def send_day(day):
send_data(day)#自当年元旦开始的天(个位)、分隔标志、天(十位)、基准标志
#天(百位)、分隔标志、未编码位、基准标志
send_bits(bcd(day//100))
utils.divide()
utils.vacancy()
utils.p_unit()
def test_divide(self):
self.assertEquals(utils.divide([]), 1)
self.assertAlmostEquals(utils.divide([2.1]), 0.47619047619047616)
self.assertAlmostEquals(utils.divide([2.1, 4.3, 2.1]),
0.052734272003374986)
self.assertAlmostEquals(utils.divide([-0.5, 10.1, 3]),
-0.06600660066006601)
def __init__(self, attention_mask_func, hidden_size, num_attention_heads,
attention_dropout):
super(ParallelSelfAttention, self).__init__()
self.attention_mask_func = attention_mask_func
# Per attention head and per partition values.
world_size = torch.distributed.get_world_size()
self.hidden_size_per_partition = divide(hidden_size, world_size)
self.hidden_size_per_attention_head = divide(hidden_size,
num_attention_heads)
self.num_attention_heads_per_partition = divide(
num_attention_heads, world_size)
# Strided linear layer.
self.query_key_value = ColumnParallelLinear( # column linear
hidden_size,
3 * hidden_size,
gather_output=False)
self.norm_factor = math.sqrt(self.hidden_size_per_attention_head)
self.scale_mask_softmax = ScaleMaskSoftmax(
mask_func=self.attention_mask_func, scale=None)
# Dropout. Note that for a single iteration, this layer will generate
# different outputs on different number of parallel partitions but
# on average it should not be partition dependent.
self.attention_dropout = torch.nn.Dropout(attention_dropout)
# Output.
self.dense = RowParallelLinear(input_size=hidden_size,
output_size=hidden_size,
input_is_parallel=True)
def send_data(data,digit=2):
dot=1
for i in range(digit):
dot*=10
unit=data%dot*10//dot#单位数字
send_bits(bcd(unit))
if i <digit-1:
utils.divide()
utils.p_unit()
def test_divide(self):
"""Expectation: divide one number by another using the correct template"""
with self.subTest("Testing divide() using integers"):
computed = utils.divide(self.i3, self.i4)
self.assertIsInstance(computed, int)
self.assertEqual(computed, int(self.i3 / self.i4))
with self.subTest("Testing divide() using floats"):
computed = utils.divide(self.f3, self.f4)
self.assertIsInstance(computed, float)
self.assertEqual(computed, self.f3 / self.f4)
def calculate_predictions(true_positive, false_positive, true_negative, false_negative):
"""
Calculate predictions based on the number of true/false positive/negative's
"""
sens_denom = true_positive + false_negative
spec_denom = true_negative + false_positive
sensitivity = divide(true_positive, sens_denom)
specificity = divide(true_negative, spec_denom)
accuracy = divide(true_positive + true_negative, sens_denom + spec_denom)
tpr = sensitivity # Calculate the true positive rate
fpr = 1 - specificity # Calculate the false positive rate
return accuracy, tpr, fpr
def send_control():
"""
未编码位、分隔标志、未编码位、基准标志+时间质量标志、校验位、未编码位、基准标志
"""
utils.vacancy()
utils.divide()
utils.vacancy()
utils.p_unit()
utils.time_quality()
utils.verify()
utils.vacancy()
utils.time_quality()
def compute(self):
if not(self.graph.processed()): self.graph.process()
user_count = len(self.graph)
self.analyze_group()
self.statistics.update({
'subgroups' : len(self.graph.groups),
'user_count': user_count,
'like_avg': divide(self.statistics['likes_total'], user_count),
'age_avg': divide(self.statistics['age_total'], user_count),
'friends_avg': divide(len(self.friends), user_count),
'friends_age_avg':divide(self.statistics['friends_age_total'], len(self.friends)),
})
return self.statistics
def hydrate(self, ids):
ids = divide(list(ids), 100)
results = []
for id in ids:
result = data_from_id(self.tw, map(str, id))
results.append(result)
return results
def __init__(self, input_size, output_size, input_is_parallel=False):
super(RowParallelLinear, self).__init__()
# Keep input parameters
self.input_size = input_size
self.output_size = output_size
self.input_is_parallel = input_is_parallel
# Divide the weight matrix along the last dimension.
world_size = torch.distributed.get_world_size()
self.input_size_per_partition = divide(input_size, world_size)
# Parameters.
# Note: torch.nn.functional.linear performs XA^T + b and as a result
# we allocate the transpose.
# Initialize weight.
self.weight = Parameter(
torch.empty(self.output_size,
self.input_size_per_partition,
device=torch.cuda.current_device(),
dtype=torch.float))
torch.nn.init.xavier_normal_(self.weight)
self.bias = Parameter(
torch.empty(self.output_size,
device=torch.cuda.current_device(),
dtype=torch.float))
# Always initialize bias to zero.
with torch.no_grad():
self.bias.zero_()
def __init__(self, pattern = "", seeds_dict = {}):
self.pattern = pattern
self.strlen = len(pattern)
self.num_of_seeds = len(seeds_dict)
self.seeds_dict = seeds_dict
self.max_seed = max(self.seeds_dict.values())
self.avg_seed = utils.divide(utils.sum(self.seeds_dict.values()),
self.num_of_seeds)
def features(self):
return {
# Device
#'device': self.device,
# Product
#'product': self.merchandise,
#Country
'country':
self.country,
# Price
# 'price': self.price,
'price_fr':
