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gogo2/crypto/brian/index-deep-new.py
Dobromir Popov 0e7997d50a live data and refactoring
2025-02-05 11:32:21 +02:00

929 lines
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#!/usr/bin/env python3
import sys
import asyncio
if sys.platform == 'win32':
asyncio.set_event_loop_policy(asyncio.WindowsSelectorEventLoopPolicy())
import os
import time
import json
import argparse
import threading
import random
import numpy as np
import torch
import torch.nn as nn
import torch.optim as optim
from datetime import datetime
import matplotlib.pyplot as plt
import math
from torch.nn import TransformerEncoder, TransformerEncoderLayer
import matplotlib.dates as mdates
from dotenv import load_dotenv
load_dotenv()
# Define global constants FIRST.
CACHE_FILE = "candles_cache.json"
TRAINING_CACHE_FILE = "training_cache.json"
# --- Helper Function for Timestamp Conversion ---
def convert_timestamp(ts):
"""
Safely converts a timestamp to a datetime object.
If the timestamp is abnormally high (e.g. in milliseconds),
it is divided by 1000.
"""
ts = float(ts)
if ts > 1e10: # Likely in milliseconds
ts /= 1000.0
return datetime.fromtimestamp(ts)
# -------------------------------
# Historical Data Fetching Functions (Using CCXT)
# -------------------------------
async def fetch_historical_data(exchange, symbol, timeframe, since, end_time, batch_size=500):
"""
Fetch historical OHLCV data for the given symbol and timeframe.
"since" and "end_time" are in milliseconds.
"""
candles = []
since_ms = since
while True:
try:
batch = await exchange.fetch_ohlcv(symbol, timeframe=timeframe, since=since_ms, limit=batch_size)
except Exception as e:
print("Error fetching historical data:", e)
break
if not batch:
break
for c in batch:
candle_dict = {
'timestamp': c[0],
'open': c[1],
'high': c[2],
'low': c[3],
'close': c[4],
'volume': c[5]
}
candles.append(candle_dict)
last_timestamp = batch[-1][0]
if last_timestamp >= end_time:
break
since_ms = last_timestamp + 1
print(f"Fetched {len(candles)} candles for timeframe {timeframe}.")
return candles
async def get_cached_or_fetch_data(exchange, symbol, timeframe, since, end_time, cache_file=CACHE_FILE, batch_size=500):
cached_candles = load_candles_cache(cache_file)
if cached_candles and timeframe in cached_candles:
last_ts = cached_candles[timeframe][-1]['timestamp']
if last_ts < end_time:
print("Fetching new candles to update cache...")
new_candles = await fetch_historical_data(exchange, symbol, timeframe, last_ts + 1, end_time, batch_size)
cached_candles[timeframe].extend(new_candles)
else:
print("Cache covers the requested period.")
return cached_candles[timeframe]
else:
candles = await fetch_historical_data(exchange, symbol, timeframe, since, end_time, batch_size)
return candles
# -------------------------------
# Cache and Training Cache Helpers
# -------------------------------
def load_candles_cache(filename):
if os.path.exists(filename):
try:
with open(filename, "r") as f:
data = json.load(f)
print(f"Loaded cached data from {filename}.")
return data
except Exception as e:
print("Error reading cache file:", e)
return {}
def save_candles_cache(filename, candles_dict):
try:
with open(filename, "w") as f:
json.dump(candles_dict, f)
except Exception as e:
print("Error saving cache file:", e)
def load_training_cache(filename):
if os.path.exists(filename):
try:
with open(filename, "r") as f:
cache = json.load(f)
print(f"Loaded training cache from {filename}.")
