cameracv/libs/opencv/modules/gapi/doc/slides/gapi_overview.org

OpenCV 4.4 Graph API

• G-API: What is, why, what's for?
  • OpenCV evolution in one slide
    • Version 1.x – Library inception
    • Version 2.x – Library rewrite
    • Version 3.0 – Welcome Transparent API (T-API)
  • OpenCV evolution in one slide (cont'd)
    • Version 4.0 – Welcome Graph API (G-API)
  • OpenCV evolution in one slide (cont'd)
    • Version 4.2 – New horizons
    • Version 4.4 – More on video
  • Why G-API?
    • Why introduce a new execution model?
  • Why G-API? (cont'd)
    • Why introduce a new execution model?
  • What is G-API for?
    • Bring the value of graph model with OpenCV where it makes sense:
• Programming with G-API
  • G-API Basics
    • G-API Concepts
  • The code is worth a thousand words
  • The code is worth a thousand words
    • Traditional OpenCV
    • OpenCV G-API
  • The code is worth a thousand words (cont'd)
    • What we have just learned?
    • What else?
  • On data objects
  • On operations and kernels
    • :B_block:BMCOL:
    • :B_block:BMCOL:
  • On operations and kernels (cont'd)
    • Defining an operation
  • On operations and kernels (cont'd)
    • GSqrt vs. cv::gapi::sqrt()
  • On operations and kernels (cont'd)
    • Implementing an operation
    • OpenCV backend
  • Operations and Kernels (cont'd)
    • Fluid backend
  • Operations and Kernels (cont'd)
    • Specifying which kernels to use
  • Heterogeneity in G-API
    • Automatic subgraph partitioning in G-API
    • :B_block:BMCOL:
    • :B_block:BMCOL:
    • :B_block:BMCOL:
    • :B_block:BMCOL:
  • Heterogeneity in G-API
    • Heterogeneity summary
• Inference and Streaming
  • Inference with G-API
    • In-graph inference example
  • Inference with G-API
    • What is the difference?
  • Inference with G-API
    • But how does it run?
  • Inference with G-API
    • Passing OpenVINO™ parameters to G-API
  • Streaming with G-API
  • Streaming with G-API
  • Streaming with G-API
  • Streaming with G-API: Example
    • Serial mode (4.0)
    • Streaming mode (since 4.2)
    • More information
• Latest features
  • Latest features
    • Python API
  • Latest features
    • Python API
• Understanding the "G-Effect"
  • Understanding the "G-Effect"
    • What is "G-Effect"?
  • Understanding the "G-Effect"
    • Memory consumption: Sobel Edge Detector
  • Understanding the "G-Effect"
    • Performance: Sobel Edge Detector
  • Understanding the "G-Effect"
    • Relative speed-up based on cache efficiency
• Resources on G-API
  • Resources on G-API
    • Repository
    • Article
    • Documentation
    • Tutorials
• Thank you!

G-API: What is, why, what's for?

OpenCV evolution in one slide

Version 1.x – Library inception

• Just a set of CV functions + helpers around (visualization, IO);

Version 2.x – Library rewrite

• OpenCV meets C++, cv::Mat replaces IplImage*;

Version 3.0 – Welcome Transparent API (T-API)

• cv::UMat is introduced as a transparent addition to cv::Mat;
• With cv::UMat, an OpenCL kernel can be enqeueud instead of immediately running C code;
• cv::UMat data is kept on a device until explicitly queried.

OpenCV evolution in one slide (cont'd)

Version 4.0 – Welcome Graph API (G-API)

• A new separate module (not a full library rewrite);
• A framework (or even a meta-framework);

• Usage model:

  • Express an image/vision processing graph and then execute it;
  • Fine-tune execution without changes in the graph;
• Similar to Halide – separates logic from platform details.

• More than Halide:

  • Kernels can be written in unconstrained platform-native code;
  • Halide can serve as a backend (one of many).

