| name | deepstream-generate-pipeline |
| description | Build DeepStream GStreamer pipelines interactively. Use when the user asks about pipelines for video/image inference, detection, tracking, or streaming — including natural phrases like 'pipeline to infer on image', 'run inference on video', 'detect objects in stream', 'save inference output', 'deepstream pipeline', 'gst-launch pipeline', 'process video with detection', 'build a pipeline', or any request involving GStreamer/DeepStream elements (nvinfer, nvstreammux, nvtracker, etc.). |
| owner | NVIDIA CORPORATION |
| service | deepstream |
| version | 1.0.0 |
| reviewed | "2026-04-27T00:00:00.000Z" |
| license | CC-BY-4.0 AND Apache-2.0 |
DeepStream Pipeline Builder
Generate ready-to-run gst-launch-1.0 pipelines for NVIDIA DeepStream SDK by collecting pipeline requirements through an interactive questionnaire, then assembling the pipeline using a standalone BM25 retrieval backend with structural metadata boosting (similarity search over 270+ verified pipelines, zero external dependencies).
Prerequisites
- Python: 3.8+ (stdlib only — no pip packages required)
- DeepStream SDK: Installed at
/opt/nvidia/deepstream/deepstream/ (for gst-inspect-1.0 validation and element verification)
- GStreamer:
gst-launch-1.0 and gst-inspect-1.0 on PATH (installed with DeepStream)
- Platform: x86 dGPU (T4, A100, L40, RTX, etc.) or aarch64 — Jetson (Orin, Xavier, Nano) / SBSA (Grace, GH200)
Usage Examples
# Fully specified — skips most questions
detect and track on 4 rtsp streams and display on jetson
# Partially specified — asks remaining questions
give me a pipeline to infer on an image
# Minimal — asks all 7 questions
build a pipeline
Supported Configurations
| Parameter | Options |
|---|
| Input | Local video (.mp4/.h264/.h265), local image (.jpg/.png), RTSP stream, USB camera, test pattern |
| Inference | None, primary (nvinfer), primary+secondary, with preprocessor, Triton (nvinferserver) |
| Tracker | None, NvDCF, IOU, NvSORT, DeepSORT |
| Sink | Display (dGPU/Jetson), save (JPG/PNG/MP4/H264), RTSP out, fakesink |
| Platform | x86 dGPU (T4, A100, L40, RTX, etc.) or aarch64 — Jetson (Orin, Xavier, Nano) / SBSA (Grace, GH200) |
| Extras | Resize, rotate/flip, crop, color format conversion |
Scripts
| Script | Purpose |
|---|
scripts/generate_pipeline.py | BM25 retrieval engine — scores and ranks pipelines from data/data.csv. Supports --format {json,compact,summary} (default json) |
scripts/validate_pipeline.py | 4-stage validator: syntax, elements, properties, live parse. Supports --format {json,summary} (default json) |
scripts/lint_data.py | Data quality linter for the pipeline CSV (--fix to auto-repair) |
Workflow
Step 1 — Collect Pipeline Requirements
You MUST Read references/requirement-extraction.md before doing this step.
It contains the query-inference table, compound-extraction examples, the full
AskUserQuestion question bank (with the default-first ordering contract), the
automatic-OSD and extras/flip-method rules, and the dynamic question-reduction
examples that this step depends on. Apply them exactly.
Order of operations:
- Infer everything you can from the query using the inference table in
references/requirement-extraction.md. The goal is to identify which of the 7 parameters (input source, num sources, inference, tracker, sink, platform, extras) the user has already specified.
- Ask the user about the unknowns via
AskUserQuestion in a single call. Do not silently default tracker/sink/platform/extras — these are real choices the user should make explicitly (display vs save, no tracker vs NvDCF, x86 dGPU vs aarch64 Jetson/SBSA, etc.). Skip only the questions whose answer is already clear from the query.
- Quote the inferred parameters back to the user in the lead-in to the question call so they can see what you already extracted. Example: "From your query I have: 3 mp4 videos, primary inference. Just need a few more details:"
Follow the inference table, question bank, and OSD/extras rules in
references/requirement-extraction.md to decide which questions to ask and how to
place transform elements, then proceed to Step 2.