return cache
except Exception as e:
print("Error loading training cache:", e)
return {"total_pnl": 0.0}
def save_training_cache(filename, cache):
try:
with open(filename, "w") as f:
json.dump(cache, f)
except Exception as e:
print("Error saving training cache:", e)
TRAINING_CACHE_FILE = "training_cache.json"
# -------------------------------
# Checkpoint Functions
# -------------------------------
LAST_DIR = os.path.join("models", "last")
BEST_DIR = os.path.join("models", "best")
os.makedirs(LAST_DIR, exist_ok=True)
os.makedirs(BEST_DIR, exist_ok=True)
def maintain_checkpoint_directory(directory, max_files=10):
files = os.listdir(directory)
if len(files) > max_files:
full_paths = [os.path.join(directory, f) for f in files]
full_paths.sort(key=lambda x: os.path.getmtime(x))
for f in full_paths[:len(files) - max_files]:
os.remove(f)
def get_best_models(directory):
best_files = []
for file in os.listdir(directory):
parts = file.split("_")
try:
loss = float(parts[1])
best_files.append((loss, file))
except Exception:
continue
return best_files
def save_checkpoint(model, optimizer, epoch, loss, last_dir=LAST_DIR, best_dir=BEST_DIR):
timestamp = datetime.now().strftime("%Y%m%d_%H%M%S")
last_filename = f"model_last_epoch_{epoch}_{timestamp}.pt"
last_path = os.path.join(last_dir, last_filename)
torch.save({
"epoch": epoch,
"loss": loss,
"model_state_dict": model.state_dict(),
"optimizer_state_dict": optimizer.state_dict()
}, last_path)
maintain_checkpoint_directory(last_dir, max_files=10)
best_models = get_best_models(best_dir)
add_to_best = False
if len(best_models) < 10:
add_to_best = True
else:
worst_loss, worst_file = max(best_models, key=lambda x: x[0])
if loss < worst_loss:
add_to_best = True
os.remove(os.path.join(best_dir, worst_file))
if add_to_best:
best_filename = f"best_{loss:.4f}_epoch_{epoch}_{timestamp}.pt"
best_path = os.path.join(best_dir, best_filename)
torch.save({
"epoch": epoch,
"loss": loss,
"model_state_dict": model.state_dict(),
"optimizer_state_dict": optimizer.state_dict()
}, best_path)
maintain_checkpoint_directory(best_dir, max_files=10)
print(f"Saved checkpoint for epoch {epoch} with loss {loss:.4f}")
def load_best_checkpoint(model, best_dir=BEST_DIR):
best_models = get_best_models(best_dir)
if not best_models:
return None
best_loss, best_file = min(best_models, key=lambda x: x[0])
path = os.path.join(best_dir, best_file)
print(f"Loading best model from checkpoint: {best_file} with loss {best_loss:.4f}")
checkpoint = torch.load(path)
old_state = checkpoint["model_state_dict"]
new_state = model.state_dict()
if "timeframe_embed.weight" in old_state:
old_embed = old_state["timeframe_embed.weight"]
new_embed = new_state["timeframe_embed.weight"]
if old_embed.shape[0] < new_embed.shape[0]:
new_embed[:old_embed.shape[0]] = old_embed
old_state["timeframe_embed.weight"] = new_embed
model.load_state_dict(old_state, strict=False)
return checkpoint
# -------------------------------
# Positional Encoding and Transformer-Based Model
# -------------------------------
class PositionalEncoding(nn.Module):
def __init__(self, d_model, dropout=0.1, max_len=5000):
super().__init__()
self.dropout = nn.Dropout(p=dropout)
position = torch.arange(max_len).unsqueeze(1)
div_term = torch.exp(torch.arange(0, d_model, 2) * (-math.log(10000.0) / d_model))
pe = torch.zeros(max_len, 1, d_model)
pe[:, 0, 0::2] = torch.sin(position * div_term)
pe[:, 0, 1::2] = torch.cos(position * div_term)
self.register_buffer('pe', pe)
def forward(self, x):
x = x + self.pe[:x.size(0)]
return self.dropout(x)
class TradingModel(nn.Module):
def __init__(self, num_channels, num_timeframes, hidden_dim=128):
super().__init__()