utils.short_float(utils.divide(self.price, self.last_price)),
# IP
#'ip_3oct': self.ip_3oct,
#'ip_2oct': self.ip_2oct,
# Time
# 'time': self.time,
# 'time_from_start': self.time_from_start,
# 'time_to_end': self.time_to_end,
# format _perc to have 2 digist after .
'time_from_start_perc':
utils.short_float(utils.divide(self.time, self.auc_length)),
'time_to_end_perc':
utils.short_float(utils.divide(self.time_to_end, self.auc_length)),
# 'time_from_day_start': self.time_from_day_start,
# 'time_to_prev_bid': self.time_to_prev_bid,
# Order
#'is_first': self.is_first,
#'is_last': self.is_last,
#'day': self.day,
'unique':
self.prev_unique,
'unique_50':
self.prev_unique_50,
# how many immediate prev bids are made by the same user?
# Url
#'ref': self.url,
}
def EStep(pose, log_var, log_activation, vote):
normal_vote = utils.divide(tf.square(vote - pose), 2 * tf.exp(log_var))
log_probs = normal_vote + utils.log(2 * np.pi) + log_var
log_probs = -0.5 * tf.reduce_sum(log_probs, axis=-1, keepdims=True)
log_act_logit = log_activation + log_probs
log_act_logit = log_probs
log_R = log_act_logit - tf.reduce_logsumexp(log_act_logit, axis=-2, keepdims=True)
return log_R
def use_my_utils(a, b):
differenceof = utils.differenceof(a, b)
sumof = utils.sumof(a, b)
multiplyof = utils.multiplyof(a, b)
divide = utils.divide(a, b)
print(differenceof)
print(sumof)
print(multiplyof)
print(divide)
def analyze_group(self):
for k, group in enumerate(self.graph.groups):
shared_songs = 0
friendships = 0
for edge in self.graph.edges:
if edge[0] in group or edge[1] in group:
friendships += 1
shared_songs += int(edge[2]['songs'])
self.statistics['shared_songs_total_group'][k] = shared_songs
self.statistics['shared_songs_avg_group'][k] = divide(shared_songs, friendships) if shared_songs else 0
def migrate_node(self, src_node):
nodes = [n for n in self.masters if n.name != src_node.name]
slot_count = len(src_node.slots)
if slot_count <= 0:
return
slots = divide(slot_count, len(nodes))
nodes.sort(key=lambda x: len(x.slots))
for node, count in zip(nodes, slots):
src, dst = (src_node, node)
self.migrate(src, dst, count)
def fill_slots(self):
masters = self.masters
slots = itertools.chain(*[n.slots for n in masters])
missing = list(set(range(self.CLUSTER_HASH_SLOTS)).difference(slots))
div = divide(len(missing), len(masters))
masters.sort(key=lambda x: len(x.slots))
i = 0
for count, node in zip(div, masters):
node.add_slots(*missing[i:count + i])
i += count
def features(self):
return {
# Device
#'device': self.device,
# Product
#'product': self.merchandise,
#Country
'country': self.country,
# Price
# 'price': self.price,
'price_fr': utils.short_float(utils.divide(self.price, self.last_price)),
# IP
#'ip_3oct': self.ip_3oct,
#'ip_2oct': self.ip_2oct,
# Time
# 'time': self.time,
# 'time_from_start': self.time_from_start,
# 'time_to_end': self.time_to_end,
# format _perc to have 2 digist after .
'time_from_start_perc': utils.short_float(utils.divide(self.time, self.auc_length)),
'time_to_end_perc': utils.short_float(utils.divide(self.time_to_end, self.auc_length)),
# 'time_from_day_start': self.time_from_day_start,
# 'time_to_prev_bid': self.time_to_prev_bid,
# Order
#'is_first': self.is_first,
#'is_last': self.is_last,
#'day': self.day,
'unique': self.prev_unique,
'unique_50': self.prev_unique_50,
# how many immediate prev bids are made by the same user?
# Url
#'ref': self.url,
}
def bind_slots_force(self):
masters = self.masters
slots = itertools.chain(*[n.slots for n in masters])
missing = list(set(range(self.CLUSTER_HASH_SLOTS)).difference(slots))
div = divide(len(missing), len(masters))
masters.sort(key=lambda x: len(x.slots))
i = 0
for count, node in zip(div, masters):
for slot in missing[i:count + i]:
self.update_slot_mapping(slot, node.name)
i += count
def count_proximity_over_cooc(self, list, cache=False):
"""
list - check proximity over cooccurrence for the given list of terms
"""
prox = self.count_proximity(list, cache)
cooc = self.count_cooccurrence(list, cache)
result = utils.divide(prox, cooc)
if self.debug:
print "Calculated proximity count for terms %s - %0.5f (cooc - %d)" % (list,
result,
cooc)
return result
def compute_metrics(stats_authors):
#Keep only the possible candidates:
stats_authors = {
s: stats_authors[s]
for s in stats_authors if stats_authors[s]["Candidate"]
}
#Compute (more complex) metrics:
for authorName, authorStats in stats_authors.items():
stats_authors[authorName]["Following-Followers Ratio"] = divide(
authorStats["Following"], authorStats["Followers"])
stats_authors[authorName]["TotViews"] = sum(authorStats["ViewsSerie"])
stats_authors[authorName]["Views-Followers Ratio"] = divide(
authorStats["TotViews"],
authorStats["Followers"],
round_result=False)
stats_authors[authorName]["AverageLikes"] = divide(
authorStats["NLikes"], authorStats["NVideos"])
stats_authors[authorName]["AverageViews"] = divide(
sum(authorStats["ViewsSerie"]), authorStats["NVideos"])
save_metrics(stats_authors)
return stats_authors
def split_tensor_along_last_dim(tensor,
num_partitions,
contiguous_split_chunks=False):
"""Split a tensor along its last dimension.
