IBM Analog Hardware Acceleration Kit is an open source Python toolkit for exploring and using the capabilities of in-memory computing devices in the context of artificial intelligence.
⚠️ This library is currently in beta and under active development. Please be mindful of potential issues and keep an eye for improvements, new features and bug fixes in upcoming versions.
The toolkit consists of two main components:
A series of primitives and features that allow using the toolkit within
PyTorch:
- Analog neural network modules (fully connected layer, 1d/2d/3d convolution layers, LSTM layer, sequential container).
- Analog training using torch training workflow:
- Analog torch optimizers (SGD).
- Analog in-situ training using customizable device models and algorithms (Tiki-Taka).
- Analog inference using torch inference workflow:
- State-of-the-art statistical model of a phase-change memory (PCM) array calibrated on hardware measurements from a 1 million PCM devices chip.
- Hardware-aware training with hardware non-idealities and noise included in the forward pass to make the trained models more robust during inference on Analog hardware.
A high-performant (CUDA-capable) C++ simulator that allows for simulating a wide range of analog devices and crossbar configurations by using abstract functional models of material characteristics with adjustable parameters. Features include:
- Forward pass output-referred noise and device fluctuations, as well as adjustable ADC and DAC discretization and bounds
- Stochastic update pulse trains for rows and columns with finite weight update size per pulse coincidence
- Device-to-device systematic variations, cycle-to-cycle noise and adjustable asymmetry during analog update
- Adjustable device behavior for exploration of material specifications for training and inference
- State-of-the-art dynamic input scaling, bound management, and update management schemes
Along with the two main components, the toolkit includes other functionalities such as:
- A library of device presets that are calibrated to real hardware data and based on models in the literature, along with a configuration that specifies a particular device and optimizer choice.
- A module for executing high-level use cases ("experiments"), such as neural network training with minimal code overhead.
- A utility to automatically convert a downloaded model (e.g., pre-trained) to its equivalent Analog model by replacing all linear/conv layers to Analog layers (e.g., for convenient hardware-aware training).
- Integration with the AIHW Composer platform, a no-code web experience that allows executing experiments in the cloud.
In case you are using the IBM Analog Hardware Acceleration Kit for your research, please cite the AICAS21 paper that describes the toolkit:
Malte J. Rasch, Diego Moreda, Tayfun Gokmen, Manuel Le Gallo, Fabio Carta, Cindy Goldberg, Kaoutar El Maghraoui, Abu Sebastian, Vijay Narayanan. "A flexible and fast PyTorch toolkit for simulating training and inference on analog crossbar arrays" (2021 IEEE 3rd International Conference on Artificial Intelligence Circuits and Systems)
from torch import Tensor
from torch.nn.functional import mse_loss
# Import the aihwkit constructs.
from aihwkit.nn import AnalogLinear
from aihwkit.optim import AnalogSGD
x = Tensor([[0.1, 0.2, 0.4, 0.3], [0.2, 0.1, 0.1, 0.3]])
y = Tensor([[1.0, 0.5], [0.7, 0.3]])
# Define a network using a single Analog layer.
model = AnalogLinear(4, 2)
# Use the analog-aware stochastic gradient descent optimizer.
opt = AnalogSGD(model.parameters(), lr=0.1)
opt.regroup_param_groups(model)
# Train the network.
for epoch in range(10):
pred = model(x)
loss = mse_loss(pred, y)
loss.backward()
opt.step()
print('Loss error: {:.16f}'.format(loss))You can find more examples in the examples/ folder of the project, and
more information about the library in the documentation. Please note that
the examples have some additional dependencies - you can install them via
pip install -r requirements-examples.txt.
You can find interactive notebooks and tutorials in the notebooks/ directory.
We also recommend to take a look at the tutorial article that describes the usage of the toolkit that can be found here:
Manuel Le Gallo, Corey Lammie, Julian Buechel, Fabio Carta, Omobayode Fagbohungbe, Charles Mackin, Hsinyu Tsai, Vijay Narayanan, Abu Sebastian, Kaoutar El Maghraoui, Malte J. Rasch. "Using the IBM Analog In-Memory Hardware Acceleration Kit for Neural Network Training and Inference" (APL Machine Learning Journal:1(4) 2023)
In traditional hardware architecture, computation and memory are siloed in different locations. Information is moved back and forth between computation and memory units every time an operation is performed, creating a limitation called the von Neumann bottleneck.
Analog AI delivers radical performance improvements by combining compute and memory in a single device, eliminating the von Neumann bottleneck. By leveraging the physical properties of memory devices, computation happens at the same place where the data is stored. Such in-memory computing hardware increases the speed and energy efficiency needed for next-generation AI workloads.
An in-memory computing chip typically consists of multiple arrays of memory devices that communicate with each other. Many types of memory devices such as phase-change memory (PCM), resistive random-access memory (RRAM), and Flash memory can be used for in-memory computing.
Memory devices have the ability to store synaptic weights in their analog charge (Flash) or conductance (PCM, RRAM) state. When these devices are arranged in a crossbar configuration, it allows to perform an analog matrix-vector multiplication in a single time step, exploiting the advantages of analog storage capability and Kirchhoff’s circuits laws. You can learn more about it in our online demo.
In deep learning, data propagation through multiple layers of a neural network involves a sequence of matrix multiplications, as each layer can be represented as a matrix of synaptic weights. The devices are arranged in multiple crossbar arrays, creating an artificial neural network where all matrix multiplications are performed in-place in an analog manner. This structure allows to run deep learning models at reduced energy consumption.
- IBM Research blog: [Open-sourcing analog AI simulation]: https://research.ibm.com/blog/analog-ai-for-efficient-computing
- We are proud to share that the AIHWKIT and the companion cloud composer received the IEEE OPEN SOURCE SCIENCE award in 2023.
The preferred way to install this package is by using the Python package index:
pip install aihwkitThere is a conda package for aihwkit available in conda-forge. It can be installed in a conda environment running on a Linux or WSL in a Windows system.
-
CPU
conda install -c conda-forge aihwkit
-
GPU
conda install -c conda-forge aihwkit-gpu
If you encounter any issues during download or want to compile the package
for your environment, please take a look at the advanced installation guide.
That section describes the additional libraries and tools required for
compiling the sources using a build system based on cmake.
For GPU support, you can also build a docker container following the CUDA Dockerfile instructions. You can then run a GPU enabled docker container using the follwing command from your peoject dircetory
docker run --rm -it --gpus all -v $(pwd):$HOME --name aihwkit aihwkit:cuda bashIBM Research has developed IBM Analog Hardware Acceleration Kit, with Malte Rasch, Diego Moreda, Fabio Carta, Julian Büchel, Corey Lammie, Charles Mackin, Kim Tran, Tayfun Gokmen, Manuel Le Gallo-Bourdeau, and Kaoutar El Maghraoui as the initial core authors, along with many contributors.
You can contact us by opening a new issue in the repository or alternatively
at the aihwkit@us.ibm.com email address.
This project is licensed under Apache License 2.0.