# One branch per channel.
self.channel_branches = nn.ModuleList([
nn.Sequential(
nn.Linear(FEATURES_PER_CHANNEL, hidden_dim),
nn.LayerNorm(hidden_dim),
nn.GELU(),
nn.Dropout(0.1)
) for _ in range(num_channels)
])
self.timeframe_embed = nn.Embedding(num_channels, hidden_dim)
self.pos_encoder = PositionalEncoding(hidden_dim)
encoder_layers = TransformerEncoderLayer(
d_model=hidden_dim, nhead=4, dim_feedforward=512,
dropout=0.1, activation='gelu', batch_first=True
)
self.transformer = TransformerEncoder(encoder_layers, num_layers=2)
self.attn_pool = nn.Linear(hidden_dim, 1)
self.high_pred = nn.Sequential(
nn.Linear(hidden_dim, hidden_dim // 2),
nn.GELU(),
nn.Linear(hidden_dim // 2, 1)
)
self.low_pred = nn.Sequential(
nn.Linear(hidden_dim, hidden_dim // 2),
nn.GELU(),
nn.Linear(hidden_dim // 2, 1)
)
def forward(self, x, timeframe_ids):
batch_size, num_channels, _ = x.shape
channel_outs = []
for i in range(num_channels):
channel_out = self.channel_branches[i](x[:, i, :])
channel_outs.append(channel_out)
stacked = torch.stack(channel_outs, dim=1)
tf_embeds = self.timeframe_embed(timeframe_ids)
stacked = stacked + tf_embeds.unsqueeze(0)
transformer_out = self.transformer(stacked)
attn_weights = torch.softmax(self.attn_pool(transformer_out), dim=1)
aggregated = (transformer_out * attn_weights).sum(dim=1)
return self.high_pred(aggregated).squeeze(), self.low_pred(aggregated).squeeze()
# -------------------------------
# Technical Indicator Helpers
# -------------------------------
def compute_sma(candles_list, index, period=10):
start = max(0, index - period + 1)
values = [candle["close"] for candle in candles_list[start:index+1]]
return sum(values)/len(values) if values else 0.0
def compute_sma_volume(candles_list, index, period=10):
start = max(0, index - period + 1)
values = [candle["volume"] for candle in candles_list[start:index+1]]
return sum(values)/len(values) if values else 0.0
def get_aligned_candle_with_index(candles_list, target_ts):
best_idx = 0
for i, candle in enumerate(candles_list):
if candle["timestamp"] <= target_ts:
best_idx = i
else:
break
return best_idx, candles_list[best_idx]
def get_features_for_tf(candles_list, index, period=10):
candle = candles_list[index]
f_open = candle["open"]
f_high = candle["high"]
f_low = candle["low"]
f_close = candle["close"]
f_volume = candle["volume"]
sma_close = compute_sma(candles_list, index, period)
sma_volume= compute_sma_volume(candles_list, index, period)
return [f_open, f_high, f_low, f_close, f_volume, sma_close, sma_volume]
# -------------------------------
# Backtest Environment Class
# -------------------------------
class BacktestEnvironment:
def __init__(self, candles_dict, base_tf, timeframes, window_size=None):
self.candles_dict = candles_dict # full candles dict across timeframes
self.base_tf = base_tf
self.timeframes = timeframes
self.full_candles = candles_dict[base_tf]
if window_size is None:
window_size = 100 if len(self.full_candles) >= 100 else len(self.full_candles)
self.window_size = window_size
self.reset()
def reset(self):
self.start_index = random.randint(0, len(self.full_candles) - self.window_size)
self.candle_window = self.full_candles[self.start_index:self.start_index+self.window_size]
self.current_index = 0
self.trade_history = []
self.position = None
return self.get_state(self.current_index)
def __len__(self):
return self.window_size
def get_order_features(self, index):
candle = self.candle_window[index]
if self.position is None:
return [0.0] * FEATURES_PER_CHANNEL
else:
flag = 1.0
diff = (candle["open"] - self.position["entry_price"]) / candle["open"]
return [flag, diff] + [0.0] * (FEATURES_PER_CHANNEL - 2)
def get_state(self, index):
state_features = []
base_ts = self.candle_window[index]["timestamp"]
for tf in self.timeframes:
if tf == self.base_tf:
candle = self.candle_window[index]
features = get_features_for_tf([candle], 0)
else:
aligned_idx, _ = get_aligned_candle_with_index(self.candles_dict[tf], base_ts)
features = get_features_for_tf(self.candles_dict[tf], aligned_idx)
state_features.append(features)
order_features = self.get_order_features(index)
state_features.append(order_features)
for _ in range(NUM_INDICATORS):
state_features.append([0.0] * FEATURES_PER_CHANNEL)
return np.array(state_features, dtype=np.float32)
def step(self, action):
base = self.candle_window
if self.current_index >= len(base) - 1:
current_state = self.get_state(self.current_index)
return current_state, 0.0, None, True, 0.0, 0.0