Arguments:
tensor: input tensor.
num_partitions: number of partitions to split the tensor
contiguous_split_chunks: If True, make each chunk contiguous in memory.
"""
last_dim = tensor.dim() - 1
last_dim_size = divide(tensor.size()[last_dim], num_partitions)
# Split
tensor_list = torch.split(tensor,
split_size_or_sections=last_dim_size,
dim=last_dim)
return tensor_list
def choose_solo_notes(self):
rest_beginning = random.choice([True, False, False, False, False])
rest_middle = random.choice([True, True, False])
rest_end = random.choice([True, True, True, False, False])
rests = [rest_beginning, rest_middle, rest_end]
num_rests = rests.count(True)
min_num_divs = 3 + num_rests
num_divs = random.randint(min_num_divs, 9)
divs = divide(16, num_divs)
notes = [{'pitch': None, 'duration': div / 4.0} for div in divs]
if rest_beginning:
notes[0]['pitch'] = 'rest'
if rest_end:
notes[-1]['pitch'] = 'rest'
if rest_middle:
if rest_beginning:
start = 2
else:
start = 1
if rest_end:
end = -2
else:
end = -1
middle_rest_index = random.choice(range(len(notes))[start:end])
notes[middle_rest_index]['pitch'] = 'rest'
for note in notes:
if note['pitch'] != 'rest':
note['pitch'] = ps = random.choice(self.soloist_shared_notes)
self.soloist_shared_notes = [p for p in frange(ps - 2, ps + 3) if p in self.all_soloists_shared_notes]
self.soloist_shared_notes = [p for p in frange(ps - 5, ps + 6) if p in self.all_soloists_shared_notes]
return notes
async def list_category(self, ctx):
embeds = []
for categories in divide(list(self.bot.categoryDB.find()), 10):
embed = Embed(title='카테고리 목록', color=Color.green())
for category in categories:
embed.add_field(name=category['name'],
value=f'`{category["description"]}`')
embeds.append(embed)
if embeds:
msg = await ctx.send(embed=embeds[0])
await Paginator(self.bot, msg, embeds=embeds).start()
else:
await ctx.send(embed=Embed(
title='카테고리 목록', description='카테고리가 없습니다', color=Color.green())
)
def __init__(self, g: Graph, levels_to_build):
super().__init__()
self.g = g
self.division = divide(g)
self.levels_to_build = levels_to_build
self.final = []
self.start = FactorGraph(g, sorted([CongruenceClass([node]) for node in g.nodes]), '∆')
self.add_node(self.start)
self.levels_count = g.number_of_nodes() - 1
if self.levels_to_build is not None:
self.levels_count = min(self.levels_to_build, self.levels_count)
self.levels = [[] for _ in range(self.levels_count)]
self.levels_set = [set() for _ in range(self.levels_count)]
self.nodes_levels = {}
self._build()
async def help(self, ctx):
embeds = [
Embed(title='도움',
description='`이모지`로 페이지를 넘기세요',
color=Color.green())
]
for i in range(len(self.bot.cogs)):
cog = self.bot.cogs[list(self.bot.cogs.keys())[i]]
embeds[0].add_field(name=f'{i + 1}페이지 | {cog.name}',
value=f'`{cog.description}`',
inline=True)
for cmds in divide(cog.get_commands(), 10):
embed = Embed(title=f'{cog.name} 도움', color=Color.green())
embed.set_footer(text=f'Page {i + 1}')
for cmd in cmds:
if 'commands' not in dir(cmd):
embed.add_field(
name=f'{self.bot.command_prefix}{cmd.name}'
if not cmd.usage else
f'{self.bot.command_prefix}{cmd.usage}',
value=cmd.help or '설명 없음',
inline=True)
else:
for child_cmd in cmd.commands:
embed.add_field(
name=
f'{self.bot.command_prefix}{cmd.name} {child_cmd.name}'
if not child_cmd.usage else
f'{self.bot.command_prefix}{cmd.name} {child_cmd.usage}',
value=child_cmd.help or '설명 없음',
inline=True)
embeds.append(embed)
msg = await ctx.send(embed=embeds[0])
await Paginator(self.bot, msg, embeds=embeds).start()
async def list_post(self, ctx, *, query: str = None):
if not query:
postlist = list(self.bot.postDB.find())
title = '글 목록'
no_description = '글이 없습니다'
else:
postlist = []
_idlist = []
_postlist = self.bot.postDB.get({'title': {'$regex': f'.*{query}.*'}}) + self.bot.postDB.get({'content': {'$regex': f'.*{query}.*'}})
for data in _postlist:
if data['_id'] in _idlist:
continue
_idlist.append(data['_id'])
postlist.append(data)
title = f'"{query}" 검색 결과'
no_description = '검색 결과가 없습니다'
embeds = []
for categories in divide(postlist, 10):
embed = Embed(
title=title,
color=Color.green()
)
for post in categories:
embed.add_field(name=f'{post["title"]} ({post["_id"]})', value=f'by `{self.bot.get_user(int(post["authorID"]))}` :heart: `{len(post["hearts"])}` :speech_balloon: `{len(self.bot.commentDB.get({"postID": post["_id"]}))}`', inline=False)
