--- name: perf-activation-recompute description: Validate and use selective and full activation recompute in Megatron Bridge to reduce GPU memory usage at the cost of extra compute. when_to_use: Reducing GPU memory via activation recompute, or investigating a commit that changed recompute settings and caused OOM or a regression; 'recompute_granularity', 'recompute_num_layers', 'recompute_modules', 'recompute_method', 'selective recompute', 'full recompute', 'activation memory OOM'. --- # Activation Recompute Stable docs: @docs/training/activation-recomputation.md Card: @skills/perf-activation-recompute/card.yaml ## What It Is Activation recompute trades GPU compute for memory by discarding intermediate activations during the forward pass and recomputing them during backward. Megatron Bridge supports two granularities: | Granularity | What you specify | What gets recomputed | Memory savings | Compute cost | |---|---|---|---|---| | `selective` | `recompute_modules` list (e.g. `core_attn`, `mlp`) | specific submodules within each layer | moderate (module-dependent) | low to high | | `full` | `recompute_num_layers` + `recompute_method` | entire transformer layers (N layers) | strongest | highest | Note: MCore names these "selective" (submodule-level) vs "full" (layer-level). "Full" means recomputing full layers, not the full model — you still choose how many layers via `recompute_num_layers`. ## Quick Decision 1. **Set `PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True` first** — most borderline OOMs are caused by memory fragmentation, not capacity. This fixes it at zero cost. See @skills/perf-memory-tuning/SKILL.md. 2. Start with `recompute_granularity=selective`, `recompute_modules=[core_attn]` (often already the default in recipes). 3. Add `layernorm` to recompute modules — nearly free compute-wise but saves negligible memory. Only helps in extremely borderline cases. 4. Add `mlp` as a last resort — saves ~3 GB but costs ~16% GPU utilization on large dense models (Llama3 70B). 5. Use `recompute_granularity=full` only when selective recompute still does not fit. CPU offloading (`cpu_offloading=True`) is an alternative that avoids recompute cost entirely, but it is **incompatible with PP > 1**. ## Enablement ### Selective recompute (default for most recipes) ```python cfg.model.recompute_granularity = "selective" cfg.model.recompute_modules = ["core_attn"] ``` ### Selective recompute with additional modules ```python cfg.model.recompute_granularity = "selective" cfg.model.recompute_modules = ["core_attn", "layernorm"] # or ["mlp"] or ["mlp", "core_attn"] ``` ### Full-layer recompute ```python cfg.model.recompute_granularity = "full" cfg.model.recompute_method = "uniform" cfg.model.recompute_num_layers = 4 ``` ### Available recompute_modules | Module | What it recomputes | Compute cost | Memory savings | |---|---|---|---| | `core_attn` | attention softmax/dropout/QKV dot product | low (Flash Attention already recomputes internally) | moderate | | `layernorm` | layer normalization | negligible (~0%) | negligible | | `mlp` | full FFN block | high (~16% on Llama3 70B, hidden=28672) | ~3 GB | | `moe` | MoE expert dispatch | varies | varies | | `moe_act` | MoE activation functions | low | small | | `shared_experts` | shared expert layers | moderate | moderate | | `mla_up_proj` | Multi-Latent Attention up projection | moderate | moderate | ### Performance harness CLI ```bash python scripts/performance/run_performance_workload.py \ --recompute_granularity selective \ --recompute_modules core_attn layernorm \ ... ``` ## Compatibility and Constraints - `recompute_granularity=selective` requires a non-empty `recompute_modules` list - `recompute_granularity=full` requires `recompute_method` and `recompute_num_layers` - **Layer-level recompute (`recompute_granularity="full"` + `recompute_num_layers`) is incompatible with TE-scoped CUDA graphs.