current_state = self.get_state(self.current_index)
next_index = self.current_index + 1
next_state = self.get_state(next_index)
next_candle = base[next_index]
reward = 0.0
if self.position is None:
if action == 2: # BUY (open long)
self.position = {"entry_price": next_candle["open"], "entry_index": self.current_index}
else:
if action == 0: # SELL (close trade)
exit_price = next_candle["close"]
reward = exit_price - self.position["entry_price"]
trade = {
"entry_index": self.position["entry_index"],
"entry_price": self.position["entry_price"],
"exit_index": next_index,
"exit_price": exit_price,
"pnl": reward
}
self.trade_history.append(trade)
self.position = None
self.current_index = next_index
done = (self.current_index >= len(base) - 1)
actual_high = next_candle["high"]
actual_low = next_candle["low"]
return current_state, reward, next_state, done, actual_high, actual_low
# -------------------------------
# Enhanced Training Loop
# -------------------------------
def train_on_historical_data(env, model, device, args, start_epoch, optimizer, scheduler):
lambda_trade = args.lambda_trade
training_cache = load_training_cache(TRAINING_CACHE_FILE)
total_pnl = training_cache.get("total_pnl", 0.0)
for epoch in range(start_epoch, args.epochs):
env.reset()
loss_accum = 0.0
steps = len(env) - 1
for i in range(steps):
state = env.get_state(i)
current_open = env.candle_window[i]["open"]
actual_high = env.candle_window[i+1]["high"]
actual_low = env.candle_window[i+1]["low"]
state_tensor = torch.FloatTensor(state).unsqueeze(0).to(device)
timeframe_ids = torch.arange(state.shape[0]).to(device)
pred_high, pred_low = model(state_tensor, timeframe_ids)
L_pred = torch.abs(pred_high - torch.tensor(actual_high, device=device)) + \
torch.abs(pred_low - torch.tensor(actual_low, device=device))
profit_buy = pred_high - current_open
profit_sell = current_open - pred_low
L_trade = - torch.max(profit_buy, profit_sell)
current_open_tensor = torch.tensor(current_open, device=device)
signal_strength = torch.max(pred_high - current_open_tensor, current_open_tensor - pred_low)
penalty_term = args.penalty_noaction * torch.clamp(args.threshold - signal_strength, min=0)
loss = L_pred + lambda_trade * L_trade + penalty_term
optimizer.zero_grad()
loss.backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), 1.0)
optimizer.step()
loss_accum += loss.item()
scheduler.step()
epoch_loss = loss_accum / steps
if len(env.trade_history) == 0:
epoch_loss *= 3
epoch_pnl = sum(trade["pnl"] for trade in env.trade_history)
total_pnl += epoch_pnl
print(f"Epoch {epoch+1} Loss: {epoch_loss:.4f} | Epoch PnL: {epoch_pnl:.2f} | Total PnL: {total_pnl:.2f}")
save_checkpoint(model, optimizer, epoch, loss_accum)
simulate_trades(model, env, device, args)
update_live_html(env.candle_window, env.trade_history, epoch+1, epoch_loss, total_pnl)
training_cache["total_pnl"] = total_pnl
save_training_cache(TRAINING_CACHE_FILE, training_cache)
# -------------------------------
# Live Plotting (for Live Mode)
# -------------------------------
def live_preview_loop(candles, env):
plt.ion()
fig, ax = plt.subplots(figsize=(12, 6))
while True:
update_live_chart(ax, candles, env.trade_history)
plt.draw()
plt.pause(1)
# -------------------------------
# Live HTML Chart Update (with Volume and Loss)
# -------------------------------
def update_live_html(candles, trade_history, epoch, loss, total_pnl):
from io import BytesIO
import base64
fig, ax = plt.subplots(figsize=(12, 6))
update_live_chart(ax, candles, trade_history)
epoch_pnl = sum(trade["pnl"] for trade in trade_history)
ax.set_title(f"Epoch {epoch} | Loss: {loss:.4f} | PnL: {epoch_pnl:.2f}| Total PnL: {total_pnl:.2f}")
buf = BytesIO()
fig.savefig(buf, format='png')
plt.close(fig)
buf.seek(0)
image_base64 = base64.b64encode(buf.getvalue()).decode('utf-8')
html_content = f"""
<!DOCTYPE html>
<html>
<head>
<meta charset="utf-8">
<meta http-equiv="refresh" content="1">
<title>Live Trading Chart - Epoch {epoch}</title>
<style>
body {{
margin: 0;
padding: 0;
display: flex;
justify-content: center;
align-items: center;
background-color: #f4f4f4;
}}
.chart-container {{
text-align: center;
}}
img {{
max-width: 100%;
height: auto;
}}
</style>
</head>
<body>
<div class="chart-container">
<h2>Epoch {epoch} | Loss: {loss:.4f} | PnL: {epoch_pnl:.2f}| Total PnL: {total_pnl:.2f}</h2>
<img src="data:image/png;base64,{image_base64}" alt="Live Chart"/>
</div>
</body>
</html>
"""
with open("live_chart.html", "w") as f:
f.write(html_content)
print("Updated live_chart.html.")
