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gke-inference

Deploys and optimizes AI/ML inference workloads on GKE, using GPUs, TPUs, and model servers. Use when deploying GKE inference servers, configuring GKE GPU resources for inference, or deploying LLMs on GKE. Don't use for generic batch jobs or HPC task queues (use gke-batch-hpc instead).

How do I install this agent skill?

npx skills add https://github.com/google/skills --skill gke-inference
view source ↗

Is this agent skill safe to install?

  • Gen Agent Trust Hubpass

    This skill provides guidance for deploying and optimizing AI inference workloads on Google Kubernetes Engine (GKE). It utilizes official gcloud and kubectl tools to manage infrastructure and follows security best practices for handling sensitive credentials.

  • Socketpass

    No alerts

  • Snykpass

    Risk: LOW · No issues

What does this agent skill do?

GKE AI/ML Inference

This reference covers deploying AI/ML inference workloads on GKE using Google's Inference Quickstart (GIQ) and best practices for LLM serving.

MCP Tools: apply_k8s_manifest, get_k8s_resource, get_k8s_logs, get_k8s_rollout_status, describe_k8s_resource, list_k8s_events. CLI-only: gcloud container ai profiles *

When to Use

  • Deploy an AI model (Llama, Gemma, Mistral, etc.) to GKE
  • Generate optimized Kubernetes manifests for inference
  • Select GPU/TPU accelerators for model serving
  • Configure autoscaling for LLM inference

Prerequisites

  • A golden path GKE Autopilot cluster (GPU workloads are supported via ComputeClasses and NAP)
  • gcloud CLI authenticated
  • Sufficient GPU/TPU quota in the target region

Workflow

1. Discovery: Find Models and Hardware

# List all supported models
gcloud container ai profiles models list --quiet

# Find valid accelerator/server combinations for a model
gcloud container ai profiles list --model=<MODEL_NAME> --quiet

# Example: what can run Gemma 2 9B?
gcloud container ai profiles list --model=gemma-2-9b-it --quiet

2. Generate Manifest

gcloud container ai profiles manifests create \
  --model=<MODEL_NAME> \
  --model-server=<SERVER> \
  --accelerator-type=<ACCELERATOR> \
  --target-ntpot-milliseconds=<NTPOT> --quiet > inference.yaml

Parameters:

  • --model: Model ID (e.g., gemma-2-9b-it, llama-3-8b)
  • --model-server: Inference server (vllm, tgi, triton, tensorrt-llm)
  • --accelerator-type: GPU/TPU type (nvidia-l4, nvidia-tesla-a100, nvidia-h100-80gb)
  • --target-ntpot-milliseconds: Target Normalized Time Per Output Token (optional, for latency optimization)

Example:

gcloud container ai profiles manifests create \
  --model=gemma-2-9b-it \
  --model-server=vllm \
  --accelerator-type=nvidia-l4 \
  --target-ntpot-milliseconds=50 --quiet > inference.yaml

3. Review and Deploy

# Review for placeholders (HF tokens, PVCs)
cat inference.yaml

# Deploy
kubectl apply -f inference.yaml

# Monitor
kubectl get pods -w
kubectl logs -f <POD_NAME>

Some models require Hugging Face tokens. Create a Kubernetes Secret and reference it in the manifest.

GPU ComputeClass for Inference

For Autopilot clusters, create a ComputeClass to target GPU nodes:

apiVersion: cloud.google.com/v1
kind: ComputeClass
metadata:
  name: l4-inference
spec:
  priorities:
  - machineFamily: g2
    gpu:
      type: nvidia-l4
      count: 1
    minCores: 4
    minMemoryGb: 16

Accelerator Selection Guide

AcceleratorBest ForMemoryRelative Cost
NVIDIA T4Budget inference,16 GBLowest
: : lightweight legacy : : :
: : models : : :
NVIDIA L4 (G2)Small-medium model24 GBLow
: : inference, video, : : :
: : graphics : : :
NVIDIA RTX PRO 6000Multimodal AI,96 GBMedium
: (G4) : high-fidelity 3D, : : :
: : fine-tuning : : :
Cloud TPU v5eCost-effectiveVariesMedium
: : transformer inference : : :
Cloud TPU v5pHigh-performanceVariesHigh
: : training : : :
Cloud TPU v6eHigh-efficiency next-gen32 GB/chipMedium-High
: (Trillium) : training & serving : : :
Cloud TPU v7xUltra-scale inference &192 GB/chipHigh
: (Ironwood) : agentic workflows : : :
NVIDIA A100Large model inference,40/80 GBHigh
: : enterprise ML : : :
NVIDIA H100 / H200Frontier model training,80/141 GBHighest
: : high throughput : : :
NVIDIA B200 (A4)Blackwell-scale192 GBHighest
: : training, FP4 precision : : :
NVIDIA GB200 (A4X)Rack-scale AI (GraceMassiveHighest
: : Blackwell Superchip) : : :

Autoscaling LLM Inference

GPU-based autoscaling

Use custom metrics for GPU utilization:

apiVersion: autoscaling/v2
kind: HorizontalPodAutoscaler
metadata:
  name: llm-hpa
spec:
  scaleTargetRef:
    apiVersion: apps/v1
    kind: Deployment
    name: llm-server
  minReplicas: 1
  maxReplicas: 10
  metrics:
  - type: Pods
    pods:
      metric:
        name: gpu_duty_cycle
      target:
        type: AverageValue
        averageValue: "80"

Best practices for inference autoscaling

  1. Use DCGM metrics: Golden path enables DCGM monitoring for GPU utilization metrics
  2. Set appropriate minReplicas: At least 1 for always-on serving; 0 for batch/on-demand
  3. Tune scale-down delay: LLM model loading is slow; use longer stabilization windows
  4. Consider queue depth: Scale on pending requests rather than pure GPU utilization for latency-sensitive workloads

Optimization Tips

  • Quantization: Use quantized models (GPTQ, AWQ) to reduce GPU memory and increase throughput
  • Batching: Configure model server batch size for throughput vs latency trade-off
  • Tensor parallelism: Split large models across multiple GPUs within a node
  • KV cache optimization: Tune --gpu-memory-utilization in vLLM for KV cache allocation

Troubleshooting

IssueCauseFix
InvalidUnsupported tupleRe-run `gcloud container ai
: model/accelerator : : profiles list :
: combination : : --model=<MODEL>` :
GPU quota exceededRegional quota limitRequest quota increase or
: : : try a different region :
OOM on GPUModel too large forUse larger GPU, enable
: : accelerator : quantization, or use tensor :
: : : parallelism :
Slow cold startLarge model loading fromUse local SSD for model
: : registry : caching; pre-pull images :

Add the canonical catalog link to the repository README so users can inspect current installs and available audits. The publishing guide covers the complete discovery path.

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