embeds.append(embed)
if embeds:
msg = await ctx.send(embed=embeds[0])
await Paginator(self.bot, msg, embeds=embeds).start()
else:
await ctx.send(embed=Embed(title=title, description=no_description, color=Color.green()))
def slot_balance(self, seq):
amt = self.CLUSTER_HASH_SLOTS
seq.sort(key=lambda x: x['count'], reverse=True)
chunks = divide(amt, len(seq))
pairs = list(zip(seq, chunks))
i, j = 0, len(pairs) - 1
while i < j:
m, count = pairs[i]
more = m['count'] - count
if more <= 0:
i += 1
continue
n, count = pairs[j]
need = count - n['count']
if need <= 0:
j -= 1
continue
if need < more:
n['need'].append((m['node'], need))
n['count'] += need
m['count'] -= need
j -= 1
elif need > more:
n['need'].append((m['node'], more))
n['count'] += more
m['count'] -= more
i += 1
else:
n['need'].append((m['node'], need))
n['count'] += need
m['count'] -= more
j -= 1
i += 1
return seq
from numpy import asarray
from numpy import save
import straw
from scipy.sparse import csr_matrix
import utils
highres = utils.matrix_extract(
18, 10000,
"https://hicfiles.s3.amazonaws.com/hiseq/gm12878/in-situ/combined.hic")
print('dividing, filtering and downsampling files...')
highres_sub, index = utils.divide(highres)
print("highres shape: ", highres_sub.shape)
lowres = utils.genDownsample(highres, 1 / float(16))
lowres_sub, index = utils.divide(lowres)
print("lowres shape: ", lowres_sub.shape)
save('lowres_ch18.npy', lowres_sub)
save('highres_ch18.npy', highres_sub)
str(args['resolution']))
low_chr_mat = low_cool.matrix(
balance=False).fetch("chr" + str(args['chr_num'])).astype(float)
low_chr_mat[np.isnan(low_chr_mat)] = 0
chr_frames, chr_indices = utils.divide2(low_chr_mat, args['chr_num'])
enhanced_chr_mat = low_cool.matrix(
balance=False).fetch("chr" + str(args['chr_num'])).astype(float)
enhanced_chr_mat[np.isnan(enhanced_chr_mat)] = 0
"""
average_chr_mat = low_cool.matrix(balance = False).fetch("chr" + str(args['chr_num'])).astype(float)
average_chr_mat[np.isnan(average_chr_mat)] = 0
"""
else:
chr_frames, chr_indices = utils.divide(args['LowRes_matrix_path'],
args['chr_num'], args['resolution'],
args['genome_type'])
low_chr_mat = np.load(args['LowRes_matrix_path'] + '_npy_form_tmp.npy')
enhanced_chr_mat = np.load(args['LowRes_matrix_path'] +
'_npy_form_tmp.npy')
# average_chr_mat = np.load(args['LowRes_matrix_path'] + '_npy_form_tmp.npy')
# applying model on frames
chr_frames = np.stack(chr_frames, axis=0)
chr_indices = np.stack(chr_indices, axis=0)
chr_frames = np.expand_dims(chr_frames, axis=1)
lowres_set = torch.from_numpy(chr_frames).float()
enhanced_set = Net(Variable(lowres_set))
enhanced_set = enhanced_set.data.cpu().numpy()
enhanced_set = np.reshape(
enhanced_set,
(enhanced_set.shape[0], enhanced_set.shape[2], enhanced_set.shape[3]))
use_gpu = 1
conv2d1_filters_numbers = 8
conv2d1_filters_size = 9
conv2d2_filters_numbers = 8
conv2d2_filters_size = 1
conv2d3_filters_numbers = 1
conv2d3_filters_size = 5
down_sample_ratio = 16
epochs = 10
HiC_max_value = 100
# This block is the actual training data used in the training. The training data is too large to put on Github, so only toy data is used.
input_file = '/home/zhangyan/Desktop/chr21.10kb.matrix'
low_resolution_samples, index = utils.divide(input_file)
low_resolution_samples = np.minimum(HiC_max_value, low_resolution_samples)
batch_size = low_resolution_samples.shape[0]
# Reshape the high-quality Hi-C sample as the target value of the training.
sample_size = low_resolution_samples.shape[-1]
padding = conv2d1_filters_size + conv2d2_filters_size + conv2d3_filters_size - 3
half_padding = padding / 2
output_length = sample_size - padding
print low_resolution_samples.shape
lowres_set = data.TensorDataset(
torch.from_numpy(low_resolution_samples),
def __init__(self, encoder, decoder, n_samples=1, q=6 / 5, n_lambda=29):
super(particle_flow, self).__init__()
self.n_samples = n_samples
self.intervals = divide(q, n_lambda)
self.encoder = encoder
self.decoder = decoder
if args.ci_mode and not args.ci_threshold:
parser.error("CI mode requires a threshold to be set")
cwd = os.getcwd()
master = load_tool(args.mutation_tool, cwd)
if not args.benchmark:
print("Checking project compatibility with {0}...".format(args.mutation_tool))
if not master.check():
sys.exit("Selected mutation tool reports that it doesn't support the current project.")
