address
await self.config.node_repository.call_listeners()
self.log(node, 'ip address has changed')
# update node state
if node.online is False:
node.online = True
self.log(node, 'is online')
await self.config.node_repository.call_listeners()
await self.config.room_repository.call_listeners()
# acquire node if necessary
if node.room is not None:
if node.acquired is False:
if node.ip_address != self.master_ip:
self.master.send_acquisition(node.ip_address)
node.acquired = True
self.log(node, 'acquired')
elif acquire and node.ip_address != self.master_ip:
# re-acquire if announcement is received again (e.g. in case of a restart)
self.master.send_acquisition(node.ip_address)
self.log(node, 're-acquired')
def GET(self):
nodes=Node.objects(score=20).order_by("-ID")
if Auth.is_login():
user=User.objects(id=Auth.uid()).first()
else:
user=None
if nodes.count()>20:
nodes=nodes[0:20]
return render.explore(user=user,nodes=nodes)
def addCollection(self, values, parent):
for i in range (0, len(values)):
pred = Node(EOGraph.IRI, EOGraph.firstType)
if(type(values[i])==type([])):
obj = Node(EOGraph.blankNode)
self.addTriple(parent, pred, obj)
self.addCollection(values[i], obj)
else:
obj = Literal(values[i])
self.addTriple(parent, pred, obj)
pred = Node(EOGraph.IRI, EOGraph.restType)
if(i==len(values)-1):
obj = Node(EOGraph.IRI, EOGraph.nilType)
else:
obj = Node(EOGraph.blankNode)
self.addTriple(parent, pred, obj)
parent=obj
def add():
if request.method == "GET":
return render_template("node/add.html")
elif request.method == "POST":
id = request.form["id"]
node = Node(id)
db.session.add(node)
db.session.commit()
flash("Node '%s' added successfully" % node.id)
return redirect(url_for(".show", id=node.id))
def test_amr_print_simple():
r: Node = Node('recommend-01')
a: Node = Node('advocate-01')
i: Node = Node('it')
v: Node = Node('vigorous')
r.add_child(a, 'ARG1')
a.add_child(i, 'ARG1')
a.add_child(v, 'manner')
generated_amr_str = r.amr_print()
generated_amr_no_spaces = ''.join(generated_amr_str.split())
expected_amr_str = """( d1 / recommend-01
:ARG1 ( d1_1 / advocate-01
:ARG1 ( d1_1_1 / it )
:manner ( d1_1_2 / vigorous )
)
)"""
expected_amr_no_spaces = ''.join(expected_amr_str.split())
assert generated_amr_no_spaces == expected_amr_no_spaces, \
'expected \n' + expected_amr_str + '\ngot\n' + generated_amr_str + '\n'
def DeclareEquations(self):
"""
This Method is called by the DaeTools. Here is where all the equations are defined
:return:
"""
Node.DeclareEquations(self)
self.eq_mass_balance()
self.eq_energy_balance()
self.eq_momentum_balance()
def GET(self,tag):
page=int(web.input().get('page','1'))
tag=tag.encode('utf-8')
nodes=Node.objects(tags=tag)
count=nodes.count()
if int(page)*10<count:
next=page+1
else:
next=None
results=[x for x in nodes]
return render.tags(Auth,tag,results,count,next)
def m_node(m_driver, p_driver_get_usage):
p_driver_get_usage.return_value = 30.0, [1.0, 1.0, 1.0]
return Node({
'volume_path': '/volumes',
'conf_path': '/etc/cobalt.conf',
'max_fill': 0.8,
'conf': {
'name': 'test-node',
'labels': ['ssd']
}
}, m_driver)
def node(driver):
node_conf = {
'conf_path': '/etc/cobalt.conf',
'volume_path': '/mnt',
'max_fill': 0.8,
'conf': {
'name': 'test-node',
'labels': ['ssd']
}
}
return Node(node_conf, driver)
def addEoTriples(self, graphDefinition, values, types, parent=None):
for key in graphDefinition:
pred = Node(EOGraph.IRI, EOGraph.schema.format(key))
if(type(graphDefinition[key])==type({})):
nestedGraphObject = graphDefinition[key]
node = None
if("id" in nestedGraphObject):
idValue = values[key] if key in values.keys() else ""
node = Node(EOGraph.IRI, idValue)
else:
node = Node(EOGraph.blankNode)
if(key in types.keys()):
typeValue = types[key]
self.addTriple(node, Node(EOGraph.IRI, EOGraph.fnType), Node(EOGraph.IRI, EOGraph.schema.format(typeValue)))
if(parent!=None):
self.addTriple(parent, pred, node)
self.addEoTriples(nestedGraphObject, values, types, node)
else:
subj = parent
if(key=="id" or key not in values or not values[key]):
continue
if(type(values[key])==type([])):
obj = Node(EOGraph.blankNode)
self.addTriple(parent, pred, obj)
self.addCollection(values[key], obj)
else:
obj = Literal(values[key])
self.addTriple(subj, pred, obj)
def fit_tree(self, X, y, depth=0):
"""Fit a decision tree with recursive splitting on nodes.
