arskrald/AR-2/Assets/OpenCVForUnity/Examples/Basic/MatBasicProcessingExample/MatBasicProcessingExample.cs

1807 lines
66 KiB
C#
Executable File
Raw Permalink Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

using UnityEngine;
using UnityEngine.UI;
using UnityEngine.SceneManagement;
using System;
using System.Collections;
using System.Collections.Generic;
using OpenCVForUnity.CoreModule;
using OpenCVForUnity.UnityUtils;
namespace OpenCVForUnityExample
{
/// <summary>
/// Mat Basic Processing Example
/// </summary>
public class MatBasicProcessingExample : MonoBehaviour
{
public ScrollRect exampleCodeScrollRect;
public UnityEngine.UI.Text exampleCodeText;
public ScrollRect executionResultScrollRect;
public UnityEngine.UI.Text executionResultText;
// Use this for initialization
IEnumerator Start ()
{
// fix the screen orientation.
Screen.orientation = ScreenOrientation.LandscapeLeft;
// wait for the screen orientation to change.
yield return null;
}
// Update is called once per frame
void Update ()
{
}
/// <summary>
/// Raises the destroy event.
/// </summary>
void OnDestroy ()
{
Screen.orientation = ScreenOrientation.AutoRotation;
}
private void UpdateScrollRect ()
{
exampleCodeScrollRect.verticalNormalizedPosition = executionResultScrollRect.verticalNormalizedPosition = 1f;
}
public void OnBackButtonClick ()
{
SceneManager.LoadScene ("OpenCVForUnityExample");
}
public void OnInitializationExampleButtonClick ()
{
//
// initialization example
//
// 3x3 matrix (set array value)
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
mat1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Debug.Log ("mat1=" + mat1.dump ());
// 2x2 rotation matrix
double angle = 30, a = Math.Cos (angle * Math.PI / 180), b = Math.Sin (angle * Math.PI / 180);
Mat mat2 = new Mat (2, 2, CvType.CV_64FC1);
mat2.put (0, 0, a, -b, b, a);
Debug.Log ("mat2=" + mat2.dump ());
// 5x5 all 1s matrix
Mat mat3 = Mat.ones (5, 5, CvType.CV_64FC1);
Debug.Log ("mat3=" + mat3.dump ());
// 5x5 all zeros matrix
Mat mat4 = Mat.zeros (5, 5, CvType.CV_64FC1);
Debug.Log ("mat4=" + mat4.dump ());
// 5x5 identity matrix
Mat mat5 = Mat.eye (5, 5, CvType.CV_64FC1);
Debug.Log ("mat5=" + mat5.dump ());
// 3x3 initialize with a constant
Mat mat6 = new Mat (3, 3, CvType.CV_64FC1, new Scalar (5));
Debug.Log ("mat6=" + mat6.dump ());
// 3x2 initialize with a uniform distribution random number
Mat mat7 = new Mat (3, 2, CvType.CV_8UC1);
Core.randu (mat7, 0, 256);
Debug.Log ("mat7=" + mat7.dump ());
// 3x2 initialize with a normal distribution random number
Mat mat8 = new Mat (3, 2, CvType.CV_8UC1);
Core.randn (mat8, 128, 10);
Debug.Log ("mat8=" + mat8.dump ());
exampleCodeText.text = @"
//
// initialization example
//
// 3x3 matrix (set array value)
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
mat1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Debug.Log (""mat1="" + mat1.dump());
// 2x2 rotation matrix
double angle = 30, a = Math.Cos(angle*Math.PI/180), b = Math.Sin(angle*Math.PI/180);
Mat mat2 = new Mat (2, 2, CvType.CV_64FC1);
mat2.put (0, 0, a, -b, b, a);
Debug.Log (""mat2="" + mat2.dump());
// 5x5 all 1s matrix
Mat mat3 = Mat.ones(5, 5, CvType.CV_64FC1);
Debug.Log (""mat3="" + mat3.dump());
// 5x5 all zeros matrix
Mat mat4 = Mat.zeros(5, 5, CvType.CV_64FC1);
Debug.Log (""mat4="" + mat4.dump());
// 5x5 identity matrix
Mat mat5 = Mat.eye(5, 5, CvType.CV_64FC1);
Debug.Log (""mat5="" + mat5.dump());
// 3x3 initialize with a constant
Mat mat6 = new Mat (3, 3, CvType.CV_64FC1, new Scalar(5));
Debug.Log (""mat6="" + mat6.dump());
// 3x2 initialize with a uniform distribution random number
Mat mat7 = new Mat (3, 2, CvType.CV_8UC1);
Core.randu (mat7, 0, 256);
Debug.Log (""mat7="" + mat7.dump());
// 3x2 initialize with a normal distribution random number
Mat mat8 = new Mat (3, 2, CvType.CV_8UC1);
Core.randn (mat8, 128, 10);
Debug.Log (""mat8="" + mat8.dump());
";
executionResultText.text = "mat1=" + mat1.dump () + "\n";
executionResultText.text += "mat2=" + mat2.dump () + "\n";
executionResultText.text += "mat3=" + mat3.dump () + "\n";
executionResultText.text += "mat4=" + mat4.dump () + "\n";
executionResultText.text += "mat5=" + mat5.dump () + "\n";
executionResultText.text += "mat6=" + mat6.dump () + "\n";
executionResultText.text += "mat7=" + mat7.dump () + "\n";
executionResultText.text += "mat8=" + mat8.dump () + "\n";
UpdateScrollRect ();
}
public void OnMultiChannelExampleButtonClick ()
{
//
// multi channel example
//
// 64F, channels=1, 3x3
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
Debug.Log ("mat1");
Debug.Log (" dim:" + mat1.dims () + " elemSize1:" + mat1.elemSize1 () + " channel:" + mat1.channels ());
// 64F, channels=10, 3x3
Debug.Log ("mat2");
Mat mat2 = new Mat (3, 3, CvType.CV_64FC (10));
Debug.Log (" dim:" + mat2.dims () + " elemSize1:" + mat2.elemSize1 () + " channels:" + mat2.channels ());
exampleCodeText.text = @"
//
// multi channel example
//
// 64F, channels=1, 3x3
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
Debug.Log (""mat1"");
Debug.Log ("" dim:"" + mat1.dims() + "" elemSize1:"" + mat1.elemSize1() + "" channel:"" + mat1.channels());
// 64F, channels=10, 3x3
Debug.Log (""mat2"");
Mat mat2 = new Mat (3, 3, CvType.CV_64FC(10));
Debug.Log ("" dim:"" + mat2.dims() + "" elemSize1:"" + mat2.elemSize1() + "" channels:"" + mat2.channels());
";
executionResultText.text = "mat1" + "\n";
executionResultText.text += " dim:" + mat1.dims () + " elemSize1:" + mat1.elemSize1 () + " channels:" + mat1.channels () + "\n";
executionResultText.text += "mat2" + "\n";
executionResultText.text += " dim:" + mat2.dims () + " elemSize1" + mat2.elemSize1 () + " channels:" + mat2.channels () + "\n";
UpdateScrollRect ();
}
public void OnDumpExampleButtonClick ()
{
//
// dump example
//
// 8U, channels=1, 3x3
Mat mat1 = new Mat (3, 3, CvType.CV_8UC1, new Scalar (1));
// 8U, channels=4, 3x3
Mat mat2 = new Mat (3, 3, CvType.CV_8UC4, new Scalar (1, 2, 3, 4));
// dump
Debug.Log ("mat1=" + mat1);
Debug.Log ("mat1.dump()=" + mat1.dump ());
Debug.Log ("mat1=" + mat2);
Debug.Log ("mat2.dump()=" + mat2.dump ());
exampleCodeText.text = @"
//
// dump example
//
// 8U, channels=1, 3x3
Mat mat1 = new Mat (3, 3, CvType.CV_8UC1, new Scalar(1));
// 8U, channels=4, 3x3
Mat mat2 = new Mat (3, 3, CvType.CV_8UC4, new Scalar(1, 2, 3, 4));
// dump
Debug.Log (""mat1="" + mat1);
Debug.Log (""mat1.dump()="" + mat1.dump());
Debug.Log (""mat1="" + mat2);
Debug.Log (""mat2.dump()="" + mat2.dump());
";
executionResultText.text = "mat1=" + mat1 + "\n";
executionResultText.text += "mat1.dump()=" + mat1.dump () + "\n";
executionResultText.text += "mat2=" + mat2 + "\n";
executionResultText.text += "mat2.dump()=" + mat2.dump () + "\n";
UpdateScrollRect ();
}
public void OnCVExceptionHandlingExampleButtonClick ()
{
//
// CVException handling example
//
// 32F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_32FC1);
m1.put (0, 0, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f);
// 8U, channels=1, 3x3
Mat m2 = new Mat (3, 3, CvType.CV_8UC1);
m2.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
// dump
Debug.Log ("m1=" + m1);
Debug.Log ("m1.dump()=" + m1.dump ());
Debug.Log ("m2=" + m2);
Debug.Log ("m2.dump()=" + m2.dump ());
executionResultText.text = "m1=" + m1 + "\n";
executionResultText.text += "m1.dump()=" + m1.dump () + "\n";
executionResultText.text += "m2=" + m2 + "\n";
executionResultText.text += "m2.dump()=" + m2.dump () + "\n";
// CVException handling
// Publish CVException to Debug.LogError.
