def conv1d(other_args: List[str], s_ticker: str, df_stock: pd.DataFrame):
"""
Train a 1D Convolutional Neural Net (1D CNN)
Parameters
----------
other_args:List[str]
Argparse arguments
s_ticker: str
Stock ticker
df_stock: pd.DataFrame
Dataframe of stock prices
"""
try:
ns_parser = parse_args(
prog="conv1d",
description="""1D CNN.""",
other_args=other_args,
)
if not ns_parser:
return
(
X_train,
X_valid,
y_train,
y_valid,
_,
_,
_,
y_dates_valid,
forecast_data_input,
dates_forecast_input,
scaler,
is_error,
) = prepare_scale_train_valid_test(df_stock["5. adjusted close"],
ns_parser)
if is_error:
return
print(
f"Training on {X_train.shape[0]} sequences of length {X_train.shape[1]}. Using {X_valid.shape[0]} sequences "
f" of length {X_valid.shape[1]} for validation. Model will run {ns_parser.n_loops} loops"
)
future_dates = get_next_stock_market_days(dates_forecast_input[-1],
n_next_days=ns_parser.n_days)
preds = np.zeros(
(ns_parser.n_loops, X_valid.shape[0], ns_parser.n_days))
forecast_data = np.zeros((ns_parser.n_loops, ns_parser.n_days))
for i in range(ns_parser.n_loops):
# Build Neural Network model
model = build_neural_network_model(
cfg_nn_models.Convolutional,
ns_parser.n_inputs,
ns_parser.n_days,
)
model.compile(
optimizer=optimizers[cfg_nn_models.Optimizer](lr=ns_parser.lr),
loss=cfg_nn_models.Loss,
)
model.fit(
X_train.reshape(X_train.shape[0], X_train.shape[1], 1),
y_train,
epochs=ns_parser.n_epochs,
verbose=True,
batch_size=ns_parser.n_batch_size,
validation_data=(
X_valid.reshape(X_valid.shape[0], X_valid.shape[1], 1),
y_valid,
),
callbacks=[es],
)
preds[i] = model.predict(
X_valid.reshape(X_valid.shape[0], X_valid.shape[1],
1)).reshape(X_valid.shape[0], ns_parser.n_days)
forecast_data[i] = forecast(forecast_data_input, future_dates,
model, scaler).values.flat
forecast_data_df = pd.DataFrame(forecast_data.T, index=future_dates)
if ns_parser.n_loops > 1:
forecast_data_df["Median"] = forecast_data_df.median(axis=1)
print_pretty_prediction(forecast_data_df["Median"],
df_stock["5. adjusted close"].values[-1])
else:
print_pretty_prediction(forecast_data_df[0],
df_stock["5. adjusted close"].values[-1])
plot_data_predictions(
df_stock,
np.median(preds, axis=0),
y_valid,
y_dates_valid,
scaler,
f"Conv1D Model on {s_ticker}",
forecast_data_df,
ns_parser.n_loops,
)
print("")
except Exception as e:
print(e)
traceback.print_exc()
print("")
finally:
restore_env()
def arima(other_args: List[str], s_ticker: str, df_stock: pd.DataFrame):
"""
ARIMA prediction
Parameters
----------
other_args: List[str]
Argparse arguments
s_ticker: str
ticker
df_stock: pd.DataFrame
Dataframe of prices
"""
parser = argparse.ArgumentParser(
add_help=False,
prog="arima",
description="""
In statistics and econometrics, and in particular in time series analysis, an
autoregressive integrated moving average (ARIMA) model is a generalization of an
autoregressive moving average (ARMA) model. Both of these models are fitted to time
series data either to better understand the data or to predict future points in the
series (forecasting). ARIMA(p,d,q) where parameters p, d, and q are non-negative
integers, p is the order (number of time lags) of the autoregressive model, d is the
degree of differencing (the number of times the data have had past values subtracted),
and q is the order of the moving-average model.
