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- A from-scratch, compiled Deep Learning framework.
- Implements backpropagation (i.e. first-order reverse mode autodiff) and shape inference.
- The long-term goal is to provide several "low-level" backends, aiming to seek inspiration from projects such as TinyGrad, TVM, Luminal.
- OCANNL starts with a high-level representation, but can compile everything down to
forloops.
- OCANNL starts with a high-level representation, but can compile everything down to
- The library users can compile any amount of code into a monolithic routine. Depending on the use case:
- the whole training update step can be a single routine,
- or the step can be composed of a gradient update routine (a forward pass and a backprop pass) and a params update routine (e.g. SGD with momentum, ADAM, etc.),
- or the user can compile parts of a model separately, manually composing the corresponding forward pass code and the backprop code.
- Tensor axes are split into kinds: batch, input and output. Tensor dimensions have optional labels.
- The labels ensure a more precise semantics for dimension matching.
- In the future we might introduce axis labels as an alternative to positional axis selection, it would be a separate naming mechanism.
- OCANNL has full support for the
einsumnotation, integrated with shape inference. Supports static indexing, with a built-in operation to take a slice of the batch axes, integrated with shape inference. Extensible to more static indexing patterns as needs arise.- OCANNL does not have dynamic indexing (using the last axis of one tensor as indices into another tensor). If it's needed, it can be added (we had a prototype once, removed to reduce complexity). Then it would also be integrated with shape inference.
- OCANNL has a suite of tutorials doubling as tests with inline expectations.
- OCANNL offers two main levels of abstraction.
- The support for mixed-precision computations is upcoming.
- E.g. higher-precision network components, or gradients at a higher precision than values.
- Currently (v0.3), you can select the precision, and individual computation nodes track their precision, but mixing precisions might break things.
- Should be easily extensible.
- Model surgery should be starightforward (not sure if we are there yet).
- It's a feature, not a bug!
- To scale a tensor by a number, always use pointwise-multiplication, e.g.
2*.morm*.2. - Matrix-multiplying a tensor
mby a constant number, e.g.m*2, broadcasts the number to the shape of the input axes of the tensor. This results in an output-axes-only tensor (multi-axis-vector) that is the scaled sum over the input axes of the tensorm. - Matrix-multiplying a constant number by a tensor
m, e.g.2*m, broadcasts the number to the shape of the output axes of the tensor. This results in a tensor whose inputs are of the same shape as the inputs ofm, and the output shape is 1D (scalar), that is the scaled sum over the output axes of the tensorm. - The matrix-multiply operation behaves pointwise along the batch axes.
- To scale a tensor by a number, always use pointwise-multiplication, e.g.
On the critical path for the next major release v0.4:
- Restore signs of life for the Cuda backend.
- Mixed-precision computations: working and convenient.
For more details, see CHANGES.
- v0.3 shape inference, jitted routines: a major rewrite of the whole project.
- v0.3.3: continuous integration and opam release.
- v0.3.2: new shape inference feature: tracking leftmost axes -- complete inference for splicing, ellipsis-in-the-middle allowed in einsum notation.
- v0.3.1: sanitizing code inclusion (rootness checks).
- v0.3.0: declarative shape inference; replaced the session interface with a "jitted code routines" API. Cuda defunct.
- v0.2 inching toward GPU:
- v0.2.1 naive-cuda: a Cuda backend where blocks and threads are exposed via dedicated axis types.
- v0.2.0 stack-as-device: treating the C function stack as the "device memory".
- v0.1 GCCJIT backend:
- v0.1.2: multicore computations using a thread-local "task id" index.
- v0.1.1: inlining scalar constants, improved inlining for virtual nodes.
- v0.1.0: a
Gccjitbackend, single and double precision floats, code compiled as a monolithic update step function.
- v0.0 untagged: basic design around shape inference, high-level and low-level code representation. Now-abandoned Meta-OCaml and OCaml backends.
Why not just use OWL?
OCANNL follows different design choices than OWL. For example:
- OCANNL is not functorized.
- OCANNL has fewer abstraction layers.
- OCANNL has a more powerful shape inference.
- OCANNL only supports backpropagation, while OWL supports full forward and backward auto-diff.
- Some aspects are more centralized in OCANNL than in OWL and form the "infrastructure":
- Tensor indexing mechanisms are not extensible, other than changing OCANNL code.
- Shape inference is fully handled by OCANNL and not extensible, other than changing OCANNL code.
Tensorimplements "putting pieces together".Trainhas the optimization "frontend" and utilities.arrayjit, which may one day become a standalone library: generates the code, performs backend-agnostic optimizations (virtual nodes whose computation is inlined), implements the backends.
- Some aspects that are more core to OWL are less encapsulated in OCANNL, so it should be more natural to extend them.
- OCANNL provides lower-level compilation backends than OWL, it is more self-contained in this sense.
Although the project is called ocannl, the main package is called neural_nets_lib, to avoid the (opam linter's) complaint that the name can be confused with other packages. This also clarifies that ocannl is composed of arrayjit and neural_nets_lib.
The dependency on ocaml-cudajit is optional, so you have to install it first to enable the Cuda backend.
After you get some basic grasp of the aims and design of the project by reading files in test/ and bin/, you can improve your understanding by reading lib/shape.mli, lib/tensor.mli, lib/operation.ml and lib/train.ml.
