Note: configuring train_batch_size is required. {: .notice--warning}
train_batch_size: [integer]
Value | Example |
---|---|
The effective training batch size. This is the amount of data samples that leads to one step of model update. train_batch_size is aggregated by the batch size that a single GPU processes in one forward/backward pass (a.k.a., train_step_batch_size), the gradient accumulation steps (a.k.a., gradient_accumulation_steps), and the number of GPUs. | 32 |
train_micro_batch_size_per_gpu: [integer]
Description | Default |
---|---|
Batch size to be processed by one GPU in one step (without gradient accumulation). When specified, gradient_accumulation_steps is automatically calculated using train_batch_size and number of GPUs. Should not be concurrently specified with gradient_accumulation_steps in the configuration JSON. | train_batch_size value |
gradient_accumulation_steps: [integer]
Description | Default |
---|---|
Number of training steps to accumulate gradients before averaging and applying them. This feature is sometimes useful to improve scalability since it results in less frequent communication of gradients between steps. Another impact of this feature is the ability to train with larger batch sizes per GPU. When specified, train_step_batch_size is automatically calculated using train_batch_size and number of GPUs. Should not be concurrently specified with train_step_batch_size in the configuration JSON. | 1 |
optimizer: [dictionary]
Fields | Value | Example |
---|---|---|
type | The optimizer name. DeepSpeed natively supports Adam, OneBitAdam, and LAMB optimizers and will import other optimizers from torch. | "Adam" |
params | Dictionary of parameters to instantiate optimizer. The parameter names must match the optimizer constructor signature (e.g., for Adam). | {"lr": 0.001, "eps": 1e-8} |
Example of optimizer
"optimizer": {
"type": "Adam",
"params": {
"lr": 0.001,
"betas": [
0.8,
0.999
],
"eps": 1e-8,
"weight_decay": 3e-7
}
}
Another example of optimizer with 1-bit Adam specific parameters is as follows.
"optimizer": {
"type": "OneBitAdam",
"params": {
"lr": 0.001,
"betas": [
0.8,
0.999
],
"eps": 1e-8,
"weight_decay": 3e-7,
"freeze_step": 400,
"cuda_aware": true
}
}
scheduler: [dictionary]
Fields | Value | Example |
---|---|---|
type | The scheduler name. See here for list of support schedulers. | "WarmupLR" |
params | Dictionary of parameters to instantiate scheduler. The parameter names should match scheduler constructor signature. | {"warmup_min_lr": 0, "warmup_max_lr": 0.001} |
Example of scheduler
"scheduler": {
"type": "WarmupLR",
"params": {
"warmup_min_lr": 0,
"warmup_max_lr": 0.001,
"warmup_num_steps": 1000
}
}
fp32_allreduce: [boolean]
Description | Default |
---|---|
During gradient averaging perform allreduce with 32 bit values | false |
prescale_gradients: [boolean]
Description | Default |
---|---|
Scale gradients before doing allreduce | false |
gradient_predivide_factor: [float]
Description | Default |
---|---|
Before gradient averaging predivide gradients by a specified factor, can sometimes help with fp16 stability when scaling to large numbers of GPUs | 1.0 |
sparse_gradients: [boolean]
Description | Default |
---|---|
Enable sparse compression of torch.nn.Embedding gradients. | false |
Note: this mode cannot be combined with the amp
mode described below.