** MCore calls this "full" granularity — the name refers to recomputing full transformer layers, not the full model. Even though you're selecting how many layers to recompute, MCore treats it differently from submodule recompute. Any TE-scoped scope (`attn`, `mlp`, `moe_router`, etc.) will assert. This commonly hits FP8 configs that enable TE-scoped graphs by default (e.g. `LLAMA3_70B_SFT_CONFIG_H100_FP8_CS_V1` sets `cuda_graph_impl="transformer_engine"`, `cuda_graph_scope="mlp"`). Options: - use submodule recompute (`recompute_granularity="selective"` + `recompute_modules`) — compatible with TE-scoped graphs - disable CUDA graphs (`cuda_graph_impl="none"`) and use layer-level recompute - switch to `cuda_graph_impl="local"`, `cuda_graph_scope="full_iteration"` - `distribute_saved_activations=True` cannot be combined with `sequence_parallel=True` - Combining `mlp` + `core_attn` recompute is slightly worse than `mlp` alone due to double recompute overhead ## Measured Results Llama3 70B SFT on 32x H100 80GB, FP8 (Current Scaling): - Baseline: TP=4, PP=4, VPP=5, DP=2, MBS=1, GBS=32, seq_len=4096 - Golden GPU utilization: 709.93 TFLOP/s/GPU - Regression threshold: 5% | Experiment | recompute_modules | TFLOP/s/GPU | vs Golden | Peak Mem (GB) | Result | |---|---|---|---|---|---| | Baseline | [core_attn] | ~704 | -0.8% | 58.8 (OOM rank0) | OOM | | Exp 1 | [mlp] | 593.6 | -16.4% | 55.6 | Perf regression | | Exp 2 | [mlp, core_attn] | 586.8 | -17.3% | 55.6 | Perf regression | | Exp 3 | [core_attn, layernorm] | ~702 | -1.1% | 59.6 (OOM rank0) | OOM | Key takeaways: - `layernorm` recompute is nearly free compute-wise but saves negligible memory - `mlp` recompute saves ~3 GB peak but costs ~16% because the Llama3 70B FFN (hidden=28672) is expensive to recompute - Combining `mlp` + `core_attn` is slightly worse than `mlp` alone - For this workload, the actual OOM fix was `PYTORCH_CUDA_ALLOC_CONF=expandable_segments:True` (memory fragmentation, not capacity). See @skills/perf-memory-tuning/SKILL.md. ## Code Anchors ### Recompute modules enum and selective checkpoint logic ```python # 3rdparty/Megatron-LM/megatron/core/transformer/transformer_block.py # _checkpointed_forward() applies selective recompute based on recompute_modules ``` ### Recompute config validation ```python # 3rdparty/Megatron-LM/megatron/core/transformer/transformer_config.py # Validates recompute_granularity, recompute_method, recompute_num_layers ``` ### Llama3 recipe defaults ```99:103:src/megatron/bridge/recipes/llama/llama3.py # Memory saving (recompute & offloading) cfg.model.recompute_granularity = None cfg.model.recompute_modules = None cfg.model.fine_grained_activation_offloading = False cfg.model.offload_modules = None ``` ### Full recompute + CUDA graph assertion (MCore) ```2001:2005:3rdparty/Megatron-LM/megatron/core/transformer/transformer_config.py if self.recompute_granularity: if self.recompute_granularity != "selective": assert self.cuda_graph_scope == [ CudaGraphScope.full_iteration ], "full recompute is only supported with full iteration CUDA graph." ``` ### CPU offloading PP incompatibility (MCore) ```1303:1306:3rdparty/Megatron-LM/megatron/core/transformer/transformer_config.py if self.cpu_offloading and self.pipeline_model_parallel_size > 1: raise ValueError( "Currently there is no support for Pipeline parallelism with CPU offloading" ) ``` ## Failure Diagnosis | Symptom | Cause | Confirm | Fix | |---|---|---|---| | >15% GPU utilization drop | mlp recompute on large FFN | check `recompute_modules` includes `mlp` | check `expandable_segments:True` is set; consider reducing MBS | | Still OOM after adding layernorm | layernorm activations are too small | compare peak memory before/after | add mlp recompute or check `expandable_segments:True` | | `AssertionError: full recompute is only supported with full iteration CUDA graph` | layer-level recompute (`recompute_granularity=full` + `recompute_num_layers`) with TE-scoped graphs. FP8 CS configs default to `cuda_graph_impl=transformer_engine`, `scope=mlp`. | check `cuda_graph_impl` and `cuda_graph_scope` | use submodule recompute (`selective` + `recompute_modules`), or `cuda_graph_impl=none`, or `local` + `full_iteration` | | ValueError: PP + CPU offloading | `cpu_offloading=True` with `pipeline_model_parallel_size > 1` | check PP config | disable CPU offloading or set PP=1 | | mlp+core_attn worse than mlp alone | double recompute overhead | compare Exp 1 vs Exp 2 | use mlp alone | ## Known Limitations - Per-module memory savings vary significantly by model architecture and hidden dimension - No automatic module selection — users must choose which modules to recompute - `layernorm` recompute is almost never worth it as a standalone fix - CPU offloading (the zero-compute-cost alternative) is blocked when PP > 1 ## Verification ```bash uv run python -m pytest \ tests/unit_tests/training/test_config.py -k "recompute" -q ``` Success criteria: - Unit tests pass for recompute config validation - No assertion errors from config validation