""",
)
parser.add_argument(
"-d",
"--days",
action="store",
dest="n_days",
type=check_positive,
default=5,
help="prediction days.",
)
parser.add_argument(
"-i",
"--ic",
action="store",
dest="s_ic",
type=str,
default="aic",
choices=["aic", "aicc", "bic", "hqic", "oob"],
help="information criteria.",
)
parser.add_argument(
"-s",
"--seasonal",
action="store_true",
default=False,
dest="b_seasonal",
help="Use weekly seasonal data.",
)
parser.add_argument(
"-o",
"--order",
action="store",
dest="s_order",
type=str,
help="arima model order (p,d,q) in format: p,d,q.",
)
parser.add_argument(
"-r",
"--results",
action="store_true",
dest="b_results",
default=False,
help="results about ARIMA summary flag.",
)
parser.add_argument(
"-e",
"--end",
action="store",
type=valid_date,
dest="s_end_date",
default=None,
help="The end date (format YYYY-MM-DD) to select - Backtesting",
)
try:
ns_parser = parse_known_args_and_warn(parser, other_args)
if not ns_parser:
return
# BACKTESTING
if ns_parser.s_end_date:
if ns_parser.s_end_date < df_stock.index[0]:
print(
"Backtesting not allowed, since End Date is older than Start Date of historical data\n"
)
return
if (ns_parser.s_end_date < get_next_stock_market_days(
last_stock_day=df_stock.index[0],
n_next_days=5 + ns_parser.n_days)[-1]):
print(
"Backtesting not allowed, since End Date is too close to Start Date to train model\n"
)
return
future_index = get_next_stock_market_days(
last_stock_day=ns_parser.s_end_date,
n_next_days=ns_parser.n_days)
if future_index[-1] > datetime.datetime.now():
print(
"Backtesting not allowed, since End Date + Prediction days is in the future\n"
)
return
df_future = df_stock[future_index[0]:future_index[-1]]
df_stock = df_stock[:ns_parser.s_end_date]
# Machine Learning model
if ns_parser.s_order:
t_order = tuple(int(ord) for ord in ns_parser.s_order.split(","))
model = ARIMA(df_stock["5. adjusted close"].values,
order=t_order).fit()
l_predictions = model.predict(
start=len(df_stock["5. adjusted close"]) + 1,
end=len(df_stock["5. adjusted close"]) + ns_parser.n_days,
)
else:
if ns_parser.b_seasonal:
model = pmdarima.auto_arima(
df_stock["5. adjusted close"].values,
error_action="ignore",
seasonal=True,
m=5,
information_criteria=ns_parser.s_ic,
)
else:
model = pmdarima.auto_arima(
df_stock["5. adjusted close"].values,
error_action="ignore",
seasonal=False,
information_criteria=ns_parser.s_ic,
)
l_predictions = [
i if i > 0 else 0
for i in model.predict(n_periods=ns_parser.n_days)
]
# Prediction data
l_pred_days = get_next_stock_market_days(
last_stock_day=df_stock["5. adjusted close"].index[-1],
n_next_days=ns_parser.n_days,
)
df_pred = pd.Series(l_predictions, index=l_pred_days, name="Price")
if ns_parser.b_results:
print(model.summary())
print("")
# Plotting
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.plot(df_stock.index, df_stock["5. adjusted close"], lw=2)
if ns_parser.s_order:
# BACKTESTING
if ns_parser.s_end_date:
plt.title(
f"BACKTESTING: ARIMA {str(t_order)} on {s_ticker} - {ns_parser.n_days} days prediction"
)
else:
plt.title(
f"ARIMA {str(t_order)} on {s_ticker} - {ns_parser.n_days} days prediction"
)
else:
# BACKTESTING
if ns_parser.s_end_date:
plt.title(
f"BACKTESTING: ARIMA {model.order} on {s_ticker} - {ns_parser.n_days} days prediction"
)
else:
plt.title(
f"ARIMA {model.order} on {s_ticker} - {ns_parser.n_days} days prediction"
)
plt.xlim(df_stock.index[0],
get_next_stock_market_days(df_pred.index[-1], 1)[-1])
plt.xlabel("Time")
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=1,
c="tab:green",
linestyle="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="tab:green")
plt.axvspan(df_stock.index[-1],
df_pred.index[-1],
facecolor="tab:orange",
alpha=0.2)
_, _, ymin, ymax = plt.axis()
plt.vlines(df_stock.index[-1],
ymin,
ymax,
linewidth=1,
linestyle="--",
color="k")
# BACKTESTING
if ns_parser.s_end_date:
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=1,
c="tab:blue",
linestyle="--",
)
if gtff.USE_ION:
plt.ion()
plt.show()
# BACKTESTING
if ns_parser.s_end_date:
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.subplot(211)
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="green")
plt.scatter(df_future.index,
df_future["5. adjusted close"],
c="tab:blue",
lw=3)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=2,
c="tab:blue",
ls="--",
)
plt.scatter(df_pred.index, df_pred, c="green", lw=3)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=2,
c="green",
ls="--",
)
plt.title("BACKTESTING: Real data price versus Prediction")
plt.xlim(df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks(
[
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1)
],
visible=True,
)
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
plt.xticks([])
plt.subplot(212)
plt.axhline(y=0, color="k", linestyle="--", linewidth=2)
plt.plot(
df_future.index,
100 *
(df_pred.values - df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
lw=2,
c="red",
)
plt.scatter(
df_future.index,
100 *
(df_pred.values - df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
c="red",
lw=5,
)
plt.title(
"BACKTESTING: Error between Real data and Prediction [%]")
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
0,
100 * (df_pred.values[0] -
df_future["5. adjusted close"].values[0]) /
df_future["5. adjusted close"].values[0],
],
lw=2,
ls="--",
c="red",
)
plt.xlim(df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks(
[
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1)
],
visible=True,
)
plt.xlabel("Time")
plt.ylabel("Prediction Error (%)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
if gtff.USE_ION:
plt.ion()
plt.show()
# Refactor prediction dataframe for backtesting print
df_pred.name = "Prediction"
df_pred = df_pred.to_frame()
df_pred["Real"] = df_future["5. adjusted close"]
if gtff.USE_COLOR:
patch_pandas_text_adjustment()
print("Time Real [$] x Prediction [$]")
print(
df_pred.apply(price_prediction_backtesting_color,
axis=1).to_string())
else:
print(df_pred[["Real", "Prediction"]].round(2).to_string())
print("")
print_prediction_kpis(df_pred["Real"].values,
df_pred["Prediction"].values)
else:
# Print prediction data
print_pretty_prediction(df_pred,
df_stock["5. adjusted close"].values[-1])
print("")
except Exception as e:
print(e, "\n")
def k_nearest_neighbors(l_args, s_ticker, df_stock):
parser = argparse.ArgumentParser(
add_help=False,
prog="knn",
description="""
K nearest neighbors is a simple algorithm that stores all
available cases and predict the numerical target based on a similarity measure
(e.g. distance functions).
