# SELD233 Spatial Implementation Guide ## Purpose This document is the implementation guide for the independent SELD233 spatial modality. It answers four questions: - which classes and functions were implemented for the core path - which classes are already scaffolded and should be reused as-is - what each interface accepts and returns - what concrete code is still deferred outside the current scope This guide should be read together with: - `docs/spatial_encoder_plan.md` - `docs/seld233_spatial_scaffold.md` ## Fixed Constraints - Do not modify the DCASE baseline repository. - Do not modify the original QwenOmni main classes for this feature; use the new spatial subclasses. - A batch must be either all mono or all FOA. - Mono batch: - must contain exactly one `<|AUDIO|>` - must not contain `<|spatial|>` - only the original audio path is active - FOA batch: - must contain exactly one `<|AUDIO|>` - must contain exactly one `<|spatial|>` - both audio and spatial paths are active - Audio is clipped to `0-20s`. - Sample rate is `16kHz`. - Spatial token rate target is `2.5 Hz`. - Full `20s` limits: - max samples: `320000` - max feature frames: `1000` - max SELD frames: `200` - max spatial tokens: `50` ## Status Summary ### Already scaffolded and reusable - `qwen2_5_omni_spur/spatial_seld233_utils.py` - `qwen2_5_omni_spur/modules/seldnet233_spatial_adapter.py` - `qwen2_5_omni_spur/modules/spatial_token_projector.py` - `qwen2_5_omni_spur/processing_qwen2_5_omni_spatial.py` - `qwen2_5_omni_spur/modeling_qwen2_5_omni_spatial.py` - config additions in `qwen2_5_omni_spur/configuration_qwen2_5_omni.py` ### Must still be implemented - training script migration to the new spatial subclasses - inference script migration to the new spatial subclasses ### Explicitly deferred for now - `image + spatial` joint RoPE - `use_audio_in_video=True` - `return_audio=True` talker path with spatial modality ## Implementation Inventory | Priority | File | Symbol | Current State | Required Action | | --- | --- | --- | --- | --- | | P0 | `qwen2_5_omni_spur/modules/seldnet233_feature_bridge.py` | `SeldNet233FeatureBridge._extract_online_features` | implemented | no further action for the current scope | | P0 | `qwen2_5_omni_spur/modules/seldnet233_backbone.py` | `SeldNet233Backbone._run_seldnet_backbone` | implemented | no further action for the current scope | | P1 | `training-qwen-omni/train_spur_spatial_only_hf.py` | `main()` and config wiring | legacy | migrate only if this script is needed for training runs | | P1 | `qwen-omni-inference.py` | script body | legacy | migrate only if this script is needed for ad hoc inference | | P2 | `qwen2_5_omni_spur/modeling_qwen2_5_omni_spatial.py` | `get_rope_index` | partial | only needed later if image + spatial is required | | P2 | `qwen2_5_omni_spur/modeling_qwen2_5_omni_spatial.py` | `generate(return_audio=True)` path | partial | only needed if talker output is required later | ## Detailed Interface Guide ### 1. `SeldNet233FeatureBridge` File: - `qwen2_5_omni_spur/modules/seldnet233_feature_bridge.py` Class: - `SeldNet233FeatureBridge` Already implemented: - constructor - input validation - waveform mask -> valid length conversion - waveform length -> feature length conversion - output mask bookkeeping - online baseline-aligned STFT / log-mel / intensity-vector extraction - baseline `foa_wts` normalization Input contract: - `spatial_audio`: `torch.Tensor`, shape `[B, T_audio_max, 4]` - `spatial_audio_lengths`: `torch.LongTensor`, shape `[B]` - `feature_lengths`: `torch.LongTensor`, shape `[B]` - `feature_attention_mask`: `torch.BoolTensor`, shape `[B, T_feat_max]` Output contract: - `SeldNet233FeatureBridgeOutput.features`: `[B, 7, T_feat_max, 64]` - `SeldNet233FeatureBridgeOutput.feature_attention_mask`: `[B, T_feat_max]` - `SeldNet233FeatureBridgeOutput.feature_lengths`: `[B]` Required implementation content: 1. Load or derive the exact task-233 feature configuration. 2. Reproduce the baseline feature math for FOA: - `4ch` log-mel - `3ch` FOA intensity vector 3. Use the task-233 normalization weights. 4. Keep output frame count aligned with `feature_lengths`. 5. Zero-fill padded tail frames only after valid frames are computed. Recommended private helpers to add inside this file: - `_load_task233_feature_config()` - `_load_feature_stats()` - `_compute_stft(...)` - `_compute_logmel_channels(...)` - `_compute_intensity_vector_channels(...)` - `_normalize_feature_tensor(...)