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---
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title: Optimizations Guide
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description: A guide to the performance and memory optimizations available in Axolotl.
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---
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Axolotl includes numerous optimizations to speed up training, reduce memory usage, and handle large models.
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This guide provides a high-level overview and directs you to the detailed documentation for each feature.
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## Speed Optimizations
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These optimizations focus on increasing training throughput and reducing total training time.
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### Sample Packing
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Improves GPU utilization by combining multiple short sequences into a single packed sequence for training. This requires enabling one of the [attention](#attention-implementations) implementations below.
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- **Config:** `sample_packing: true`
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- **Learn more:** [Sample Packing](multipack.qmd)
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### Attention Implementations
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Using an optimized attention implementation is critical for training speed.
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- **[Flash Attention 2](https://github.com/Dao-AILab/flash-attention)**: `attn_implementation: flash_attention_2`. **(Recommended)** The industry standard for fast attention on modern GPUs. Requires Ampere or higher. For AMD, check [AMD Support](https://github.com/Dao-AILab/flash-attention?tab=readme-ov-file#amd-rocm-support).
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- **[Flex Attention](https://pytorch.org/blog/flexattention/)**: `attn_implementation: flex_attention`.
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- **[SDP Attention](https://docs.pytorch.org/docs/stable/generated/torch.nn.functional.scaled_dot_product_attention.html)**: `attn_implementation: sdpa`. PyTorch's native implementation.
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- **[Xformers](https://github.com/facebookresearch/xformers)**: `attn_implementation: xformers`. Works with FP16.
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See [Attention](attention.qmd) for the full list of backends and the canonical values.
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### LoRA Optimizations
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Leverages optimized kernels to accelerate LoRA training and reduce memory usage.
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- **Learn more:** [LoRA Optimizations Documentation](lora_optims.qmd)
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## Memory Optimizations
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These techniques help you fit larger models or use bigger batch sizes on your existing hardware.
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### Parameter Efficient Finetuning (LoRA & QLoRA)
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Drastically reduces memory by training a small set of "adapter" parameters instead of the full model. This is the most common and effective memory-saving technique.
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- Examples: Find configs with `lora` or `qlora` in the [examples directory](https://github.com/axolotl-ai-cloud/axolotl/tree/main/examples/llama-3).
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- Config Reference: See `adapter`, `load_in_4bit`, and `load_in_8bit` in the [Configuration Reference](config-reference.qmd).
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### Gradient Checkpointing & Activation Offloading
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These techniques save VRAM by changing how activations are handled.
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- Gradient Checkpointing: re-computes activations during the backward pass, trading compute time for VRAM.
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- Activation Offloading: moves activations to CPU RAM or disk, trading I/O overhead for VRAM.
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- Learn more: [Gradient Checkpointing and Offloading Docs](gradient_checkpointing.qmd)
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### Layer Offloading
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Offloads frozen (non-trainable) decoder layer parameters to CPU and streams them back to GPU one layer at a time during forward/backward passes using CUDA stream prefetching. Especially effective for LoRA/QLoRA where most parameters are frozen.
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- **Config:** `layer_offloading: true`
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- **Learn more:** [Layer Offloading Docs](gradient_checkpointing.qmd#enabling-layer-offloading)
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### Cut Cross Entropy (CCE)
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Reduces VRAM usage by using an optimized cross-entropy loss calculation.
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- **Learn more:** [Custom Integrations - CCE](custom_integrations.qmd#cut-cross-entropy)
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### Liger Kernels
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Provides efficient Triton kernels to improve training speed and reduce memory usage.
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- **Learn more:** [Custom Integrations - Liger Kernels](custom_integrations.qmd#liger-kernels)
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### Fused RMSNorm + RoPE (Qwen3 / Qwen3-MoE / Qwen3.5 / Qwen3.5-MoE / Qwen3.6 dense / Qwen3.6-MoE)
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Replaces the per-layer `q_norm + apply_rotary_pos_emb` (and matching K path) with a single Triton kernel launch on the full-attention layers. Opt-in. The kernel computes in fp32 and rounds once, so it matches an fp32 reference to within bf16 rounding — i.e. it is *more* accurate than the eager bf16 path, which rounds at several intermediate steps. Gemma 4 always uses the fused path (no flag needed). Qwen3.6 checkpoints are loaded by transformers under the `qwen3_5` / `qwen3_5_moe` model_types, so the same flag covers both generations.
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```yaml
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fused_attn_kernel: true
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```
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- **Compile-safe:** the kernel is wrapped as a `torch.library.triton_op` and traces under `torch.compile(fullgraph=True)`.
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- **Hardware note:** on sm_120 (Blackwell) combining with `torch_compile: true` is a net win; on sm_86 (Ampere consumer) `torch_compile: true` currently regresses the surrounding Inductor-generated kernels — keep compile off there.
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### Expert Kernels
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Optimized per-expert grouped-GEMM kernels for MoE training, with LoRA support.
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- **ScatterMoE**: Triton, any CUDA GPU.
