Sometimes it is helpful to understand the life cycle of a Taichi kernel. In short, compilation will only happen on the first invocation of an instance of a kernel.
The life cycle of a Taichi kernel has the following stages:
- Kernel registration
- Template instantiation and caching
- Python AST transforms
- Taichi IR compilation, optimization, and executable generation
Let's consider the following simple kernel:
@ti.kerneldef add(field: ti.template(), delta: ti.i32): for i in field: field[i] += delta
We allocate two 1D fields to simplify discussion:
x = ti.field(dtype=ti.f32, shape=128)y = ti.field(dtype=ti.f32, shape=16)
ti.kernel decorator is executed, a kernel named
registered. Specifically, the Python Abstract Syntax Tree (AST) of the
add function will be memorized. No compilation will happen until the
first invocation of
add is called for the first time, the Taichi frontend compiler
will instantiate the kernel.
When you have a second call with the same template signature (explained later), e.g.,
Taichi will directly reuse the previously compiled binary.
Arguments hinted with
ti.template() are template arguments, and will
incur template instantiation. For example,
will lead to a new instantiation of add.
Template signatures are what distinguish different instantiations of
a kernel template. The signature of
add(x, 42) is
(x, ti.i32), which
is the same as that of
add(x, 1). Therefore, the latter can reuse the
previously compiled binary. The signature of
add(y, 42) is
(y, ti.i32), a different value from the previous signature, hence a
new kernel will be instantiated and compiled.
Many basic operations in the Taichi standard library are implemented using Taichi kernels using metaprogramming tricks. Invoking them will incur implicit kernel instantiations.
you invoke these functions, you will see kernel instantiations, as
Taichi kernels will be generated to offload the hard work to multiple
As mentioned before, the second time you call the same operation, the cached compiled kernel will be reused and no further compilation is needed.
When a new instantiation happens, the Taichi frontend compiler (i.e.,
ASTTransformer Python class) will transform the kernel body AST
into a Python script, which, when executed, emits a Taichi frontend AST.
Basically, some patches are applied to the Python AST so that the Taichi
frontend can recognize it.
The Taichi AST lowering pass translates Taichi frontend IR into hierarchical static single assignment (SSA) IR, which allows a series of further IR passes to happen, such as
- Loop vectorization
- Type inference and checking
- General simplifications such as common subexpression elimination (CSE), dead instruction elimination (DIE), constant folding, and store forwarding
- Access lowering
- Data access optimizations
- Reverse-mode automatic differentiation (if using differentiable programming)
- Parallelization and offloading
- Atomic operation demotion
Finally, the optimized SSA IR is fed into backend compilers such as LLVM or Apple Metal/OpenGL shader compilers. The backend compilers then generate high-performance executable CPU/GPU programs.
Taichi kernels will be ultimately launched as multi-threaded CPU tasks or GPU kernels.