Utils.setDebugMode (true, false);
Mat m3 = m1 / m2; // element type is different.
Debug.Log ("m3=" + m3);
Utils.setDebugMode (false);
// Throw CVException.
Utils.setDebugMode (true, true);
try {
Mat m4 = m1 / m2; // element type is different.
Debug.Log ("m4=" + m4);
} catch (Exception e) {
Debug.Log ("CVException: " + e);
executionResultText.text += "CVException: " + e + "\n";
}
Utils.setDebugMode (false);
exampleCodeText.text = @"
//
// CVException handling example
//
// 32F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_32FC1);
m1.put (0, 0, 1.0f, 2.0f, 3.0f, 4.0f, 5.0f, 6.0f, 7.0f, 8.0f, 9.0f);
// 8U, channels=1, 3x3
Mat m2 = new Mat (3, 3, CvType.CV_8UC1);
m2.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
// dump
Debug.Log (""m1="" + m1);
Debug.Log (""m1.dump()="" + m1.dump ());
Debug.Log (""m2="" + m2);
Debug.Log (""m2.dump()="" + m2.dump ());
#if UNITY_STANDALONE || UNITY_EDITOR
// Publish CVException to Debug.LogError.
Utils.setDebugMode (true, false);
Mat m3 = m1 / m2;
Debug.Log(""m3="" + m3);
Utils.setDebugMode (false);
// Throw CVException.
Utils.setDebugMode (true, true);
try
{
Mat m4 = m1 / m2;
Debug.Log(""m4="" + m4);
}
catch (Exception e)
{
Debug.Log (""CVException: "" + e);
}
Utils.setDebugMode (false);
#else
Debug.Log (""The setDebugMode method is only supported on WIN, MAC and LINUX."");
#endif
";
UpdateScrollRect ();
}
public void OnPropertyExampleButtonClick ()
{
//
// property example
//
// 64F, channels=1, 3x4
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
// number of rows
Debug.Log ("rows:" + mat1.rows ());
// number of columns
Debug.Log ("cols:" + mat1.cols ());
// number of dimensions
Debug.Log ("dims:" + mat1.dims ());
// size
Debug.Log ("size[]:" + mat1.size ().width + ", " + mat1.size ().height);
// bit depth ID
Debug.Log ("depth (ID):" + mat1.depth () + "(=" + CvType.CV_64F + ")");
// number of channels
Debug.Log ("channels:" + mat1.channels ());
// size of one element
Debug.Log ("elemSize:" + mat1.elemSize () + "[byte]");
// size for one channel in one element
Debug.Log ("elemSize1 (elemSize/channels):" + mat1.elemSize1 () + "[byte]");
// total number of elements
Debug.Log ("total:" + mat1.total ());
// total number of channels within one step
Debug.Log ("step1 (step/elemSize1):" + mat1.step1 ());
// is the data continuous?
Debug.Log ("isContinuous:" + mat1.isContinuous ());
// is it a submatrix?
Debug.Log ("isSubmatrix:" + mat1.isSubmatrix ());
// is the data empty?
Debug.Log ("empty:" + mat1.empty ());
exampleCodeText.text = @"
//
// property example
//
// 64F, channels=1, 3x4
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
// number of rows
Debug.Log (""rows:"" + mat1.rows());
// number of columns
Debug.Log (""cols:"" + mat1.cols());
// number of dimensions
Debug.Log (""dims:"" + mat1.dims());
// size
Debug.Log (""size[]:"" + mat1.size().width + "", "" + mat1.size().height);
// bit depth ID
Debug.Log (""depth (ID):"" + mat1.depth() + ""(="" + CvType.CV_64F + "")"");
// number of channels
Debug.Log (""channels:"" + mat1.channels());
// size of one element
Debug.Log (""elemSize:"" + mat1.elemSize() + ""[byte]"");
// size for one channel in one element
Debug.Log (""elemSize1 (elemSize/channels):"" + mat1.elemSize1() + ""[byte]"");
// total number of elements
Debug.Log (""total:"" + mat1.total());
// total number of channels within one step
Debug.Log (""step1 (step/elemSize1):"" + mat1.step1());
// is the data continuous?
Debug.Log (""isContinuous:"" + mat1.isContinuous());
// is it a submatrix?
Debug.Log (""isSubmatrix:"" + mat1.isSubmatrix());
// is the data empty?
Debug.Log (""empty:"" + mat1.empty());
";
executionResultText.text = "rows:" + mat1.rows () + "\n";
executionResultText.text += "cols:" + mat1.cols () + "\n";
executionResultText.text += "dims:" + mat1.dims () + "\n";
executionResultText.text += "size[]:" + mat1.size ().width + ", " + mat1.size ().height + "\n";
executionResultText.text += "depth (ID):" + mat1.depth () + "(=" + CvType.CV_64F + ")" + "\n";
executionResultText.text += "channels:" + mat1.channels () + "\n";
executionResultText.text += "elemSize:" + mat1.elemSize () + "\n";
executionResultText.text += "elemSize1 (elemSize/channels):" + mat1.elemSize1 () + "\n";
executionResultText.text += "total:" + mat1.total () + "\n";
executionResultText.text += "step1 (step/elemSize1):" + mat1.step1 () + "\n";
executionResultText.text += "isContinuous:" + mat1.isContinuous () + "\n";
executionResultText.text += "isSubmatrix:" + mat1.isSubmatrix () + "\n";
executionResultText.text += "empty:" + mat1.empty () + "\n";
UpdateScrollRect ();
}
public void OnFourArithmeticOperationExampleButtonClick ()
{
//
// four arithmetic operation example
//
// 64F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0);
Debug.Log ("m1=" + m1.dump ());
executionResultText.text = "m1=" + m1.dump () + "\n";
// matrix and scalar
Mat m2 = m1 + new Scalar (3);
Mat m3 = m1 - new Scalar (3);
Mat m4 = m1 * 3; //scaling
Mat m5 = m1 / 3;
Debug.Log ("m1+3=" + m2.dump ());
Debug.Log ("m1-3=" + m3.dump ());
Debug.Log ("m1*3=" + m4.dump ());
Debug.Log ("m1/3=" + m5.dump ());
executionResultText.text += "m1+3=" + m2.dump () + "\n";
executionResultText.text += "m1-3=" + m3.dump () + "\n";
executionResultText.text += "m1*3=" + m4.dump () + "\n";
executionResultText.text += "m1/3=" + m5.dump () + "\n";
// matrix and matrix
Mat m6 = m1 + m1;
Mat m7 = m1.mul (m2);
Mat m8 = m1.mul (m2, 2); //add scaling factor
Debug.Log ("m1+m1=" + m6.dump ());
Debug.Log ("m1.mul(m2)=" + m7.dump ());
Debug.Log ("m1.mul(m2, 2)=" + m8.dump ());
executionResultText.text += "m1+m1=" + m6.dump () + "\n";
executionResultText.text += "m1.mul(m2)=" + m7.dump () + "\n";
executionResultText.text += "m1.mul(m2, 2)=" + m8.dump () + "\n";
// CVException handling
// 8U, channels=1, 3x3
Mat m9 = new Mat (3, 3, CvType.CV_8UC1);
m9.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
// 64F, channels=1, 3x3
Mat m10 = new Mat (2, 2, CvType.CV_64FC1);
m10.put (0, 0, 1.0, 2.0, 3.0, 4.0);
// Publish CVException to Debug.LogError.
