# 2D Tensor Parallelism Author: Zhengda Bian, Yongbin Li **Prerequisite** - [Define Your Configuration](../basics/define_your_config.md) - [Configure Parallelization](../basics/configure_parallelization.md) - [1D Tensor Parallelism](./1D_tensor_parallel.md) **Example Code** - [ColossalAI-Examples - 2D Tensor Parallelism](https://github.com/hpcaitech/ColossalAI-Examples/tree/main/features/tensor_parallel/tensor_parallel_2d.py) **Related Paper** - [An Efficient 2D Method for Training Super-Large Deep Learning Models](https://arxiv.org/pdf/2104.05343.pdf) ## Introduction 1D tensor parallelism does not partition activations, which can also consume a great amount of memory in terms of large-scale models. To evenly distribute the computation and memory load, [an efficient 2D tensor parallelism algorithm](https://arxiv.org/pdf/2104.05343.pdf) was introduced based on SUMMA (Scalable Universal Matrix Multiplication Algorithm). Let's still take a linear layer $Y = XA$ as an example. Given $P=q\times q$ processors (necessary condition), e.g. $q=2$, we split both the input $X$ and weight $A$ into $$ \left[\begin{matrix} X_{10} & X_{11} \\ X_{00} & X_{01} \end{matrix} \right] \text{~and~} \left[\begin{matrix} A_{10} & A_{11} \\ A_{00} & A_{01} \end{matrix} \right]. $$ The calculation includes $q$ steps. When $t=1$, $X_{i0}$ is broadcasted in its row, and $A_{0j}$ is broadcasted in its column. So, we have $$ \left[\begin{matrix} X_{10},A_{00} & X_{10},A_{01} \\ X_{00},A_{00} & X_{00},A_{01} \end{matrix} \right]. $$ Then we multiply $X_{i0}$ and $A_{0j}$ on each processor $(i, j)$ as $$ \left[\begin{matrix} X_{10}A_{00} & X_{10}A_{01} \\ X_{00}A_{00} & X_{00}A_{01} \end{matrix} \right] (1). $$ Similarly, when $t=2$, $X_{i1}$ is broadcasted in its row, $A_{1j}$ is broadcasted in its column, and we multiply them as $$ \left[\begin{matrix} X_{11}A_{10} & X_{11}A_{11} \\ X_{01}A_{10} & X_{01}A_{11} \end{matrix} \right] (2). $$ By adding $(1)$ and $(2)$ up, we have $$ Y = XA = \left[\begin{matrix} X_{10}A_{00}+X_{11}A_{10} & X_{10}A_{01}+X_{11}A_{11} \\ X_{00}A_{00}+X_{01}A_{10} & X_{00}A_{01}+X_{01}A_{11} \end{matrix} \right]. $$ ## Efficiency Given $P=q\times q$ processors, we present the theoretical computation and memory cost, as well as the communication cost based on the ring algorithm in both the forward and backward pass of 2D tensor parallelism. | Computation | Memory (parameters) | Memory (activations) | Communication (bandwidth) | Communication (latency) | | :-: | :-: | :-: | :-: | :-: | | $O(1/q^2)$ | $O(1/q^2)$ | $O(1/q^2)$ | $O(6(q-1)/q)$ | $O(6(q-1))$ | ## Usage To enable 2D tensor parallelism for our model, e.g. on 4 GPUs, we need to configure the parallism setting as below. ```python CONFIG = dict(parallel=dict( data=1, pipeline=1, tensor=dict(size=4, mode='2d'), )) ``` Then Colossal-AI will automatically apply 2D parallelism to all the layers from `colossalai.nn`. Let's define a model that consists of a two-layer multi-layer perceptron (MLP) as below. ```python import colossalai import colossalai.nn as col_nn import torch from colossalai.utils import print_rank_0 class MLP(torch.nn.Module): def __init__(self, dim: int = 256): super().__init__() intermediate_dim = dim * 4 self.dense_1 = col_nn.Linear(dim, intermediate_dim) print_rank_0(f'Weight of the first linear layer: {self.dense_1.weight.shape}') self.activation = torch.nn.GELU() self.dense_2 = col_nn.Linear(intermediate_dim, dim) print_rank_0(f'Weight of the second linear layer: {self.dense_2.weight.shape}') self.dropout = col_nn.Dropout(0.1) def forward(self, x): x = self.dense_1(x) print_rank_0(f'Output of the first linear layer: {x.shape}') x = self.activation(x) x = self.dense_2(x) print_rank_0(f'Output of the second linear layer: {x.shape}') x = self.dropout(x) return x ``` Launch Colossal-AI on 4 GPUs and build the model ```python parser = colossalai.get_default_parser() colossalai.launch(config=CONFIG, rank=args.rank, world_size=args.world_size, local_rank=args.local_rank, host=args.host, port=args.port) m = MLP() ``` We will see the shapes of partitioned parameters(e.g. weights) in the MLP model. ```shell Weight of the first linear layer: torch.Size([128, 512]) Weight of the second linear layer: torch.Size([512, 128]) ``` The complete weight of the first linear layer is supposed to have the shape `[256, 1024]`. After the partitioning of 2D parallelism, it becomes `[128, 512]` on each GPU. Similarly, the second layer partitions the weight `[1024, 256]` into `[512, 128]`. We can run the model with some random inputs. ```python from colossalai.context import ParallelMode from colossalai.core import global_context as gpc from colossalai.utils import get_current_device x = torch.randn((16, 256), device=get_current_device()) # partition input torch.distributed.broadcast(x, src=0) x = torch.chunk(x, 2, dim=0)[gpc.get_local_rank(ParallelMode.PARALLEL_2D_COL)] x = torch.chunk(x, 2, dim=-1)[gpc.get_local_rank(ParallelMode.PARALLEL_2D_ROW)] print_rank_0(f'Input: {x.shape}') x = m(x) ``` Then we can see the shapes of activation results. ```shell Input: torch.Size([8, 128]) Output of the first linear layer: torch.Size([8, 512]) Output of the second linear layer: torch.Size([8, 128]) ``` The activation tensors in 2D parallelism are all split in both row and column. E.g. the output of the first linear layer has the shape `[8, 512]`, while the second layer has the output of `[8, 128]`.