print("Creating mutants...")
mdir, mutants = master.mutate()
print("Scoring mutants in parallel...")
divided_mutants = divide(mutants, args.scorers)
# functools.partial is instead of lamda below, as the latter can't be pickled
toolfun = functools.partial(load_tool, args.mutation_tool)
scorefun = functools.partial(local_scorer.create_and_score, toolfun, cwd, mdir)
with Pool(processes=args.scorers) as pool:
nested_results = pool.map(scorefun, divided_mutants, 1)
results = ScoringResult(flatten_list(nested_results))
if not args.benchmark:
print("Loading mutant metadata from the filesystem...")
results.add_metadata(cwd, mdir)
if args.ci_mode:
def features(self):
# global human_cnt
# if self.is_robot or (self.is_human and human_cnt > 0):
# if self.is_human:
# human_cnt -= 1
# self.find_increment_patterns()
#self.find_inc_price_patterns()
increments = self.get_all_increments()
bids_count = len(self.bids)
true_bids_count = len(increments)
# Auctions
auctions_count = len(self.auctions)
sim_auctions = self.get_sim_auctions()
won_auctions_count = len(self.win_bids)
auction_rank = 0.0
for auc, bids in self.auctions.iteritems():
auction_rank += shared.auction_rank[auc]
if self.auctions:
auction_rank /= len(self.auctions)
# Price
human_price_rmse_per_auction = self.get_price_rmse(self.last_bids, shared.human_median_price_per_auction, 'auction')
human_price_rmse_per_product = self.get_price_rmse(self.last_bids, shared.human_median_price_per_product, 'merchandise')
robot_price_rmse_per_auction = self.get_price_rmse(self.last_bids, shared.robot_median_price_per_auction, 'auction')
robot_price_rmse_per_product = self.get_price_rmse(self.last_bids, shared.robot_median_price_per_product, 'merchandise')
# Stats per auction
avg_countries_per_auction = self.get_per_auction(np.average, self.counties_per_auction)
median_countries_per_auction = self.get_per_auction(np.median, self.counties_per_auction)
std_countries_per_auction = self.get_per_auction(np.std, self.counties_per_auction)
avg_devices_per_auction = self.get_per_auction(np.average, self.devices_per_auction)
median_devices_per_auction = self.get_per_auction(np.median, self.devices_per_auction)
std_devices_per_auction = self.get_per_auction(np.std, self.devices_per_auction)
avg_referrals_per_auction = self.get_per_auction(np.average, self.referrals_per_auction)
median_referrals_per_auction = self.get_per_auction(np.median, self.referrals_per_auction)
std_referrals_per_auction = self.get_per_auction(np.std, self.referrals_per_auction)
avg_ips_per_auction = self.get_per_auction(np.average, self.ips_per_auction)
median_ips_per_auction = self.get_per_auction(np.median, self.ips_per_auction)
std_ips_per_auction = self.get_per_auction(np.std, self.ips_per_auction)
# avg_inc_per_auction = self.get_per_auction(np.average, self.increments_per_auction)
# median_inc_per_auction = self.get_per_auction(np.median, self.increments_per_auction)
# std_inc_per_auction = self.get_per_auction(np.std, self.increments_per_auction)
# IP
avg_ips_per_increment = utils.divide(sum([inc.ips_count for inc in increments]), len(increments))
frequent_ip = '.'.join(self.get_frequent(self.ips).split('.')[:2])
ip_octets = defaultdict(int)
for ip, count in self.ips.iteritems():
octets = ip.split('.')
ip_octets['.'.join(octets[:1])] += count
ip_octets['.'.join(octets[:2])] += count
ip_octets['.'.join(octets[:3])] += count
ip_octets['.'.join(octets[:4])] += count
sorted_octets = sorted(ip_octets.items(), key=operator.itemgetter(1), reverse=True)
# Countries
cnt_mask = 0
seen_countries = set(self.countries.keys())
for country in seen_countries:
i = shared.countries.index(country)
cnt_mask |= (1<<(i+1))
cnt_mask = str(cnt_mask)
countries_inc = defaultdict(int)
for inc in self.bids:
countries_inc[inc.country] += 1
country_rank = 0
for country, count in countries_inc.iteritems():
country_rank += shared.country_rank[country] * count
if len(countries_inc):
country_rank = float(country_rank) / sum(countries_inc.values())
regions_mask = 0
seen_regions = set([shared.country_to_region[c] for c in seen_countries])
for region in seen_regions:
i = shared.regions.index(region)
regions_mask |= (1<<(i+1))
regions_mask = str(regions_mask)
# Products
all_products = ['mobile', 'jewelry', 'home goods', 'sporting goods', 'auto parts', 'office equipment', 'computers', 'books and music', 'furniture', 'clothing']
products_mask = 0 # compute all products user bidded on as a number
for p in self.products.keys():
i = all_products.index(p)+1
if not i:
continue
products_mask |= (1<<i)
products_mask = str(products_mask)
# Bids
bid_on_unpopular = -1.0
for bid in self.bids:
