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plan-capacity

pjt222
Updated 2 days ago
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Otherai

About

This skill performs capacity planning using historical metrics and growth models to forecast resource needs with `predict_linear`. It identifies bottlenecks, calculates headroom, and recommends scaling actions to prevent saturation. Use it before traffic spikes, product launches, during quarterly reviews, or when observing rising utilization trends.

Quick Install

Claude Code

Recommended
Primary
npx skills add pjt222/agent-almanac -a claude-code
Plugin CommandAlternative
/plugin add https://github.com/pjt222/agent-almanac
Git CloneAlternative
git clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/plan-capacity

Copy and paste this command in Claude Code to install this skill

Documentation

name: plan-capacity description: > Kapazitaetsplanung anhand historischer Metriken und Wachstumsmodelle durchfuehren. predict_linear fuer Prognosen verwenden, Ressourcenengpaesse identifizieren, Spielraum berechnen und Skalierungsmassnahmen empfehlen, bevor Saettigung eintritt. Verwenden, vor saisonalen Traffic-Spitzen oder Produktlaunches, waehrend vierteljaehrlicher Kapazitaets- reviews, wenn Ressourcenauslastungstrends aufwaerts zeigen oder vor Budget-Planungszyklen. locale: de source_locale: en source_commit: 6f65f316 translator: claude-opus-4-6 translation_date: 2026-03-16 license: MIT allowed-tools: Read Write Edit Bash Grep Glob metadata: author: Philipp Thoss version: "1.0" domain: observability complexity: intermediate language: multi tags: capacity-planning, forecasting, predict-linear, growth, headroom

Kapazitaet planen

Ressourcenbedarf prognostizieren und Saettigung durch datengetriebene Kapazitaetsplanung vermeiden.

Wann verwenden

  • Vor saisonalen Traffic-Spitzen (Feiertage, Verkaufsereignisse)
  • Bei der Planung neuer Feature-Launches
  • Waehrend vierteljaehrlicher Kapazitaets-Reviews
  • Wenn Ressourcenauslastungstrends aufwaerts zeigen
  • Vor Budget-Planungszyklen

Eingaben

  • Pflichtfeld: Historische Metriken (CPU, Arbeitsspeicher, Festplatte, Netzwerk, Anfragen/Sek.)
  • Pflichtfeld: Zeitbereich fuer Trendanalyse (mindestens 4 Wochen)
  • Optional: Geschaeftliche Wachstumsprognosen (erwartetes Nutzerwachstum, Feature-Launches)
  • Optional: Budgeteinschraenkungen

Vorgehensweise

Schritt 1: Historische Metriken sammeln

Schluessel-Ressourcenmetriken aus Prometheus abfragen:

# CPU usage trend over 8 weeks
avg(rate(node_cpu_seconds_total{mode!="idle"}[5m])) by (instance)

# Memory usage trend
avg(node_memory_MemTotal_bytes - node_memory_MemAvailable_bytes) by (instance)

# Disk usage growth
avg(node_filesystem_size_bytes - node_filesystem_free_bytes) by (instance, device)

# Request rate growth
sum(rate(http_requests_total[5m])) by (service)

# Database connection pool usage
avg(db_connection_pool_used / db_connection_pool_max) by (instance)

Zur Analyse exportieren:

# Export 8 weeks of CPU data
curl -G 'http://prometheus:9090/api/v1/query_range' \
  --data-urlencode 'query=avg(rate(node_cpu_seconds_total{mode!="idle"}[5m])) by (instance)' \
  --data-urlencode 'start=2024-12-15T00:00:00Z' \
  --data-urlencode 'end=2025-02-09T00:00:00Z' \
  --data-urlencode 'step=1h' | jq '.data.result' > cpu_8weeks.json

Erwartet: Saubere Zeitreihendaten fuer jede Ressource ohne grosse Luecken.

Bei Fehler: Fehlende Daten reduzieren die Prognosegenauigkeit. Metrik-Aufbewahrung und Scrape-Intervalle pruefen.

Schritt 2: Wachstumsraten mit predict_linear berechnen

Prometheus's predict_linear() verwenden, um Saettigung zu prognostizieren:

# Predict when CPU will hit 80% (4 weeks ahead)
predict_linear(
  avg(rate(node_cpu_seconds_total{mode!="idle"}[5m]))[8w:],
  4*7*24*3600  # 4 weeks in seconds
) > 0.80

# Predict disk full date (8 weeks ahead)
predict_linear(
  avg(node_filesystem_size_bytes - node_filesystem_free_bytes)[8w:],
  8*7*24*3600
) > 0.95 * avg(node_filesystem_size_bytes)

# Predict memory pressure (2 weeks ahead)
predict_linear(
  avg(node_memory_MemTotal_bytes - node_memory_MemAvailable_bytes)[8w:],
  2*7*24*3600
) / avg(node_memory_MemTotal_bytes) > 0.90

# Predict request rate capacity breach (4 weeks ahead)
predict_linear(
  sum(rate(http_requests_total[5m]))[8w:],
  4*7*24*3600
) > 10000  # known capacity limit