Step 2 — Build the Natural Language Query
From the user's answers, construct a single descriptive query string. Follow this pattern:
Please provide a GStreamer pipeline that [operation] on [num_sources] [input_type] [input_detail] [tracker_detail] and [output_action] [platform_detail]
Examples of constructed queries:
| User Selections | Constructed Query |
|---|
| Local video, 1 source, Primary detector, No tracker, Display, dGPU | "Please provide a GStreamer pipeline that performs primary inference on a single mp4 video and displays the output" |
| RTSP, 4 sources, Primary+Secondary, NvDCF, Save MP4, dGPU | "Please provide a GStreamer pipeline that performs primary and secondary inference with NvDCF tracker on 4 RTSP streams and saves output to MP4 file" |
| Local video, 2 sources, Primary with preprocessor, IOU, Display, Jetson | "Please provide a GStreamer pipeline that performs preprocessing before primary inference with IOU tracker on 2 mp4 streams and displays the output on Jetson" |
| Local image, 1 source, None, No tracker, Save file, dGPU, Rotate 90° cw | "Please provide a GStreamer pipeline that rotates a single jpg image 90° clockwise before processing and saves it to a file" |
| Local video, 3 sources, Primary detector, NvDCF, Save MP4, dGPU, Rotate 180° | "Please provide a GStreamer pipeline that rotates 3 mp4 videos 180° before primary inference with NvDCF tracker and saves output to MP4 file" |
Step 3 — Run the Pipeline Generator Script
Execute the backend script with the constructed query and user parameters:
python3 <skill-path>/scripts/generate_pipeline.py \
--query "<constructed_query>" \
--source-type "<Local video file|Local image file|RTSP stream|USB camera|Test pattern>" \
--num-sources <N> \
--inference "<None|primary|primary+secondary|primary+preprocess|primary+secondary+preprocess|primary-triton|primary+secondary-triton>" \
--tracker "<none|NvDCF|IOU|NvSORT|DeepSORT>" \
--sink "<display|display-jetson|save-jpg|save-png|save-mp4|save-h264|rtsp-out|fakesink>" \
--platform "<dGPU|Jetson|SBSA>" \
--extras "<none|resize|rotate|crop|color-convert|osd>" \
--format compact
Always pass --format compact. The compact mode returns only confidence + the top retrieved pipeline (~25 lines), instead of dumping all 10 retrievals as ~150 lines of JSON in the chat. The json mode (default for backward compat) is only useful when debugging the retriever directly. A summary mode (single human-readable line) also exists for non-Claude callers.
The script will (zero external dependencies — pure Python stdlib):
- Load the pipeline dataset (270+ verified DeepStream pipelines)
- Extract structural metadata from each pipeline (platform, source type, sink type, inference mode, tracker, stream count)
- Score with BM25 (document-length-normalized) + domain-specific synonym expansion on both queries and documents
- Apply structural boosting — results matching the user's platform/source/sink/inference get boosted, mismatches get penalized
- Return the top-K results as JSON with a
confidence field (high/medium/low) based on the top score
- Claude uses these retrieved examples + the assembly rules below to construct the final pipeline
When confidence is low, rely more heavily on the assembly rules below rather than the retrieved examples.
Step 4 — Validate the Pipeline
Before presenting, run the validation script to catch syntax errors, unknown elements, and linking issues:
python3 <skill-path>/scripts/validate_pipeline.py "<assembled_pipeline>" --format summary
Always pass --format summary. Summary prints a single status line (e.g. valid · 11 elements · 0 warnings · live-parse skipped (multi-stream)), with errors/warnings indented underneath only if present. The default json mode emits ~40 lines of structured output and is only useful for programmatic callers.
The validator performs 4 checks:
- Syntax check — unbalanced quotes, empty pipe segments, missing source/sink
- Element check — verifies each element exists via
gst-inspect-1.0
- Property check — validates known properties for DeepStream elements
- Live parse check — uses
gst-launch-1.0 itself to construct the pipeline graph (with fakesrc/fakesink substituted), catching linking errors and pad mismatches. Automatically skipped for multi-stream pipelines (those with named pad refs like m.sink_0) since fakesrc cannot negotiate caps through named pads.
If validation fails ("valid": false), fix the errors and re-validate before presenting. Limit validation retries to a maximum of 2 attempts — if the pipeline still fails after 2 fixes, present it as-is (the remaining checks already cover syntax, element, property, and structural correctness). If there are only warnings, present the pipeline but mention the warnings to the user.
Step 5 — Present the Pipeline
5.1 — Output format (THE ONLY ACCEPTED FORM)
Your response must be exactly five blocks, in this order:
- One-line status badge (validation + confidence)
- Single bash code block containing the full
gst-launch-1.0 -e … command with concrete absolute paths, on one line (no \ continuations, no shell variables, no shell wrapper)
- Breakdown table grouped by stage
- Suggestions bullet list
- (only if pre-flight failed) a
⚠ line above the status badge stating which default path is missing
That is the ONLY accepted output shape for this step. The Section 5.3 template in references/output-format.md is the literal template — match it.
