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import os, tempfile
import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
from pandas.api.types import is_datetime64_any_dtype as is_datetime
from sklearn.model_selection import train_test_split
from sklearn.metrics import mean_absolute_error, r2_score
from sklearn.ensemble import GradientBoostingRegressor, RandomForestRegressor
import gradio as gr
# ---------- Helpers ----------
def infer_target_column(df: pd.DataFrame):
for c in ["power_usage_kwh", "energy_kwh", "power_kwh", "energy"]:
if c in df.columns:
return c
raise ValueError("Target column not found. Expected one of: "
"['power_usage_kwh','energy_kwh','power_kwh','energy'].")
def ensure_datetime_naive(df: pd.DataFrame, tz_target: str = "Asia/Dubai"):
if "timestamp" not in df.columns:
return df
# Parse robustly with UTC, then convert to target tz and drop tz
ts = pd.to_datetime(df["timestamp"], errors="coerce", utc=True)
try:
ts = ts.dt.tz_convert(tz_target).dt.tz_localize(None)
except Exception:
try:
ts = ts.dt.tz_localize(None)
except Exception:
pass
df = df.copy()
df["timestamp"] = ts
return df
def feature_engineer(df: pd.DataFrame) -> pd.DataFrame:
df = df.copy()
df = ensure_datetime_naive(df, tz_target="Asia/Dubai")
# Light numeric imputation
num_cols = df.select_dtypes(include=[np.number]).columns
df[num_cols] = df[num_cols].ffill().bfill()
# Time features
if "timestamp" in df.columns and is_datetime(df["timestamp"]):
df["hour"] = df["timestamp"].dt.hour
df["dayofweek"] = df["timestamp"].dt.dayofweek
df["is_weekend"] = (df["dayofweek"] >= 5).astype(int)
df["month"] = df["timestamp"].dt.month
df["dayofyear"] = df["timestamp"].dt.dayofyear
df["hour_sin"] = np.sin(2*np.pi*df["hour"]/24)
df["hour_cos"] = np.cos(2*np.pi*df["hour"]/24)
df["dow_sin"] = np.sin(2*np.pi*df["dayofweek"]/7)
df["dow_cos"] = np.cos(2*np.pi*df["dayofweek"]/7)
else:
for c in ["hour","dayofweek","is_weekend","month","dayofyear","hour_sin","hour_cos","dow_sin","dow_cos"]:
if c not in df.columns:
df[c] = 0
# Domain features
tgt = infer_target_column(df)
if "cooling_eff_pct" in df.columns:
df["cooling_ineff_pct"] = 100 - df["cooling_eff_pct"]
if "server_load_pct" in df.columns:
df["energy_per_load"] = df[tgt] / np.maximum(df["server_load_pct"], 1)
if "ambient_temp_c" in df.columns and "server_load_pct" in df.columns:
df["temp_load_interaction"] = df["ambient_temp_c"] * df["server_load_pct"]
# Target lags/rollings
df["target_lag1"] = df[tgt].shift(1)
df["target_roll3"] = df[tgt].rolling(3, min_periods=1).mean()
df["target_roll24"] = df[tgt].rolling(24, min_periods=1).mean()
# Fill NaNs from shifts
df = df.ffill().bfill()
return df
def get_model(name: str):
return GradientBoostingRegressor(random_state=42) if name == "Gradient Boosting" \
else RandomForestRegressor(n_estimators=300, random_state=42)
def feature_target_split(df: pd.DataFrame):
y_col = infer_target_column(df)
X = df.drop(columns=[c for c in [y_col, "timestamp"] if c in df.columns], errors="ignore")
X = X.select_dtypes(include=[np.number]).copy()
y = df[y_col].astype(float)
return X, y, y_col
# ---------- Core pipeline ----------
def run_pipeline(file_path, model_name):
title = "⚑ AI-Driven Data Center Energy Optimization Dashboard"
try:
if not file_path:
return (title, "Please upload a CSV file.", None, None, None, None, None, None)
df_raw = pd.read_csv(file_path)
df = feature_engineer(df_raw)
# Guardrail
if len(df) < 10:
return (title, "Not enough rows to train a model (need >= 10).", None, None, None, None, None, None)
X, y, y_col = feature_target_split(df)
# Split, train, predict
test_size = 0.25 if len(df) >= 25 else 0.2
X_train, X_test, y_train, y_test = train_test_split(
X, y, test_size=test_size, random_state=42
)
model = get_model(model_name)
model.fit(X_train, y_train)
y_pred_all = model.predict(X)
y_pred_test = model.predict(X_test)
mae = mean_absolute_error(y_test, y_pred_test)
r2 = r2_score(y_test, y_pred_test)
avg_actual = float(np.mean(y))
avg_pred = float(np.mean(y_pred_all))
# ------ Visualizations ------
ts_plot = None
if "timestamp" in df.columns and is_datetime(df["timestamp"]):
plot_df = df.copy().sort_values("timestamp")