OpenCV evolution in one slide (cont'd)

Version 4.2 – New horizons

• Introduced in-graph inference via OpenVINO™ Toolkit;
• Introduced video-oriented Streaming execution mode;
• Extended focus from individual image processing to the full application pipeline optimization.

Version 4.4 – More on video

• Introduced a notion of stateful kernels;

  • The road to object tracking, background subtraction, etc. in the graph;
• Added more video-oriented operations (feature detection, Optical flow).

Why G-API?

Why introduce a new execution model?

• Ultimately it is all about optimizations;

  • or at least about a possibility to optimize;
• A CV algorithm is usually not a single function call, but a composition of functions;
• Different models operate at different levels of knowledge on the algorithm (problem) we run.

Why G-API? (cont'd)

Why introduce a new execution model?

• Traditional – every function can be optimized (e.g. vectorized) and parallelized, the rest is up to programmer to care about.
• Queue-based – kernels are enqueued dynamically with no guarantee where the end is or what is called next;
• Graph-based – nearly all information is there, some compiler magic can be done!

What is G-API for?

Bring the value of graph model with OpenCV where it makes sense:

• Memory consumption can be reduced dramatically;
• Memory access can be optimized to maximize cache reuse;

• Parallelism can be applied automatically where it is hard to do it manually;

  • It also becomes more efficient when working with graphs;

• Heterogeneity gets extra benefits like:

  • Avoiding unnecessary data transfers;
  • Shadowing transfer costs with parallel host co-execution;
  • Improving system throughput with frame-level pipelining.

Programming with G-API

G-API Basics

G-API Concepts

• Graphs are built by applying operations to data objects;

  • API itself has no "graphs", it is expression-based instead;
• Data objects do not hold actual data, only capture dependencies;
• Operations consume and produce data objects.

• A graph is defined by specifying its boundaries with data objects:

  • What data objects are inputs to the graph?
  • What are its outputs?

The code is worth a thousand words

#include <opencv2/gapi.hpp>                            // G-API framework header
#include <opencv2/gapi/imgproc.hpp>                    // cv::gapi::blur()
#include <opencv2/highgui.hpp>                         // cv::imread/imwrite

int main(int argc, char *argv[]) {
    if (argc < 3) return 1;

    cv::GMat in;                                       // Express the graph:
    cv::GMat out = cv::gapi::blur(in, cv::Size(3,3));  // `out` is a result of `blur` of `in`

    cv::Mat in_mat = cv::imread(argv[1]);              // Get the real data
    cv::Mat out_mat;                                   // Output buffer (may be empty)

    cv::GComputation(cv::GIn(in), cv::GOut(out))       // Declare a graph from `in` to `out`
        .apply(cv::gin(in_mat), cv::gout(out_mat));    // ...and run it immediately

    cv::imwrite(argv[2], out_mat);                     // Save the result
    return 0;
}

The code is worth a thousand words

Traditional OpenCV   B_block BMCOL

#include <opencv2/core.hpp>
#include <opencv2/imgproc.hpp>

#include <opencv2/highgui.hpp>

int main(int argc, char *argv[]) {
    using namespace cv;
    if (argc != 3) return 1;

    Mat in_mat = imread(argv[1]);
    Mat gx, gy;

    Sobel(in_mat, gx, CV_32F, 1, 0);
    Sobel(in_mat, gy, CV_32F, 0, 1);

    Mat mag, out_mat;
    sqrt(gx.mul(gx) + gy.mul(gy), mag);
    mag.convertTo(out_mat, CV_8U);

    imwrite(argv[2], out_mat);
    return 0;
}

OpenCV G-API   B_block BMCOL

#include <opencv2/gapi.hpp>
#include <opencv2/gapi/core.hpp>
#include <opencv2/gapi/imgproc.hpp>
#include <opencv2/highgui.hpp>

int main(int argc, char *argv[]) {
    using namespace cv;
    if (argc != 3) return 1;