` Important shape transitions: - raw FOA waveform: `[B, T_audio_max, 4]` - internal channels-first view: `[B, 4, T_audio_max]` - mel-like features before stacking: `[B, 4, T_feat_max, 64]` - intensity-vector features: `[B, 3, T_feat_max, 64]` - final baseline tensor: `[B, 7, T_feat_max, 64]` Validation checklist: - same sample length gives same `T_feat` as `samples_to_feature_frames` - values match offline baseline extraction on the same clip - normalization path is identical to baseline task `233` ### 2. `SeldNet233Backbone` File: - `qwen2_5_omni_spur/modules/seldnet233_backbone.py` Class: - `SeldNet233Backbone` Already implemented: - constructor - input validation - feature length -> SELD length conversion - output mask bookkeeping - dynamic baseline loading - checkpoint restore with shape-compatible filtering - last MHSA LayerNorm hidden capture Input contract: - `seld233_features`: `torch.Tensor`, shape `[B, 7, T_feat_max, 64]` - `seld233_feature_lengths`: `torch.LongTensor`, shape `[B]` - `hidden_lengths`: `torch.LongTensor`, shape `[B]` - `hidden_attention_mask`: `torch.BoolTensor`, shape `[B, T_seld_max]` Output contract: - `SeldNet233BackboneOutput.hidden_states`: `[B, T_seld_max, 128]` - `SeldNet233BackboneOutput.hidden_attention_mask`: `[B, T_seld_max]` - `SeldNet233BackboneOutput.hidden_lengths`: `[B]` Required implementation content: 1. Dynamically load `parameters.py` and `seldnet_model.py` from the baseline repo path. 2. Build the task-233 baseline model. 3. Restore the pretrained checkpoint from `seld233_checkpoint_path`. 4. Freeze the backbone if `seld233_freeze_backbone=True`. 5. Register a hook at the final MHSA shared representation. 6. Feed the baseline-compatible features into the model. 7. Return the captured hidden tensor, not accdoa heads and not sed logits. Recommended private helpers to add inside this file: - `_load_baseline_modules()` - `_build_seld233_model()` - `_load_checkpoint_weights()` - `_register_hidden_hook()` - `_prepare_baseline_input_layout(...)` Important shape transitions: - model input for this wrapper: `[B, 7, T_feat_max, 64]` - likely baseline internal flattened layout: `[B, T_feat_max, 448]` - captured MHSA hidden: `[B, T_seld_max, 128]` Validation checklist: - checkpoint path exists - hook fires exactly once per forward - hidden dim is exactly `128` - hidden length matches `feature_frames_to_seld_frames` ### 3. `SeldNet233SpatialAdapter` File: - `qwen2_5_omni_spur/modules/seldnet233_spatial_adapter.py` Class: - `SeldNet233SpatialAdapter` Status: - already usable once feature bridge and backbone are implemented Input modes already supported: - raw audio path: - `spatial_audio [B, T_audio_max, 4]` - offline feature path: - `seld233_features [B, 7, T_feat_max, 64]` - direct hidden path: - `seld233_hidden_states [B, T_seld_max, 128]` Output: - `spatial_tokens [B, T_spat_max, 256]` - `spatial_token_attention_mask [B, T_spat_max]` - `spatial_token_lengths [B]` No new implementation is required here unless you want to change: - downsampling rule - token MLP architecture - token dimension Current downsampling rule: - `T_spat = ceil(T_seld / 4)` - effective rate: `10 Hz -> 2.5 Hz` ### 4. `SpatialTokenProjector` File: - `qwen2_5_omni_spur/modules/spatial_token_projector.py` Class: - `SpatialTokenProjector` Status: - already implemented Input: - `spatial_tokens [B, T_spat, D_in]` Output: - projected tokens `[B, T_spat, D_llm]` No further code is required here unless model capacity needs tuning. ### 5. `Qwen2_5OmniSpatialProcessor` File: - `qwen2_5_omni_spur/processing_qwen2_5_omni_spatial.py` Class: - `Qwen2_5OmniSpatialProcessor` Status: - implemented scaffold - should be reused, not rewritten Important public interfaces: - `__call__(...)` - `sync_spatial_tokenizer_with_model(model)` Input behavior: - mono batch: - prompt must include one `<|AUDIO|>` - prompt must not include `<|spatial|>` - FOA batch: - prompt must include one `<|AUDIO|>` - prompt must include one `<|spatial|>` Output keys already supported: - `input_ids` - `input_features` - `feature_attention_mask` - `spatial_audio` - `spatial_audio_attention_mask` - `spatial_audio_lengths` - `spatial_tokens` - `seld233_features` - `seld233_feature_attention_mask` - `seld233_feature_lengths` - `spatial_token_lengths` No core algorithm is missing here. What still needs to happen outside this file: - training script must actually instantiate this processor - inference script must actually instantiate this processor - both scripts must call `processor.sync_spatial_tokenizer_with_model(model)` ### 6. `Qwen2_5OmniSpatialThinkerForConditionalGeneration` File: - `qwen2_5_omni_spur/modeling_qwen2_5_omni_spatial.py` Class: - `Qwen2_5OmniSpatialThinkerForConditionalGeneration` Status: - spatial injection path is implemented - tokenizer sync helper is implemented - prefill spatial routing is implemented - video + audio + spatial RoPE is implemented for `use_audio_in_video=False` Important public interfaces: - `forward(...)