{: .notice--warning}
fp16: [dictionary]
Description | Default |
---|---|
Configuration for using mixed precision/FP16 training that leverages NVIDIA's Apex package. An example, including the available dictionary keys is illustrated below. NOTE: this does not use Apex's AMP mode that allows for more flexibility in mixed precision training modes, this mode is similar to AMP's O2 mode. Please see AMP support below if you want to use more complex mixed precision modes. If you want to use ZeRO (currently) you must use this mode. | None |
"fp16": {
"enabled": true,
"loss_scale": 0,
"initial_scale_power": 32,
"loss_scale_window": 1000,
"hysteresis": 2,
"min_loss_scale": 1
}
fp16:enabled: [boolean]
Description | Default |
---|---|
enabled is a fp16 parameter indicating whether or not FP16 training enabled. | false |
fp16:loss_scale: [float]
Description | Default |
---|---|
loss_scale is a fp16 parameter representing the loss scaling value for FP16 training. The default value of 0.0 results in dynamic loss scaling, otherwise the value will be used for static fixed loss scaling. | 0.0 |
fp16:initial_scale_power: [integer]
Description | Default |
---|---|
initial_loss_scale_power is a fp16 parameter representing the power of the initial dynamic loss scale value. The actual loss scale is computed as 2initial_loss_scale_power. | 32 |
fp16:loss_scale_window: [integer]
Description | Default |
---|---|
loss_scale_window is a fp16 parameter representing the window over which to raise/lower the dynamic loss scale value. | 1000 |
fp16:hysteresis: [integer]
Description | Default |
---|---|
hysteresis is a fp16 parameter representing the delay shift in dynamic loss scaling. | 2 |
fp16:min_loss_scale: [integer]
Description | Default |
---|---|
min_loss_scale is a fp16 parameter representing the minimum dynamic loss scale value. | 1000 |
Note: this mode cannot be combined with the fp16
mode described above. In addition this mode is not currently compatible with ZeRO.
{: .notice--warning}
amp: [dictionary]
Description | Default |
---|---|
Configuration for using automatic mixed precision (AMP) training that leverages NVIDIA's Apex AMP package. An example, including the available dictionary keys is illustrated below. Is not compatible with fp16 mode above or ZeRO. Any parameters outside of "enabled" will be passed to AMP's initialize call, see the API and descriptions here at the apex.amp.initialize documentation. |
None |
"amp": {
"enabled": true,
...
"opt_level": "O1",
...
}
amp:enabled: [boolean]
Description | Default |
---|---|
enabled is an amp parameter indicating whether or not AMP training is enabled. | false |
amp params: [various]
Description | Default |
---|---|
Any parameters outside of "enabled" will be passed to AMP's initialize call, see the API and descriptions here at the apex.amp.initialize documentation. | None |
gradient_clipping: [float]
Description | Default |
---|---|
Enable gradient clipping with value | 0 |
Enabling and configure ZeRO memory optimizations
"zero_optimization": {
"stage": [0|1|2],
"allgather_partitions": [true|false],
"allgather_bucket_size": 500000000,
"overlap_comm": false,
"reduce_scatter": [true|false],
"reduce_bucket_size": 500000000,
"contiguous_gradients" : [true|false],
"cpu_offload": [true|false]
}
zero_optimization: [dictionary]
Description | Default |
---|---|
Enable ZeRO memory optimization wrapper for FP16 Training. Currently compatible only with Adam optimizer. | false |
stage: [integer]
Description | Default |
---|---|
Chooses different stages of ZeRO Optimizer. Stage 0, 1, and 2 refer to disabled, optimizer state partitioning, and optimizer+gradient state partitiong, respectively. | 0 |
allgather_partitions: [boolean]
Description | Default |
---|---|
Chooses between allgather collective or a series of broadcast collectives to gather updated parameters from all the GPUs at the end of each step | true |
allgather_bucket_size: [boolean]
Description | Default |
---|---|
Number of elements allgathered at a time. Limits the memory required for the allgather for large model sizes | 500000000 |
overlap_comm: [boolean]
Description | Default |
---|---|
Attempts to overlap the reduction of the gradients with backward computation | false |
reduce_scatter: [boolean]
Description | Default |
---|---|
Uses reduce or reduce scatter instead of allreduce to average gradients | true |
reduce_bucket_size: [boolean]
Description | Default |
---|---|
Number of elements reduced/allreduced at a time. Limits the memory required for the allgather for large model sizes | 500000000 |
contiguous_gradients: [boolean]
Description | Default |
---|---|
Copies the gradients to a contiguous buffer as they are produced. Avoids memory fragmentation during backward pass. Only useful when running very large models. | False |
cpu_offload: [boolean]
Description | Default |
---|---|
Enable offloading of optimizer memory and computation to CPU. This frees up GPU memory for larger models or batch sizes. | False |
steps_per_print: [integer]
Description | Default |
---|---|
Print train loss every N steps | 10 |
wall_clock_breakdown: [boolean]
Description | Default |
---|---|
Enable timing of the latency of forward/backward/update training phases | false |
