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mirror of https://github.com/microsoft/qlib.git synced 2026-07-14 16:26:55 +08:00

Delete the setting of SFM on the Alpha158.

This commit is contained in:
lwwang1995
2020-12-08 10:49:43 +08:00
committed by you-n-g
parent ec40845513
commit 4596a7e000
2 changed files with 0 additions and 564 deletions

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@@ -1,471 +0,0 @@
# Copyright (c) Microsoft Corporation.
# Licensed under the MIT License.
from __future__ import division
from __future__ import print_function
import os
import numpy as np
import pandas as pd
import copy
from sklearn.metrics import roc_auc_score, mean_squared_error
import logging
from ...utils import (
unpack_archive_with_buffer,
save_multiple_parts_file,
create_save_path,
drop_nan_by_y_index,
)
from ...log import get_module_logger, TimeInspector
import torch
import torch.nn as nn
import torch.nn.init as init
import torch.optim as optim
from torch.utils.data import DataLoader
from ...model.base import Model
from ...data.dataset import DatasetH
from ...data.dataset.handler import DataHandlerLP
class SFM_Model(nn.Module):
def __init__(
self,
d_feat=6,
output_dim=1,
freq_dim=10,
hidden_size=64,
dropout_W=0.0,
dropout_U=0.0,
device="cpu",
):
super().__init__()
self.input_dim = d_feat
self.output_dim = output_dim
self.freq_dim = freq_dim
self.hidden_dim = hidden_size
self.device = device
self.W_i = nn.Parameter(init.xavier_uniform_(torch.empty((self.input_dim, self.hidden_dim))))
self.U_i = nn.Parameter(init.orthogonal_(torch.empty(self.hidden_dim, self.hidden_dim)))
self.b_i = nn.Parameter(torch.zeros(self.hidden_dim))
self.W_ste = nn.Parameter(init.xavier_uniform_(torch.empty(self.input_dim, self.hidden_dim)))
self.U_ste = nn.Parameter(init.orthogonal_(torch.empty(self.hidden_dim, self.hidden_dim)))
self.b_ste = nn.Parameter(torch.ones(self.hidden_dim))
self.W_fre = nn.Parameter(init.xavier_uniform_(torch.empty(self.input_dim, self.freq_dim)))
self.U_fre = nn.Parameter(init.orthogonal_(torch.empty(self.hidden_dim, self.freq_dim)))
self.b_fre = nn.Parameter(torch.ones(self.freq_dim))
self.W_c = nn.Parameter(init.xavier_uniform_(torch.empty(self.input_dim, self.hidden_dim)))
self.U_c = nn.Parameter(init.orthogonal_(torch.empty(self.hidden_dim, self.hidden_dim)))
self.b_c = nn.Parameter(torch.zeros(self.hidden_dim))
self.W_o = nn.Parameter(init.xavier_uniform_(torch.empty(self.input_dim, self.hidden_dim)))
self.U_o = nn.Parameter(init.orthogonal_(torch.empty(self.hidden_dim, self.hidden_dim)))
self.b_o = nn.Parameter(torch.zeros(self.hidden_dim))
self.U_a = nn.Parameter(init.orthogonal_(torch.empty(self.freq_dim, 1)))
self.b_a = nn.Parameter(torch.zeros(self.hidden_dim))
self.W_p = nn.Parameter(init.xavier_uniform_(torch.empty(self.hidden_dim, self.output_dim)))
self.b_p = nn.Parameter(torch.zeros(self.output_dim))
self.activation = nn.Tanh()
self.inner_activation = nn.Hardsigmoid()
self.dropout_W, self.dropout_U = (dropout_W, dropout_U)
self.fc_out = nn.Linear(self.output_dim, 1)
self.states = []
def forward(self, input):
input = input.reshape(len(input), self.input_dim, -1) # [N, F, T]
input = input.permute(0, 2, 1) # [N, T, F]
time_step = input.shape[1]
for ts in range(time_step):
x = input[:, ts, :]
if len(self.states) == 0: # hasn't initialized yet
self.init_states(x)
self.get_constants(x)
p_tm1 = self.states[0]
h_tm1 = self.states[1]
S_re_tm1 = self.states[2]
S_im_tm1 = self.states[3]
time_tm1 = self.states[4]
B_U = self.states[5]
B_W = self.states[6]
frequency = self.states[7]
x_i = torch.matmul(x * B_W[0], self.W_i) + self.b_i
x_ste = torch.matmul(x * B_W[0], self.W_ste) + self.b_ste
x_fre = torch.matmul(x * B_W[0], self.W_fre) + self.b_fre
x_c = torch.matmul(x * B_W[0], self.W_c) + self.b_c
x_o = torch.matmul(x * B_W[0], self.W_o) + self.b_o
i = self.inner_activation(x_i + torch.matmul(h_tm1 * B_U[0], self.U_i))
ste = self.inner_activation(x_ste + torch.matmul(h_tm1 * B_U[0], self.U_ste))
fre = self.inner_activation(x_fre + torch.matmul(h_tm1 * B_U[0], self.U_fre))