Ein Prognose-Dashboard erstellen:

{
  "dashboard": {
    "title": "Capacity Forecast",
    "panels": [
      {
        "title": "CPU Saturation Forecast (4 weeks)",
        "targets": [
          {
            "expr": "predict_linear(avg(rate(node_cpu_seconds_total{mode!=\"idle\"}[5m]))[8w:], 4*7*24*3600)",
            "legendFormat": "Predicted CPU"
          },
          {
            "expr": "0.80",
            "legendFormat": "Target Threshold (80%)"
          }
        ]
      },
      {
        "title": "Disk Full Date",
        "targets": [
          {
            "expr": "(avg(node_filesystem_size_bytes) - predict_linear(avg(node_filesystem_free_bytes)[8w:], 8*7*24*3600)) / avg(node_filesystem_size_bytes)",
            "legendFormat": "Predicted Usage %"
          }
        ]
      }
    ]
  }
}

Erwartet: Klare Visualisierung, die zeigt, wann Ressourcen Schwellenwerte ueberschreiten werden.

Bei Fehler: Wenn Prognosen falsch aussehen (negative Werte, wilde Schwankungen), auf folgendes pruefen:

  • Unzureichende Historie (mindestens 4 Wochen erforderlich)
  • Stufenfoermige Spitzen (Deployments, Migrationen) verzerren den Trend
  • Saisonale Muster, die das lineare Modell nicht erfasst

Schritt 3: Aktuellen Spielraum berechnen

Sicherheitsspanne vor der Saettigung bestimmen:

# CPU headroom (percentage remaining before 80% threshold)
(0.80 - avg(rate(node_cpu_seconds_total{mode!="idle"}[5m]))) / 0.80 * 100

# Memory headroom (bytes remaining before 90% usage)
avg(node_memory_MemAvailable_bytes) - (avg(node_memory_MemTotal_bytes) * 0.10)

# Request rate headroom (requests/sec before saturation)
10000 - sum(rate(http_requests_total[5m]))

# Time until saturation (weeks until CPU hits 80%)
(0.80 - avg(rate(node_cpu_seconds_total{mode!="idle"}[5m]))) /
  deriv(avg(rate(node_cpu_seconds_total{mode!="idle"}[5m]))[8w:]) /
  (7*24*3600)

Einen Spielraum-Zusammenfassungsbericht erstellen:

cat > capacity_headroom.md <<'EOF'
# Capacity Headroom Report (2025-02-09)

## Current Utilization
- **CPU**: 45% average (target: <80%)
- **Memory**: 62% (target: <90%)
- **Disk**: 71% (target: <95%)
- **Request Rate**: 4,200 req/s (capacity: 10,000)

## Headroom Analysis
- **CPU**: 35% headroom → ~12 weeks until saturation
- **Memory**: 28% headroom → ~16 weeks until saturation
- **Disk**: 24% headroom → ~8 weeks until full
- **Request Rate**: 5,800 req/s headroom → ~20 weeks until capacity

## Priority Actions
1. **Disk**: Implement log rotation or expand volume within 4 weeks
2. **CPU**: Plan horizontal scaling in next quarter
3. **Memory**: Monitor but no immediate action needed
EOF

Erwartet: Quantifizierter Spielraum fuer jede Ressource mit Zeitschatzungen bis zur Saettigung.

Bei Fehler: Wenn der Spielraum bereits negativ ist, befindet man sich im reaktiven Modus. Sofortige Skalierung erforderlich.

Schritt 4: Wachstumsszenarien modellieren

Geschaeftliche Prognosen einbeziehen:

# Example Python script for scenario modeling
import pandas as pd
import numpy as np

# Load historical data
df = pd.read_json('cpu_8weeks.json')

# Calculate weekly growth rate
growth_rate_weekly = df['value'].pct_change(periods=7).mean()

# Scenario 1: Current trend
weeks_ahead = 12
current_trend = df['value'].iloc[-1] * (1 + growth_rate_weekly) ** weeks_ahead

# Scenario 2: 2x user growth (marketing campaign)
accelerated_trend = df['value'].iloc[-1] * (1 + growth_rate_weekly * 2) ** weeks_ahead

# Scenario 3: New feature launch (+30% baseline)
feature_launch = (df['value'].iloc[-1] * 1.30) * (1 + growth_rate_weekly) ** weeks_ahead

print(f"Current Trend (12 weeks): {current_trend:.1%} CPU")
print(f"2x Growth Scenario: {accelerated_trend:.1%} CPU")
print(f"Feature Launch Scenario: {feature_launch:.1%} CPU")
print(f"Threshold: 80%")

Erwartet: Mehrere Szenarien zeigen die Auswirkungen von Geschaeftsaenderungen auf die Kapazitaet.

Bei Fehler: Wenn Szenarien die Kapazitaet ueberschreiten, Skalierung vor dem Ereignis priorisieren.