""",
)
parser.add_argument(
"-i",
"--input",
action="store",
dest="n_inputs",
type=check_positive,
default=40,
help="number of days to use for prediction.",
)
parser.add_argument(
"-d",
"--days",
action="store",
dest="n_days",
type=check_positive,
default=5,
help="prediction days.",
)
parser.add_argument(
"-j",
"--jumps",
action="store",
dest="n_jumps",
type=check_positive,
default=1,
help="number of jumps in training data.",
)
parser.add_argument(
"-n",
"--neighbors",
action="store",
dest="n_neighbors",
type=check_positive,
default=20,
help="number of neighbors to use on the algorithm.",
)
parser.add_argument(
"-e",
"--end",
action="store",
type=valid_date,
dest="s_end_date",
default=None,
help="The end date (format YYYY-MM-DD) to select - Backtesting",
)
try:
ns_parser = parse_known_args_and_warn(parser, l_args)
if not ns_parser:
return
# BACKTESTING
if ns_parser.s_end_date:
if ns_parser.s_end_date < df_stock.index[0]:
print(
"Backtesting not allowed, since End Date is older than Start Date of historical data\n"
)
return
if ns_parser.s_end_date < get_next_stock_market_days(
last_stock_day=df_stock.index[0],
n_next_days=ns_parser.n_inputs + ns_parser.n_days,
)[-1]:
print(
"Backtesting not allowed, since End Date is too close to Start Date to train model\n"
)
return
future_index = get_next_stock_market_days(
last_stock_day=ns_parser.s_end_date,
n_next_days=ns_parser.n_days)
if future_index[-1] > datetime.datetime.now():
print(
"Backtesting not allowed, since End Date + Prediction days is in the future\n"
)
return
df_future = df_stock[future_index[0]:future_index[-1]]
df_stock = df_stock[:ns_parser.s_end_date]
# Split training data
stock_x, stock_y = splitTrain.split_train(
df_stock["5. adjusted close"].values,
ns_parser.n_inputs,
ns_parser.n_days,
ns_parser.n_jumps,
)
if not stock_x:
print("Given the model parameters more training data is needed.\n")
return
# Machine Learning model
knn = neighbors.KNeighborsRegressor(n_neighbors=ns_parser.n_neighbors)
knn.fit(stock_x, stock_y)
# Prediction data
l_predictions = knn.predict(
df_stock["5. adjusted close"].values[-ns_parser.n_inputs:].reshape(
1, -1))[0]
l_pred_days = get_next_stock_market_days(
last_stock_day=df_stock["5. adjusted close"].index[-1],
n_next_days=ns_parser.n_days,
)
df_pred = pd.Series(l_predictions, index=l_pred_days, name="Price")
# Plotting
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.plot(df_stock.index, df_stock["5. adjusted close"], lw=2)
s_knn = f"{ns_parser.n_neighbors}-Nearest Neighbors on {s_ticker}"
# BACKTESTING
if ns_parser.s_end_date:
plt.title(
f"BACKTESTING: {s_knn} - {ns_parser.n_days} days prediction")
else:
plt.title(f"{s_knn} - {ns_parser.n_days} days prediction")
plt.xlim(df_stock.index[0],
get_next_stock_market_days(df_pred.index[-1], 1)[-1])
plt.xlabel("Time")
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=1,
c="tab:green",
linestyle="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="tab:green")
plt.axvspan(df_stock.index[-1],
df_pred.index[-1],
facecolor="tab:orange",
alpha=0.2)
_, _, ymin, ymax = plt.axis()
plt.vlines(df_stock.index[-1],
ymin,
ymax,
linewidth=1,
linestyle="--",
color="k")
# BACKTESTING
if ns_parser.s_end_date:
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=1,
c="tab:blue",
linestyle="--",
)
if gtff.USE_ION:
plt.ion()
plt.show()
# BACKTESTING
if ns_parser.s_end_date:
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.subplot(211)
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="green")
plt.scatter(df_future.index,
df_future["5. adjusted close"],
c="tab:blue",
lw=3)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=2,
c="tab:blue",
ls="--",
)
plt.scatter(df_pred.index, df_pred, c="green", lw=3)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=2,
c="green",
ls="--",
)
plt.title("BACKTESTING: Real data price versus Prediction")
plt.xlim(df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks([
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1)
])
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
plt.xticks([])
plt.subplot(212)
plt.axhline(y=0, color="k", linestyle="--", linewidth=2)
plt.plot(
df_future.index,
100 *
(df_pred.values - df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
lw=2,
c="red",
)
plt.scatter(
df_future.index,
100 *
(df_pred.values - df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
c="red",
lw=5,
)
plt.title(
"BACKTESTING: Error between Real data and Prediction [%]")