ste = torch.reshape(ste, (-1, self.hidden_dim, 1))
fre = torch.reshape(fre, (-1, 1, self.freq_dim))
f = ste * fre
c = i * self.activation(x_c + torch.matmul(h_tm1 * B_U[0], self.U_c))
time = time_tm1 + 1
omega = torch.tensor(2 * np.pi) * time * frequency
re = torch.cos(omega)
im = torch.sin(omega)
c = torch.reshape(c, (-1, self.hidden_dim, 1))
S_re = f * S_re_tm1 + c * re
S_im = f * S_im_tm1 + c * im
A = torch.square(S_re) + torch.square(S_im)
A = torch.reshape(A, (-1, self.freq_dim)).float()
A_a = torch.matmul(A * B_U[0], self.U_a)
A_a = torch.reshape(A_a, (-1, self.hidden_dim))
a = self.activation(A_a + self.b_a)
o = self.inner_activation(x_o + torch.matmul(h_tm1 * B_U[0], self.U_o))
h = o * a
p = torch.matmul(h, self.W_p) + self.b_p
self.states = [p, h, S_re, S_im, time, None, None, None]
self.states = []
return self.fc_out(p).squeeze()
def init_states(self, x):
reducer_f = torch.zeros((self.hidden_dim, self.freq_dim)).to(self.device)
reducer_p = torch.zeros((self.hidden_dim, self.output_dim)).to(self.device)
init_state_h = torch.zeros(self.hidden_dim).to(self.device)
init_state_p = torch.matmul(init_state_h, reducer_p)
init_state = torch.zeros_like(init_state_h).to(self.device)
init_freq = torch.matmul(init_state_h, reducer_f)
init_state = torch.reshape(init_state, (-1, self.hidden_dim, 1))
init_freq = torch.reshape(init_freq, (-1, 1, self.freq_dim))
init_state_S_re = init_state * init_freq
init_state_S_im = init_state * init_freq
init_state_time = torch.tensor(0).to(self.device)
self.states = [
init_state_p,
init_state_h,
init_state_S_re,
init_state_S_im,
init_state_time,
None,
None,
None,
]
def get_constants(self, x):
constants = []
constants.append([torch.tensor(1.0).to(self.device) for _ in range(6)])
constants.append([torch.tensor(1.0).to(self.device) for _ in range(7)])
array = np.array([float(ii) / self.freq_dim for ii in range(self.freq_dim)])
constants.append(torch.tensor(array).to(self.device))
self.states[5:] = constants
class SFM(Model):
"""SFM Model
Parameters
----------
input_dim : int
input dimension
output_dim : int
output dimension
lr : float
learning rate
optimizer : str
optimizer name
GPU : str
the GPU ID(s) used for training
"""
def __init__(
self,
d_feat=6,
hidden_size=64,
output_dim=1,
freq_dim=10,
dropout_W=0.0,
dropout_U=0.0,
n_epochs=200,
lr=0.001,
metric="",
batch_size=2000,
early_stop=20,
eval_steps=5,
loss="mse",
optimizer="gd",
n_jobs=10,
GPU="0",
seed=None,
**kwargs
):
# Set logger.
self.logger = get_module_logger("SFM")
self.logger.info("SFM pytorch version...")
# set hyper-parameters.
self.d_feat = d_feat
self.hidden_size = hidden_size
self.output_dim = output_dim
self.freq_dim = freq_dim
self.dropout_W = dropout_W
self.dropout_U = dropout_U
self.n_epochs = n_epochs
self.lr = lr
self.metric = metric
self.batch_size = batch_size
self.early_stop = early_stop
self.eval_steps = eval_steps
self.optimizer = optimizer.lower()
self.loss = loss
self.device = torch.device("cuda:%d" % (GPU) if torch.cuda.is_available() else "cpu")
self.n_jobs = n_jobs
self.use_gpu = torch.cuda.is_available()
self.seed = seed
self.logger.info(
"SFM parameters setting:"
"\nd_feat : {}"
"\nhidden_size : {}"
"\noutput_size : {}"
"\nfrequency_dimension : {}"
"\ndropout_W: {}"
"\ndropout_U: {}"
"\nn_epochs : {}"
"\nlr : {}"
"\nmetric : {}"
"\nbatch_size : {}"
"\nearly_stop : {}"
"\neval_steps : {}"
"\noptimizer : {}"
"\nloss_type : {}"
"\nvisible_GPU : {}"
"\nuse_GPU : {}"
"\nseed : {}".format(
d_feat,
hidden_size,
output_dim,
freq_dim,
dropout_W,
dropout_U,
n_epochs,
lr,
metric,
batch_size,
early_stop,
eval_steps,
optimizer.lower(),
loss,
GPU,
self.use_gpu,
seed,
)
)
if self.seed is not None:
np.random.seed(self.seed)
torch.manual_seed(self.seed)
self.sfm_model = SFM_Model(
d_feat=self.d_feat,
output_dim=self.output_dim,
hidden_size=self.hidden_size,
freq_dim=self.freq_dim,
dropout_W=self.dropout_W,
dropout_U=self.dropout_U,
device=self.device,
)
if optimizer.lower() == "adam":
self.train_optimizer = optim.Adam(self.sfm_model.parameters(), lr=self.lr)
elif optimizer.lower() == "gd":