# -------------------------------
# Chart Drawing Helpers (with Volume and Date+Time)
# -------------------------------
def update_live_chart(ax, candles, trade_history):
ax.clear()
times = [convert_timestamp(candle["timestamp"]) for candle in candles]
close_prices = [candle["close"] for candle in candles]
ax.plot(times, close_prices, label="Close Price", color="black", linewidth=1)
ax.set_xlabel("Time")
ax.set_ylabel("Price")
ax.xaxis.set_major_formatter(mdates.DateFormatter('%m-%d %H:%M'))
ax2 = ax.twinx()
volumes = [candle["volume"] for candle in candles]
if len(times) > 1:
times_num = mdates.date2num(times)
bar_width = (times_num[-1] - times_num[0]) / len(times) * 0.8
else:
bar_width = 0.01
ax2.bar(times, volumes, width=bar_width, alpha=0.3, color="grey", label="Volume")
ax2.set_ylabel("Volume")
for trade in trade_history:
entry_time = convert_timestamp(candles[trade["entry_index"]]["timestamp"])
exit_time = convert_timestamp(candles[trade["exit_index"]]["timestamp"])
in_price = trade["entry_price"]
out_price = trade["exit_price"]
ax.plot(entry_time, in_price, marker="^", color="green", markersize=10, label="BUY")
ax.plot(exit_time, out_price, marker="v", color="red", markersize=10, label="SELL")
ax.plot([entry_time, exit_time], [in_price, out_price], linestyle="dotted", color="blue")
lines, labels = ax.get_legend_handles_labels()
lines2, labels2 = ax2.get_legend_handles_labels()
ax.legend(lines + lines2, labels + labels2)
ax.grid(True)
fig = ax.get_figure()
fig.autofmt_xdate()
# -------------------------------
# Backtest Environment Class
# -------------------------------
class BacktestEnvironment:
def __init__(self, candles_dict, base_tf, timeframes, window_size=None):
self.candles_dict = candles_dict
self.base_tf = base_tf
self.timeframes = timeframes
self.full_candles = candles_dict[base_tf]
if window_size is None:
window_size = 100 if len(self.full_candles) >= 100 else len(self.full_candles)
self.window_size = window_size
self.reset()
def reset(self):
self.start_index = random.randint(0, len(self.full_candles)-self.window_size)
self.candle_window = self.full_candles[self.start_index:self.start_index+self.window_size]
self.current_index = 0
self.trade_history = []
self.position = None
return self.get_state(self.current_index)
def __len__(self):
return self.window_size
def get_order_features(self, index):
candle = self.candle_window[index]
if self.position is None:
return [0.0] * FEATURES_PER_CHANNEL
else:
flag = 1.0
diff = (candle["open"] - self.position["entry_price"]) / candle["open"]
return [flag, diff] + [0.0] * (FEATURES_PER_CHANNEL - 2)
def get_state(self, index):
state_features = []
base_ts = self.candle_window[index]["timestamp"]
for tf in self.timeframes:
if tf == self.base_tf:
candle = self.candle_window[index]
features = get_features_for_tf([candle], 0)
else:
aligned_idx, _ = get_aligned_candle_with_index(self.candles_dict[tf], base_ts)
features = get_features_for_tf(self.candles_dict[tf], aligned_idx)
state_features.append(features)
order_features = self.get_order_features(index)
state_features.append(order_features)
for _ in range(NUM_INDICATORS):
state_features.append([0.0]*FEATURES_PER_CHANNEL)
return np.array(state_features, dtype=np.float32)
def step(self, action):
base = self.candle_window
if self.current_index >= len(base)-1:
current_state = self.get_state(self.current_index)
return current_state, 0.0, None, True, 0.0, 0.0
current_state = self.get_state(self.current_index)
next_index = self.current_index + 1
next_state = self.get_state(next_index)
next_candle = base[next_index]
reward = 0.0
if self.position is None:
if action == 2: # BUY
self.position = {"entry_price": next_candle["open"], "entry_index": self.current_index}
else:
if action == 0: # SELL
exit_price = next_candle["close"]
reward = exit_price - self.position["entry_price"]
trade = {
"entry_index": self.position["entry_index"],
"entry_price": self.position["entry_price"],
"exit_index": next_index,
