7.8 KiB
Kernel API
[TOC]
G-API Kernel API
The core idea behind G-API is portability -- a pipeline built with G-API must be portable (or at least able to be portable). It means that either it works out-of-the box when compiled for new platform, or G-API provides necessary tools to make it running there, with little-to-no changes in the algorithm itself.
This idea can be achieved by separating kernel interface from its implementation. Once a pipeline is built using kernel interfaces, it becomes implementation-neutral -- the implementation details (i.e. which kernels to use) are passed on a separate stage (graph compilation).
Kernel-implementation hierarchy may look like:
@dot Kernel API/implementation hierarchy example digraph { rankdir=BT; node [shape=record];
ki_a [label="{ interface\nA}"]; ki_b [label="{ interface\nB}"];
{rank=same; ki_a ki_b};
"CPU::A" -> ki_a [dir="forward"]; "OpenCL::A" -> ki_a [dir="forward"]; "Halide::A" -> ki_a [dir="forward"];
"CPU::B" -> ki_b [dir="forward"]; "OpenCL::B" -> ki_b [dir="forward"]; "Halide::B" -> ki_b [dir="forward"]; } @enddot
A pipeline itself then can be expressed only in terms of A
, B
, and
so on, and choosing which implementation to use in execution becomes
an external parameter.
Defining a kernel
G-API provides a macro to define a new kernel interface -- G_TYPED_KERNEL():
@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_api
This macro is a shortcut to a new type definition. It takes three arguments to register a new type, and requires type body to be present (see [below](@ref gapi_kernel_supp_info)). The macro arguments are:
- Kernel interface name -- also serves as a name of new type defined with this macro;
- Kernel signature -- an
std::function<>
-like signature which defines API of the kernel; - Kernel's unique name -- used to identify kernel when its type informattion is stripped within the system.
Kernel declaration may be seen as function declaration -- in both cases a new entity must be used then according to the way it was defined.
Kernel signature defines kernel's usage syntax -- which parameters it takes during graph construction. Implementations can also use this signature to derive it into backend-specific callback signatures (see next chapter).
Kernel may accept values of any type, and G-API dynamic types are
handled in a special way. All other types are opaque to G-API and
passed to kernel in outMeta()
or in execution callbacks as-is.
Kernel's return value can only be of G-API dynamic type -- cv::GMat,
cv::GScalar, or cv::GArray<T>
. If an operation has more than one
output, it should be wrapped into an std::tuple<>
(which can contain
only mentioned G-API types). Arbitrary-output-number operations are
not supported.
Once a kernel is defined, it can be used in pipelines with special, G-API-supplied method "::on()". This method has the same signature as defined in kernel, so this code:
@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_on
is a perfectly legal construction. This example has some verbosity, though, so usually a kernel declaration comes with a C++ function wrapper ("factory method") which enables optional parameters, more compact syntax, Doxygen comments, etc:
@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_wrap
so now it can be used like:
@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_wrap_call
Extra information
In the current version, kernel declaration body (everything within the
curly braces) must contain a static function outMeta()
. This function
establishes a functional dependency between operation's input and
output metadata.
Metadata is an information about data kernel operates on. Since
non-G-API types are opaque to G-API, G-API cares only about G*
data
descriptors (i.e. dimensions and format of cv::GMat, etc).
outMeta()
is also an example of how kernel's signature can be
transformed into a derived callback -- note that in this example,
outMeta()
signature exactly follows the kernel signature (defined
within the macro) but is different -- where kernel expects cv::GMat,
outMeta()
takes and returns cv::GMatDesc (a G-API structure metadata
for cv::GMat).
The point of outMeta()
is to propagate metadata information within
computation from inputs to outputs and infer metadata of internal
(intermediate, temporary) data objects. This information is required
for further pipeline optimizations, memory allocation, and other
operations done by G-API framework during graph compilation.
Implementing a kernel
Once a kernel is declared, its interface can be used to implement versions of this kernel in different backends. This concept is naturally projected from object-oriented programming "Interface/Implementation" idiom: an interface can be implemented multiple times, and different implementations of a kernel should be substitutable with each other without breaking the algorithm (pipeline) logic (Liskov Substitution Principle).
Every backend defines its own way to implement a kernel interface. This way is regular, though -- whatever plugin is, its kernel implementation must be "derived" from a kernel interface type.
Kernel implementation are then organized into kernel packages. Kernel packages are passed to cv::GComputation::compile() as compile arguments, with some hints to G-API on how to select proper kernels (see more on this in "Heterogeneity"[TBD]).
For example, the aforementioned Filter2D
is implemented in
"reference" CPU (OpenCV) plugin this way (NOTE -- this is a
simplified form with improper border handling):
@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_ocv
Note how CPU (OpenCV) plugin has transformed the original kernel signature:
- Input cv::GMat has been substituted with cv::Mat, holding actual input data for the underlying OpenCV function call;
- Output cv::GMat has been transformed into extra output parameter, thus
GCPUFilter2D::run()
takes one argument more than the original kernel signature.
The basic intuition for kernel developer here is not to care where that cv::Mat objects come from instead of the original cv::GMat -- and just follow the signature conventions defined by the plugin. G-API will call this method during execution and supply all the necessary information (and forward the original opaque data as-is).
Compound kernels
Sometimes kernel is a single thing only on API level. It is convenient for users, but on a particular implementation side it would be better to have multiple kernels (a subgraph) doing the thing instead. An example is goodFeaturesToTrack() -- while in OpenCV backend it may remain a single kernel, with Fluid it becomes compound -- Fluid can handle Harris response calculation but can't do sparse non-maxima suppression and point extraction to an STL vector:
A compound kernel implementation can be defined using a generic macro GAPI_COMPOUND_KERNEL():
@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp compound
It is important to distinguish a compound kernel from G-API high-order function, i.e. a C++ function which looks like a kernel but in fact generates a subgraph. The core difference is that a compound kernel is an implementation detail and a kernel implementation may be either compound or not (depending on backend capabilities), while a high-order function is a "macro" in terms of G-API and so cannot act as an interface which then needs to be implemented by a backend.