| name | load-testing |
| description | Load test a Databricks App to find its maximum QPS. Use when: (1) User says 'load test', 'benchmark', 'QPS', 'throughput', or 'performance test', (2) User wants to find how many queries per second their app can handle, (3) User wants to set up load testing scripts for their agent, (4) User wants to view load test results/dashboard. |
Load Testing Your Databricks App
Goal: Find the maximum QPS (queries per second) your Databricks App can support.
Before You Start — Gather Parameters
Before beginning, use the AskUserQuestion tool to collect the following from the user:
- Do they already have deployed apps to test, or do they need to set up new apps?
- Do they want to mock LLM calls? Mocking isolates infrastructure throughput from LLM latency — useful for capacity planning. Testing without mocks measures end-to-end performance.
- What compute sizes do they want to test? (Medium, Large, or both)
- How many worker configurations do they want to test? (e.g., 2, 4, 6, 8 workers)
- Do they have M2M OAuth credentials (service principal client_id/client_secret)? — Recommended for tests longer than ~30 minutes. If not, guide them to create one.
- What is their
DATABRICKS_HOST? (workspace URL)
Step 1: Set Up Load Testing Scripts
Create a load-test-scripts/ directory in the project with the following files. These scripts are framework-agnostic and work with any Databricks App.
Directory Structure
<project-root>/
agent_server/ # Existing agent code
load-test-scripts/ # Load testing scripts (create this)
run_load_test.py # Main CLI — orchestrates Locust tests
locustfile.py # Locust test definition (SSE streaming, TTFT tracking)
dashboard_template.py # Generates interactive HTML dashboard from results
.env.example # Template for env vars
load-test-runs/ # Test results (auto-created per run)
<run-name>/
dashboard.html # Interactive dashboard
test_config.json # Test parameters
<label>/ # Per-config Locust CSV results
Required Files
locustfile.py — Locust load test that:
- Sends
POST /invocations with {"input": [...], "stream": true} to the app
- Parses SSE stream (
data: {json} lines) and counts chunks until data: [DONE]
- Tracks TTFT (time to first
data: line) as a custom Locust metric
- Uses M2M OAuth token exchange (
client_credentials grant to {host}/oidc/v1/token) with auto-refresh
- Implements
StepRampShape — ramps users from step_size to max_users, holding each level for step_duration seconds
run_load_test.py — CLI orchestrator that:
- Accepts
--app-url (repeatable), --client-id, --client-secret, --max-users, --step-size, --step-duration, --run-name, --dashboard, --compute-size, --label flags
- Tests each app URL sequentially (isolated metrics per config)
- Refreshes OAuth token before each app
- Runs healthcheck + warmup before each test
- Saves results to
load-test-runs/<run-name>/<label>/
- Generates dashboard at the end if
--dashboard is passed
dashboard_template.py — Generates a self-contained HTML dashboard with Chart.js:
- KPI cards (best config, peak QPS, lowest latency, total requests)
- Bar charts: QPS by config (median + peak), latency (p50 + p95), TTFT, total requests
- QPS Ramp Progression: line charts with QPS/Latency/Failures tabs and a max-users slider
- Grouped by compute size (medium/large side-by-side)
- Full results table with peak QPS, users at peak, latency percentiles, failure rate
- Can be run standalone:
uv run dashboard_template.py ../load-test-runs/<run-name>/
Install Dependencies
The load testing scripts use their own pyproject.toml inside load-test-scripts/ to avoid polluting the agent's production dependencies.
[project]
name = "load-test-scripts"
version = "0.1.0"
requires-python = ">=3.10"
dependencies = [
"locust>=2.32,<2.40",
"urllib3<2.3",
"requests",
]
Then install from within the load-test-scripts/ directory:
cd load-test-scripts/
uv sync
Note: locust>=2.43 has a known RecursionError. Pin to <2.40 to avoid it.