Utils.setDebugMode (true, false);
Mat m11 = m1 / m9; // element type is different.
Debug.Log ("m1/m9=" + m11);
executionResultText.text += "m1/m9=" + m11.dump () + "\n";
Mat m12 = m1 / m10; // matrix size is different.
Debug.Log ("m1/m10=" + m12);
executionResultText.text += "m1/m10=" + m12.dump () + "\n";
Utils.setDebugMode (false);
exampleCodeText.text = @"
//
// four arithmetic operation example
//
// 64F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1.0, 2.0, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0);
Debug.Log (""m1="" + m1.dump ());
executionResultText.text = ""m1="" + m1.dump () + ""\n"";
// matrix and scalar
Mat m2 = m1 + new Scalar (3);
Mat m3 = m1 - new Scalar (3);
Mat m4 = m1 * 3; //scaling
Mat m5 = m1 / 3;
Debug.Log (""m1+3="" + m2.dump ());
Debug.Log (""m1-3="" + m3.dump ());
Debug.Log (""m1*3="" + m4.dump ());
Debug.Log (""m1/3="" + m5.dump ());
executionResultText.text += ""m1+3="" + m2.dump () + ""\n"";
executionResultText.text += ""m1-3="" + m3.dump () + ""\n"";
executionResultText.text += ""m1*3="" + m4.dump () + ""\n"";
executionResultText.text += ""m1/3="" + m5.dump () + ""\n"";
// matrix and matrix
Mat m6 = m1 + m1;
Mat m7 = m1.mul (m2);
Mat m8 = m1.mul (m2, 2); //add scaling factor
Debug.Log (""m1+m1="" + m6.dump ());
Debug.Log (""m1.mul(m2)="" + m7.dump ());
Debug.Log (""m1.mul(m2, 2)="" + m8.dump ());
executionResultText.text += ""m1+m1="" + m6.dump () + ""\n"";
executionResultText.text += ""m1.mul(m2)="" + m7.dump () + ""\n"";
executionResultText.text += ""m1.mul(m2, 2)="" + m8.dump () + ""\n"";
// CVException handling
// 8U, channels=1, 3x3
Mat m9 = new Mat (3, 3, CvType.CV_8UC1);
m9.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
// 64F, channels=1, 3x3
Mat m10 = new Mat (2, 2, CvType.CV_64FC1);
m10.put (0, 0, 1.0, 2.0, 3.0, 4.0);
// Publish CVException to Debug.LogError.
Utils.setDebugMode (true, false);
Mat m11 = m1 / m9; // element type is different.
Debug.Log (""m1/m9="" + m11);
executionResultText.text += ""m1/m9="" + m11.dump () + ""\n"";
Mat m12 = m1 / m10; // matrix size is different.
Debug.Log (""m1/m10="" + m12);
executionResultText.text += ""m1/m10="" + m12.dump () + ""\n"";
Utils.setDebugMode (false);
";
UpdateScrollRect ();
}
public void OnConvertToExampleButtonClick ()
{
//
// convertTo example
//
// 64F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1.1, 1.2, 1.3, 2.1, 2.2, 2.3, 3.1, 3.2, 3.3);
Debug.Log ("m1=" + m1.dump ());
// dst mat, type
Mat m2 = new Mat ();
m1.convertTo (m2, CvType.CV_8U);
Debug.Log ("m2=" + m2.dump ());
// dst mat, type, scale factor, added to the scaled value
Mat m3 = new Mat ();
m1.convertTo (m3, CvType.CV_8U, 2, 10);
Debug.Log ("m3=" + m3.dump ());
exampleCodeText.text = @"
//
// convertTo example
//
// 64F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1.1, 1.2, 1.3, 2.1, 2.2, 2.3, 3.1, 3.2, 3.3);
Debug.Log (""m1="" + m1.dump());
// dst mat, type
Mat m2 = new Mat ();
m1.convertTo (m2, CvType.CV_8U);
Debug.Log (""m2="" + m2.dump());
// dst mat, type, scale factor, added to the scaled value
Mat m3 = new Mat ();
m1.convertTo (m3, CvType.CV_8U, 2, 10);
Debug.Log (""m3="" + m3.dump());
";
executionResultText.text = "m1=" + m1.dump () + "\n";
executionResultText.text += "m2=" + m2.dump () + "\n";
executionResultText.text += "m3=" + m3.dump () + "\n";
UpdateScrollRect ();
}
public void OnReshapeExampleButtonClick ()
{
//
// reshape example
//
// 64F, channels=1, 3x4
Mat m1 = new Mat (3, 4, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12);
Debug.Log ("m1=" + m1.dump ());
Debug.Log ("ch=" + m1.channels ());
// channels=2, 3x2
Mat m2 = m1.reshape (2);
Debug.Log ("m2=" + m2.dump ());
Debug.Log ("ch=" + m2.channels ());
// channels=1, 2x6
Mat m3 = m1.reshape (1, 2);
Debug.Log ("m3=" + m3.dump ());
Debug.Log ("ch=" + m3.channels ());
exampleCodeText.text = @"
//
// reshape example
//
// 64F, channels=1, 3x4
Mat m1 = new Mat (3, 4, CvType.CV_64FC1);
m1.put (0, 0, 1,2,3,4,5,6,7,8,9,10,11,12);
Debug.Log (""m1="" + m1.dump());
Debug.Log (""ch="" + m1.channels());
// channels=2, 3x2
Mat m2 = m1.reshape (2);
Debug.Log (""m2="" + m2.dump());
Debug.Log (""ch="" + m2.channels());
// channels=1, 2x6
Mat m3 = m1.reshape (1, 2);
Debug.Log (""m3="" + m3.dump());
Debug.Log (""ch="" + m3.channels());
";
executionResultText.text = "m1=" + m1.dump () + "\n";
executionResultText.text += "ch=" + m1.channels () + "\n";
executionResultText.text += "m2=" + m2.dump () + "\n";
executionResultText.text += "ch=" + m2.channels () + "\n";
executionResultText.text += "m3=" + m3.dump () + "\n";
executionResultText.text += "ch=" + m3.channels () + "\n";
UpdateScrollRect ();
}
public void OnRangeExampleButtonClick ()
{
//
// range example
//
// 64F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Debug.Log ("m1=" + m1.dump ());
// all rows
Debug.Log ("m1.rowRange(Range.all())=" + m1.rowRange (Range.all ()).dump ());
// rowRange(0,2)
Debug.Log ("m1.rowRange(new Range(0,2))=" + m1.rowRange (new Range (0, 2)).dump ());
// row(0)
Debug.Log ("m1.row(0)=" + m1.row (0).dump ());
// all cols
Debug.Log ("m1.colRange(Range.all())=" + m1.colRange (Range.all ()).dump ());
// colRange(0,2)
Debug.Log ("m1.colRange(new Range(0,2))=" + m1.colRange (new Range (0, 2)).dump ());
// col(0)
Debug.Log ("m1.col(0)=" + m1.col (0).dump ());
exampleCodeText.text = @"
//
// range example
//
// 64F, channels=1, 3x3
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Debug.Log (""m1="" + m1.dump());
