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| # Custom hardware for training | |
| The hardware you use to run model training and inference can have a big effect on performance. For a deep dive into GPUs make sure to check out Tim Dettmer's excellent [blog post](https://timdettmers.com/2020/09/07/which-gpu-for-deep-learning/). | |
| Let's have a look at some practical advice for GPU setups. | |
| ## GPU | |
| When you train bigger models you have essentially three options: | |
| - bigger GPUs | |
| - more GPUs | |
| - more CPU and NVMe (offloaded to by [DeepSpeed-Infinity](main_classes/deepspeed#nvme-support)) | |
| Let's start at the case where you have a single GPU. | |
| ### Power and Cooling | |
| If you bought an expensive high end GPU make sure you give it the correct power and sufficient cooling. | |
| **Power**: | |
| Some high end consumer GPU cards have 2 and sometimes 3 PCI-E 8-Pin power sockets. Make sure you have as many independent 12V PCI-E 8-Pin cables plugged into the card as there are sockets. Do not use the 2 splits at one end of the same cable (also known as pigtail cable). That is if you have 2 sockets on the GPU, you want 2 PCI-E 8-Pin cables going from your PSU to the card and not one that has 2 PCI-E 8-Pin connectors at the end! You won't get the full performance out of your card otherwise. | |
| Each PCI-E 8-Pin power cable needs to be plugged into a 12V rail on the PSU side and can supply up to 150W of power. | |
| Some other cards may use a PCI-E 12-Pin connectors, and these can deliver up to 500-600W of power. | |
| Low end cards may use 6-Pin connectors, which supply up to 75W of power. | |
| Additionally you want the high-end PSU that has stable voltage. Some lower quality ones may not give the card the stable voltage it needs to function at its peak. | |
| And of course the PSU needs to have enough unused Watts to power the card. | |
| **Cooling**: | |
| When a GPU gets overheated it will start throttling down and will not deliver full performance and it can even shutdown if it gets too hot. | |
| It's hard to tell the exact best temperature to strive for when a GPU is heavily loaded, but probably anything under +80C is good, but lower is better - perhaps 70-75C is an excellent range to be in. The throttling down is likely to start at around 84-90C. But other than throttling performance a prolonged very high temperature is likely to reduce the lifespan of a GPU. | |
| Next let's have a look at one of the most important aspects when having multiple GPUs: connectivity. | |
| ### Multi-GPU Connectivity | |
| If you use multiple GPUs the way cards are inter-connected can have a huge impact on the total training time. If the GPUs are on the same physical node, you can run: | |
| ``` | |
| nvidia-smi topo -m | |
| ``` | |
| and it will tell you how the GPUs are inter-connected. On a machine with dual-GPU and which are connected with NVLink, you will most likely see something like: | |
| ``` | |
| GPU0 GPU1 CPU Affinity NUMA Affinity | |
| GPU0 X NV2 0-23 N/A | |
| GPU1 NV2 X 0-23 N/A | |
| ``` | |
| on a different machine w/o NVLink we may see: | |
| ``` | |
| GPU0 GPU1 CPU Affinity NUMA Affinity | |
| GPU0 X PHB 0-11 N/A | |
| GPU1 PHB X 0-11 N/A | |
| ``` | |
| The report includes this legend: | |
| ``` | |
| X = Self | |
| SYS = Connection traversing PCIe as well as the SMP interconnect between NUMA nodes (e.g., QPI/UPI) | |
| NODE = Connection traversing PCIe as well as the interconnect between PCIe Host Bridges within a NUMA node | |
| PHB = Connection traversing PCIe as well as a PCIe Host Bridge (typically the CPU) | |
| PXB = Connection traversing multiple PCIe bridges (without traversing the PCIe Host Bridge) | |
| PIX = Connection traversing at most a single PCIe bridge | |
| NV# = Connection traversing a bonded set of # NVLinks | |
| ``` | |
| So the first report `NV2` tells us the GPUs are interconnected with 2 NVLinks, and the second report `PHB` we have a typical consumer-level PCIe+Bridge setup. | |
| Check what type of connectivity you have on your setup. Some of these will make the communication between cards faster (e.g. NVLink), others slower (e.g. PHB). | |
| Depending on the type of scalability solution used, the connectivity speed could have a major or a minor impact. If the GPUs need to sync rarely, as in DDP, the impact of a slower connection will be less significant. If the GPUs need to send messages to each other often, as in ZeRO-DP, then faster connectivity becomes super important to achieve faster training. | |
| #### NVlink | |
| [NVLink](https://en.wikipedia.org/wiki/NVLink) is a wire-based serial multi-lane near-range communications link developed by Nvidia. | |
| Each new generation provides a faster bandwidth, e.g. here is a quote from [Nvidia Ampere GA102 GPU Architecture](https://www.nvidia.com/content/dam/en-zz/Solutions/geforce/ampere/pdf/NVIDIA-ampere-GA102-GPU-Architecture-Whitepaper-V1.pdf): | |
| > Third-Generation NVLink® | |
| > GA102 GPUs utilize NVIDIA’s third-generation NVLink interface, which includes four x4 links, | |
| > with each link providing 14.0625 GB/sec bandwidth in each direction between two GPUs. Four | |
| > links provide 56.25 GB/sec bandwidth in each direction, and 112.5 GB/sec total bandwidth | |
| > between two GPUs. Two RTX 3090 GPUs can be connected together for SLI using NVLink. | |
| > (Note that 3-Way and 4-Way SLI configurations are not supported.) | |
| So the higher `X` you get in the report of `NVX` in the output of `nvidia-smi topo -m` the better. The generation will depend on your GPU architecture. | |
| Let's compare the execution of a gpt2 language model training over a small sample of wikitext. | |
| The results are: | |
| | NVlink | Time | | |
| | ----- | ---: | | |
| | Y | 101s | | |
| | N | 131s | | |
| You can see that NVLink completes the training ~23% faster. In the second benchmark we use `NCCL_P2P_DISABLE=1` to tell the GPUs not to use NVLink. | |
| Here is the full benchmark code and outputs: | |
| ```bash | |
| # DDP w/ NVLink | |
| rm -r /tmp/test-clm; CUDA_VISIBLE_DEVICES=0,1 python -m torch.distributed.launch \ | |
| --nproc_per_node 2 examples/pytorch/language-modeling/run_clm.py --model_name_or_path gpt2 \ | |
| --dataset_name wikitext --dataset_config_name wikitext-2-raw-v1 --do_train \ | |
| --output_dir /tmp/test-clm --per_device_train_batch_size 4 --max_steps 200 | |
| {'train_runtime': 101.9003, 'train_samples_per_second': 1.963, 'epoch': 0.69} | |
| # DDP w/o NVLink | |
| rm -r /tmp/test-clm; CUDA_VISIBLE_DEVICES=0,1 NCCL_P2P_DISABLE=1 python -m torch.distributed.launch \ | |
| --nproc_per_node 2 examples/pytorch/language-modeling/run_clm.py --model_name_or_path gpt2 \ | |
| --dataset_name wikitext --dataset_config_name wikitext-2-raw-v1 --do_train | |
| --output_dir /tmp/test-clm --per_device_train_batch_size 4 --max_steps 200 | |
| {'train_runtime': 131.4367, 'train_samples_per_second': 1.522, 'epoch': 0.69} | |
| ``` | |
| Hardware: 2x TITAN RTX 24GB each + NVlink with 2 NVLinks (`NV2` in `nvidia-smi topo -m`) | |
| Software: `pytorch-1.8-to-be` + `cuda-11.0` / `transformers==4.3.0.dev0` | |