tao-train-depth-anything-v2
Monocular depth estimation using Metric Depth Anything v2 or Relative Depth Anything architectures. Predicts per-pixel depth from single RGB images. Use when training, evaluating, exporting, or running inference for a TAO monocular depth model. Trigger phrases include "train monocular depth", "DepthAnything v2", "metric depth from single image", "monocular depth estimation".
How do I install this agent skill?
npx skills add https://github.com/nvidia/skills --skill tao-train-depth-anything-v2Is this agent skill safe to install?
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The tao-train-depth-anything-v2 skill facilitates monocular depth estimation workflows using the NVIDIA TAO Toolkit. It supports training, evaluation, export, and inference for Depth Anything v2 models. Security analysis shows the skill uses standard deep learning practices, such as fetching pretrained weights from official sources and executing model commands within isolated containers. No malicious patterns or unauthorized behaviors were detected.
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What does this agent skill do?
Depth Net Mono
Monocular depth estimation using Metric Depth Anything v2 or Relative Depth Anything architectures. Predicts per-pixel depth from single RGB images.
Pretrained checkpoint loading varies by model variant and use case — see the Pretrained checkpoint loading — use case matrix in references/parameters.md.
The mono and stereo skills both invoke the unified TAO depth_net CLI inside the container; the mono/stereo family is selected via model.model_type (see references/parameters.md).
For TAO Deploy TensorRT actions (gen_trt_engine, TensorRT evaluate, and TensorRT inference), read references/tao-deploy-depth-anything-v2.md first. The deploy spec template lives in this skill's references/spec_template_deploy.yaml.
PyT actions packaged by this model skill: train, evaluate, inference, export, and quantize. The PyT depth_net entrypoint does not accept a PyT-side gen_trt_engine action in the current TAO image. The gen_trt_engine action metadata must run with the TAO Deploy container, and the deploy workflow remains the deploy-specific entrypoint.
Train Action Policy
This model is AutoML-enabled at the model layer. Before handling any train-stage request, read references/skill_info.yaml and resolve the run override from either an explicit automl_policy value or the user's workflow request. Use automl_policy: on by default and only expose on / off in new launch prompts. Treat phrases like "turn off AutoML", "disable AutoML", "no HPO", or "plain training" as automl_policy: off for this run only. When automl_policy: on, automl_enabled: true, and both schemas/train.schema.json and references/spec_template_train.yaml are packaged, route the train action through tao-skill-bank:tao-run-automl by default with this model's skill_dir. Preserve workflow/application overrides for datasets, specs, output directories, GPU/platform settings, parent checkpoints, and automl_policy. Use direct model training only when automl_policy: off or the packaged train schema/template is missing; in the missing-schema case, report that AutoML is enabled but not runnable for this model until schemas are generated.
Non-train actions such as evaluate, inference, export, and deploy flows stay in this model skill. The per-run automl_policy override does not change model metadata.
Workflow
Prerequisites — data accessibility
Your dataset (RGB images + GT depth files) must be reachable from inside the container:
- SDK runner: place files at the S3 paths the runner resolves (the
S3_TRAIN/S3_EVALplaceholders shown in Typical Spec Overrides). The runner handles S3 → container-path mounting transparently. - Direct
docker run(e.g. local testing): mount the host dataset root read-only at the same in-container path:
docker run ... -v <host_data_root>:<host_data_root>:ro <container> ...
The same accessibility requirement applies to the <output_dir> written by all actions.
Step 1 — Annotation file
Per-line annotation file referenced by data_sources[*].data_file:
| Columns | Format | Use |
|---|---|---|
| 1 | <image> | Mono inference (no GT) |
| 2 | <image> <gt_depth> | Mono with GT |
Do not pass stereo annotation rows such as <left_image> <right_image> <gt_depth> directly to mono train/evaluate/inference. If only a stereo depth
dataset is available, derive a mono annotation file by keeping the left image
and GT depth columns, then mount or stage the image/depth archive at the same
container paths referenced by that derived annotation file.
If you already have one, point to it. Otherwise generate via depth_net convert:
depth_net convert -e <convert_spec.yaml>
convert_spec.yaml template:
results_dir: <directory where generated annotation files are written>
data_root: <directory whose immediate children are scene/sample folders that contain your image+depth files; convert walks data_root recursively but expects per-scene subdirectories at one level below>
image_dir_pattern: [<substring matching left/RGB image paths>]
depth_dir_pattern: [<substring matching GT depth paths>]
image_extension: '' # optional .endswith filter, e.g. '.jpg'
depth_extension: '' # optional, swapped during depth derivation, e.g. '.png'
split_ratio: 0.0 # 0.0/1.0 = test-only; 0.8 = 80/20 train+val
convert walks data_root recursively, selects paths whose path-string contains all substrings in image_dir_pattern (AND-filter), then derives the depth path by replacing image_dir_pattern[0] with depth_dir_pattern[0] and image_extension with depth_extension. Inspect your dataset's directory layout and identify the substring distinguishing RGB images from depth files (e.g. rgb_ vs sync_depth_).
