forecast-operational-metrics
Acerca de
Esta habilidad pronostica métricas de infraestructura y aplicaciones como el uso de CPU y memoria utilizando Prophet o statsmodels para planificación de capacidad y optimización de costos. Permite visualizar predicciones en Grafana y alertas proactivas por agotamiento de recursos. Úsela al planificar adquisiciones de hardware, optimizar gastos en la nube o configurar políticas de escalado basadas en la carga pronosticada.
Instalación rápida
Claude Code
Recomendadonpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/forecast-operational-metricsCopia y pega este comando en Claude Code para instalar esta habilidad
Documentación
預營指
預來資用與系指以謀容與優費。
見 Extended Examples 備全設與模。
用
- 預基容求(CPU、記、碟、網)
- 為下季謀硬/雲資購
- 欲預費軌以優雲費
- 須依預載設先動擴策
- 預用者流以謀事
- 預庫存長以備份
- 估 API 用以設速限
入
- 必:歷時序指(最少 3-12 月)
- 必:指類(CPU、記、請求/秒、費等)
- 必:預域(前 N 日、週、或月)
- 可:已知來事(布、廣、假)
- 可:季信(日、週、年模)
- 可:外回歸(如廣費、用註冊)
行
一:設環境並載數
裝預庫並備時序數。
# Create virtual environment
python -m venv venv
source venv/bin/activate
# Install forecasting libraries
pip install prophet statsmodels pandas numpy
pip install plotly matplotlib seaborn
pip install prometheus-api-client influxdb-client
pip install grafana-api
以 MetricsLoader 載並備:
# forecasting/data_loader.py (abbreviated)
import pandas as pd
from datetime import datetime, timedelta
class MetricsLoader:
def load_from_prometheus(self, query: str, lookback_days: int = 90, step: str = "1h"):
"""Load historical metrics from Prometheus."""
# ... implementation (see EXAMPLES.md for complete code)
def resample_and_aggregate(self, df: pd.DataFrame, freq: str = "1H"):
"""Resample time series to regular intervals."""
# ... implementation (see EXAMPLES.md)
# Example usage
loader = MetricsLoader(prometheus_url="http://prometheus:9090")
df = loader.load_from_prometheus(
query='avg(rate(container_cpu_usage_seconds_total[5m]))',
lookback_days=90,
)
df_daily = loader.resample_and_aggregate(df, freq="1D")
全 MetricsLoader 實現見 EXAMPLES.md Step 1。
得:時序數以規隔載、缺值已填、備供預。
敗:數有隙→用前填或插值;確回期有足數(建 90+ 日);驗時戳時區一致;察偏歪預之離群(>5 sigma)。
二:施 Prophet 預
用 Facebook Prophet 自動察季並預。
# forecasting/prophet_forecaster.py (abbreviated)
from prophet import Prophet
class ProphetForecaster:
def __init__(self, growth: str = "linear", seasonality_mode: str = "multiplicative"):
self.growth = growth
self.prophet_params = {
"growth": growth,
"seasonality_mode": seasonality_mode,
# ... additional parameters (see EXAMPLES.md)
}
def fit(self, df: pd.DataFrame, regressors=None, holidays=None):
"""Train Prophet model on historical data."""
# ... implementation (see EXAMPLES.md)
def forecast(self, periods: int, freq: str = "D"):
"""Generate forecast for future periods."""
# ... implementation (see EXAMPLES.md)
# Example usage
forecaster = ProphetForecaster(growth="linear", seasonality_mode="multiplicative")
forecaster.fit(df_daily)
forecast = forecaster.forecast(periods=30, freq="D")
forecaster.plot_forecast(forecast, save_path="results/cpu_forecast.png")
全 ProphetForecaster 實現見 EXAMPLES.md Step 2。
得:前 30+ 日預含信區已生、季模於件圖捕、交驗 MAPE < 15%。
敗:預不實→試異長模(線對邏);季缺→調 seasonality_mode;準劣(<70% MAPE)→加歷數或外回歸,察數質議。
三:施 ARIMA/SARIMAX 預(替)
用 statsmodels 傳時序預。
# forecasting/arima_forecaster.py (abbreviated)
from statsmodels.tsa.statespace.sarimax import SARIMAX
class ARIMAForecaster:
def __init__(self, order: tuple = (1, 1, 1), seasonal_order: tuple = (1, 1, 1, 7)):
self.order = order
self.seasonal_order = seasonal_order
def fit(self, df: pd.DataFrame, exog=None):
"""Train SARIMAX model."""
series = df.set_index("timestamp")["value"]
self.model = SARIMAX(series, exog=exog, order=self.order, seasonal_order=self.seasonal_order)
self.fitted_model = self.model.fit(disp=False)
# ... implementation (see EXAMPLES.md)
def forecast(self, steps: int, exog_future=None):
"""Generate forecast for future periods."""
# ... implementation (see EXAMPLES.md)
# Auto-select parameters
best_order, best_seasonal = auto_arima(series, seasonal=True)
forecaster = ARIMAForecaster(order=best_order, seasonal_order=best_seasonal)
forecaster.fit(df_hourly)
forecast = forecaster.forecast(steps=168) # 7 days
全 ARIMAForecaster 實現與 auto_arima 函見 EXAMPLES.md Step 3。
得:ARIMA 模以最優參擬、預含信區生、診圖示白噪殘。
敗:模不收→簡參(減 p、q、P、Q);預軌誤→察差階(d、D);殘非白噪→加 AR/MA 項;確序長 >2x 季週。
四:識容門與警
析預以知資何時竭。
# forecasting/capacity_planning.py (abbreviated)
from datetime import datetime
class CapacityPlanner:
def __init__(self, capacity_limit: float, warning_threshold: float = 0.8):
self.capacity_limit = capacity_limit
self.warning_threshold = warning_threshold
def find_exhaustion_date(self, forecast: pd.DataFrame):
"""Find when forecast exceeds capacity limit."""
exceeded = forecast[forecast["yhat"] >= self.capacity_limit]
# ... implementation (see EXAMPLES.md)
def generate_capacity_report(self, forecast: pd.DataFrame):
"""Generate comprehensive capacity planning report."""