` - `prepare_inputs_for_generation(...)` - `sync_spatial_tokenizer(...)` Input contract: - normal Qwen text/audio inputs - optional spatial inputs: - `spatial_audio [B, T_audio_max, 4]` - `seld233_features [B, 7, T_feat_max, 64]` - `spatial_tokens [B, T_spat_max, D_spat]` - matching length or mask tensors Output behavior: - if no spatial input is provided, it falls back to the base thinker - if spatial input is provided, it injects projected spatial embeddings at `<|spatial|>` positions Still missing only if scope expands later: - true multimodal RoPE for `image + spatial` - talker/audio-output path ### 7. `Qwen2_5OmniSpatialForConditionalGeneration` File: - `qwen2_5_omni_spur/modeling_qwen2_5_omni_spatial.py` Class: - `Qwen2_5OmniSpatialForConditionalGeneration` Status: - implemented scaffold Important public interfaces: - `sync_spatial_tokenizer(...)` - `generate(...)` No core code is missing for text-only generation with audio/spatial input. Still deferred: - `return_audio=True` path ## Script-Level Work ### 8. Training Script File: - `training-qwen-omni/train_spur_spatial_only_hf.py` Current issue: - it still uses the old SPUR audio-fusion line Minimum required changes: 1. Replace imports: - old: - `Qwen2_5OmniProcessor` - `Qwen2_5OmniForConditionalGeneration` - new: - `Qwen2_5OmniSpatialProcessor` - `Qwen2_5OmniSpatialForConditionalGeneration` 2. Replace old SPUR config overrides with new `seld233_*` thinker config fields. 3. After loading processor and model, call: - `processor.sync_spatial_tokenizer_with_model(model)` 4. Update prompt construction: - mono batch prompt: includes `<|AUDIO|>` only - FOA batch prompt: includes `<|AUDIO|><|spatial|>` 5. Ensure collator preserves mono or FOA batch homogeneity. 6. Ensure audio clips are clipped to `20s`. 7. Ensure training batch uses the new processor output keys. Functions that most likely need modification: - `apply_spur_config_overrides(...)` - `main()` ### 9. Inference Script File: - `qwen-omni-inference.py` Current issue: - it still uses the old processor/model path Minimum required changes: 1. Replace imports with the new spatial subclasses. 2. Load FOA audio without collapsing channels. 3. Build prompt with canonical tokens: - FOA: `<|AUDIO|><|spatial|> ...` - mono: `<|AUDIO|> ...` 4. Call: - `processor.sync_spatial_tokenizer_with_model(model)` 5. Print or assert: - `spatial_token_lengths` - number of `<|spatial|>` token positions after tokenization 6. Run one prefill/generation sanity check. There is no reusable function boundary in the current script; the top-level script body itself needs to be migrated. ## Suggested Implementation Order 1. Implement `SeldNet233FeatureBridge._extract_online_features`. 2. Implement `SeldNet233Backbone._run_seldnet_backbone`. 3. Run a direct module test: - `spatial_audio -> feature bridge -> backbone -> adapter` 4. Migrate `training-qwen-omni/train_spur_spatial_only_hf.py`. 5. Migrate `qwen-omni-inference.py`. 6. Only after that, consider optional RoPE/talker extensions. ## Required Checks After Each Stage ### After feature bridge - same clip gives matching online vs offline task-233 features - feature tensor is `[B, 7, T_feat_max, 64]` - feature mask matches `feature_lengths` ### After backbone - checkpoint loads successfully - captured hidden is `[B, T_seld_max, 128]` - hidden length matches derived `T_seld` ### After end-to-end spatial adapter - `spatial_tokens` is `[B, T_spat_max, 256]` - `spatial_token_lengths` equals `ceil(T_seld / 4)` - no placeholder count mismatch ### After training/inference migration - `<|spatial|>` is present in tokenizer vocab - `config.thinker_config.spatial_token_index` is set - thinker embedding size matches tokenizer size - mono batch runs without spatial injection - FOA batch runs with spatial injection ## Out of Scope For The Next Coding Stage - support mixed mono/FOA batches - support image/video + spatial at the same time - support talker audio generation with spatial tokens - change the task-233 feature definition or baseline architecture