Step 2 (Optional): Mock Your Agent for Load Testing
Mocking is optional — you can skip this step to test your real agent end-to-end (including LLM latency). However, mocking is useful for:
- Capacity planning — isolating Apps infrastructure throughput from LLM latency (which adds 1-30s per request)
- Cost savings — avoiding FMAPI/token usage during load tests
- Reproducibility — getting consistent measurements independent of LLM response variability
How to Mock
The mock timing is controlled by two environment variables (set in app.yaml or databricks.yml):
MOCK_CHUNK_DELAY_MS — delay between text chunks in milliseconds (default: 10)
MOCK_CHUNK_COUNT — number of text chunks per response (default: 80)
For OpenAI Agents SDK templates: Create a MockAsyncOpenAI client that replaces AsyncDatabricksOpenAI. It simulates tool call streaming (instant) and text response streaming (delayed chunks). A reference implementation is available at examples/mock_openai_client.py:
from agent_server.mock_openai_client import MockAsyncOpenAI
set_default_openai_client(MockAsyncOpenAI())
set_default_openai_api("chat_completions")
For LangGraph templates: Replace the ChatDatabricks model with a mock that returns pre-built AIMessage objects with tool calls and text content using configurable delays.
For custom agents: Wrap whatever external API calls you make (LLM, vector search, etc.) with mock implementations that return realistic response shapes.
Step 3: Deploy Load Testing Apps
Deploy multiple Databricks Apps with varying compute sizes and worker counts.
Recommended Test Matrix
| Compute Size | Workers | App Name |
|---|
| Medium | 2 | <your-app>-medium-w2 |
| Medium | 4 | <your-app>-medium-w4 |
| Medium | 6 | <your-app>-medium-w6 |
| Medium | 8 | <your-app>-medium-w8 |
| Large | 6 | <your-app>-large-w6 |
| Large | 8 | <your-app>-large-w8 |
| Large | 10 | <your-app>-large-w10 |
| Large | 12 | <your-app>-large-w12 |
Configuring Compute Size
Databricks CLI:
databricks apps create <app-name> --compute-size MEDIUM
databricks apps update <app-name> --compute-size LARGE
Databricks UI: Go to Compute > Apps > your app > Edit > Configure > Compute.
Configuring Worker Count
start-server (via AgentServer.run()) accepts a --workers flag directly. Pass the worker count in the command array using a DAB variable — no wrapper script needed:
variables:
app_name:
default: "my-agent-medium-w2"
workers:
default: "2"
resources:
apps:
load_test_app:
name: ${var.app_name}
source_code_path: .
config:
command: ["uv", "run", "start-server", "--workers", "${var.workers}"]
env:
- name: MOCK_CHUNK_DELAY_MS
value: "10"
- name: MOCK_CHUNK_COUNT
value: "80"
targets:
medium-w2:
default: true
variables:
app_name: "my-agent-medium-w2"
workers: "2"
large-w8:
variables:
app_name: "my-agent-large-w8"
workers: "8"
Deploying
databricks bundle deploy --target medium-w2
databricks bundle run load_test_app --target medium-w2
Verify apps are ACTIVE before proceeding:
databricks apps get <app-name> --output json | jq '{app_status, compute_status, url}'
Step 4: Run Load Tests
Authentication — M2M OAuth (Required for Long Tests)
Load tests can run for hours. U2M OAuth tokens expire and break your test mid-run. Use M2M (machine-to-machine) OAuth with a service principal instead.
