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# Kernel API {#gapi_kernel_api}
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[TOC]
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# G-API Kernel API
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The core idea behind G-API is portability -- a pipeline built with
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G-API must be portable (or at least able to be portable). It means
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that either it works out-of-the box when compiled for new platform,
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_or_ G-API provides necessary tools to make it running there, with
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little-to-no changes in the algorithm itself.
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This idea can be achieved by separating kernel interface from its
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implementation. Once a pipeline is built using kernel interfaces, it
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becomes implementation-neutral -- the implementation details
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(i.e. which kernels to use) are passed on a separate stage (graph
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compilation).
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Kernel-implementation hierarchy may look like:
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@dot Kernel API/implementation hierarchy example
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digraph {
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rankdir=BT;
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node [shape=record];
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ki_a [label="{<f0> interface\nA}"];
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ki_b [label="{<f0> interface\nB}"];
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{rank=same; ki_a ki_b};
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"CPU::A" -> ki_a [dir="forward"];
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"OpenCL::A" -> ki_a [dir="forward"];
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"Halide::A" -> ki_a [dir="forward"];
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"CPU::B" -> ki_b [dir="forward"];
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"OpenCL::B" -> ki_b [dir="forward"];
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"Halide::B" -> ki_b [dir="forward"];
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}
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@enddot
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A pipeline itself then can be expressed only in terms of `A`, `B`, and
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so on, and choosing which implementation to use in execution becomes
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an external parameter.
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# Defining a kernel {#gapi_defining_kernel}
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G-API provides a macro to define a new kernel interface --
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G_TYPED_KERNEL():
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@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_api
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This macro is a shortcut to a new type definition. It takes three
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arguments to register a new type, and requires type body to be present
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(see [below](@ref gapi_kernel_supp_info)). The macro arguments are:
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1. Kernel interface name -- also serves as a name of new type defined
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with this macro;
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2. Kernel signature -- an `std::function<>`-like signature which defines
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API of the kernel;
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3. Kernel's unique name -- used to identify kernel when its type
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informattion is stripped within the system.
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Kernel declaration may be seen as function declaration -- in both cases
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a new entity must be used then according to the way it was defined.
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Kernel signature defines kernel's usage syntax -- which parameters
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it takes during graph construction. Implementations can also use this
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signature to derive it into backend-specific callback signatures (see
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next chapter).
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Kernel may accept values of any type, and G-API _dynamic_ types are
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handled in a special way. All other types are opaque to G-API and
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passed to kernel in `outMeta()` or in execution callbacks as-is.
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Kernel's return value can _only_ be of G-API dynamic type -- cv::GMat,
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cv::GScalar, or `cv::GArray<T>`. If an operation has more than one
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output, it should be wrapped into an `std::tuple<>` (which can contain
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only mentioned G-API types). Arbitrary-output-number operations are
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not supported.
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Once a kernel is defined, it can be used in pipelines with special,
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G-API-supplied method "::on()". This method has the same signature as
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defined in kernel, so this code:
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@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_on
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is a perfectly legal construction. This example has some verbosity,
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though, so usually a kernel declaration comes with a C++ function
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wrapper ("factory method") which enables optional parameters, more
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compact syntax, Doxygen comments, etc:
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@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_wrap
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so now it can be used like:
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@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_wrap_call
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# Extra information {#gapi_kernel_supp_info}
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In the current version, kernel declaration body (everything within the
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curly braces) must contain a static function `outMeta()`. This function
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establishes a functional dependency between operation's input and
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output metadata.
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_Metadata_ is an information about data kernel operates on. Since
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non-G-API types are opaque to G-API, G-API cares only about `G*` data
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descriptors (i.e. dimensions and format of cv::GMat, etc).
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`outMeta()` is also an example of how kernel's signature can be
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transformed into a derived callback -- note that in this example,
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`outMeta()` signature exactly follows the kernel signature (defined
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within the macro) but is different -- where kernel expects cv::GMat,
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`outMeta()` takes and returns cv::GMatDesc (a G-API structure metadata
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for cv::GMat).
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The point of `outMeta()` is to propagate metadata information within
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computation from inputs to outputs and infer metadata of internal
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(intermediate, temporary) data objects. This information is required
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for further pipeline optimizations, memory allocation, and other
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operations done by G-API framework during graph compilation.
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<!-- TODO add examples -->
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# Implementing a kernel {#gapi_kernel_implementing}
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Once a kernel is declared, its interface can be used to implement
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versions of this kernel in different backends. This concept is
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naturally projected from object-oriented programming
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"Interface/Implementation" idiom: an interface can be implemented
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multiple times, and different implementations of a kernel should be
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substitutable with each other without breaking the algorithm
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(pipeline) logic (Liskov Substitution Principle).
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Every backend defines its own way to implement a kernel interface.
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This way is regular, though -- whatever plugin is, its kernel
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implementation must be "derived" from a kernel interface type.
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Kernel implementation are then organized into _kernel
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packages_. Kernel packages are passed to cv::GComputation::compile()
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as compile arguments, with some hints to G-API on how to select proper
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kernels (see more on this in "Heterogeneity"[TBD]).
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For example, the aforementioned `Filter2D` is implemented in
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"reference" CPU (OpenCV) plugin this way (*NOTE* -- this is a
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simplified form with improper border handling):
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@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp filter2d_ocv
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Note how CPU (OpenCV) plugin has transformed the original kernel
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signature:
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- Input cv::GMat has been substituted with cv::Mat, holding actual input
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data for the underlying OpenCV function call;
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- Output cv::GMat has been transformed into extra output parameter, thus
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`GCPUFilter2D::run()` takes one argument more than the original
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kernel signature.
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The basic intuition for kernel developer here is _not to care_ where
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that cv::Mat objects come from instead of the original cv::GMat -- and
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just follow the signature conventions defined by the plugin. G-API
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will call this method during execution and supply all the necessary
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information (and forward the original opaque data as-is).
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# Compound kernels {#gapi_kernel_compound}
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Sometimes kernel is a single thing only on API level. It is convenient
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for users, but on a particular implementation side it would be better to
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have multiple kernels (a subgraph) doing the thing instead. An example
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is goodFeaturesToTrack() -- while in OpenCV backend it may remain a
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single kernel, with Fluid it becomes compound -- Fluid can handle Harris
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response calculation but can't do sparse non-maxima suppression and
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point extraction to an STL vector:
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<!-- PIC -->
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A compound kernel _implementation_ can be defined using a generic
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macro GAPI_COMPOUND_KERNEL():
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@snippet samples/cpp/tutorial_code/gapi/doc_snippets/kernel_api_snippets.cpp compound
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<!-- TODO: ADD on how Compound kernels may simplify dispatching -->
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<!-- TODO: Add details on when expand() is called! -->
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It is important to distinguish a compound kernel from G-API high-order
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function, i.e. a C++ function which looks like a kernel but in fact
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generates a subgraph. The core difference is that a compound kernel is
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an _implementation detail_ and a kernel implementation may be either
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compound or not (depending on backend capabilities), while a
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high-order function is a "macro" in terms of G-API and so cannot act as
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an interface which then needs to be implemented by a backend.
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