Schritt 5: Skalierungsempfehlungen generieren

Handlungsorientierte Empfehlungen erstellen:

## Capacity Scaling Plan

### Immediate Actions (Next 4 Weeks)
1. **Disk Expansion** [Priority: HIGH]
   - Current: 500GB, 71% used
   - Projected full date: 2025-04-01 (8 weeks)
   - Action: Expand to 1TB by 2025-03-15
   - Cost: $50/month additional
   - Justification: 5 weeks lead time needed

2. **Log Rotation Policy** [Priority: MEDIUM]
   - Current: Logs retained 90 days
   - Action: Reduce to 30 days, archive to S3
   - Savings: ~150GB disk space
   - Cost: $5/month S3 storage

### Near-Term Actions (Next Quarter)
3. **Horizontal Scaling - API Tier** [Priority: MEDIUM]
   - Current: 4 instances, 45% CPU
   - Projected: 65% CPU by 2025-05-01
   - Action: Add 2 instances (to 6 total)
   - Cost: $400/month
   - Trigger: When CPU avg exceeds 60% for 7 days

4. **Database Connection Pool** [Priority: LOW]
   - Current: 50 max connections, 40% used
   - Projected: 55% by Q3
   - Action: Increase to 75 in Q2
   - Cost: None (configuration change)

### Long-Term Planning (Next 6 Months)
5. **Migration to Auto-Scaling** [Priority: MEDIUM]
   - Current: Manual scaling
   - Action: Implement Kubernetes HPA (Horizontal Pod Autoscaler)
   - Timeline: Q3 2025
   - Benefit: Automatic response to load spikes

Erwartet: Priorisierte Liste mit Kosten, Zeitplaenen und Ausloesebedingungen.

Bei Fehler: Wenn Empfehlungen wegen Kosten abgelehnt werden, Schwellenwerte ueberarbeiten oder Risiko akzeptieren.

Schritt 6: Kapazitaets-Alerts einrichten

Alerts fuer geringen Spielraum erstellen:

# capacity_alerts.yml
groups:
  - name: capacity
    interval: 1h
    rules:
      - alert: CPUCapacityLow
        expr: |
          (0.80 - avg(rate(node_cpu_seconds_total{mode!="idle"}[5m]))) / 0.80 < 0.20
        for: 24h
        labels:
          severity: warning
        annotations:
          summary: "CPU headroom below 20%"
          description: "Current CPU headroom: {{ $value | humanizePercentage }}. Scaling needed within 4 weeks."

      - alert: DiskFillForecast
        expr: |
          predict_linear(avg(node_filesystem_free_bytes)[8w:], 4*7*24*3600) < 0.10 * avg(node_filesystem_size_bytes)
        for: 1h
        labels:
          severity: warning
        annotations:
          summary: "Disk projected to fill within 4 weeks"
          description: "Expand disk volume soon."

      - alert: MemoryCapacityLow
        expr: |
          avg(node_memory_MemAvailable_bytes) < 0.15 * avg(node_memory_MemTotal_bytes)
        for: 6h
        labels:
          severity: warning
        annotations:
          summary: "Memory headroom below 15%"

Erwartet: Alerts loesen vor der Saettigung aus und geben Zeit fuer proaktive Skalierung.

Bei Fehler: Schwellenwerte anpassen, wenn Alerts zu oft auslosen (Alert-Ueberlastung) oder zu spaet (reaktives Handeln).

Validierung

  • Historische Metriken decken mindestens 8 Wochen ab
  • predict_linear()-Abfragen liefern sinnvolle Prognosen (keine negativen Werte)
  • Spielraum fuer alle kritischen Ressourcen berechnet
  • Wachstumsszenarien enthalten geschaeftliche Prognosen
  • Skalierungsempfehlungen haben Kosten und Zeitplaene
  • Kapazitaets-Alerts konfiguriert und getestet
  • Bericht mit Ingenieurleitung und Finanzen besprochen

Haeufige Stolperfallen

  • Unzureichende Historie: Lineare Prognosen benoetigen mindestens 4 Wochen Daten. Weniger davon macht Prognosen unzuverlaessig.
  • Stufenfoermige Aenderungen ignorieren: Deployments, Migrationen oder Feature-Launches verzerren Trends. Filtern oder annotieren.
  • Lineare Annahme: Nicht alles Wachstum ist linear. Exponentielles Wachstum (virale Produkte) erfordert andere Modelle.
  • Vorlaufzeit vergessen: Cloud-Provisioning ist schnell, aber Beschaffung, Budgets und Migrationen dauern Wochen. Fruehzeitig planen.
  • Keine Budget-Abstimmung: Kapazitaetsplanung ohne Budget-Zustimmung fuehrt zu Last-Minute-Hektik. Finanzen fruehzeitig einbeziehen.

Verwandte Skills

  • setup-prometheus-monitoring - Metriken fuer die Kapazitaetsplanung sammeln
  • build-grafana-dashboards - Prognosen und Spielraum visualisieren
  • optimize-cloud-costs - Kapazitaetsplanung mit Kostenoptimierung ausbalancieren

GitHub Repository

pjt222/agent-almanac
Path: i18n/de/skills/plan-capacity
0
agentsagentskillsai-assisted-developmentclaude-codeskillsteams

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