// all rows
Debug.Log (""m1.rowRange(Range.all())="" + m1.rowRange(Range.all()).dump());
// rowRange(0,2)
Debug.Log (""m1.rowRange(new Range(0,2))="" + m1.rowRange(new Range(0,2)).dump());
// row(0)
Debug.Log (""m1.row(0)="" + m1.row(0).dump());
// all cols
Debug.Log (""m1.colRange(Range.all())="" + m1.colRange(Range.all()).dump());
// colRange(0,2)
Debug.Log (""m1.colRange(new Range(0,2))="" + m1.colRange(new Range(0,2)).dump());
// col(0)
Debug.Log (""m1.col(0)="" + m1.col(0).dump());
";
executionResultText.text = "m1=" + m1.dump () + "\n";
executionResultText.text += "m1.rowRange(Range.all())=" + m1.rowRange (Range.all ()).dump () + "\n";
executionResultText.text += "m1.rowRange(new Range(0,2))=" + m1.rowRange (new Range (0, 2)).dump () + "\n";
executionResultText.text += "m1.row(0)=" + m1.row (0).dump () + "\n";
executionResultText.text += "m1.colRange(Range.all())=" + m1.colRange (Range.all ()).dump () + "\n";
executionResultText.text += "m1.colRange(new Range(0,2))=" + m1.colRange (new Range (0, 2)).dump () + "\n";
executionResultText.text += "m1.col(0)=" + m1.col (0).dump () + "\n";
UpdateScrollRect ();
}
public void OnShallowCopyAndDeepCopyExampleButtonClick ()
{
//
// shallow copy and deep copy example
//
// 3x3 matrix
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
mat1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
// shallow copy
Mat m_shallow = mat1;
// deep copy (clone, copyTo)
Mat m_deep1 = mat1.clone ();
Mat m_deep2 = new Mat ();
mat1.copyTo (m_deep2);
Debug.Log ("mat1=" + mat1.dump ());
Debug.Log ("m_shallow=" + m_shallow.dump ());
Debug.Log ("m_deep1=" + m_deep1.dump ());
Debug.Log ("m_deep2=" + m_deep2.dump ());
executionResultText.text = "mat1=" + mat1.dump () + "\n";
executionResultText.text += "m_shallow=" + m_shallow.dump () + "\n";
executionResultText.text += "m_deep1=" + m_deep1.dump () + "\n";
executionResultText.text += "m_deep2=" + m_deep2.dump () + "\n";
// rewrite (0, 0) element of matrix mat1
mat1.put (0, 0, 100);
Debug.Log ("mat1=" + mat1.dump ());
Debug.Log ("m_shallow=" + m_shallow.dump ());
Debug.Log ("m_deep1=" + m_deep1.dump ());
Debug.Log ("m_deep2=" + m_deep2.dump ());
executionResultText.text += "mat1=" + mat1.dump () + "\n";
executionResultText.text += "m_shallow=" + m_shallow.dump () + "\n";
executionResultText.text += "m_deep1=" + m_deep1.dump () + "\n";
executionResultText.text += "m_deep2=" + m_deep2.dump () + "\n";
Debug.Log ("mat1.Equals(m_shallow)=" + mat1.Equals (m_shallow));
Debug.Log ("mat1.Equals(m_deep1)=" + mat1.Equals (m_deep1));
Debug.Log ("mat1.Equals(m_deep2)=" + mat1.Equals (m_deep2));
executionResultText.text += "mat1.Equals(m_shallow)=" + mat1.Equals (m_shallow) + "\n";
executionResultText.text += "mat1.Equals(m_deep1)=" + mat1.Equals (m_deep1) + "\n";
executionResultText.text += "mat1.Equals(m_deep2)=" + mat1.Equals (m_deep2) + "\n";
exampleCodeText.text = @"
//
// shallow copy and deep copy example
//
// 3x3 matrix
Mat mat1 = new Mat (3, 3, CvType.CV_64FC1);
mat1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
// shallow copy
Mat m_shallow = mat1;
// deep copy (clone, copyTo)
Mat m_deep1 = mat1.clone();
Mat m_deep2 = new Mat();
mat1.copyTo (m_deep2);
Debug.Log (""mat1="" + mat1.dump());
Debug.Log (""m_shallow="" + m_shallow.dump());
Debug.Log (""m_deep1="" + m_deep1.dump());
Debug.Log (""m_deep2="" + m_deep2.dump());
// rewrite (0, 0) element of matrix mat1
mat1.put(0, 0, 100);
Debug.Log (""mat1="" + mat1.dump());
Debug.Log (""m_shallow="" + m_shallow.dump());
Debug.Log (""m_deep1="" + m_deep1.dump());
Debug.Log (""m_deep2="" + m_deep2.dump());
Debug.Log (""mat1.Equals(m_shallow)="" + mat1.Equals(m_shallow));
Debug.Log (""mat1.Equals(m_deep1)="" + mat1.Equals(m_deep1));
Debug.Log (""mat1.Equals(m_deep2)="" + mat1.Equals(m_deep2));
";
UpdateScrollRect ();
}
public void OnMergeExampleButtonClick ()
{
//
// simple composition: Merge example
//
// 2x2 matrix
Mat m1 = new Mat (2, 2, CvType.CV_64FC1);
m1.put (0, 0, 1.0, 2.0, 3.0, 4.0);
Mat m2 = new Mat (2, 2, CvType.CV_64FC1);
m2.put (0, 0, 1.1, 2.1, 3.1, 4.1);
Mat m3 = new Mat (2, 2, CvType.CV_64FC1);
m3.put (0, 0, 1.2, 2.2, 3.2, 4.2);
List<Mat> mv = new List<Mat> ();
mv.Add (m1);
mv.Add (m2);
mv.Add (m3);
// merge
Mat m_merged = new Mat ();
Core.merge (mv, m_merged);
// dump
Debug.Log ("m_merged=" + m_merged.dump ());
exampleCodeText.text = @"
//
// simple composition: Merge example
//
// 2x2 matrix
Mat m1 = new Mat (2, 2, CvType.CV_64FC1);
m1.put (0, 0, 1.0, 2.0, 3.0, 4.0);
Mat m2 = new Mat (2, 2, CvType.CV_64FC1);
m2.put (0, 0, 1.1, 2.1, 3.1, 4.1);
Mat m3 = new Mat (2, 2, CvType.CV_64FC1);
m3.put (0, 0, 1.2, 2.2, 3.2, 4.2);
List<Mat> mv = new List<Mat>();
mv.Add (m1);
mv.Add (m2);
mv.Add (m3);
// merge
Mat m_merged = new Mat();
Core.merge (mv, m_merged);
// dump
Debug.Log (""m_merged="" + m_merged.dump());
";
executionResultText.text = "m_merged=" + m_merged.dump () + "\n";
UpdateScrollRect ();
}
public void OnMixChannelsExampleButtonClick ()
{
//
// complex composition: mixChannels example
//
// 2x2 matrix
Mat m1 = new Mat (2, 2, CvType.CV_64FC1);
m1.put (0, 0, 1.0, 2.0, 3.0, 4.0);
Mat m2 = new Mat (2, 2, CvType.CV_64FC1);
m2.put (0, 0, 1.1, 2.1, 3.1, 4.1);
Mat m3 = new Mat (2, 2, CvType.CV_64FC1);
m3.put (0, 0, 1.2, 2.2, 3.2, 4.2);
List<Mat> mv = new List<Mat> ();
mv.Add (m1);
mv.Add (m2);
mv.Add (m3);
// mat for output must be allocated.