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
0,
100 * (df_pred.values[0] -
df_future["5. adjusted close"].values[0]) /
df_future["5. adjusted close"].values[0],
],
lw=2,
ls="--",
c="red",
)
plt.xlim(df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks([
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1)
])
plt.xlabel("Time")
plt.ylabel("Prediction Error (%)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
if gtff.USE_ION:
plt.ion()
plt.show()
# Refactor prediction dataframe for backtesting print
df_pred.name = "Prediction"
df_pred = df_pred.to_frame()
df_pred["Real"] = df_future["5. adjusted close"]
if gtff.USE_COLOR:
patch_pandas_text_adjustment()
print("Time Real [$] x Prediction [$]")
print(
df_pred.apply(price_prediction_backtesting_color,
axis=1).to_string())
else:
print(df_pred[["Real", "Prediction"]].round(2).to_string())
print("")
print_prediction_kpis(df_pred["Real"].values,
df_pred["Prediction"].values)
else:
# Print prediction data
print_pretty_prediction(df_pred,
df_stock["5. adjusted close"].values[-1])
print("")
except Exception as e:
print(e)
print("")
def k_nearest_neighbors(other_args: List[str], s_ticker: str,
df_stock: pd.DataFrame):
"""
Train KNN model
Parameters
----------
other_args: List[str]
List of argparse arguments
s_ticker: str
Ticker
df_stock: pd.DataFrame
Dataframe of stock prices
Returns
-------
"""
parser = argparse.ArgumentParser(
add_help=False,
prog="knn",
description="""
K nearest neighbors is a simple algorithm that stores all
available cases and predict the numerical target based on a similarity measure
(e.g. distance functions).
""",
)
parser.add_argument(
"-i",
"--input",
action="store",
dest="n_inputs",
type=check_positive,
default=40,
help="number of days to use as input for prediction.",
)
parser.add_argument(
"-d",
"--days",
action="store",
dest="n_days",
type=check_positive,
default=5,
help="prediction days.",
)
parser.add_argument(
"-j",
"--jumps",
action="store",
dest="n_jumps",
type=check_positive,
default=1,
help="number of jumps in training data.",
)
parser.add_argument(
"-n",
"--neighbors",
action="store",
dest="n_neighbors",
type=check_positive,
default=20,
help="number of neighbors to use on the algorithm.",
)
parser.add_argument(
"-e",
"--end",
action="store",
type=valid_date,
dest="s_end_date",
default=None,
help="The end date (format YYYY-MM-DD) to select for testing",
)
parser.add_argument(
"-t",
"--test_size",
default=0.2,
dest="valid_split",
type=float,
help="Percentage of data to validate in sample",
)
parser.add_argument(
"-p",
"--pp",
action="store",
dest="s_preprocessing",
default="none",
choices=["normalization", "standardization", "minmax", "none"],
help="pre-processing data.",
)
try:
ns_parser = parse_known_args_and_warn(parser, other_args)
if not ns_parser:
return
(
X_train,
X_valid,
y_train,
y_valid,
_,
_,
_,
y_dates_valid,
forecast_data_input,
dates_forecast_input,
scaler,
is_error,
) = prepare_scale_train_valid_test(df_stock["5. adjusted close"],
ns_parser)
if is_error:
print("Error preparing data")
return
print(
f"Training on {X_train.shape[0]} sequences of length {X_train.shape[1]}. Using {X_valid.shape[0]} sequences "
f" of length {X_valid.shape[1]} for validation")
future_dates = get_next_stock_market_days(dates_forecast_input[-1],
n_next_days=ns_parser.n_days)
# Machine Learning model
knn = neighbors.KNeighborsRegressor(n_neighbors=ns_parser.n_neighbors)
knn.fit(
X_train.reshape(X_train.shape[0], X_train.shape[1]),
y_train.reshape(y_train.shape[0], y_train.shape[1]),
)
preds = knn.predict(X_valid.reshape(X_valid.shape[0],
X_valid.shape[1]))
forecast_data = knn.predict(forecast_data_input.reshape(1, -1))
forecast_data_df = pd.DataFrame(forecast_data.T, index=future_dates)
print_pretty_prediction(forecast_data_df[0],
df_stock["5. adjusted close"].values[-1])
plot_data_predictions(
df_stock,
preds,
y_valid,
y_dates_valid,
scaler,
f"KNN Model with {ns_parser.n_neighbors} Neighbors on {s_ticker}",
forecast_data_df,
1,
)
except Exception as e:
print(e)
print("")
def regression(l_args, s_ticker, df_stock, polynomial):
parser = argparse.ArgumentParser(
add_help=False,
prog="regression",
description="""
Regression attempts to model the relationship between
two variables by fitting a linear/quadratic/cubic/other equation to
observed data. One variable is considered to be an explanatory variable,
and the other is considered to be a dependent variable.