Args:
X (ndarray): training set without class labels.
y (ndarray) : class labels for training set.
depth (int) : starting depth of decision tree.
Returns:
tree (Node): root node of learned decision tree.
"""
# Get number of training observations in current node with each class label 0 and 1.
class_distribution = [np.sum(y == i) for i in range(self.n_classes)]
# Instantiate node to grow the decision tree.
tree = Node(n=y.size,
class_distribution=class_distribution,
gini_index=_gini(y, self.n_classes))
# Perform recursive splitting to max depth.
if depth < self.max_depth:
gini_index, split_index = self.get_split(X, y)
# Get indices for data and class labels to go to the left child, send the rest to the right child.
if split_index is not None:
index_left = (X[:, split_index] == 1)
X_left, y_left = X[index_left], y[index_left]
X_right, y_right = X[~index_left], y[~index_left]
tree.gini_index = gini_index
tree.feature_index = split_index
depth += 1
tree.left = self.fit_tree(X_left, y_left, depth=depth)
tree.right = self.fit_tree(X_right, y_right, depth=depth)
return tree
def wibednode(id):
logging.debug('Node request from node with id %s', id)
output = {}
logging.debug('NODE REQUEST: %s', request.get_json(force=True))
try:
input = json.loads(request.data)
validateInput(input)
# Attempt to get existing node from id
node = Node.query.get(id)
# If it doesn't exist, create a new one
if not node:
if Node.Status(input["status"]) == Node.Status.IDLE:
output["reinit"] = {}
return jsonify(**output)
else:
node = Node(id)
db.session.add(node)
# Update node fields based on input
updateNode(node, input)
handleExperimentData(node, input, output)
handleFirmwareUpgrade(node, input, output)
handleCommands(node, input, output)
handleSendRestore(node, input, output)
except Exception as e:
logging.debug('Exception joining node: %s', e)
output["errors"] = [str(e)]
db.session.rollback()
logging.debug('SERVER REPLY: %s', output)
return jsonify(**output)
def POST(self):
name=web.input().get("name")
_tags=web.input().get("tags")
source=web.input().get("source")
if _tags:
tags=[x for x in _tags.split(",")]
else:
tags=[]
user=User.objects(id=Auth.uid()).first()
creatorID=user.ID
intro=web.input().get("intro")
picurl=web.input().get("picurl",None)
price=web.input().get("price")
link=web.input().get("source")
store=get_store("store")
price=web.input().get("price")
buyinfo=Buy_info(link=link,store=store,price=price)
#check if none
pic=urllib2.urlopen(picurl).read()
ID=Node.objects.count()+1
open(str(ID)+".jpg","wb").write(pic)
u = UpYun(BUCKETNAME,USER,PASSWORD)
data = open(str(ID)+".jpg",'rb')
u.setContentMD5(md5file(data))
a = u.writeFile('/o'+str(ID)+'.jpg',data)
if not a:
return "get picture erro"
#cut_item_picture(STATIC_FILE,ID,str(ID)+".jpg")
node=Node(creatorID=creatorID,ID=ID,name=name,des=intro,picurl=picurl,tags=tags,buy_info=[buyinfo])
node.picinfo=101 #a out sidelink
node.save()
share=Share_items(ID=Share_items.objects.count()+1,creatorID=user.ID,itemID=ID,flag=1,content="")
share.save()
#加入到shareitem中
#todo count更新
tweet=Tweet(ID=Tweet.objects.count()+1,AutherID=user.ID,SubjectID=ID,flag=1,content=str(ID))
tweet.save()
return web.seeother("/item/"+str(ID)+"/")
def _process_shift(self, action):
current_token = self.tokens[self.current_token_index]
if self.parser_parameters.with_reattach and self._is_named_entity():
if self.parser_parameters.with_gold_concept_labels:
node = self._make_named_entity(action.label, self.named_entity_metadata[0][1])
else:
node = self._make_named_entity(self.index_word_map[current_token], self.named_entity_metadata[0][1])
self.named_entity_metadata.pop(0)
elif self.parser_parameters.with_reattach and self._is_date_entity():
node = self._make_date_entity(self.date_entity_metadata[0][1], self.date_entity_metadata[0][2])
self.date_entity_metadata.pop(0)
else:
if self.parser_parameters.with_gold_concept_labels:
node = Node(action.label)
else:
node = Node(self.index_word_map[current_token])
self.stack.append(node)
self.buffer_indices.pop(0)
if len(self.buffer_indices) != 0:
self.current_token_index = self.buffer_indices[0]