Mat m_mixed1 = new Mat (2, 2, CvType.CV_64FC2);
Mat m_mixed2 = new Mat (2, 2, CvType.CV_64FC2);
MatOfInt fromTo = new MatOfInt (0, 0, 1, 1, 1, 3, 2, 2);
List<Mat> mixv = new List<Mat> ();
mixv.Add (m_mixed1);
mixv.Add (m_mixed2);
// mix
Core.mixChannels (mv, mixv, fromTo);
// dump
Debug.Log ("m_mixed1=" + m_mixed1.dump ());
Debug.Log ("m_mixed2=" + m_mixed2.dump ());
exampleCodeText.text = @"
//
// complex composition: mixChannels example
//
// 2x2 matrix
Mat m1 = new Mat (2, 2, CvType.CV_64FC1);
m1.put (0, 0, 1.0, 2.0, 3.0, 4.0);
Mat m2 = new Mat (2, 2, CvType.CV_64FC1);
m2.put (0, 0, 1.1, 2.1, 3.1, 4.1);
Mat m3 = new Mat (2, 2, CvType.CV_64FC1);
m3.put (0, 0, 1.2, 2.2, 3.2, 4.2);
List<Mat> mv = new List<Mat>();
mv.Add (m1);
mv.Add (m2);
mv.Add (m3);
// mat for output must be allocated.
Mat m_mixed1 = new Mat(2, 2, CvType.CV_64FC2);
Mat m_mixed2 = new Mat(2, 2, CvType.CV_64FC2);
MatOfInt fromTo = new MatOfInt (0,0, 1,1, 1,3, 2,2);
List<Mat> mixv = new List<Mat> ();
mixv.Add (m_mixed1);
mixv.Add (m_mixed2);
// mix
Core.mixChannels (mv, mixv, fromTo);
// dump
Debug.Log (""m_mixed1="" + m_mixed1.dump());
Debug.Log (""m_mixed2="" + m_mixed2.dump());
";
executionResultText.text = "m_mixed1=" + m_mixed1.dump () + "\n";
executionResultText.text += "m_mixed2=" + m_mixed2.dump () + "\n";
UpdateScrollRect ();
}
public void OnSplitExampleButtonClick ()
{
//
// split example
//
// channels=3, 2x3 matrix
Mat m1 = new Mat (2, 3, CvType.CV_64FC3);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18);
List<Mat> planes = new List<Mat> ();
// split
Core.split (m1, planes);
// dump
foreach (Mat item in planes) {
Debug.Log (item.dump ());
}
exampleCodeText.text = @"
//
// split example
//
// channels=3, 2x3 matrix
Mat m1 = new Mat (2, 3, CvType.CV_64FC3);
m1.put (0, 0, 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18);
List<Mat> planes = new List<Mat>();
// split
Core.split (m1, planes);
// dump
foreach (Mat item in planes) {
Debug.Log (item.dump());
}
";
executionResultText.text = "";
foreach (Mat item in planes) {
executionResultText.text += item.dump () + "\n";
}
UpdateScrollRect ();
}
public void OnReduceExampleButtonClick ()
{
//
// reduce example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 5, 3, 4, 2, 6, 7, 8, 9);
Mat v1 = new Mat ();
Mat v2 = new Mat ();
Mat v3 = new Mat ();
Mat v4 = new Mat ();
// reduce 3 x 3 matrix to one row
Core.reduce (m1, v1, 0, Core.REDUCE_SUM); // total value of each column
Core.reduce (m1, v2, 0, Core.REDUCE_AVG); // total average value of each column
Core.reduce (m1, v3, 0, Core.REDUCE_MIN); // minimum value of each column
Core.reduce (m1, v4, 0, Core.REDUCE_MAX); // maximum value of each column
// dump
Debug.Log ("m1=" + m1.dump ());
Debug.Log ("v1(sum)=" + v1.dump ());
Debug.Log ("v2(avg)=" + v2.dump ());
Debug.Log ("v3(min)=" + v3.dump ());
Debug.Log ("v4(max)=" + v4.dump ());
executionResultText.text = "m1=" + m1.dump () + "\n";
executionResultText.text += "v1(sum)=" + v1.dump () + "\n";
executionResultText.text += "v2(avg)=" + v2.dump () + "\n";
executionResultText.text += "v3(min)=" + v3.dump () + "\n";
executionResultText.text += "v4(max)=" + v4.dump () + "\n";
// reduce 3 x 3 matrix to one col
Core.reduce (m1, v1, 1, Core.REDUCE_SUM); // total value of each row
Core.reduce (m1, v2, 1, Core.REDUCE_AVG); // total average value of row
Core.reduce (m1, v3, 1, Core.REDUCE_MIN); // minimum value of each row
Core.reduce (m1, v4, 1, Core.REDUCE_MAX); // maximum value of each row
// dump
Debug.Log ("m1=" + m1.dump ());
Debug.Log ("v1(sum)=" + v1.dump ());
Debug.Log ("v2(avg)=" + v2.dump ());
Debug.Log ("v3(min)=" + v3.dump ());
Debug.Log ("v4(max)=" + v4.dump ());
executionResultText.text += "m1=" + m1.dump () + "\n";
executionResultText.text += "v1(sum)=" + v1.dump () + "\n";
executionResultText.text += "v2(avg)=" + v2.dump () + "\n";
executionResultText.text += "v3(min)=" + v3.dump () + "\n";
executionResultText.text += "v4(max)=" + v4.dump () + "\n";
exampleCodeText.text = @"
//
// reduce example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 5, 3, 4, 2, 6, 7, 8, 9);
Mat v1 = new Mat ();
Mat v2 = new Mat ();
Mat v3 = new Mat ();
Mat v4 = new Mat ();
// reduce 3 x 3 matrix to one row
Core.reduce (m1, v1, 0, Core.REDUCE_SUM); // total value of each column
Core.reduce (m1, v2, 0, Core.REDUCE_AVG); // total average value of each column
Core.reduce (m1, v3, 0, Core.REDUCE_MIN); // minimum value of each column
Core.reduce (m1, v4, 0, Core.REDUCE_MAX); // maximum value of each column
// dump
Debug.Log (""m1="" + m1.dump());
Debug.Log (""v1(sum)="" + v1.dump());
Debug.Log (""v2(avg)="" + v2.dump());
Debug.Log (""v3(min)="" + v3.dump());
Debug.Log (""v4(max)="" + v4.dump());
// reduce 3 x 3 matrix to one col
Core.reduce (m1, v1, 1, Core.REDUCE_SUM); // total value of each row
Core.reduce (m1, v2, 1, Core.REDUCE_AVG); // total average value of row
Core.reduce (m1, v3, 1, Core.REDUCE_MIN); // minimum value of each row
Core.reduce (m1, v4, 1, Core.REDUCE_MAX); // maximum value of each row
// dump
Debug.Log (""m1="" + m1.dump());
Debug.Log (""v1(sum)="" + v1.dump());
Debug.Log (""v2(avg)="" + v2.dump());
Debug.Log (""v3(min)="" + v3.dump());
Debug.Log (""v4(max)="" + v4.dump());
";
UpdateScrollRect ();
}
public void OnSubmatrixExampleButtonClick ()
{
//