""",
)
parser.add_argument(
"-i",
"--input",
action="store",
dest="n_inputs",
type=check_positive,
default=40,
help="number of days to use for prediction.",
)
parser.add_argument(
"-d",
"--days",
action="store",
dest="n_days",
type=check_positive,
default=5,
help="prediction days.",
)
parser.add_argument(
"-j",
"--jumps",
action="store",
dest="n_jumps",
type=check_positive,
default=1,
help="number of jumps in training data.",
)
parser.add_argument(
"-e",
"--end",
action="store",
type=valid_date,
dest="s_end_date",
default=None,
help="The end date (format YYYY-MM-DD) to select - Backtesting",
)
if polynomial == USER_INPUT:
parser.add_argument(
"-p",
"--polynomial",
action="store",
dest="n_polynomial",
type=check_positive,
required=True,
help="polynomial associated with regression.",
)
try:
ns_parser = parse_known_args_and_warn(parser, l_args)
if not ns_parser:
return
# BACKTESTING
if ns_parser.s_end_date:
if ns_parser.s_end_date < df_stock.index[0]:
print(
"Backtesting not allowed, since End Date is older than Start Date of historical data\n"
)
return
if ns_parser.s_end_date < get_next_stock_market_days(
last_stock_day=df_stock.index[0],
n_next_days=ns_parser.n_inputs + ns_parser.n_days,
)[-1]:
print(
"Backtesting not allowed, since End Date is too close to Start Date to train model\n"
)
return
future_index = get_next_stock_market_days(
last_stock_day=ns_parser.s_end_date,
n_next_days=ns_parser.n_days)
if future_index[-1] > datetime.datetime.now():
print(
"Backtesting not allowed, since End Date + Prediction days is in the future\n"
)
return
df_future = df_stock[future_index[0]:future_index[-1]]
df_stock = df_stock[:ns_parser.s_end_date]
# Split training data
stock_x, stock_y = splitTrain.split_train(
df_stock["5. adjusted close"].values,
ns_parser.n_inputs,
ns_parser.n_days,
ns_parser.n_jumps,
)
if not stock_x:
print("Given the model parameters more training data is needed.\n")
return
# Machine Learning model
if polynomial == LINEAR:
model = linear_model.LinearRegression(n_jobs=-1)
else:
if polynomial == USER_INPUT:
polynomial = ns_parser.n_polynomial
model = pipeline.make_pipeline(
preprocessing.PolynomialFeatures(polynomial),
linear_model.Ridge())
model.fit(stock_x, stock_y)
l_predictions = model.predict(
df_stock["5. adjusted close"].values[-ns_parser.n_inputs:].reshape(
1, -1))[0]
# Prediction data
l_pred_days = get_next_stock_market_days(
last_stock_day=df_stock["5. adjusted close"].index[-1],
n_next_days=ns_parser.n_days,
)
df_pred = pd.Series(l_predictions, index=l_pred_days, name="Price")
# Plotting
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.plot(df_stock.index, df_stock["5. adjusted close"], lw=2)
# BACKTESTING
if ns_parser.s_end_date:
plt.title(
f"BACKTESTING: Regression (polynomial {polynomial}) on {s_ticker} - {ns_parser.n_days} days prediction"
)
else:
plt.title(
f"Regression (polynomial {polynomial}) on {s_ticker} - {ns_parser.n_days} days prediction"
)
plt.xlim(df_stock.index[0],
get_next_stock_market_days(df_pred.index[-1], 1)[-1])
plt.xlabel("Time")
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=1,
c="tab:green",
linestyle="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="tab:green")
plt.axvspan(df_stock.index[-1],
df_pred.index[-1],
facecolor="tab:orange",
alpha=0.2)
_, _, ymin, ymax = plt.axis()
plt.vlines(df_stock.index[-1],
ymin,
ymax,
linewidth=1,
linestyle="--",
color="k")
# BACKTESTING
if ns_parser.s_end_date:
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=1,
c="tab:blue",
linestyle="--",
)
if gtff.USE_ION:
plt.ion()
plt.show()
# BACKTESTING
if ns_parser.s_end_date:
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.subplot(211)
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="green")
plt.scatter(df_future.index,
df_future["5. adjusted close"],
c="tab:blue",
lw=3)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=2,
c="tab:blue",
ls="--",
)
plt.scatter(df_pred.index, df_pred, c="green", lw=3)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=2,
c="green",
ls="--",
)
plt.title("BACKTESTING: Real data price versus Prediction")
plt.xlim(df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks(
[
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1)
],
visible=True,
)
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
plt.xticks([])
plt.subplot(212)
plt.axhline(y=0, color="k", linestyle="--", linewidth=2)
plt.plot(
df_future.index,
100 *
(df_pred.values - df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
lw=2,
c="red",
)
plt.scatter(
df_future.index,
100 *
(df_pred.values - df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
c="red",
lw=5,
)
plt.title(
"BACKTESTING: Error between Real data and Prediction [%]")
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
0,
100 * (df_pred.values[0] -