    GMat in;
    GMat gx  = gapi::Sobel(in, CV_32F, 1, 0);
    GMat gy  = gapi::Sobel(in, CV_32F, 0, 1);
    GMat mag = gapi::sqrt(  gapi::mul(gx, gx)
                          + gapi::mul(gy, gy));
    GMat out = gapi::convertTo(mag, CV_8U);
    GComputation sobel(GIn(in), GOut(out));

    Mat in_mat = imread(argv[1]), out_mat;
    sobel.apply(in_mat, out_mat);
    imwrite(argv[2], out_mat);
    return 0;
}

The code is worth a thousand words (cont'd)

What we have just learned?

• G-API functions mimic their traditional OpenCV ancestors;
• No real data is required to construct a graph;
• Graph construction and graph execution are separate steps.

What else?

• Graph is first expressed and then captured in an object;

• Graph constructor defines protocol; user can pass vectors of inputs/outputs like

  cv::GComputation(cv::GIn(...), cv::GOut(...))

• Calls to .apply() must conform to graph's protocol

On data objects

Graph protocol defines what arguments a computation was defined on (both inputs and outputs), and what are the shapes (or types) of those arguments:

Shape	Argument	Size
GMat	Mat	Static; defined during
		graph compilation
GScalar	Scalar	4 x double
GArray<T>	std::vector<T>	Dynamic; defined in runtime
GOpaque<T>	T	Static, sizeof(T)

GScalar may be value-initialized at construction time to allow expressions like GMat a = 2*(b + 1).

On operations and kernels

:B_block:BMCOL:

• Graphs are built with Operations over virtual Data;
• Operations define interfaces (literally);
• Kernels are implementations to Operations (like in OOP);
• An Operation is platform-agnostic, a kernel is not;
• Kernels are implemented for Backends, the latter provide APIs to write kernels;
• Users can add their own operations and kernels, and also redefine "standard" kernels their own way.

:B_block:BMCOL:

digraph G {
node [shape=box];
rankdir=BT;

Gr [label="Graph"];
Op [label="Operation\nA"];
{rank=same
Impl1 [label="Kernel\nA:2"];
Impl2 [label="Kernel\nA:1"];
}

Op -> Gr [dir=back, label="'consists of'"];
Impl1 -> Op [];
Impl2 -> Op [label="'is implemented by'"];

node [shape=note,style=dashed];
{rank=same
Op;
CommentOp [label="Abstract:\ndeclared via\nG_API_OP()"];
}
{rank=same
Comment1 [label="Platform:\ndefined with\nOpenCL backend"];
Comment2 [label="Platform:\ndefined with\nOpenCV backend"];
}

CommentOp -> Op      [constraint=false, style=dashed, arrowhead=none];
Comment1  -> Impl1   [style=dashed, arrowhead=none];
Comment2  -> Impl2   [style=dashed, arrowhead=none];
}

On operations and kernels (cont'd)

Defining an operation

• A type name (every operation is a C++ type);
• Operation signature (similar to std::function<>);
• Operation identifier (a string);
• Metadata callback – describe what is the output value format(s), given the input and arguments.
• Use OpType::on(...) to use a new kernel OpType to construct graphs.

G_API_OP(GSqrt,<GMat(GMat)>,"org.opencv.core.math.sqrt") {
    static GMatDesc outMeta(GMatDesc in) { return in; }
};

On operations and kernels (cont'd)

GSqrt vs. cv::gapi::sqrt()

• How a type relates to a functions from the example?