export DATABRICKS_HOST=https://your-workspace.cloud.databricks.com
export DATABRICKS_CLIENT_ID=<your-client-id>
export DATABRICKS_CLIENT_SECRET=<your-client-secret>
Parameters Reference
| Parameter | Required | Default | Description |
|---|
--app-url | Yes | — | App URL(s) to test (repeatable) |
--client-id | Recommended | DATABRICKS_CLIENT_ID env | Service principal client ID |
--client-secret | Recommended | DATABRICKS_CLIENT_SECRET env | Service principal client secret |
--label | No | Auto-derived from URL | Human-readable label per app (repeatable) |
--compute-size | No | Auto-detected or medium | Compute size tag per app: medium, large (repeatable) |
--max-users | No | 300 | Maximum concurrent simulated users |
--step-size | No | 20 | Users added per ramp step |
--step-duration | No | 30 | Seconds per ramp step |
--spawn-rate | No | 20 | User spawn rate (users/sec) |
--run-name | No | <timestamp> | Name for this run — results saved to load-test-runs/<run-name>/ |
--dashboard | No | Off | Generate interactive HTML dashboard after tests |
Example Commands
cd load-test-scripts/
uv run run_load_test.py \
--app-url https://my-app.aws.databricksapps.com \
--client-id <ID> --client-secret <SECRET> \
--dashboard --run-name quick-test
uv run run_load_test.py \
--app-url https://my-app-medium-w2.aws.databricksapps.com \
--app-url https://my-app-medium-w4.aws.databricksapps.com \
--app-url https://my-app-large-w8.aws.databricksapps.com \
--app-url https://my-app-large-w10.aws.databricksapps.com \
--compute-size medium --compute-size medium \
--compute-size large --compute-size large \
--max-users 1000 --step-size 20 --step-duration 10 \
--dashboard --run-name overnight-sweep
for RUN in r1 r2 r3 r4 r5; do
uv run run_load_test.py \
--app-url ... \
--client-id <ID> --client-secret <SECRET> \
--max-users 1000 --step-size 20 --step-duration 10 \
--run-name my_test_${RUN} --dashboard || break
done
What Happens During a Run
- Healthcheck — verifies the app streams correctly (receives
[DONE])
- Warmup — sends sequential requests to warm up the app
- Ramp-to-saturation — steps up concurrent users every
step_duration seconds
- When QPS plateaus despite adding users, you've found the saturation point
Estimated Duration
(max_users / step_size) * step_duration seconds per app
- With defaults:
(300 / 20) * 30 = 15 steps * 30s = ~7.5 min per app
- For 4 apps: ~30 min per run
Step 5: View Results Dashboard
Opening the Dashboard
open load-test-runs/<run-name>/dashboard.html
Regenerating the Dashboard
cd load-test-scripts/
uv run dashboard_template.py ../load-test-runs/<run-name>/
What the Dashboard Shows
- KPI Cards — Best config (peak QPS), overall peak QPS, lowest latency, total requests
- QPS by Config — Grouped bars showing median QPS and peak QPS side-by-side
- Latency by Config — Grouped bars showing p50 and p95 latency
- TTFT by Config — Time to first token (p50 and p95)
- Total Requests Served — How many requests each config handled
- QPS Ramp Progression — Line charts with tabs for QPS, QPS (excl. failures), Latency, and Failures. Includes a max-users slider to zoom into lower concurrency ranges. Charts are grouped by compute size (medium/large).
- Full Results Table — All configs with peak QPS, users at peak, latency percentiles, and failure rate
- Load Test Parameters — Summary of test configuration for reproducibility
Interpreting Results
- Peak QPS — Maximum QPS at any ramp step. This is the throughput ceiling.
- Users at Peak — Concurrent users when peak QPS was achieved. More users beyond this doesn't help.
- Failure Rate — Should be 0% or very low. High rates mean the app is overloaded.
- QPS Ramp Chart — Look for where the line flattens. That's the saturation point.
Troubleshooting
| Issue | Solution |
|---|
| Auth token expired mid-test | Use M2M OAuth (--client-id/--client-secret) instead of static tokens |
| Healthcheck fails | Verify app is ACTIVE: databricks apps get <name> --output json |
| 0 QPS / no results | Check load-test-runs/<run-name>/<label>/locust_output.log for errors |
| Low QPS despite high user count | App is saturated — try more workers or larger compute |
| High failure rate | App is overloaded — reduce --max-users or increase workers/compute |
| Dashboard shows no ramp data | Ensure results_stats_history.csv exists in each result subdir |