df_future["5. adjusted close"].values[0]) /
df_future["5. adjusted close"].values[0],
],
lw=2,
ls="--",
c="red",
)
plt.xlim(df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks(
[
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1)
],
visible=True,
)
plt.xlabel("Time")
plt.ylabel("Prediction Error (%)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
if gtff.USE_ION:
plt.ion()
plt.show()
# Refactor prediction dataframe for backtesting print
df_pred.name = "Prediction"
df_pred = df_pred.to_frame()
df_pred["Real"] = df_future["5. adjusted close"]
if gtff.USE_COLOR:
patch_pandas_text_adjustment()
print("Time Real [$] x Prediction [$]")
print(
df_pred.apply(price_prediction_backtesting_color,
axis=1).to_string())
else:
print(df_pred[["Real", "Prediction"]].round(2).to_string())
print("")
print_prediction_kpis(df_pred["Real"].values,
df_pred["Prediction"].values)
else:
# Print prediction data
print_pretty_prediction(df_pred,
df_stock["5. adjusted close"].values[-1])
print("")
except SystemExit:
print("")
except Exception as e:
print(e)
print("")
def exponential_smoothing(l_args, s_ticker, df_stock):
parser = argparse.ArgumentParser(
add_help=False,
prog="ets",
description="""
Exponential Smoothing, see https://otexts.com/fpp2/taxonomy.html
Trend='N', Seasonal='N': Simple Exponential Smoothing
Trend='N', Seasonal='A': Exponential Smoothing
Trend='N', Seasonal='M': Exponential Smoothing
Trend='A', Seasonal='N': Holt’s linear method
Trend='A', Seasonal='A': Additive Holt-Winters’ method
Trend='A', Seasonal='M': Multiplicative Holt-Winters’ method
Trend='Ad', Seasonal='N': Additive damped trend method
Trend='Ad', Seasonal='A': Exponential Smoothing
Trend='Ad', Seasonal='M': Holt-Winters’ damped method
Trend component: N: None, A: Additive, Ad: Additive Damped
Seasonality component: N: None, A: Additive, M: Multiplicative
""",
)
parser.add_argument(
"-d",
"--days",
action="store",
dest="n_days",
type=check_positive,
default=5,
help="prediction days.",
)
parser.add_argument(
"-t",
"--trend",
action="store",
dest="trend",
type=check_valid_trend,
default="N",
help="Trend component: N: None, A: Additive, Ad: Additive Damped.",
)
parser.add_argument(
"-s",
"--seasonal",
action="store",
dest="seasonal",
type=check_valid_seasonal,
default="N",
help="Seasonality component: N: None, A: Additive, M: Multiplicative.",
)
parser.add_argument(
"-p",
"--periods",
action="store",
dest="seasonal_periods",
type=check_positive,
default=5,
help="Seasonal periods.",
)
parser.add_argument(
"-e",
"--end",
action="store",
type=valid_date,
dest="s_end_date",
default=None,
help="The end date (format YYYY-MM-DD) to select - Backtesting",
)
try:
ns_parser = parse_known_args_and_warn(parser, l_args)
if not ns_parser:
return
# BACKTESTING
if ns_parser.s_end_date:
if ns_parser.s_end_date < df_stock.index[0]:
print(
"Backtesting not allowed, since End Date is older than Start Date of historical data\n"
)
return
if (ns_parser.s_end_date < get_next_stock_market_days(
last_stock_day=df_stock.index[0],
n_next_days=5 + ns_parser.n_days)[-1]):
print(
"Backtesting not allowed, since End Date is too close to Start Date to train model\n"
)
return
future_index = get_next_stock_market_days(
last_stock_day=ns_parser.s_end_date,
n_next_days=ns_parser.n_days)
if future_index[-1] > datetime.datetime.now():
print(
"Backtesting not allowed, since End Date + Prediction days is in the future\n"
)
return
df_future = df_stock[future_index[0]:future_index[-1]]
df_stock = df_stock[:ns_parser.s_end_date]
# Get ETS model
model, title = get_exponential_smoothing_model(
df_stock["5. adjusted close"].values,
ns_parser.trend,
ns_parser.seasonal,
ns_parser.seasonal_periods,
)
if model.mle_retvals.success:
forecast = model.forecast(ns_parser.n_days)
l_pred_days = get_next_stock_market_days(
last_stock_day=df_stock["5. adjusted close"].index[-1],
n_next_days=ns_parser.n_days,
)
df_pred = pd.Series(forecast, index=l_pred_days, name="Price")
if ~np.isnan(forecast).any():
print(f"\n{title}")
print("\nFit model parameters:")
for key, value in model.params.items():
print(f"{key} {' '*(18-len(key))}: {value}")
print("\nAssess fit model:")
print(f"AIC: {round(model.aic, 2)}")
print(f"BIC: {round(model.bic, 2)}")
print(f"SSE: {round(model.sse, 2)}\n")
# Plotting
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.plot(df_stock.index, df_stock["5. adjusted close"], lw=2)
# BACKTESTING
if ns_parser.s_end_date:
plt.title(f"BACKTESTING: {title} on {s_ticker}")
else:
plt.title(f"{title} on {s_ticker}")
plt.xlim(
df_stock.index[0],
get_next_stock_market_days(df_pred.index[-1], 1)[-1],
)
plt.xlabel("Time")
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_pred.values[0]
],
lw=1,
c="tab:green",
linestyle="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="tab:green")