• These functions are just wrappers over ::on:

  G_API_OP(GSqrt,<GMat(GMat)>,"org.opencv.core.math.sqrt") {
      static GMatDesc outMeta(GMatDesc in) { return in; }
  };
  GMat gapi::sqrt(const GMat& src) { return GSqrt::on(src); }

• Why – Doxygen, default parameters, 1:n mapping:

  cv::GMat custom::unsharpMask(const cv::GMat &src,
                               const int       sigma,
                               const float     strength) {
      cv::GMat blurred   = cv::gapi::medianBlur(src, sigma);
      cv::GMat laplacian = cv::gapi::Laplacian(blurred, CV_8U);
      return (src - (laplacian * strength));
  }

On operations and kernels (cont'd)

Implementing an operation

• Depends on the backend and its API;
• Common part for all backends: refer to operation being implemented using its type.

OpenCV backend

• OpenCV backend is the default one: OpenCV kernel is a wrapped OpenCV function:

  GAPI_OCV_KERNEL(GCPUSqrt, cv::gapi::core::GSqrt) {
      static void run(const cv::Mat& in, cv::Mat &out) {
          cv::sqrt(in, out);
      }
  };

Operations and Kernels (cont'd)

Fluid backend

• Fluid backend operates with row-by-row kernels and schedules its execution to optimize data locality:

  GAPI_FLUID_KERNEL(GFluidSqrt, cv::gapi::core::GSqrt, false) {
      static const int Window = 1;
      static void run(const View &in, Buffer &out) {
          hal::sqrt32f(in .InLine <float>(0)
                       out.OutLine<float>(0),
                       out.length());
      }
  };

• Note run changes signature but still is derived from the operation signature.

Operations and Kernels (cont'd)

Specifying which kernels to use

• Graph execution model is defined by kernels which are available/used;

• Kernels can be specified via the graph compilation arguments:

  #include <opencv2/gapi/fluid/core.hpp>
  #include <opencv2/gapi/fluid/imgproc.hpp>
  ...
  auto pkg = cv::gapi::combine(cv::gapi::core::fluid::kernels(),
                               cv::gapi::imgproc::fluid::kernels());
  sobel.apply(in_mat, out_mat, cv::compile_args(pkg));

• Users can combine kernels of different backends and G-API will partition the execution among those automatically.

Heterogeneity in G-API

Automatic subgraph partitioning in G-API

:B_block:BMCOL:

digraph G {
rankdir=TB;
ranksep=0.3;

node [shape=box margin=0 height=0.25];
A; B; C;

node [shape=ellipse];
GMat0;
GMat1;
GMat2;
GMat3;

GMat0 -> A -> GMat1 -> B -> GMat2;
GMat2 -> C;
GMat0 -> C -> GMat3

subgraph cluster {style=invis; A; GMat1; B; GMat2; C};
}

The initial graph: operations are not resolved yet.

:B_block:BMCOL:

digraph G {
rankdir=TB;
ranksep=0.3;

node [shape=box margin=0 height=0.25];
A; B; C;

node [shape=ellipse];
GMat0;
GMat1;
GMat2;
GMat3;

GMat0 -> A -> GMat1 -> B -> GMat2;
GMat2 -> C;
GMat0 -> C -> GMat3

subgraph cluster {style=filled;color=azure2; A; GMat1; B; GMat2; C};
}

All operations are handled by the same backend.

:B_block:BMCOL:

digraph G {
rankdir=TB;
ranksep=0.3;

node [shape=box margin=0 height=0.25];
A; B; C;

node [shape=ellipse];
GMat0;
GMat1;
GMat2;
GMat3;

GMat0 -> A -> GMat1 -> B -> GMat2;
GMat2 -> C;
GMat0 -> C -> GMat3

subgraph cluster_1 {style=filled;color=azure2; A; GMat1; B; }
subgraph cluster_2 {style=filled;color=ivory2; C};
}

A & B are of backend 1, C is of backend 2.