Xp = plot_df.drop(columns=[c for c in [y_col, "timestamp"] if c in plot_df.columns], errors="ignore")
Xp = Xp.select_dtypes(include=[np.number]).copy()
yp = model.predict(Xp)
ts_plot = plt.figure(figsize=(9, 3.6))
plt.plot(plot_df["timestamp"], plot_df[y_col], label="Actual")
plt.plot(plot_df["timestamp"], yp, label="Predicted")
plt.title("Time Series: Actual vs Predicted")
plt.xlabel("Time"); plt.ylabel(y_col)
plt.legend(); plt.tight_layout()
sc_plot = plt.figure(figsize=(4.6, 3.8))
plt.scatter(y_test, y_pred_test, alpha=0.6)
mn = min(y_test.min(), y_pred_test.min()); mx = max(y_test.max(), y_pred_test.max())
plt.plot([mn, mx], [mn, mx], linestyle="--")
plt.title("Holdout: Actual vs Predicted")
plt.xlabel("Actual"); plt.ylabel("Predicted")
plt.tight_layout()
res = y_test - y_pred_test
resid_plot = plt.figure(figsize=(4.6, 3.6))
plt.hist(res, bins=30)
plt.title("Holdout Residuals (Actual βˆ’ Predicted)")
plt.xlabel("Residual"); plt.ylabel("Count")
plt.tight_layout()
fi_plot = None
if hasattr(model, "feature_importances_"):
importances = model.feature_importances_
fi = (pd.DataFrame({"feature": X.columns, "importance": importances})
.sort_values("importance", ascending=False).head(12))
fi_plot = plt.figure(figsize=(6.2, 3.8))
plt.barh(fi["feature"][::-1], fi["importance"][::-1])
plt.title("Top Feature Importances")
plt.tight_layout()
# Save predictions for download
out_df = df.copy()
out_df[f"{y_col}_pred"] = y_pred_all
tmp = tempfile.NamedTemporaryFile(delete=False, suffix=".csv")
out_df.to_csv(tmp.name, index=False)
# --------- Copy text (explainer + KPIs) ---------
explainer = (
"### 🧠 What this app does\n"
"This AI-driven dashboard learns the relationship between **server load**, **ambient temperature**, "
"**cooling efficiency**, and time features to **predict power usage**. "
"Use it to quantify drivers of energy consumption, monitor deviations, and surface optimization levers.\n\n"
"### πŸ”Ž Why it matters\n"
"- Reduces **OPEX** by forecasting and optimizing energy usage\n"
"- Identifies high-impact drivers (feature importance)\n"
"- Enables proactive actions (e.g., workload shaping, cooling set-point tuning)\n\n"
"### βš™οΈ How it works (high-level)\n"
"1) Cleans and engineers features (diurnal/weekly cycles, rolling stats, domain signals)\n"
"2) Trains a tree ensemble (Gradient Boosting or Random Forest)\n"
"3) Evaluates on a holdout split and produces predictions for the entire dataset\n"
"4) Visualizes time series, accuracy scatter, residuals, and top feature importance\n"
)
kpis = (
f"**Model:** {model_name}\n\n"
f"**Target:** {y_col}\n"
f"**Avg {y_col} (actual):** {avg_actual:,.2f}\n"
f"**Avg {y_col} (predicted):** {avg_pred:,.2f}\n"
f"**Rows:** {len(df):,}\n\n"
f"**Holdout MAE:** {mae:,.2f} | **RΒ²:** {r2:,.3f}"
)
# Sample preview table
preview = out_df.head(10)
return (
title,
explainer,
kpis,
preview,
ts_plot,
sc_plot,
resid_plot,
fi_plot,
tmp.name
)
except Exception as e:
err = f"❌ **Error:** {type(e).__name__}: {e}"
return (title, err, None, None, None, None, None, None, None)
# ---------- Gradio UI ----------
import gradio
gradio.close_all() # avoid port conflicts in Colab
with gr.Blocks(title="AI-Driven Data Center Energy Optimization") as demo:
gr.Markdown("## ⚑ AI-Driven Data Center Energy Optimization Dashboard")
with gr.Row():
fpath = gr.File(label="πŸ“ Upload Dataset (CSV)", file_types=[".csv"], type="filepath")
model_name = gr.Dropdown(
choices=["Gradient Boosting", "Random Forest"],
value="Gradient Boosting",
label="πŸ” Select Model"
)
run_btn = gr.Button("▢️ Run")
title_out = gr.Markdown()
explainer_out = gr.Markdown()
kpi_out = gr.Markdown()
table_out = gr.Dataframe(label="πŸ“‹ Sample (+ Predictions)", wrap=True, row_count=("fixed", 10))
gr.Markdown("### πŸ“ˆ Visual Insights")
ts_plot = gr.Plot(label="Time Series: Actual vs Predicted")
sc_plot = gr.Plot(label="Holdout: Actual vs Predicted")
resid_plot = gr.Plot(label="Residuals (Histogram)")
fi_plot = gr.Plot(label="Top Feature Importances")
dl = gr.File(label="πŸ“₯ Download Data (+ Predictions)")
run_btn.click(
fn=run_pipeline,
inputs=[fpath, model_name],
outputs=[title_out, explainer_out, kpi_out, table_out, ts_plot, sc_plot, resid_plot, fi_plot, dl]
)
demo.launch(share=True)