if bid.merchandise in ["auto parts", "clothing", "furniture"]:
bid_on_unpopular = 1.0
break
# Generate
# TODO: add count of times user reached max price in auction (measure greediness)
labels = ["country", "device", "product", "ip", "ref", "auction", "bids", "increments", "won_auctions", "sim_auctions"]
values = [len(self.countries), len(self.devices), len(self.products), len(self.ips), len(self.referrals), auctions_count, len(self.bids), true_bids_count, won_auctions_count, sim_auctions]
#ops = ["+", "-", "*", "/"]
ops = ["/"]
generated_features = dict()
for op in ops:
for i in xrange(len(labels)):
al = labels[i]
av = values[i]
for j in xrange(i+1, len(labels)):
bl = labels[j]
bv = values[j]
if op == "+":
generated_features[al+op+bl] = av+bv
elif op == "-":
generated_features[al+op+bl] = av-bv
elif op == "*":
generated_features[al+op+bl] = av*bv
elif op == "/":
generated_features[al+op+bl] = utils.divide(av,bv)
# Time
time_hist_prob = 0
for bid in self.bids:
i = bisect.bisect_left(shared.human_hist_bins, bid.time)
time_hist_prob += shared.human_hist[i-1]
if self.bids:
time_hist_prob /= float(len(self.bids))
features = {
"set_0": self.bidder_id in shared.set0,
# Address
# "addr_1": self.get_addr_1(),
# "addr_2": self.get_addr_2(),
# "is_addr_1_unique": len(shared.addr_1[self.get_addr_1()]) == 1,
# "is_addr_2_unique": len(shared.addr_2[self.get_addr_2()]) == 1,
# "addr_1=a3d2de7675556553a5f08e4c88d2c228": self.get_addr_1() == 'a3d2de7675556553a5f08e4c88d2c228',
# Devices
# "devices": len(self.devices),
# TODO: devices per last X bids
#"avg_devices_per_auction": avg_devices_per_auction,
#"median_devices_per_auction": median_devices_per_auction,
#"std_devices_per_auction": std_devices_per_auction,
# Time
"time_hist_prob": time_hist_prob,
# Country
#"unique_countries_count": len(self.countries),
# "frequent_country": self.get_frequent(self.countries),
"avg_countries_per_auction": avg_countries_per_auction,
"median_countries_per_auction": median_countries_per_auction,
"std_countries_per_auction": std_countries_per_auction,
# "seen_countries": cnt_mask,
#"country_rank": country_rank,
# "seen_regions": regions_mask,
#"regions_count": len(seen_regions),
"country_change": self.get_change_rate('country'),
# Products
# "frequent_product": self.get_frequent(self.products),
"bid_on_unpopular": bid_on_unpopular,
# "products_mask": products_mask,
# IP
#"unique_ips": len(self.ips),
"avg_ips_per_auction": avg_ips_per_auction,
"median_ips_per_auction": median_ips_per_auction,
"std_ips_per_auction": std_ips_per_auction,
#"avg_unique_ips": utils.divide(len(self.ips), bids_count),
#"avg_ips": utils.divide(sum(self.ips.values()), bids_count),
"avg_ips_per_increment": avg_ips_per_increment,
# "frequent_ip": frequent_ip,
#"frequent_ip_class": self.get_ip_class(frequent_ip), # http://www.vlsm-calc.net/ipclasses.php
# "most_popular_octet": sorted_octets[0][0] if sorted_octets else '',
#"ip_rank": self.get_ip_rank(self.bids),
"ip_change": self.get_change_rate('ip_pref'),
# Referrals
# "frequent_referral": self.get_frequent(self.referrals),
#"referrals_count": len(self.referrals),
"avg_referrals_per_auction": avg_referrals_per_auction,
"median_referrals_per_auction": median_referrals_per_auction,
"std_referrals_per_auction": std_referrals_per_auction,
"referral_change": self.get_change_rate('url'),
# Auctions
# "auctions_count": auctions_count,
#"won_auctions_count": won_auctions_count,
#"sim_auctions": sim_auctions,
# "auction_rank": auction_rank,
# Payment
# "payment_type": self.get_payment_type(),
# "payment_acct": self.get_payment_acct(),
# "is_pmt_type_unique": len(shared.pmt_type[self.get_payment_type()]) == 1,
# "is_pmt_acct_unique": len(shared.pmt_accnt[self.get_payment_acct()]) == 1,
#"payment_type=addr_1": self.get_payment_type() == self.get_addr_1(),
#"payment_acct=addr_2": self.get_payment_acct() == self.get_addr_2(),
# Bids
#"true_bids_count": true_bids_count,
# "avg_inc_per_auction": avg_inc_per_auction,
# "median_inc_per_auction": median_inc_per_auction,
# "std_inc_per_auction": std_inc_per_auction,
# Price
# rmse is calculated based on won_price and measure user price threshold/estimate
# expect to have it bigger for humans and smaller for robots
#"human_price_rmse_per_auction": human_price_rmse_per_auction,
#"human_price_rmse_per_auction": human_price_rmse_per_auction,
#"robot_price_rmse_per_auction": robot_price_rmse_per_auction,
#"robot_price_rmse_per_product": robot_price_rmse_per_product,
}
features.update(generated_features)
# features.update(buckets_dict)
return features
def train():
# Initialize torch.distributed
init_distributed()
print_rank_0('AutoMP: training ParallelTransformerLayer...')