:B_block:BMCOL:

digraph G {
rankdir=TB;
ranksep=0.3;

node [shape=box margin=0 height=0.25];
A; B; C;

node [shape=ellipse];
GMat0;
GMat1;
GMat2;
GMat3;

GMat0 -> A -> GMat1 -> B -> GMat2;
GMat2 -> C;
GMat0 -> C -> GMat3

subgraph cluster_1 {style=filled;color=azure2; A};
subgraph cluster_2 {style=filled;color=ivory2; B};
subgraph cluster_3 {style=filled;color=azure2; C};
}

A & C are of backend 1, B is of backend 2.

Heterogeneity in G-API

Heterogeneity summary

• G-API automatically partitions its graph in subgraphs (called "islands") based on the available kernels;
• Adjacent kernels taken from the same backend are "fused" into the same "island";

• G-API implements a two-level execution model:

  • Islands are executed at the top level by a G-API's Executor;
  • Island internals are run at the bottom level by its Backend;
• G-API fully delegates the low-level execution and memory management to backends.

Inference and Streaming

Inference with G-API

In-graph inference example

• Starting with OpencV 4.2 (2019), G-API allows to integrate infer operations into the graph:

  G_API_NET(ObjDetect, <cv::GMat(cv::GMat)>, "pdf.example.od");
  
  cv::GMat in;
  cv::GMat blob = cv::gapi::infer<ObjDetect>(bgr);
  cv::GOpaque<cv::Size> size = cv::gapi::streaming::size(bgr);
  cv::GArray<cv::Rect>  objs = cv::gapi::streaming::parseSSD(blob, size);
  cv::GComputation pipelne(cv::GIn(in), cv::GOut(objs));

• Starting with OpenCV 4.5 (2020), G-API will provide more streaming- and NN-oriented operations out of the box.

Inference with G-API

What is the difference?

• ObjDetect is not an operation, cv::gapi::infer<T> is;

• cv::gapi::infer<T> is a generic operation, where T=ObjDetect describes the calling convention:

  • How many inputs the network consumes,
  • How many outputs the network produces.

• Inference data types are GMat only:

  • Representing an image, then preprocessed automatically;
  • Representing a blob (n-dimensional Mat), then passed as-is.
• Inference backends only need to implement a single generic operation infer.

Inference with G-API

But how does it run?

• Since infer is an Operation, backends may provide Kernels implenting it;

• The only publicly available inference backend now is OpenVINO™:

  • Brings its infer kernel atop of the Inference Engine;
• NN model data is passed through G-API compile arguments (like kernels);
• Every NN backend provides its own structure to configure the network (like a kernel API).

Inference with G-API

Passing OpenVINO™ parameters to G-API

• ObjDetect example:

  auto face_net = cv::gapi::ie::Params<ObjDetect> {
      face_xml_path,        // path to the topology IR
      face_bin_path,        // path to the topology weights
      face_device_string,   // OpenVINO plugin (device) string
  };
  auto networks = cv::gapi::networks(face_net);
  pipeline.compile(.., cv::compile_args(..., networks));

• AgeGender requires binding Op's outputs to NN layers:

  auto age_net = cv::gapi::ie::Params<AgeGender> {
      ...
  }.cfgOutputLayers({"age_conv3", "prob"}); // array<string,2> !
  

Streaming with G-API

digraph {
  rankdir=LR;
  node [shape=box];

  cap [label=Capture];
  dec [label=Decode];
  res [label=Resize];
  cnn [label=Infer];
  vis [label=Visualize];

  cap -> dec;
  dec -> res;
  res -> cnn;
  cnn -> vis;
}

Anatomy of a regular video analytics application

Streaming with G-API

digraph {
  node [shape=box margin=0 width=0.3 height=0.4]
  nodesep=0.2;
  rankdir=LR;

  subgraph cluster0 {
  colorscheme=blues9
  pp [label="..." shape=plaintext];
  v0 [label=V];
  label="Frame N-1";
  color=7;
  }

  subgraph cluster1 {
  colorscheme=blues9
  c1 [label=C];
  d1 [label=D];
  r1 [label=R];
  i1 [label=I];
  v1 [label=V];
  label="Frame N";
  color=6;
  }