"exit_price": exit_price,
"pnl": reward
}
self.trade_history.append(trade)
self.position = None
self.current_index = next_index
done = (self.current_index >= len(base)-1)
actual_high = next_candle["high"]
actual_low = next_candle["low"]
return current_state, reward, next_state, done, actual_high, actual_low
# -------------------------------
# Enhanced Training Loop
# -------------------------------
def train_on_historical_data(env, model, device, args, start_epoch, optimizer, scheduler):
lambda_trade = args.lambda_trade
training_cache = load_training_cache(TRAINING_CACHE_FILE)
total_pnl = training_cache.get("total_pnl", 0.0)
for epoch in range(start_epoch, args.epochs):
env.reset()
loss_accum = 0.0
steps = len(env) - 1
for i in range(steps):
state = env.get_state(i)
current_open = env.candle_window[i]["open"]
actual_high = env.candle_window[i+1]["high"]
actual_low = env.candle_window[i+1]["low"]
state_tensor = torch.FloatTensor(state).unsqueeze(0).to(device)
timeframe_ids = torch.arange(state.shape[0]).to(device)
pred_high, pred_low = model(state_tensor, timeframe_ids)
L_pred = torch.abs(pred_high - torch.tensor(actual_high, device=device)) + \
torch.abs(pred_low - torch.tensor(actual_low, device=device))
profit_buy = pred_high - current_open
profit_sell = current_open - pred_low
L_trade = - torch.max(profit_buy, profit_sell)
current_open_tensor = torch.tensor(current_open, device=device)
signal_strength = torch.max(pred_high - current_open_tensor, current_open_tensor - pred_low)
penalty_term = args.penalty_noaction * torch.clamp(args.threshold - signal_strength, min=0)
loss = L_pred + lambda_trade * L_trade + penalty_term
optimizer.zero_grad()
loss.backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), 1.0)
optimizer.step()
loss_accum += loss.item()
scheduler.step()
epoch_loss = loss_accum / steps
if len(env.trade_history) == 0:
epoch_loss *= 3
epoch_pnl = sum(trade["pnl"] for trade in env.trade_history)
total_pnl += epoch_pnl
print(f"Epoch {epoch+1} Loss: {epoch_loss:.4f} | Epoch PnL: {epoch_pnl:.2f} | Total PnL: {total_pnl:.2f}")
save_checkpoint(model, optimizer, epoch, loss_accum)
simulate_trades(model, env, device, args)
update_live_html(env.candle_window, env.trade_history, epoch+1, epoch_loss, total_pnl)
training_cache["total_pnl"] = total_pnl
save_training_cache(TRAINING_CACHE_FILE, training_cache)
# -------------------------------
# Live Plotting (for Live Mode)
# -------------------------------
def live_preview_loop(candles, env):
plt.ion()
fig, ax = plt.subplots(figsize=(12, 6))
while True:
update_live_chart(ax, candles, env.trade_history)
plt.draw()
plt.pause(1)
# -------------------------------
# Live HTML Chart Update (with Volume and Loss)
# -------------------------------
def update_live_html(candles, trade_history, epoch, loss, total_pnl):
from io import BytesIO
import base64
fig, ax = plt.subplots(figsize=(12, 6))
update_live_chart(ax, candles, trade_history)
epoch_pnl = sum(trade["pnl"] for trade in trade_history)
ax.set_title(f"Epoch {epoch} | Loss: {loss:.4f} | PnL: {epoch_pnl:.2f}| Total PnL: {total_pnl:.2f}")
buf = BytesIO()
fig.savefig(buf, format='png')
plt.close(fig)
buf.seek(0)
image_base64 = base64.b64encode(buf.getvalue()).decode('utf-8')
html_content = f"""
<!DOCTYPE html>
<html>
<head>
<meta charset="utf-8">
<meta http-equiv="refresh" content="1">
<title>Live Trading Chart - Epoch {epoch}</title>
<style>
body {{
margin: 0;
padding: 0;
display: flex;
justify-content: center;
align-items: center;
background-color: #f4f4f4;
}}
.chart-container {{
text-align: center;
}}
img {{
max-width: 100%;
height: auto;
}}
</style>
</head>
<body>
<div class="chart-container">
<h2>Epoch {epoch} | Loss: {loss:.4f} | PnL: {epoch_pnl:.2f}| Total PnL: {total_pnl:.2f}</h2>
<img src="data:image/png;base64,{image_base64}" alt="Live Chart"/>
</div>
</body>
</html>
"""
with open("live_chart.html", "w") as f:
f.write(html_content)
print("Updated live_chart.html.")