batch_size = args.batch_size
sequence_length = args.sequence_length
hidden_size = args.hidden_size
vocab_size = args.vocab_size
hidden_dropout = args.hidden_dropout
attention_dropout = args.attention_dropout
num_layers = args.num_layers
layernorm_epsilon = args.layernorm_epsilon
num_attention_heads = args.num_attention_heads
input_indices = torch.randint(low=0,
high=vocab_size,
size=(batch_size, sequence_length))
input_indices = input_indices.to(torch.cuda.current_device())
labels = torch.randint(low=0,
high=vocab_size,
size=(batch_size, sequence_length))
labels = labels.to(torch.cuda.current_device())
position_indices = torch.tile(torch.arange(start=0, end=sequence_length),
(batch_size, 1))
position_indices = position_indices.to(torch.cuda.current_device())
def init_method_normal(tensor):
return torch.nn.init.normal_(tensor, mean=0.0, std=1.0)
def gpt2_attention_mask_func(attention_scores, ltor_mask):
attention_scores.masked_fill_(ltor_mask, -10000.0)
return attention_scores
def init_method_normal(tensor):
return torch.nn.init.normal_(tensor, mean=0.0, std=1.0)
embedding = Embedding(hidden_size=hidden_size,
vocab_size=vocab_size,
max_sequence_length=sequence_length,
embedding_dropout_prob=hidden_dropout,
init_method=init_method_normal)
embedding_output = embedding.forward(input_indices, position_indices)
transformer_layer = ParallelTransformerLayer(
attention_mask_func=gpt2_attention_mask_func,
layer_number=0,
hidden_size=hidden_size,
layernorm_epsilon=layernorm_epsilon,
num_attention_heads=num_attention_heads,
attention_dropout=attention_dropout,
hidden_dropout=hidden_dropout)
# attention_mask, loss_mask, position_ids = get_ltor_masks_and_position_ids(input_indices, vocab_size - 1)
attention_mask = (torch.randint(
low=0,
high=2,
size=(sequence_length,
divide(num_attention_heads, torch.distributed.get_world_size()),
batch_size, batch_size)) < 0).cuda()
optimizer = torch.optim.SGD(transformer_layer.parameters(), lr=0.01)
profiler = Profiler(os.path.join('benchmark', args.exp_name))
num_epochs = 5
tot_time = 0
nproc = torch.distributed.get_world_size()
for epoch in range(num_epochs):
input_ = torch.rand(size=embedding_output.size()).cuda()
overall_name = f'transformer_layer_np-{nproc}_hs-{hidden_size}_nah-{num_attention_heads}_bsz-{batch_size}'
profiler.start(overall_name)
fname = f'transformer_layer_forward_np-{nproc}_hs-{hidden_size}_nah-{num_attention_heads}_bsz-{batch_size}'
# Forward pass
profiler.start(fname)
loss = transformer_layer.forward(input_, attention_mask)
train_loss = torch.mean(loss)
# print(train_loss)
torch.cuda.synchronize()
profiler.stop(fname)
# Backward pass
bname = f'transformer_layer_backward_np-{nproc}_hs-{hidden_size}_nah-{num_attention_heads}_bsz-{batch_size}'
profiler.start(bname)
optimizer.zero_grad()
train_loss.backward()
optimizer.step()
torch.cuda.synchronize()
profiler.stop(bname)
profiler.stop(overall_name)
"""
# this works if format of file names in a COO_folder is not like chr[chr_num].txt but we should care about sequence of filenames to be same in
# folder of high resolution files and folder of low resolution files
chr_files_list = [f for f in os.listdir(COO_folder_path) if (not f.startswith('.')) & (not f.endswith('_npy_form_tmp.npy'))]
chr_num_list = []
for f in chr_files_list:
m = re.search('chr(\d+|x)', f, re.IGNORECASE)
chr_num_list.append(int(m.group(1)))
"""
frames_data = []
index_data = []
for i in range(args['min_chrN'], args['max_chrN'] + 1):
chr_COO_file_name = "chr" + str(i) + ".txt"
chr_data_path = os.path.join(COO_folder_path, chr_COO_file_name)
temp_frames, temp_index = utils.divide(chr_data_path, i,
args['resolution'],
args['genome_type'],
args['COO_format'])
frames_data.extend(temp_frames)
index_data.extend(temp_index)
print("chr" + str(i) + " is done!")
frames_data = np.stack(frames_data, axis=0)
index_data = np.stack(index_data, axis=0)
if not os.path.exists(args['output_folder_path']):
os.makedirs(args['output_folder_path'])
np.save(
os.path.join(args['output_folder_path'],
args['output_file_name'] + ".npy"), frames_data)
np.save(
os.path.join(args['output_folder_path'],
args['output_file_name'] + "-index.npy"), index_data)
delimiter = opt.delimiter
expRes = 10000
## need to make resolution adjustable.
length = chrs_length[chrN - 1] / expRes
# divide the input matrix into sub-matrixes.
inputMatrix = utils.readFiles(input_file, length + 1, expRes, delimiter)
print("inputMatrix is symmetric?")
print(is_symmetric(inputMatrix))
compareMatrix = utils.readFiles(compare_matrix, length + 1, expRes, delimiter)
print("compareMatrix is symmetric?")
print(is_symmetric(compareMatrix))
low_resolution_samples, index = utils.divide(inputMatrix, chrN)
low_resolution_samples = np.minimum(
HiC_max_value, low_resolution_samples
) # why use HiC_max_value, in this way, low_resolution_samples will not change.