plt.axvspan(
df_stock.index[-1],
df_pred.index[-1],
facecolor="tab:orange",
alpha=0.2,
)
_, _, ymin, ymax = plt.axis()
plt.vlines(
df_stock.index[-1],
ymin,
ymax,
linewidth=1,
linestyle="--",
color="k",
)
# BACKTESTING
if ns_parser.s_end_date:
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=1,
c="tab:blue",
linestyle="--",
)
if gtff.USE_ION:
plt.ion()
plt.show()
# BACKTESTING
if ns_parser.s_end_date:
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.subplot(211)
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="green")
plt.scatter(
df_future.index,
df_future["5. adjusted close"],
c="tab:blue",
lw=3,
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=2,
c="tab:blue",
ls="--",
)
plt.scatter(df_pred.index, df_pred, c="green", lw=3)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_pred.values[0]
],
lw=2,
c="green",
ls="--",
)
plt.title("BACKTESTING: Real data price versus Prediction")
plt.xlim(
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1),
)
plt.ylabel("Share Price ($)")
plt.grid(b=True,
which="major",
color="#666666",
linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
plt.xticks([])
plt.subplot(212)
plt.axhline(y=0, color="k", linestyle="--", linewidth=2)
plt.plot(
df_future.index,
100 * (df_pred.values -
df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
lw=2,
c="red",
)
plt.scatter(
df_future.index,
100 * (df_pred.values -
df_future["5. adjusted close"].values) /
df_future["5. adjusted close"].values,
c="red",
lw=5,
)
plt.title(
"BACKTESTING: Error between Real data and Prediction [%]"
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
0,
100 * (df_pred.values[0] -
df_future["5. adjusted close"].values[0]) /
df_future["5. adjusted close"].values[0],
],
lw=2,
ls="--",
c="red",
)
plt.xlim(
df_stock.index[-1],
df_pred.index[-1] + datetime.timedelta(days=1),
)
plt.xlabel("Time")
plt.ylabel("Prediction Error (%)")
plt.grid(b=True,
which="major",
color="#666666",
linestyle="-")
plt.minorticks_on()
plt.grid(b=True,
which="minor",
color="#999999",
linestyle="-",
alpha=0.2)
plt.legend(["Real data", "Prediction data"])
if gtff.USE_ION:
plt.ion()
plt.show()
# Refactor prediction dataframe for backtesting print
df_pred.name = "Prediction"
df_pred = df_pred.to_frame()
df_pred["Real"] = df_future["5. adjusted close"]
if gtff.USE_COLOR:
patch_pandas_text_adjustment()
print("Time Real [$] x Prediction [$]")
print(
df_pred.apply(price_prediction_backtesting_color,
axis=1).to_string())
else:
print(df_pred[["Real",
"Prediction"]].round(2).to_string())
print("")
print_prediction_kpis(df_pred["Real"].values,
df_pred["Prediction"].values)
else:
# Print prediction data
print_pretty_prediction(
df_pred, df_stock["5. adjusted close"].values[-1])
print("")
else:
print(
"RuntimeWarning: invalid value encountered in double_scalars."
)
else:
print("ConvergenceWarning: Optimization failed to converge.")
except Exception as e:
print(e)
print("")
def simple_moving_average(l_args, s_ticker, df_stock):
parser = argparse.ArgumentParser(
add_help=False,
prog="sma",
description="""
Moving Averages are used to smooth the data in an array to
help eliminate noise and identify trends. The Simple Moving Average is literally
the simplest form of a moving average. Each output value is the average of the
previous n values. In a Simple Moving Average, each value in the time period carries
equal weight, and values outside of the time period are not included in the average.
This makes it less responsive to recent changes in the data, which can be useful for
filtering out those changes.
""",
)
parser.add_argument(
"-l",
"--length",
action="store",
dest="n_length",
type=check_positive,
default=20,
help="length of SMA window.",
)
parser.add_argument(
"-d",
"--days",
action="store",
dest="n_days",
type=check_positive,
default=5,
help="prediction days.",
)
parser.add_argument(
"-e",
"--end",
action="store",
type=valid_date,
dest="s_end_date",
default=None,
help="The end date (format YYYY-MM-DD) to select - Backtesting",
)
try:
ns_parser = parse_known_args_and_warn(parser, l_args)
if not ns_parser:
return
# BACKTESTING
if ns_parser.s_end_date:
if ns_parser.s_end_date < df_stock.index[0]:
print(
"Backtesting not allowed, since End Date is older than Start Date of historical data\n"
)
return
if (
ns_parser.s_end_date
< get_next_stock_market_days(
last_stock_day=df_stock.index[0], n_next_days=5 + ns_parser.n_days
)[-1]
):
print(
"Backtesting not allowed, since End Date is too close to Start Date to train model\n"
)
return
future_index = get_next_stock_market_days(
last_stock_day=ns_parser.s_end_date, n_next_days=ns_parser.n_days
)
if future_index[-1] > datetime.datetime.now():
print(
"Backtesting not allowed, since End Date + Prediction days is in the future\n"