  subgraph cluster2 {
  colorscheme=blues9
  c2 [label=C];
  nn [label="..." shape=plaintext];
  label="Frame N+1";
  color=5;
  }

  c1 -> d1 -> r1 -> i1 -> v1;

  pp-> v0;
  v0 -> c1 [style=invis];
  v1 -> c2 [style=invis];
  c2 -> nn;
}

Serial execution of the sample video analytics application

Streaming with G-API

digraph {
  nodesep=0.2;
  ranksep=0.2;
  node [margin=0 width=0.4 height=0.2];
  node [shape=plaintext]
  Camera [label="Camera:"];
  GPU [label="GPU:"];
  FPGA [label="FPGA:"];
  CPU [label="CPU:"];
  Time [label="Time:"];
  t6  [label="T6"];
  t7  [label="T7"];
  t8  [label="T8"];
  t9  [label="T9"];
  t10 [label="T10"];
  tnn [label="..."];

  node [shape=box margin=0 width=0.4 height=0.4 colorscheme=blues9]
  node [color=9] V3;
  node [color=8] F4; V4;
  node [color=7] DR5; F5; V5;
  node [color=6] C6; DR6; F6; V6;
  node [color=5] C7; DR7; F7; V7;
  node [color=4] C8; DR8; F8;
  node [color=3] C9; DR9;
  node [color=2] C10;

  {rank=same; rankdir=LR; Camera C6 C7 C8 C9 C10}
  Camera -> C6 -> C7 -> C8 -> C9 -> C10 [style=invis];

  {rank=same; rankdir=LR; GPU DR5 DR6 DR7 DR8 DR9}
  GPU -> DR5 -> DR6 -> DR7 -> DR8 -> DR9 [style=invis];

  C6 -> DR5 [style=invis];
  C6 -> DR6 [constraint=false];
  C7 -> DR7 [constraint=false];
  C8 -> DR8 [constraint=false];
  C9 -> DR9 [constraint=false];

  {rank=same; rankdir=LR; FPGA F4 F5 F6 F7 F8}
  FPGA -> F4 -> F5 -> F6 -> F7 -> F8 [style=invis];

  DR5 -> F4 [style=invis];
  DR5 -> F5 [constraint=false];
  DR6 -> F6 [constraint=false];
  DR7 -> F7 [constraint=false];
  DR8 -> F8 [constraint=false];

  {rank=same; rankdir=LR; CPU V3 V4 V5 V6 V7}
  CPU -> V3 -> V4 -> V5 -> V6 -> V7 [style=invis];

  F4 -> V3 [style=invis];
  F4 -> V4 [constraint=false];
  F5 -> V5 [constraint=false];
  F6 -> V6 [constraint=false];
  F7 -> V7 [constraint=false];

  {rank=same; rankdir=LR; Time t6 t7 t8 t9 t10 tnn}
  Time -> t6 -> t7 -> t8 -> t9 -> t10 -> tnn [style=invis];

  CPU -> Time [style=invis];
  V3 -> t6  [style=invis];
  V4 -> t7  [style=invis];
  V5 -> t8  [style=invis];
  V6 -> t9  [style=invis];
  V7 -> t10 [style=invis];
}

Pipelined execution for the video analytics application

Streaming with G-API: Example

Serial mode (4.0)   B_block BMCOL

pipeline = cv::GComputation(...);

cv::VideoCapture cap(input);
cv::Mat in_frame;
std::vector<cv::Rect> out_faces;

while (cap.read(in_frame)) {
    pipeline.apply(cv::gin(in_frame),
                   cv::gout(out_faces),
                   cv::compile_args(kernels,
                                    networks));
    // Process results
    ...
}