// submatrix (ROI) example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Debug.Log ("m1=" + m1.dump ());
executionResultText.text = "m1=" + m1.dump () + "\n";
// get submatrix (ROI) of range (row[0_2] col[0_2])
Mat m2 = new Mat (m1, new OpenCVForUnity.CoreModule.Rect (0, 0, 2, 2));
Debug.Log ("m2=" + m2.dump ());
executionResultText.text += "m2=" + m2.dump () + "\n";
Debug.Log ("m2.submat()=" + m2.submat (0, 2, 0, 2).dump ());
executionResultText.text += "m2.submat()=" + m2.submat (0, 2, 0, 2).dump () + "\n";
// find the parent matrix size of the submatrix (ROI) m2 and its position in it
Size wholeSize = new Size ();
Point ofs = new Point ();
m2.locateROI (wholeSize, ofs);
Debug.Log ("wholeSize:" + wholeSize.width + "x" + wholeSize.height);
Debug.Log ("offset:" + ofs.x + ", " + ofs.y);
executionResultText.text += "wholeSize:" + wholeSize.width + "x" + wholeSize.height + "\n";
executionResultText.text += "offset:" + ofs.x + ", " + ofs.y + "\n";
// expand the range of submatrix (ROI)
m2.adjustROI (0, 1, 0, 1);
Debug.Log ("rows=" + m2.rows () + ", " + "cols=" + m2.cols ());
Debug.Log ("m2=" + m2.dump ());
executionResultText.text += "rows=" + m2.rows () + ", " + "cols=" + m2.cols () + "\n";
executionResultText.text += "m2=" + m2.dump () + "\n";
exampleCodeText.text = @"
//
// submatrix (ROI) example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Debug.Log (""m1="" + m1.dump ());
// get submatrix (ROI) of range (row[0_2] col[0_2])
Mat m2 = new Mat (m1, new OpenCVForUnity.CoreModule.Rect(0,0,2,2));
Debug.Log (""m2="" + m2.dump());
Debug.Log (""m2.submat()="" + m2.submat(0,2,0,2).dump());
// find the parent matrix size of the submatrix (ROI) m2 and its position in it
Size wholeSize = new Size ();
Point ofs = new Point ();
m2.locateROI (wholeSize, ofs);
Debug.Log (""wholeSize:"" + wholeSize.width + ""x"" + wholeSize.height);
Debug.Log (""offset:"" + ofs.x + "", "" + ofs.y);
// expand the range of submatrix (ROI)
m2.adjustROI(0, 1, 0, 1);
Debug.Log (""rows="" + m2.rows() + "", "" + ""cols="" + m2.cols());
Debug.Log (""m2="" + m2.dump());
";
UpdateScrollRect ();
}
public void OnRandShuffleExampleButtonClick ()
{
//
// randShuffle example
//
// 4x5 matrix
Mat m1 = new Mat (4, 5, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20);
Debug.Log ("m1(original)=" + m1.dump ());
executionResultText.text = "m1(original)=" + m1.dump () + "\n";
// shuffle
Core.randShuffle (m1, UnityEngine.Random.value);
Debug.Log ("m1(shuffle)=" + m1.dump ());
executionResultText.text += "m1(shuffle)=" + m1.dump () + "\n";
// submatrix
Mat m2 = new Mat (m1, new OpenCVForUnity.CoreModule.Rect (1, 1, 3, 2));
Debug.Log ("m2(sub-matrix)=" + m2.dump ());
executionResultText.text += "m2(sub-matrix)=" + m2.dump () + "\n";
Core.randShuffle (m2, UnityEngine.Random.value);
Debug.Log ("m2(sub-matrix)=" + m2.dump ());
Debug.Log ("m1=" + m1.dump ());
executionResultText.text += "m2(shuffle sub-matrix)=" + m2.dump () + "\n";
executionResultText.text += "m1=" + m1.dump () + "\n";
exampleCodeText.text = @"
//
// randShuffle example
//
// 4x5 matrix
Mat m1 = new Mat (4, 5, CvType.CV_64FC1);
m1.put (0, 0, 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20);
Debug.Log (""m1(original)="" + m1.dump ());
// shuffle
Core.randShuffle (m1, UnityEngine.Random.value);
Debug.Log (""m1(shuffle)="" + m1.dump ());
// submatrix
Mat m2 = new Mat (m1, new OpenCVForUnity.CoreModule.Rect(1,1,3,2));
Debug.Log (""m2(sub-matrix)="" + m2.dump());
Core.randShuffle (m2, UnityEngine.Random.value);
Debug.Log (""m2(sub-matrix)="" + m2.dump());
Debug.Log (""m1="" + m1.dump ());
";
UpdateScrollRect ();
}
public void OnSortExampleButtonClick ()
{
//
// sort example
//
// 5x5 matrix
Mat m1 = new Mat (5, 5, CvType.CV_8UC1);
Core.randu (m1, 0, 25);
Debug.Log ("m1=" + m1.dump ());
executionResultText.text = "m1=" + m1.dump () + "\n";
Mat dst_mat = new Mat ();
// sort ascending
Core.sort (m1, dst_mat, Core.SORT_EVERY_ROW | Core.SORT_ASCENDING);
Debug.Log ("ROW|ASCENDING:" + dst_mat.dump ());
executionResultText.text += "ROW|ASCENDING:" + dst_mat.dump () + "\n";
// sort descending
Core.sort (m1, dst_mat, Core.SORT_EVERY_ROW | Core.SORT_DESCENDING);
Debug.Log ("ROW|DESCENDING:" + dst_mat.dump ());
executionResultText.text += "ROW|DESCENDING:" + dst_mat.dump () + "\n";
// sort ascending
Core.sort (m1, dst_mat, Core.SORT_EVERY_COLUMN | Core.SORT_ASCENDING);
Debug.Log ("COLUMN|ASCENDING:" + dst_mat.dump ());
executionResultText.text += "COLUMN|ASCENDING:" + dst_mat.dump () + "\n";
// sort descending
Core.sort (m1, dst_mat, Core.SORT_EVERY_COLUMN | Core.SORT_DESCENDING);
Debug.Log ("COLUMN|DESCENDING:" + dst_mat.dump ());
executionResultText.text += "COLUMN|DESCENDING:" + dst_mat.dump () + "\n";
exampleCodeText.text = @"
//
// sort example
//
// 5x5 matrix
Mat m1 = new Mat (5, 5, CvType.CV_8UC1);
Core.randu (m1, 0, 25);
Debug.Log (""m1="" + m1.dump ());
executionResultText.text = ""m1="" + m1.dump() + ""\n"";
Mat dst_mat = new Mat ();
// sort ascending
Core.sort (m1, dst_mat, Core.SORT_EVERY_ROW|Core.SORT_ASCENDING);
Debug.Log (""ROW|ASCENDING:"" + dst_mat.dump ());
// sort descending
Core.sort (m1, dst_mat, Core.SORT_EVERY_ROW|Core.SORT_DESCENDING);
Debug.Log (""ROW|DESCENDING:"" + dst_mat.dump ());
// sort ascending
Core.sort (m1, dst_mat, Core.SORT_EVERY_COLUMN|Core.SORT_ASCENDING);
Debug.Log (""COLUMN|ASCENDING:"" + dst_mat.dump ());