def POST(self):
picurl=web.input().get("check")
name=web.input().get("name")
_tags=web.input().get("tags")
source=web.input().get("source")
if _tags:
tags=[x for x in _tags.split(",")]
else:
tags=[]
user=User.objects(id=Auth.uid()).first()
creatorID=user.ID
intro=web.input().get("intro")
price=web.input().get("price")
link=web.input().get("source")
store=web.input().get("store")
#store=get_store(link).decode("utf-8")
price=web.input().get("price")
buyinfo=Buy_info(link=link,store=store,price=price)
pic=urllib2.urlopen(picurl).read()
ID=Node.objects.count()+1
open(str(ID)+".jpg","wb").write(pic)
u = UpYun(BUCKETNAME,USER,PASSWORD)
data = open(str(ID)+".jpg",'rb')
u.setContentMD5(md5file(data))
a = u.writeFile('/o'+str(ID)+'.jpg',data)
if not a:
return "get picture erro"
#cut_item_picture(STATIC_FILE,ID,str(ID)+".jpg")
node=Node(creatorID=creatorID,ID=ID,name=name,des=intro,picurl=picurl,tags=tags,buy_info=[buyinfo])
node.picinfo=101 #a out sidelink
node.save()
share=Share_items(ID=Share_items.objects.count()+1,creatorID=user.ID,itemID=ID,flag=1,content="")
share.save()
content=u'''<h1>发布成功</h1><p>你可以<a href="/item/%s/">去看看</a>或者
<a href="%s">回到刚才的逛的</a>'''%(str(ID),source)
return render.info(content=content)
return web.seeother("/item/"+str(ID)+"/")
def main():
"""
Main process for blockchain node.
"""
logging.basicConfig(level=logging.INFO)
logging.info('\nStarting node server...')
# Unpack network file
with open("./photoblocks/network.json") as f:
network = json.load(f)
# Test local db connection
db = redis.Redis(host='redis', port=6379)
while True:
try:
if db.execute_command('PING'):
logging.info(f'\nConnected to the local database server.')
break
else:
continue
except Exception as e:
logging.error(f'\n{e}')
continue
# Construct Node object
logging.info('\nCreating Node data structure from configuration...')
node = Node(network["local"])
logging.info(f'\nNode data structure created.')
# Start a node socket client
logging.info('\nStarting node socket client on background thread...')
thread = threading.Thread(target=ClientSock, args=(network, node))
logging.info('\nThread process created.')
thread.daemon = True
thread.start()
logging.info('\nThread process started.')
time.sleep(5)
# Start node socket server
logging.info('\nStarting node socket server on background thread...')
thread = threading.Thread(target=serversock, args=())
logging.info('\nThread process created.')
thread.daemon = True
thread.start()
logging.info('\nThread process started.')
while True:
time.sleep(5)
def validateInput(input):
if not input:
raise Exception("No input data provided.")
if not "status" in input:
raise Exception("No status information provided.")
# Convert INT representation of status to Enum.
input["status"] = Node.Status(input["status"])
if input["status"] == Node.Status.INIT:
if not "model" in input:
raise Exception("No model information provided.")
if not "version" in input:
raise Exception("No firmware version information provided.")
def _parse_nodes(self):
node_sheet = self.workbook.sheet_by_name(NODE_SHEET)
rows = node_sheet.get_rows()
for i, each_row in enumerate(rows):
if i == 0:
# skip header row
continue
label = each_row[0].value
size = each_row[1].value
try:
color = each_row[2].value
except IndexError:
color = random_colors_generator()
node = Node(label=label, size=size, color=color)
self.nodes.append(node)
def load(self) -> None:
"""Loads the configuration file and parses it into class attributes."""
self.type = NodeType[self.data.get('type').upper()]
# load rooms
for room_data in self.data.get('rooms'):
self.rooms.append(Room.from_json(room_data))
# load nodes
for node_data in self.data.get('nodes'):
self.nodes.append(Node.from_json(node_data, self))
# load speakers
for speaker_data in self.data.get('speakers'):
self.speakers.append(Speaker.from_json(speaker_data, self))
# load rooms calibration data after loading speakers
for room_data in self.data.get('rooms'):
room = self.room_repository.get_room(room_data.get('id'), fail=True)
room.calibration_points_from_json(room_data.get('calibration_points'), self)