)
return
df_future = df_stock[future_index[0] : future_index[-1]]
df_stock = df_stock[: ns_parser.s_end_date]
# Prediction data
l_predictions = list()
for pred_day in range(ns_parser.n_days):
if pred_day < ns_parser.n_length:
l_ma_stock = df_stock["5. adjusted close"].values[
-ns_parser.n_length + pred_day :
]
else:
l_ma_stock = list()
l_predictions.append(np.mean(np.append(l_ma_stock, l_predictions)))
l_pred_days = get_next_stock_market_days(
last_stock_day=df_stock["5. adjusted close"].index[-1],
n_next_days=ns_parser.n_days,
)
df_pred = pd.Series(l_predictions, index=l_pred_days, name="Price")
# Plotting
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.plot(df_stock.index, df_stock["5. adjusted close"], lw=2)
# BACKTESTING
if ns_parser.s_end_date:
plt.title(
f"BACKTESTING: {ns_parser.n_length} Moving Average on {s_ticker} - {ns_parser.n_days} days prediction"
)
else:
plt.title(
f"{ns_parser.n_length} Moving Average on {s_ticker} - {ns_parser.n_days} days prediction"
)
plt.xlim(
df_stock.index[0], get_next_stock_market_days(df_pred.index[-1], 1)[-1]
)
plt.xlabel("Time")
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True, which="minor", color="#999999", linestyle="-", alpha=0.2)
df_ma = df_stock["5. adjusted close"].rolling(window=ns_parser.n_length).mean()
plt.plot(df_ma.index, df_ma, lw=2, linestyle="--", c="tab:orange")
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=1,
c="tab:green",
linestyle="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="tab:green")
plt.axvspan(
df_stock.index[-1], df_pred.index[-1], facecolor="tab:orange", alpha=0.2
)
_, _, ymin, ymax = plt.axis()
plt.vlines(
df_stock.index[-1], ymin, ymax, linewidth=1, linestyle="--", color="k"
)
# BACKTESTING
if ns_parser.s_end_date:
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=1,
c="tab:blue",
linestyle="--",
)
if gtff.USE_ION:
plt.ion()
plt.show()
# BACKTESTING
if ns_parser.s_end_date:
plt.figure(figsize=plot_autoscale(), dpi=PLOT_DPI)
plt.subplot(211)
plt.plot(
df_future.index,
df_future["5. adjusted close"],
lw=2,
c="tab:blue",
ls="--",
)
plt.plot(df_pred.index, df_pred, lw=2, c="green")
plt.scatter(
df_future.index, df_future["5. adjusted close"], c="tab:blue", lw=3
)
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
df_stock["5. adjusted close"].values[-1],
df_future["5. adjusted close"].values[0],
],
lw=2,
c="tab:blue",
ls="--",
)
plt.scatter(df_pred.index, df_pred, c="green", lw=3)
plt.plot(
[df_stock.index[-1], df_pred.index[0]],
[df_stock["5. adjusted close"].values[-1], df_pred.values[0]],
lw=2,
c="green",
ls="--",
)
plt.title("BACKTESTING: Real data price versus Prediction")
plt.xlim(df_stock.index[-1], df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks(
[df_stock.index[-1], df_pred.index[-1] + datetime.timedelta(days=1)],
visible=True,
)
plt.ylabel("Share Price ($)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True, which="minor", color="#999999", linestyle="-", alpha=0.2)
plt.legend(["Real data", "Prediction data"])
plt.xticks([])
plt.subplot(212)
plt.axhline(y=0, color="k", linestyle="--", linewidth=2)
plt.plot(
df_future.index,
100
* (df_pred.values - df_future["5. adjusted close"].values)
/ df_future["5. adjusted close"].values,
lw=2,
c="red",
)
plt.scatter(
df_future.index,
100
* (df_pred.values - df_future["5. adjusted close"].values)
/ df_future["5. adjusted close"].values,
c="red",
lw=5,
)
plt.title("BACKTESTING: Error between Real data and Prediction [%]")
plt.plot(
[df_stock.index[-1], df_future.index[0]],
[
0,
100
* (df_pred.values[0] - df_future["5. adjusted close"].values[0])
/ df_future["5. adjusted close"].values[0],
],
lw=2,
ls="--",
c="red",
)
plt.xlim(df_stock.index[-1], df_pred.index[-1] + datetime.timedelta(days=1))
plt.xticks(
[df_stock.index[-1], df_pred.index[-1] + datetime.timedelta(days=1)],
visible=True,
)
plt.xlabel("Time")
plt.ylabel("Prediction Error (%)")
plt.grid(b=True, which="major", color="#666666", linestyle="-")
plt.minorticks_on()
plt.grid(b=True, which="minor", color="#999999", linestyle="-", alpha=0.2)
plt.legend(["Real data", "Prediction data"])
if gtff.USE_ION:
plt.ion()
plt.show()
# Refactor prediction dataframe for backtesting print
df_pred.name = "Prediction"
df_pred = df_pred.to_frame()
df_pred["Real"] = df_future["5. adjusted close"]
if gtff.USE_COLOR:
patch_pandas_text_adjustment()
print("Time Real [$] x Prediction [$]")
print(
df_pred.apply(
price_prediction_backtesting_color, axis=1
).to_string()
)
else:
print(df_pred[["Real", "Prediction"]].round(2).to_string())
print("")
print_prediction_kpis(df_pred["Real"].values, df_pred["Prediction"].values)
else:
# Print prediction data
print_pretty_prediction(df_pred, df_stock["5. adjusted close"].values[-1])
print("")
except Exception as e:
print(e)
print("")