dump_state: [boolean]
Description | Default |
---|---|
Print out state information of DeepSpeed object after initialization | false |
"activation_checkpointing": {
"partition_activations": false,
"cpu_checkpointing": false,
"contiguous_memory_optimization": false,
"number_checkpoints": null,
"synchronize_checkpoint_boundary": false,
"profile": false
}
partition_activations: [boolean]
Description | Default |
---|---|
Enables partition activation when used with model parallelism | false |
cpu_checkpointing: [boolean]
Description | Default |
---|---|
Offloads partitioned activations to CPU if partition_activations is enabled | false |
contiguous_memory_optimization: [boolean]
Description | Default |
---|---|
Copies partitioned activations so that they are contiguous in memory | false |
number_checkpoints: [integer]
Description | Default |
---|---|
Total number of activation checkpoints used to allocate memory buffer for contiguous_memoty_optimization | None |
synchronize_checkpoint_boundary: [boolean]
Description | Default |
---|---|
Inserts torch.cuda.synchronize() at each checkpoint boundary. | false |
profile: [boolean]
Description | Default |
---|---|
Logs the forward and backward time for each checkpoint function | false |
sparse_attention: [dictionary]
Fields | Value | Example |
---|---|---|
mode | A string determining sparsity structure type. Deepspeed currently supports "dense" , "fixed" , "bigbird" , "bslongformer" , and "variable" . |
"fixed" |
block | An integer determining the block size. Current implementation of sparse self-attention is based on blocked sparse matrices. In which this parameter defines size of such blocks, Block X Block . |
16 |
different_layout_per_head | A boolean determining if each head should be assigned a different sparsity layout; this will be satisfied based on availability. | false |
num_local_blocks | An integer determining the number of random blocks in each block row; only used in "fixed" mode. |
4 |
num_global_blocks | An integer determining how many consecutive blocks in a local window is used as the representative of the window for global attention; used in "fixed" and "bigbird" modes. |
1 |
attention | A string determining attention type. Attention can be "unidirectional" , such as autoregressive models, in which tokens attend only to tokens appear before them in the context. Considering that, the upper triangular of attention matrix is empty. Or it can be "bidirectional" , such as BERT, in which tokens can attend to any other tokens before or after them. Then, the upper triangular part of the attention matrix is mirror of the lower triangular; used in "fixed" and "variable" modes. |
"bidirectional" |
horizontal_global_attention | A boolean determining if blocks that are global representative of a local window, also attend to all other blocks. This is valid only if attention type is "bidirectional" . Looking at the attention matrix, that means global attention not only includes the vertical blocks, but also horizontal blocks; used in "fixed" and "variable" modes. |
false |
num_different_global_patterns | An integer determining number of different global attentions layouts. While global attention can be fixed by which block/s are representative of any local window, since there are multi-heads, each head can use a different global representative; used only in "fixed" mode. |
4 |
num_random_blocks | An integer determining the number of random blocks in each block row; used in "variable" and "bigbird" modes. |
0 |
local_window_blocks | A list of integers determining the number of blocks in each local attention window. It assumes first number determines # of blocks in the first local window, second the second window, ..., and the last number determines the number of blocks in the remaining local windows; only used in "variable" mode. |
[4] |
global_block_indices | A list of integers determining which blocks are considered as global attention. Given indices, determine the blocks that all other token blocks attend to and they attend to all other token blocks. Notice that if global_block_end_indices parameter is set, this parameter is used as starting index of each global window; used in "variable" and "bslongformer" modes. |
[0] |
global_block_end_indices | A list of integers determining end indices of global window blocks. By default this is not used. But if it is set, it must have the same size of global_block_indices parameter, and combining this two parameters, for each index i, blocks from global_block_indices[i] to global_block_end_indices[i], exclusive, are considered as global attention; used in "variable" and "bslongformer" modes. |
None |
num_sliding_window_blocks | An integer determining the number of blocks in sliding local attention window; used in "bigbird" and "bslongformer" modes. |
3 |
Example of sparse_attention
"sparse_attention": {
"mode": "fixed",
"block": 16,
"different_layout_per_head": true,
"num_local_blocks": 4,
"num_global_blocks": 1,
"attention": "bidirectional",
"horizontal_global_attention": false,
"num_different_global_patterns": 4,
"num_random_blocks": 0,
"local_window_blocks": [4],
"global_block_indices": [0],
"global_block_end_indices": None,
"num_sliding_window_blocks": 3
}