Streaming mode (since 4.2)   B_block BMCOL

pipeline = cv::GComputation(...);

auto in_src = cv::gapi::wip::make_src
    <cv::gapi::wip::GCaptureSource>(input)
auto cc = pipeline.compileStreaming
    (cv::compile_args(kernels, networks))
cc.setSource(cv::gin(in_src));
cc.start();

std::vector<cv::Rect> out_faces;
while (cc.pull(cv::gout(out_faces))) {
    // Process results
    ...
}

More information

https://opencv.org/hybrid-cv-dl-pipelines-with-opencv-4-4-g-api/

Latest features

Latest features

Python API

• Initial Python3 binding is available now in master (future 4.5);
• Only basic CV functionality is supported (core & imgproc namespaces, selecting backends);
• Adding more programmability, inference, and streaming is next.

Latest features

Python API

import numpy as np
import cv2 as cv

sz  = (1280, 720)
in1 = np.random.randint(0, 100, sz).astype(np.uint8)
in2 = np.random.randint(0, 100, sz).astype(np.uint8)

g_in1 = cv.GMat()
g_in2 = cv.GMat()
g_out = cv.gapi.add(g_in1, g_in2)
gr    = cv.GComputation(g_in1, g_in2, g_out)

pkg   = cv.gapi.core.fluid.kernels()
out   = gr.apply(in1, in2, args=cv.compile_args(pkg))

Understanding the "G-Effect"

Understanding the "G-Effect"

What is "G-Effect"?

• G-API is not only an API, but also an implementation;

  • i.e. it does some work already!
• We call "G-Effect" any measurable improvement which G-API demonstrates against traditional methods;

• So far the list is:

  • Memory consumption;
  • Performance;
  • Programmer efforts.

Note: in the following slides, all measurements are taken on Intel\textregistered{} Core\texttrademark-i5 6600 CPU.

Understanding the "G-Effect"

Memory consumption: Sobel Edge Detector

• G-API/Fluid backend is designed to minimize footprint:

Input	OpenCV	G-API/Fluid	Factor
	MiB	MiB	Times
512 x 512	17.33	0.59	28.9x
640 x 480	20.29	0.62	32.8x
1280 x 720	60.73	0.72	83.9x
1920 x 1080	136.53	0.83	164.7x
3840 x 2160	545.88	1.22	447.4x

• The detector itself can be written manually in two for loops, but G-API covers cases more complex than that;
• OpenCV code requires changes to shrink footprint.

Understanding the "G-Effect"

Performance: Sobel Edge Detector

• G-API/Fluid backend also optimizes cache reuse:

Input	OpenCV	G-API/Fluid	Factor
	ms	ms	Times
320 x 240	1.16	0.53	2.17x
640 x 480	5.66	1.89	2.99x
1280 x 720	17.24	5.26	3.28x
1920 x 1080	39.04	12.29	3.18x
3840 x 2160	219.57	51.22	4.29x

• The more data is processed, the bigger "G-Effect" is.

Understanding the "G-Effect"

Relative speed-up based on cache efficiency

\begin{figure} \begin{tikzpicture} \begin{axis}[ xlabel={Image size}, ylabel={Relative speed-up}, nodes near coords, width=0.8\textwidth, xtick=data, xticklabels={QVGA, VGA, HD, FHD, UHD}, height=4.5cm, ] \addplot plot coordinates {(1, 1.0) (2, 1.38) (3, 1.51) (4, 1.46) (5, 1.97)}; \end{axis} \end{tikzpicture} \end{figure}

The higher resolution is, the higher relative speed-up is (with speed-up on QVGA taken as 1.0).

Resources on G-API

Resources on G-API

Repository

• https://github.com/opencv/opencv (see modules/gapi)

Article

• https://opencv.org/hybrid-cv-dl-pipelines-with-opencv-4-4-g-api/

Documentation

• https://docs.opencv.org/4.4.0/d0/d1e/gapi.html

Tutorials

• https://docs.opencv.org/4.4.0/df/d7e/tutorial_table_of_content_gapi.html

Thank you!