// sort descending
Core.sort (m1, dst_mat, Core.SORT_EVERY_COLUMN|Core.SORT_DESCENDING);
Debug.Log (""COLUMN|DESCENDING:"" + dst_mat.dump ());
";
UpdateScrollRect ();
}
public void OnComparisonExampleButtonClick ()
{
//
// comparison example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Mat m2 = new Mat (3, 3, CvType.CV_64FC1);
m2.put (0, 0, 9, 8, 7, 6, 5, 4, 3, 2, 1);
Debug.Log ("m1=" + m1.dump ());
Debug.Log ("m2=" + m2.dump ());
executionResultText.text = "m1=" + m1.dump () + "\n";
executionResultText.text += "m2=" + m2.dump () + "\n";
Mat dst_mat = new Mat ();
// GT (M1 > M2)
Core.compare (m1, m2, dst_mat, Core.CMP_GT);
Debug.Log ("GT (M1 > M2)=" + dst_mat.dump ());
executionResultText.text += "GT (M1 > M2)=" + dst_mat.dump () + "\n";
// GE (M1 >= M2)
Core.compare (m1, m2, dst_mat, Core.CMP_GE);
Debug.Log ("GE (M1 >= M2)=" + dst_mat.dump ());
executionResultText.text += "GE (M1 >= M2)=" + dst_mat.dump () + "\n";
// EQ (M1 == M2)
Core.compare (m1, m2, dst_mat, Core.CMP_EQ);
Debug.Log ("EQ (M1 == M2)=" + dst_mat.dump ());
executionResultText.text += "EQ (M1 == M2)=" + dst_mat.dump () + "\n";
// NE (M1 != M2)
Core.compare (m1, m2, dst_mat, Core.CMP_NE);
Debug.Log ("NE (M1 != M2)=" + dst_mat.dump ());
executionResultText.text += "NE (M1 != M2)=" + dst_mat.dump () + "\n";
// LE (M1 <= M2)
Core.compare (m1, m2, dst_mat, Core.CMP_LE);
Debug.Log ("LE (M1 <= M2)=" + dst_mat.dump ());
executionResultText.text += "LE (M1 <= M2)=" + dst_mat.dump () + "\n";
// LT (M1 < M2)
Core.compare (m1, m2, dst_mat, Core.CMP_LT);
Debug.Log ("LT (M1 < M2)=" + dst_mat.dump ());
executionResultText.text += "LT (M1 < M2)=" + dst_mat.dump () + "\n";
exampleCodeText.text = @"
//
// comparison example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1,2,3,4,5,6,7,8,9);
Mat m2 = new Mat (3, 3, CvType.CV_64FC1);
m2.put (0, 0, 10,11,12,13,14,15,16,17,18);
Debug.Log (""m1="" + m1.dump ());
Debug.Log (""m2="" + m2.dump ());
Mat dst_mat = new Mat ();
// GT (M1 > M2)
Core.compare (m1, m2, dst_mat, Core.CMP_GT);
Debug.Log (""GT (M1 > M2)="" + dst_mat.dump ());
// GE (M1 >= M2)
Core.compare (m1, m2, dst_mat, Core.CMP_GE);
Debug.Log (""GE (M1 >= M2)="" + dst_mat.dump ());
// EQ (M1 == M2)
Core.compare (m1, m2, dst_mat, Core.CMP_EQ);
Debug.Log (""EQ (M1 == M2)="" + dst_mat.dump ());
// NE (M1 != M2)
Core.compare (m1, m2, dst_mat, Core.CMP_NE);
Debug.Log (""NE (M1 != M2)="" + dst_mat.dump ());
// LE (M1 <= M2)
Core.compare (m1, m2, dst_mat, Core.CMP_LE);
Debug.Log (""LE (M1 <= M2)="" + dst_mat.dump ());
// LT (M1 < M2)
Core.compare (m1, m2, dst_mat, Core.CMP_LT);
Debug.Log (""LT (M1 < M2)="" + dst_mat.dump ());
";
UpdateScrollRect ();
}
public void OnOperatorsExampleButtonClick ()
{
//
// operators example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9);
Mat m2 = new Mat (3, 3, CvType.CV_64FC1);
m2.put (0, 0, 10, 11, 12, 13, 14, 15, 16, 17, 18);
Scalar s = new Scalar (5);
double alpha = 3;
Debug.Log ("m1=" + m1.dump ());
Debug.Log ("m2=" + m2.dump ());
Debug.Log ("s=" + s);
Debug.Log ("alpha=" + alpha);
executionResultText.text = "m1=" + m1.dump () + "\n";
executionResultText.text += "m2=" + m2.dump () + "\n";
executionResultText.text += "s=" + s + "\n";
executionResultText.text += "alpha=" + alpha + "\n";
// Addition, subtraction, negation: A+B, A-B, A+s, A-s, s+A, s-A, -A
// (M1 + M2 = Core.add (M1, M2, M_dst))
Debug.Log ("m1+m2=" + (m1 + m2).dump ());
executionResultText.text += "m1+m2=" + (m1 + m2).dump () + "\n";
// (M1 + s = Core.add (M1, s, M_dst))
Debug.Log ("m1+s=" + (m1 + s).dump ());
executionResultText.text += "m1+s=" + (m1 + s).dump () + "\n";
// (M1 M2 = Core.subtract (M1, M2, M_dst))
Debug.Log ("m1-m2=" + (m1 - m2).dump ());
executionResultText.text += "m1-m2=" + (m1 - m2).dump () + "\n";
// (M1 s = Core.subtract (M1, s, M_dst))
Debug.Log ("m1-s=" + (m1 - s).dump ());
executionResultText.text += "m1-s=" + (m1 - s).dump () + "\n";
// (-M1 = Core.multiply (M1, Scalar.all (-1), M_dst))
Debug.Log ("-m1=" + (-m1).dump ());
executionResultText.text += "-m1=" + (-m1).dump () + "\n";
// Scaling: A*alpha A/alpha
// (M1 * 3 = Core.multiply (M1, Scalar.all (3), M_dst))
Debug.Log ("m1*alpha=" + (m1 * alpha).dump ());
executionResultText.text += "m1*alpha=" + (m1 * alpha).dump () + "\n";
// (M1 / 3 = Core.divide (M1, Scalar.all (3), M_dst))
Debug.Log ("m1/alpha=" + (m1 / alpha).dump ());
executionResultText.text += "m1/alpha=" + (m1 / alpha).dump () + "\n";
// Per-element multiplication and division: A.mul(B), A/B, alpha/A
// (M1.mul(M2) = M1.mul (M2))
Debug.Log ("m1.mul(m2)=" + (m1.mul (m2)).dump ());
executionResultText.text += "m1.mul(m2)=" + (m1.mul (m2)).dump () + "\n";
// (M1 / M2 = Core.divide (M1, M2, M_dst))
Debug.Log ("m1/m2=" + (m1 / m2).dump ());
executionResultText.text += "m1/m2=" + (m1 / m2).dump () + "\n";
// (3 / M1 = Core.divide (new Mat (M1.size (), M1.type (), Scalar.all (3)), M1, M_dst))
Debug.Log ("alpha/m2=" + (alpha / m2).dump ());
executionResultText.text += "alpha/m2=" + (alpha / m2).dump () + "\n";
// Matrix multiplication: A*B
// (M1 * M2 = Core.gemm (M1, M2, 1, new Mat (), 0, M_dst))
Debug.Log ("m1*m2=" + (m1 * m2).dump ());
executionResultText.text += "m1*m2=" + (m1 * m2).dump () + "\n";
// Bitwise logical operations: A logicop B, A logicop s, s logicop A, ~A, where logicop is one of : &, |, ^.