batch_size = low_resolution_samples.shape[0] #256
# batch_size=256
print("batch_size:", batch_size)
# Reshape the high-quality Hi-C sample as the target value of the training.
sample_size = low_resolution_samples.shape[-1]
padding = conv2d1_filters_size + conv2d2_filters_size + conv2d3_filters_size - 3
half_padding = padding / 2
output_length = sample_size - padding
def test_process(self):
numSets = [[1,-1,2,4,3.2, 4.1], [1], [-1,2]]
for nums in numSets:
self.assertAlmostEquals(self.node._processReturn(nums, 1),
utils.divide(nums))
self.assertTimeIndependent(nums)
def count_cooc_over_min_freq(self, list, cache=False):
cooc, frequencies = self.count_cooc_and_freq(list, cache)
return utils.divide(cooc, min(frequencies))
def generate_diff_player_shots_closest_defender(
self, player_daily_shots_closest_defender,
player_total_shots_closest_defender):
player_daily_shots_closest_defender = player_daily_shots_closest_defender[
['player_id', 'fg3m', 'fg3a', 'def_dist']]
player_total_shots_closest_defender = player_total_shots_closest_defender[
['player_id', 'fg3m', 'fg3a', 'def_dist']]
# Tight
player_daily_shots_closest_defender_tight = player_daily_shots_closest_defender[
(player_daily_shots_closest_defender['def_dist'] ==
'0-2 Feet - Very Tight') |
(player_daily_shots_closest_defender['def_dist'] ==
'2-4 Feet - Tight')].drop('def_dist',
axis=1).groupby(['player_id'
]).sum().reset_index()
player_daily_shots_closest_defender_tight[
'fg3_pct'] = player_daily_shots_closest_defender_tight.apply(
lambda row: divide(row.fg3m, row.fg3a), axis=1)
player_daily_shots_closest_defender_tight.columns = [
str(col) + '_daily_tight' if col != 'player_id' else col
for col in player_daily_shots_closest_defender_tight
]
player_total_shots_closest_defender_tight = player_total_shots_closest_defender[
(player_total_shots_closest_defender['def_dist'] ==
'0-2 Feet - Very Tight') |
(player_total_shots_closest_defender['def_dist'] ==
'2-4 Feet - Tight')].drop('def_dist',
axis=1).groupby(['player_id'
]).sum().reset_index()
player_total_shots_closest_defender_tight[
'fg3_pct'] = player_total_shots_closest_defender_tight.apply(
lambda row: divide(row.fg3m, row.fg3a), axis=1)
player_total_shots_closest_defender_tight.columns = [
str(col) + '_total_tight' if col != 'player_id' else col
for col in player_total_shots_closest_defender_tight
]
merged_df_tight = player_daily_shots_closest_defender_tight.merge(
player_total_shots_closest_defender_tight,
how='inner',
on='player_id')
merged_df_tight['fg3m_diff_tight'] = merged_df_tight.apply(
lambda row: row.fg3m_daily_tight - row.fg3m_total_tight, axis=1)
merged_df_tight['fg3a_diff_tight'] = merged_df_tight.apply(
lambda row: row.fg3a_daily_tight - row.fg3a_total_tight, axis=1)
merged_df_tight['fg3_pct_diff_tight'] = merged_df_tight.apply(
lambda row: row.fg3_pct_daily_tight - row.fg3_pct_total_tight,
axis=1)
# Open
player_daily_shots_closest_defender_open = player_daily_shots_closest_defender[
(player_daily_shots_closest_defender['def_dist'] ==
'4-6 Feet - Open') |
(player_daily_shots_closest_defender['def_dist'] ==
'6+ Feet - Wide Open')].drop('def_dist', axis=1).groupby(
['player_id']).sum().reset_index()
player_daily_shots_closest_defender_open[
'fg3_pct'] = player_daily_shots_closest_defender_open.apply(
lambda row: divide(row.fg3m, row.fg3a), axis=1)
player_daily_shots_closest_defender_open.columns = [
str(col) + '_daily_open' if col != 'player_id' else col
for col in player_daily_shots_closest_defender_open
]
player_total_shots_closest_defender_open = player_total_shots_closest_defender[
(player_total_shots_closest_defender['def_dist'] ==
'4-6 Feet - Open') |
(player_total_shots_closest_defender['def_dist'] ==
'6+ Feet - Wide Open')].drop('def_dist', axis=1).groupby(
['player_id']).sum().reset_index()
player_total_shots_closest_defender_open[
'fg3_pct'] = player_total_shots_closest_defender_open.apply(
lambda row: divide(row.fg3m, row.fg3a), axis=1)
player_total_shots_closest_defender_open.columns = [
str(col) + '_total_open' if col != 'player_id' else col
for col in player_total_shots_closest_defender_open
]
merged_df_open = player_daily_shots_closest_defender_open.merge(
player_total_shots_closest_defender_open,
how='inner',
on='player_id')
merged_df_open['fg3m_diff_open'] = merged_df_open.apply(
lambda row: row.fg3m_daily_open - row.fg3m_total_open, axis=1)
merged_df_open['fg3a_diff_open'] = merged_df_open.apply(
lambda row: row.fg3a_daily_open - row.fg3a_total_open, axis=1)
merged_df_open['fg3_pct_diff_open'] = merged_df_open.apply(
lambda row: row.fg3_pct_daily_open - row.fg3_pct_total_open,
axis=1)
return merged_df_tight.merge(merged_df_open,
how='inner',
on='player_id')