data_root must point at the parent that contains the per-scene subdirectories (e.g. for NYU eval, use /data/nyu_v2/eval/test, not /data/nyu_v2/eval/test/bathroom — the latter limits the walk to a single scene). Always include the leading dot in image_extension / depth_extension (e.g. '.jpg' not 'jpg'); the substring swap is form-sensitive and a mismatch silently corrupts derived paths.
Step 2 — Pair model_type and dataset_name based on your data
Default — generic class for each task:
| Data category | model_type | dataset_name |
|---|---|---|
| Disparity-encoded data (pixels) | RelativeDepthAnything | RelativeMonoDataset |
| Metric depth (meters) | MetricDepthAnything | MetricMonoDataset |
| Mono inference (no GT, any image) | matches train choice | RelativeMonoDataset or MetricMonoDataset |
Dataset-specific class — switch when the data needs preprocessing the generic class does not perform:
| Special case | model_type | dataset_name | What the class adds |
|---|---|---|---|
NYU sync_depth_*.png (raw uint16 millimetres) — relative | RelativeDepthAnything | NYUDV2Relative | mm→m unit conversion + Eigen evaluation crop |
NYU sync_depth_*.png (raw uint16 millimetres) — metric | MetricDepthAnything | NYUDV2 | same |
Using a generic class on data that requires unit conversion (e.g. raw NYU uint16 PNGs) results in an empty valid mask and silent train_loss = NaN. Match the class to your data's encoding.
For relative mono data (RelativeMonoDataset or NYUDV2Relative), leave dataset.min_depth and dataset.max_depth unset or set both to null. Non-null metric depth ranges are passed into the relative dataset constructor and fail with BaseRelativeMonoDataset.__init__() got an unexpected keyword argument 'min_depth'.
Step 3 — Write spec yaml from Typical Spec Overrides
Copy the action block from Typical Spec Overrides (references/spec-overrides.md). Replace:
model.model_typefrom Step 2dataset.<...>.data_sources[*].dataset_namefrom Step 2data_sources[*].data_filewith the path from Step 1 (S3 path under SDK runner, host path for direct docker)- For metric finetune: additionally apply the Metric Variant Finetuning Recipe in
references/finetuning-recipes.md.
For mono training set train.precision: fp32 (recommended) or bf16 (Ampere SM80+, alternative).
Step 4 — Run
Create writable home/cache directories inside the mounted output path before using
--user. Some TAO containers do not have an /etc/passwd entry for the host UID,
and PyTorch / matplotlib need writable cache paths when running as that UID.
mkdir -p <output_dir>/home \
<output_dir>/.cache/matplotlib \
<output_dir>/.cache/torchinductor \
<output_dir>/.cache/xdg
docker run --gpus 'device=0' --shm-size 16G --ipc=host \
--user "$(id -u):$(id -g)" \
-e USER="$(id -un)" \
-e LOGNAME="$(id -un)" \
-e HOME=<output_dir>/home \
-e MPLCONFIGDIR=<output_dir>/.cache/matplotlib \
-e TORCHINDUCTOR_CACHE_DIR=<output_dir>/.cache/torchinductor \
-e XDG_CACHE_HOME=<output_dir>/.cache/xdg \
-v <data_root>:<data_root>:ro \
-v <output_dir>:<output_dir> \
<container> \
depth_net <action> -e <spec.yaml>
Without --user "$(id -u):$(id -g)" the container writes outputs as nobody:nogroup, blocking host-side cleanup and retry.
Step 5 — Verify
- Container exit code 0
status.jsonkpiblock populated- For
train: inspect per-steptrain_lossdirectly — the entrypoint reportsExecution status: PASSeven whentrain_loss = NaN(see the Metric Variant Finetuning Recipe → Sanity-run PASS criteria inreferences/finetuning-recipes.md) - For
evaluate/inference: artifacts underresults_dir
For TAO Deploy TensorRT actions (gen_trt_engine, TensorRT evaluate, and TensorRT inference), read references/tao-deploy-depth-anything-v2.md first. Deploy spec templates live in this skill's references/ folder with the spec_template_deploy_*.yaml prefix.