self.train_optimizer = optim.SGD(self.sfm_model.parameters(), lr=self.lr)
else:
raise NotImplementedError("optimizer {} is not supported!".format(optimizer))
self._fitted = False
self.sfm_model.to(self.device)
def train_epoch(self, data_loader):
self.sfm_model.train()
for data in data_loader:
feature = data[:, :, 0:-1].to(self.device)
label = data[:, -1, -1].to(self.device)
pred = self.sfm_model(feature.float())
loss = self.loss_fn(pred, label)
self.train_optimizer.zero_grad()
loss.backward()
torch.nn.utils.clip_grad_value_(self.sfm_model.parameters(), 3.0)
self.train_optimizer.step()
def test_epoch(self, data_loader):
self.sfm_model.eval()
scores = []
losses = []
for data in data_loader:
feature = data[:, :, 0:-1].to(self.device)
# feature[torch.isnan(feature)] = 0
label = data[:, -1, -1].to(self.device)
pred = self.sfm_model(feature.float())
loss = self.loss_fn(pred, label)
losses.append(loss.item())
score = self.metric_fn(pred, label)
scores.append(score.item())
return np.mean(losses), np.mean(scores)
def fit(
self,
dataset: DatasetH,
evals_result=dict(),
verbose=True,
save_path=None,
):
dl_train = dataset.prepare("train", data_key=DataHandlerLP.DK_L)
dl_valid = dataset.prepare("valid", data_key=DataHandlerLP.DK_L)
dl_train.config(fillna_type="ffill+bfill") # process nan brought by dataloader
dl_valid.config(fillna_type="ffill+bfill") # process nan brought by dataloader
train_loader = DataLoader(dl_train, batch_size=self.batch_size, shuffle=True, num_workers=self.n_jobs)
valid_loader = DataLoader(dl_valid, batch_size=self.batch_size, shuffle=False, num_workers=self.n_jobs)
if save_path == None:
save_path = create_save_path(save_path)
stop_steps = 0
train_loss = 0
best_score = -np.inf
best_epoch = 0
evals_result["train"] = []
evals_result["valid"] = []
# train
self.logger.info("training...")
self._fitted = True
for step in range(self.n_epochs):
self.logger.info("Epoch%d:", step)
self.logger.info("training...")
self.train_epoch(train_loader)
self.logger.info("evaluating...")
train_loss, train_score = self.test_epoch(train_loader)
val_loss, val_score = self.test_epoch(valid_loader)
self.logger.info("train %.6f, valid %.6f" % (train_score, val_score))
evals_result["train"].append(train_score)
evals_result["valid"].append(val_score)
if val_score > best_score:
best_score = val_score
stop_steps = 0
best_epoch = step
best_param = copy.deepcopy(self.sfm_model.state_dict())
else:
stop_steps += 1
if stop_steps >= self.early_stop:
self.logger.info("early stop")
break
self.logger.info("best score: %.6lf @ %d" % (best_score, best_epoch))
self.sfm_model.load_state_dict(best_param)
torch.save(best_param, save_path)
if self.use_gpu:
torch.cuda.empty_cache()
def mse(self, pred, label):
loss = (pred - label) ** 2
return torch.mean(loss)
def loss_fn(self, pred, label):
mask = ~torch.isnan(label)
if self.loss == "mse":
return self.mse(pred[mask], label[mask])
raise ValueError("unknown loss `%s`" % self.loss)
def metric_fn(self, pred, label):
mask = torch.isfinite(label)
if self.metric == "" or self.metric == "loss":
return -self.loss_fn(pred[mask], label[mask])
raise ValueError("unknown metric `%s`" % self.metric)
def predict(self, dataset):
if not self._fitted:
raise ValueError("model is not fitted yet!")
dl_test = dataset.prepare("test", data_key=DataHandlerLP.DK_I)
dl_test.config(fillna_type="ffill+bfill")
test_loader = DataLoader(dl_test, batch_size=self.batch_size, num_workers=self.n_jobs)
self.sfm_model.eval()
preds = []
for data in test_loader:
feature = data[:, :, 0:-1].to(self.device)
with torch.no_grad():
if self.use_gpu:
pred = self.sfm_model(feature.float()).detach().cpu().numpy()
else:
pred = self.sfm_model(feature.float()).detach().numpy()
preds.append(pred)
return pd.Series(np.concatenate(preds), index=dl_test.get_index())
class AverageMeter(object):
"""Computes and stores the average and current value"""
def __init__(self):
self.reset()
def reset(self):
self.val = 0
self.avg = 0
self.sum = 0
self.count = 0
def update(self, val, n=1):
self.val = val
self.sum += val * n
self.count += n
self.avg = self.sum / self.count