# ... implementation (see EXAMPLES.md)
# Example usage
planner = CapacityPlanner(capacity_limit=1000, warning_threshold=0.8)
report = planner.generate_capacity_report(forecast)
print(f"Warning Date: {report['warning_date']}")
print(f"Exhaustion Date: {report['exhaustion_date']}")
recommendation = planner.recommend_scaling_action(report)
全 CapacityPlanner 實現見 EXAMPLES.md Step 4。
得:報示容限達時、建含急度、長率已算。
敗:竭日不實→驗 capacity_limit 正;長率過高→察歷數離群;熟系考非線長模。
五:於 Grafana 視預
推預數於 Grafana 以實時監。
# forecasting/grafana_integration.py (abbreviated)
import requests
class GrafanaForecaster:
def __init__(self, grafana_url: str, api_key: str, dashboard_uid: str = None):
self.grafana_url = grafana_url.rstrip("/")
self.api_key = api_key
self.dashboard_uid = dashboard_uid
def create_annotation(self, text: str, tags: list, time: datetime = None):
"""Create annotation in Grafana for forecast events."""
# ... implementation (see EXAMPLES.md)
def create_capacity_alert_annotation(self, capacity_report: dict):
"""Create Grafana annotation for capacity warnings."""
# ... implementation (see EXAMPLES.md)
# Export to CSV for Grafana datasource
def export_forecast_to_csv(forecast: pd.DataFrame, output_path: str):
"""Export forecast in format compatible with Grafana CSV datasource."""
# ... implementation (see EXAMPLES.md)
# Example usage
grafana = GrafanaForecaster(
grafana_url="http://grafana:3000",
api_key="YOUR_API_KEY",
dashboard_uid="your-dashboard-uid",
)
grafana.create_capacity_alert_annotation(report)
export_forecast_to_csv(forecast, "grafana/forecasts/cpu_forecast.csv")
全 GrafanaForecaster 實現見 EXAMPLES.md Step 5。
得:預注現於 Grafana 儀表、容警見為直標、預數經 CSV 源可取。
敗:驗 Grafana API 鑰權正;察儀 UID 正;確注時戳為毫秒;與管合前以 curl 試 API。
六:自動生預
設表作常生預。
# forecasting/scheduler.py (abbreviated)
import schedule
import time
def generate_daily_forecast():
"""Generate forecast for all monitored metrics."""
logger.info("Starting daily forecast generation")
metrics_config = [
{"name": "cpu_usage", "query": "...", "capacity_limit": 0.8, "forecast_days": 30},
{"name": "memory_usage", "query": "...", "capacity_limit": 32, "forecast_days": 30},
{"name": "disk_usage", "query": "...", "capacity_limit": 500, "forecast_days": 90},
]
loader = MetricsLoader(prometheus_url="http://prometheus:9090")
for metric_config in metrics_config:
df = loader.load_from_prometheus(query=metric_config["query"], lookback_days=90)
forecaster = ProphetForecaster()
forecaster.fit(df)
forecast = forecaster.forecast(periods=metric_config["forecast_days"])
planner = CapacityPlanner(capacity_limit=metric_config["capacity_limit"])
report = planner.generate_capacity_report(forecast)
export_forecast_to_csv(forecast, f"grafana/forecasts/{metric_config['name']}_forecast.csv")
# ... (see EXAMPLES.md for complete implementation)
# Schedule daily at 2 AM
schedule.every().day.at("02:00").do(generate_daily_forecast)
while True:
schedule.run_pending()
time.sleep(60)
全表作實現見 EXAMPLES.md Step 6。
得:諸指預日生、容報已記、CSV 為 Grafana 出、要容警已發。
敗:驗表作續運(用 systemd/supervisor);察 Prometheus 連;確碟足空為預出;施暫敗重試;設監於表作本身。
驗
- 歷數含 90+ 日續指已載
- Prophet 預於件圖捕日/週季
- 預信區於驗含 85-95% 實值
- 已知景之容竭日算正
- ARIMA 模殘於診圖似白噪
- Grafana 注現於預警/竭日
- 自動預日運無須人干
- 預準(MAPE)於驗集 <15%
忌
- 歷數不足:3-12 月方可信季察;<60 日勿預
- 忽已知事:假、布、廣歪預;加為外回歸或假
- 長期預過信:>30-90 日準降;為向導非精預
- 容限靜:基設隨時變;加資源時更 capacity_limit
- 異常預:訓數離群傳於預;清數或用穩法
- 不更模:系變後預舊;週重訓或大架變後重訓
- 忽信區:點預誤導;謀恒用上下界
- 錯季週:時數用日、日數用週;錯致預劣
參
detect-anomalies-aiops- 異察補預供先動監plan-capacity- 基容謀流build-grafana-dashboards- 視預與容軌
Repositorio GitHub
Frequently asked questions
What is the forecast-operational-metrics skill?
forecast-operational-metrics is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform forecast-operational-metrics-related tasks without extra prompting.
How do I install forecast-operational-metrics?
Use the install commands on this page: add forecast-operational-metrics to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does forecast-operational-metrics belong to?
forecast-operational-metrics is in the Design category, tagged design.
Is forecast-operational-metrics free to use?
Yes. forecast-operational-metrics is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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