Training Requirements
- Valid
dataset_namevalues for monodata_sources(case-insensitive):ThreeDVLM,FSD,NvCLIP,IssacStereo,Crestereo,Middlebury,NYUDV2,NYUDV2Relative,RelativeMonoDataset,MetricMonoDataset.NYUDV2carries metric depth GT (meters) — pair withMetricDepthAnything;NYUDV2Relativeis the same data with relative-depth conventions — pair withRelativeDepthAnything. - Monitoring metric: val/d1, val/loss
- For AutoML sanity runs on the packaged relative-depth smoke data, use
val/d1as the primary monitor.val/losscan be emitted asNaNeven when the trainer exits successfully and writes a usable checkpoint, so it is not a reliable AutoML objective unless the run's status metrics show a finite value.
Per-Action Dataset Requirements
| Action | Spec Key | Source | Files | List? |
|---|---|---|---|---|
| evaluate | dataset.test_dataset.data_sources | eval_dataset | data_file: annotations.txt + dataset_name | Yes |
| inference | dataset.infer_dataset.data_sources | inference_dataset | data_file: annotations.txt + dataset_name | Yes |
| quantize | dataset.train_dataset.data_sources | train_datasets | data_file: annotations.txt + dataset_name | Yes |
| quantize | dataset.val_dataset.data_sources | eval_dataset | data_file: annotations.txt + dataset_name | Yes |
| quantize | dataset.quant_calibration_dataset.images_dir | train_datasets | images.tar.gz | No |
| train | dataset.train_dataset.data_sources | train_datasets | data_file: annotations.txt + dataset_name | Yes |
| train | dataset.val_dataset.data_sources | eval_dataset | data_file: annotations.txt + dataset_name | Yes |
Typical Spec Overrides
Data source overrides are mandatory for every action — construct data source paths from the Per-Action Dataset Requirements table above and include them in spec_overrides. Each data_sources entry is a dict with two mandatory fields: data_file and dataset_name. See references/spec-overrides.md for the full per-action override blocks (train, evaluate, export, inference, quantize), the S3_TRAIN / S3_EVAL placeholders, the relative-variant precision recommendation, and the quantize known-issue note.
Eval Dataset
Optional. Val dataset configured via dataset.val_dataset.data_sources (each entry needs data_file and dataset_name).
Important Parameters
See references/parameters.md for the full parameter glossary (model, train, dataset, export, and inference keys with options, defaults, and sources) and the Pretrained checkpoint loading — use case matrix.
Finetuning Recipes
See references/finetuning-recipes.md for:
- Relative Variant Finetuning Recipe — finetune from a TAO-trained
RelativeDepthAnythingcheckpoint (lr5e-6,LambdaLR, sanity-vs-convergent guidance, deploy LSQ alignment note). - Metric Variant Finetuning Recipe — checkpoint compatibility, required overrides, the dataset normalization block (
normalize_depth/min_depth/max_depth) required in train AND export specs, trainer-enforced defaults, precision, the 1-epoch sanity-run override, and the Sanity-run PASS criteria with the NaN-mitigation order.
Multi-GPU / Multi-Node
Launch method: Lightning-managed (single python process, Lightning spawns workers).
| Spec Key | Description | Default |
|---|---|---|
train.num_gpus | Number of GPUs | 1 |
train.gpu_ids | GPU device indices | [0] |
train.num_nodes | Number of nodes | 1 |
train.distributed_strategy | ddp or fsdp | ddp |
ddpwith activation checkpointing:find_unused_parameters=Falseddpwithout:find_unused_parameters=Truefsdpforces precision to FP16
Multi-node env vars (set by orchestrator): WORLD_SIZE, NODE_RANK, MASTER_ADDR, MASTER_PORT, NUM_GPU_PER_NODE.
Export / TRT Defaults
- TRT data types: FP32, BF16 (Ampere SM80+). FP16 is not supported for the ViT-L mono backbone.
- Fresh-install TRT precision:
fp32. BF16 is supported on Ampere SM80+ hardware, but keep smoke tests on FP32 unless the user explicitly requests BF16.
Hardware
Minimum 1 GPU(s), recommended 2 GPU(s). 24GB+ VRAM per GPU. ViT-Large encoder is memory intensive. Use fp32 (recommended) or bf16 (Ampere SM80+, alternative) for training. Activation checkpointing is available for larger inputs.
Error Patterns
See references/troubleshooting.md for the full error-pattern catalog (depth range mismatch, relative dataset rejecting min_depth, missing pretrained weights, encoder key location, dataset_name not in struct, depth_net_mono not found, metric variant hyperparameter sourcing, and export ONNX overwrite).
Spec Param / Parent Model Inference
See references/spec-param-inference.md for the model-specific inference mappings (the TAO Core depth_net_mono.config.json action table), checkpoint-file naming under <results_dir>/train/, the dn_model_latest.pth policy, the parent-gen_trt_engine rationale, and the parent_model / parent_job_id resolution rules.
Deployment
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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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