# -------------------------------
# Chart Drawing Helpers (with Volume and Date+Time)
# -------------------------------
def update_live_chart(ax, candles, trade_history):
ax.clear()
times = [convert_timestamp(candle["timestamp"]) for candle in candles]
close_prices = [candle["close"] for candle in candles]
ax.plot(times, close_prices, label="Close Price", color="black", linewidth=1)
ax.set_xlabel("Time")
ax.set_ylabel("Price")
ax.xaxis.set_major_formatter(mdates.DateFormatter('%m-%d %H:%M'))
ax2 = ax.twinx()
volumes = [candle["volume"] for candle in candles]
if len(times) > 1:
times_num = mdates.date2num(times)
bar_width = (times_num[-1] - times_num[0]) / len(times) * 0.8
else:
bar_width = 0.01
ax2.bar(times, volumes, width=bar_width, alpha=0.3, color="grey", label="Volume")
ax2.set_ylabel("Volume")
for trade in trade_history:
entry_time = convert_timestamp(candles[trade["entry_index"]]["timestamp"])
exit_time = convert_timestamp(candles[trade["exit_index"]]["timestamp"])
in_price = trade["entry_price"]
out_price = trade["exit_price"]
ax.plot(entry_time, in_price, marker="^", color="green", markersize=10, label="BUY")
ax.plot(exit_time, out_price, marker="v", color="red", markersize=10, label="SELL")
ax.plot([entry_time, exit_time], [in_price, out_price], linestyle="dotted", color="blue")
lines, labels = ax.get_legend_handles_labels()
lines2, labels2 = ax2.get_legend_handles_labels()
ax.legend(lines + lines2, labels + labels2)
ax.grid(True)
fig = ax.get_figure()
fig.autofmt_xdate()
# -------------------------------
# Global Constants for Features
# -------------------------------
NUM_INDICATORS = 20
FEATURES_PER_CHANNEL = 7
ORDER_CHANNELS = 1
# -------------------------------
# Backtest Environment with Sliding Window and Order Info (Already Defined Above)
# [See BacktestEnvironment class above]
# -------------------------------
# -------------------------------
# General Simulation of Trades Function
# -------------------------------
def simulate_trades(model, env, device, args):
if args.main_tf == "1s":
simulate_trades_1s(env)
return
env.reset()
while True:
i = env.current_index
if i >= len(env.candle_window) - 1:
break
state = env.get_state(i)
current_open = env.candle_window[i]["open"]
state_tensor = torch.FloatTensor(state).unsqueeze(0).to(device)
timeframe_ids = torch.arange(state.shape[0]).to(device)
pred_high, pred_low = model(state_tensor, timeframe_ids)
pred_high = pred_high.item()
pred_low = pred_low.item()
if (pred_high - current_open) > args.threshold or (current_open - pred_low) > args.threshold:
if (pred_high - current_open) >= (current_open - pred_low):
action = 2
else:
action = 0
_, _, _, done, _, _ = env.step(action)
else:
manual_trade(env)
if env.current_index >= len(env.candle_window) - 1:
break
# -------------------------------
# Argument Parsing
# -------------------------------
def parse_args():
parser = argparse.ArgumentParser()
parser.add_argument('--mode', choices=['train', 'live', 'inference'], default='train')
parser.add_argument('--epochs', type=int, default=1000)
parser.add_argument('--lr', type=float, default=3e-4)
parser.add_argument('--threshold', type=float, default=0.005,
help="Minimum predicted move to trigger trade (used in loss; model may override manual trades).")
parser.add_argument('--lambda_trade', type=float, default=1.0,
help="Weight for the trade surrogate loss.")
parser.add_argument('--penalty_noaction', type=float, default=10.0,
help="Penalty if no action is taken (used in loss).")
parser.add_argument('--start_fresh', action='store_true', help="Start training from scratch.")
parser.add_argument('--main_tf', type=str, default='1m',
help="Desired main timeframe to focus on (e.g., '1s' or '1m').")
parser.add_argument('--fetch', action='store_true', help="Fetch fresh data from exchange on start.")
parser.add_argument('--symbol', type=str, default='BTC/USDT', help="Trading pair symbol.")