5.2 — Pre-flight check (run before composing the response)
Run one Bash ls over the default paths the pipeline will reference (sample video, PGIE config, tracker lib/config). The result tells you whether to mark the badge with ⚠ default path not found: <path> and bump the matching "Use your own …" suggestion to the top.
ls /opt/nvidia/deepstream/deepstream/samples/streams/sample_1080p_h264.mp4 \
/opt/nvidia/deepstream/deepstream/samples/configs/deepstream-app/config_infer_primary.txt \
2>&1
5.3 / 5.4 — Worked example & forbidden anti-patterns
You MUST Read references/output-format.md before composing this response. It contains the literal Section 5.3 template your output must match exactly, and the Section 5.4 gallery of forbidden output shapes (heredoc wrappers, shell-var indirection, \ line-continuations, stray "Run it" lines, Write-to-script). Mirror Section 5.3; never emit any Section 5.4 form.
5.5 — Self-check before sending the response
Before you emit your reply, mentally tick each box. If any check fails, rewrite the response.
5.6 — Pre-flight failure variant
If the Section 5.2 ls reported one or more missing default paths, prepend a ⚠ line above the status badge and bump the matching "Use your own …" suggestion to the top:
⚠ default path not found: `/opt/nvidia/deepstream/deepstream/samples/streams/sample_1080p_h264.mp4` — substitute your own video path before running
✓ Validated · 11 elements · 0 warnings · confidence: HIGH
```bash
gst-launch-1.0 -e filesrc location=/opt/nvidia/deepstream/deepstream/samples/streams/sample_1080p_h264.mp4 ! …
```
[breakdown + suggestions as in Section 5.3, with the "Use your own video" suggestion bumped to the top]
On length: 5–8 stream pipelines run long when on a single line. That is correct and intended — chat clients render bash code blocks faithfully and copy reproduces them correctly. Long ≠ split.
Step 6 — Offer Refinement
After presenting the pipeline, ask the user if they want to adjust anything:
Want me to modify anything? For example:
- Change the number of streams
- Add/remove tracker or secondary inference
- Switch between display and file output
- Change the platform (x86 dGPU / aarch64 Jetson / SBSA)
If the user requests changes, go back to Step 2 with updated parameters — do NOT re-ask all 7 questions. Only ask about the specific parameter that changed, or just apply the change directly if it's clear.
Step 6.5 — Optional: Save Pipeline to a Script
Only do this step when the user explicitly asks (e.g. "save it", "save to pipeline.sh", "write it to a file", "put it in ~/run.sh"). Do not create the file proactively — Step 5 always shows the concrete pipeline in chat for direct copy-paste; saving is a follow-up convenience.
-
Filename: Default to /tmp/pipeline.sh if the user just says "save it". Use the exact path the user named otherwise (e.g. ~/run.sh, scripts/demo.sh).
-
File contents: Two lines — shebang + the same single-line pipeline shown in chat (concrete absolute paths, no shell vars). Keep them in sync — what the user runs from the file is bit-for-bit identical to what they could have copy-pasted.
#!/usr/bin/env bash
gst-launch-1.0 -e filesrc location=/opt/nvidia/deepstream/deepstream/samples/streams/sample_1080p_h264.mp4 ! qtdemux ! h264parse ! nvv4l2decoder ! m.sink_0 … ! nvdsosd ! nveglglessink
Use the Write tool to create the file.
-
Confirm to user with the run command:
Saved to <path>. Run it with:
bash <path>
Pipeline Assembly Rules
When the script is not available or fails, assemble the pipeline using the rules in references/assembly-rules.md. These rules cover source elements, multi-stream patterns, inference chains, tracker configs, sink elements, and extra operations. They also serve as validation for script output.
Error Handling
| Failure | Cause | Recovery |
|---|
generate_pipeline.py returns confidence: low | Query doesn't match any pipeline in the dataset closely | Rely on the assembly rules in this skill instead of retrieved examples |
validate_pipeline.py reports unknown element | GStreamer/DeepStream not installed or not on PATH | Install DeepStream SDK; confirm gst-inspect-1.0 nvinfer works |
| Validation fails after 2 retries | Unusual element combination or linking issue | Present the pipeline as-is with a warning — syntax/element/property checks still passed |
Script not found at <skill-path>/scripts/ | Skill not installed correctly or path misconfigured | Verify the skill directory is symlinked into .claude/skills/ or .cursor/skills/ |
Testing
Run the test suite to verify retrieval quality and validator correctness:
python3 -m unittest discover -s <skill-path>/tests -v
The suite includes:
- Unit tests for the BM25 retriever (tokenizer, synonym expansion, metadata extraction, scoring)
- Unit tests for the validator (syntax, structure, property, named-pad checks)
- Golden regression tests — 20+ query→expected-result pairs ensuring retrieval quality doesn't regress
- Data quality linter — checks the CSV for duplicates, syntax issues, and structural bugs:
python3 <skill-path>/scripts/lint_data.py
python3 <skill-path>/scripts/lint_data.py --fix
Security, Limitations & Notes
Security posture, known limitations, and operational notes are documented in references/security-and-limitations.md. Read that file when you need details on subprocess safety, input validation, platform/SDK requirements, the multi-stream dry-run caveat, or sample-path/config-file reminders.