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- **SonicMoE**: CUTLASS / cute-DSL, Hopper (H100/H200) or Blackwell (B200/GB200).
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- **Config:** `use_scattermoe: true` or `use_sonicmoe: true`
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- **Learn more:** [Custom Integrations - Kernels Integration](custom_integrations.qmd#kernels-integration)
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## Long Context Models
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Techniques to train models on sequences longer than their original context window.
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### RoPE Scaling
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Extends a model's context window by interpolating its Rotary Position Embeddings.
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- **Config:** Pass the `rope_scaling` config under the `overrides_of_model_config: `. To learn how to set RoPE, check the respective model config.
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### Sequence Parallelism
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Splits long sequences across multiple GPUs, enabling training with sequence lengths that would not fit on a single device.
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- **Learn more:** [Sequence Parallelism Documentation](sequence_parallelism.qmd)
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### Artic Long Sequence Training (ALST)
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ALST is a recipe that combines several techniques to train long-context models efficiently. It typically involves:
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- TiledMLP to reduce memory usage in MLP layers.
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- Tiled Loss functions (like [CCE](#cut-cross-entropy-(cce) or [Liger](#liger-kernels)).
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- Activation Offloading to CPU.
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- Example: [ALST Example Configuration](https://github.com/axolotl-ai-cloud/axolotl/tree/main/examples/alst)
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## Large Models (Distributed Training)
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To train models that don't fit on a single GPU, you'll need to use a distributed training strategy like FSDP or DeepSpeed. These frameworks shard the model weights, gradients, and optimizer states across multiple GPUs and nodes.
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- **Learn more:** [Multi-GPU Guide](multi-gpu.qmd)
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- **Learn more:** [Multi-Node Guide](multi-node.qmd)
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### N-D Parallelism (Beta)
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For advanced scaling, Axolotl allows you to compose different parallelism techniques (e.g., Data, Tensor, Sequence, Expert Parallelism). This is a powerful approach to train an extremely large model by overcoming multiple bottlenecks at once.
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- **Learn more:** [N-D Parallelism Guide](nd_parallelism.qmd)
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## Quantization
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Techniques to reduce the precision of model weights for memory savings.
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### 4-bit Training (QLoRA)
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The recommended approach for quantization-based training. It loads the base model in 4-bit using `bitsandbytes` and then trains QLoRA adapters. See [Adapter Finetuning](#adapter-finetuning-lora-qlora) for details.
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### FP8 Training
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Enables training with 8-bit floating point precision on supported hardware (e.g., NVIDIA Hopper series GPUs) for significant speed and memory gains.
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- **Example:** [Llama 3 FP8 FSDP Example](https://github.com/axolotl-ai-cloud/axolotl/blob/main/examples/llama-3/3b-fp8-fsdp2.yaml)
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### NVFP4 (W4A4) LoRA
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Train LoRA adapters on a ModelOpt NVFP4 MoE checkpoint (the experts stay 4-bit-packed; LoRA `A` / `B` train in bf16).
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Two kernels support it: **SonicMoE** (`use_sonicmoe: true`, W4A4 native on Blackwell SM100+ or W4A16 elsewhere) and **ScatterMoE** (`use_scattermoe: true`, W4A16 on any CUDA GPU).
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- **Config:** `use_sonicmoe: true` or `use_scattermoe: true` with a ModelOpt NVFP4 `base_model` (e.g. `nvidia/Qwen3-30B-A3B-NVFP4`)
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- **Examples:** [Qwen3-30B-A3B (SonicMoE)](https://github.com/axolotl-ai-cloud/axolotl/blob/main/examples/qwen3/30b-a3b-nvfp4-lora.yaml), [GLM-5.2 (ScatterMoE)](https://github.com/axolotl-ai-cloud/axolotl/blob/main/examples/glm_moe_dsa/glm-5.2-nvfp4-lora.yaml)
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- **Learn more:** [ScatterMoE NVFP4](custom_integrations.qmd#scattermoe-nvfp4-w4a16-lora) / [SonicMoE NVFP4](custom_integrations.qmd#sonicmoe-nvfp4-w4a4-lora)
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### Quantization Aware Training (QAT)
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Simulates quantization effects during training, helping the model adapt and potentially improving the final accuracy of the quantized model.
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- **Learn more:** [QAT Documentation](qat.qmd)
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### GPTQ
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Allows you to finetune LoRA adapters on top of a model that has already been quantized using the GPTQ method.
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- **Example:** [GPTQ LoRA Example](https://github.com/axolotl-ai-cloud/axolotl/blob/main/examples/llama-2/gptq-lora.yml)
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### MoE Expert Quantization
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Quantizes MoE expert weights on load to reduce VRAM when training MoE models with adapters. Required for Transformers v5+ MoE models where experts use fused `nn.Parameter` tensors.
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- **Config:** `quantize_moe_experts: true`
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- **Learn more:** [MoE Expert Quantization](expert_quantization.qmd)
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