return parser.parse_args()
def random_action():
return random.randint(0, 2)
# -------------------------------
# Main Function
# -------------------------------
async def main():
args = parse_args()
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
print("Using device:", device)
# If --fetch flag is provided, top-up cached OHLCV data with fresh data from exchange.
if args.fetch:
import ccxt.async_support as ccxt
exchange = ccxt.binance({'enableRateLimit': True})
now_ms = int(time.time()*1000)
# Determine default "since" time based on cache.
cached = load_candles_cache(CACHE_FILE)
if cached and args.main_tf in cached and len(cached[args.main_tf]) > 0:
last_ts = cached[args.main_tf][-1]['timestamp']
since = last_ts + 1
else:
# Default: fetch candles from the last 2 days.
since = now_ms - 2*24*60*60*1000
# Top-up data for the main timeframe.
print(f"Fetching fresh data for {args.symbol} on timeframe {args.main_tf} from {since} to {now_ms}...")
fresh_candles = await get_cached_or_fetch_data(exchange, args.symbol, args.main_tf, since, now_ms)
# Update cache (for simplicity, we store only the main timeframe here).
candles_dict = {args.main_tf: fresh_candles}
save_candles_cache(CACHE_FILE, candles_dict)
await exchange.close()
else:
candles_dict = load_candles_cache(CACHE_FILE)
if not candles_dict:
print("No cached data available. Run with --fetch to load fresh data from the exchange.")
return
# Define desired timeframes list.
default_timeframes = ["1s", "1m", "5m", "15m", "1h", "1d"]
timeframes = [tf for tf in default_timeframes if tf in candles_dict]
if args.main_tf not in timeframes:
print(f"Desired main timeframe {args.main_tf} is not available. Available: {timeframes}")
return
base_tf = args.main_tf
hidden_dim = 128
total_channels = len(timeframes) + ORDER_CHANNELS + NUM_INDICATORS
model = TradingModel(total_channels, len(timeframes)).to(device)
if args.mode == 'train':
env = BacktestEnvironment(candles_dict, base_tf, timeframes, window_size=100)
start_epoch = 0
checkpoint = None
if not args.start_fresh:
checkpoint = load_best_checkpoint(model)
if checkpoint is not None:
start_epoch = checkpoint.get("epoch", 0) + 1
print(f"Resuming training from epoch {start_epoch}.")
else:
print("No checkpoint found. Starting training from scratch.")
else:
print("Starting training from scratch as requested.")
optimizer = optim.AdamW(model.parameters(), lr=args.lr, weight_decay=1e-5)
scheduler = torch.optim.lr_scheduler.CosineAnnealingLR(optimizer, T_max=args.epochs - start_epoch)
if checkpoint is not None:
optim_state = checkpoint.get("optimizer_state_dict", None)
if optim_state is not None and "param_groups" in optim_state:
try:
optimizer.load_state_dict(optim_state)
print("Loaded optimizer state from checkpoint.")
except Exception as e:
print("Failed to load optimizer state due to:", e)
print("Deleting all checkpoints and starting fresh.")
for chk_dir in [LAST_DIR, BEST_DIR]:
for f in os.listdir(chk_dir):
os.remove(os.path.join(chk_dir, f))
else:
print("No valid optimizer state found; using fresh optimizer state.")
train_on_historical_data(env, model, device, args, start_epoch, optimizer, scheduler)
elif args.mode == 'live':
load_best_checkpoint(model)
env = BacktestEnvironment(candles_dict, base_tf, timeframes, window_size=100)
preview_thread = threading.Thread(target=live_preview_loop, args=(env.candle_window, env), daemon=True)
preview_thread.start()
print("Starting live trading loop. (For main_tf={} using manual override if model signal is weak.)".format(args.main_tf))
while True:
if args.main_tf == "1s":
simulate_trades_1s(env)
else:
state = env.get_state(env.current_index)
current_open = env.candle_window[env.current_index]["open"]
state_tensor = torch.FloatTensor(state).unsqueeze(0).to(device)
timeframe_ids = torch.arange(state.shape[0]).to(device)
pred_high, pred_low = model(state_tensor, timeframe_ids)
pred_high = pred_high.item()
pred_low = pred_low.item()
if (pred_high - current_open) > args.threshold or (current_open - pred_low) > args.threshold:
if (pred_high - current_open) >= (current_open - pred_low):
action = 2
else:
action = 0
_, _, _, done, _, _ = env.step(action)
else:
manual_trade(env)
if env.current_index >= len(env.candle_window)-1:
print("Reached end of simulation window; resetting environment.")
env.reset()
await asyncio.sleep(1)
elif args.mode == 'inference':
load_best_checkpoint(model)
print("Running inference...")
# Inference logic goes here.
else:
print("Invalid mode specified.")
if __name__ == "__main__":
asyncio.run(main())
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