// (M1 & M2 = Core.bitwise_and (M1, M2, M_dst))
Debug.Log ("m1&m2=" + (m1 & m2).dump ());
executionResultText.text += "m1&m2=" + (m1 & m2).dump () + "\n";
// (M1 | M2 = Core.bitwise_or (M1, M2, M_dst))
Debug.Log ("m1|m2=" + (m1 | m2).dump ());
executionResultText.text += "m1|m2=" + (m1 | m2).dump () + "\n";
// (M1 ^ M2 = Core.bitwise_xor (M1, M2, M_dst))
Debug.Log ("m1^m2=" + (m1 ^ m2).dump ());
executionResultText.text += "m1^m2=" + (m1 ^ m2).dump () + "\n";
// (~M1 = Core.bitwise_not (M1, M_dst))
Debug.Log ("~m1=" + (~m1).dump ());
executionResultText.text += "~m1=" + (~m1).dump () + "\n";
// Note.
// The assignment operator behavior is different from OpenCV (c ++).
// For example, C = A + B will not be expanded to cv :: add (A, B, C).
// Also cannot assign a scalar to Mat like C = s.
exampleCodeText.text = @"
//
// operators example
//
// 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_64FC1);
m1.put (0, 0, 1,2,3,4,5,6,7,8,9);
Mat m2 = new Mat (3, 3, CvType.CV_64FC1);
m2.put (0, 0, 10,11,12,13,14,15,16,17,18);
Scalar s = new Scalar (5);
double alpha = 3;
Debug.Log (""m1="" + m1.dump ());
Debug.Log (""m2="" + m2.dump ());
Debug.Log (""s="" + s);
Debug.Log (""alpha="" + alpha);
// Addition, subtraction, negation: A+B, A-B, A+s, A-s, s+A, s-A, -A
// (M1 + M2 = Core.add (M1, M2, M_dst))
Debug.Log (""m1+m2="" + (m1 + m2).dump());
// (M1 + s = Core.add (M1, s, M_dst))
Debug.Log (""m1+s="" + (m1 + s).dump());
// (M1 M2 = Core.subtract (M1, M2, M_dst))
Debug.Log (""m1-m2="" + (m1 - m2).dump());
// (M1 s = Core.subtract (M1, s, M_dst))
Debug.Log (""m1-s="" + (m1 - s).dump());
// (-M1 = Core.multiply (M1, Scalar.all (-1), M_dst))
Debug.Log (""-m1="" + (-m1).dump());
// Scaling: A*alpha A/alpha
// (M1 * 3 = Core.multiply (M1, Scalar.all (3), M_dst))
Debug.Log (""m1*alpha="" + (m1*alpha).dump());
// (M1 / 3 = Core.divide (M1, Scalar.all (3), M_dst))
Debug.Log (""m1/alpha="" + (m1/alpha).dump());
// Per-element multiplication and division: A.mul(B), A/B, alpha/A
// (M1.mul(M2) = M1.mul (M2))
Debug.Log (""m1.mul(m2)="" + (m1.mul(m2)).dump());
// (M1 / M2 = Core.divide (M1, M2, M_dst))
Debug.Log (""m1/m2="" + (m1 / m2).dump());
// (3 / M1 = Core.divide (new Mat (M1.size (), M1.type (), Scalar.all (3)), M1, M_dst))
Debug.Log (""alpha/m2="" + (alpha / m2).dump());
// Matrix multiplication: A*B
// (M1 * M2 = Core.gemm (M1, M2, 1, new Mat (), 0, M_dst))
Debug.Log (""m1*m2="" + (m1 * m2).dump());
// Bitwise logical operations: A logicop B, A logicop s, s logicop A, ~A, where logicop is one of : &, |, ^.
// (M1 & M2 = Core.bitwise_and (M1, M2, M_dst))
Debug.Log (""m1&m2="" + (m1 & m2).dump());
// (M1 | M2 = Core.bitwise_or (M1, M2, M_dst))
Debug.Log (""m1|m2="" + (m1 | m2).dump());
// (M1 ^ M2 = Core.bitwise_xor (M1, M2, M_dst))
Debug.Log (""m1^m2="" + (m1 ^ m2).dump());
// (~M1 = Core.bitwise_not (M1, M_dst))
Debug.Log (""~m1="" + (~m1).dump());
// Note.
// The assignment operator behavior is different from OpenCV (c ++).
// For example, C = A + B will not be expanded to cv :: add (A, B, C).
// Also cannot assign a scalar to Mat like C = s.
";
UpdateScrollRect ();
}
public void OnGetAndPutExampleButtonClick ()
{
//
// get and put example
//
// channels=4 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_8UC4, new Scalar (1, 2, 3, 4));
Debug.Log ("m1=" + m1.dump ());
executionResultText.text = "m1=" + m1.dump () + "\n";
// get an element value.
double[] m1_1_1 = m1.get (1, 1);
Debug.Log ("m1[1,1]=" + m1_1_1 [0] + ", " + m1_1_1 [1] + ", " + m1_1_1 [2] + ", " + m1_1_1 [3]);
executionResultText.text += "m1[1,1]=" + m1_1_1 [0] + ", " + m1_1_1 [1] + ", " + m1_1_1 [2] + ", " + m1_1_1 [3] + "\n";
// get an array of all element values.
byte[] m1_array = new byte[m1.total () * m1.channels ()];
m1.get (0, 0, m1_array);
string dump_str = "";
foreach (var i in m1_array) {
dump_str += i + ", ";
}
Debug.Log ("m1_array=" + dump_str);
executionResultText.text += "m1_array=" + dump_str + "\n";
// another faster way. (use Utils.copyFromMat())
Utils.copyFromMat (m1, m1_array);
dump_str = "";
foreach (var i in m1_array) {
dump_str += i + ", ";
}
Debug.Log ("m1_array (use Utils.copyFromMat())=" + dump_str);
executionResultText.text += "m1_array (use Utils.copyFromMat())=" + dump_str + "\n";
// put an element value in a matrix.
Mat m2 = m1.clone ();
m2.put (1, 1, 5, 6, 7, 8);
Debug.Log ("m2=" + m2.dump ());
executionResultText.text += "m2=" + m2.dump () + "\n";
// put an array of element values in a matrix.
byte[] m2_arr = new byte[] {
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8,
5,
6,
7,
8
};
m2.put (0, 0, m2_arr);
Debug.Log ("m2=" + m2.dump ());
executionResultText.text += "m2=" + m2.dump () + "\n";
// another faster way. (use Utils.copyToMat())
Utils.copyToMat (m2_arr, m2);
Debug.Log ("m2 (use Utils.copyToMat())=" + m2.dump ());
executionResultText.text += "m2 (use Utils.copyToMat())=" + m2.dump () + "\n";
// fill element values (setTo method)
m2.setTo (new Scalar (100, 100, 100, 100));
Debug.Log ("m2=" + m2.dump ());
executionResultText.text += "m2=" + m2.dump () + "\n";
exampleCodeText.text = @"
//
// get and put example
//
// channels=4 3x3 matrix
Mat m1 = new Mat (3, 3, CvType.CV_8UC4 , new Scalar(1,2,3,4));
Debug.Log (""m1="" + m1.dump ());
// get an element value.
double[] m1_1_1 = m1.get(1,1);
Debug.Log (""m1[1,1]="" + m1_1_1[0] + "", "" + m1_1_1[1] + "", "" + m1_1_1[2] + "", "" + m1_1_1[3]);
// get an array of all element values.
byte[] m1_array = new byte[m1.total () * m1.channels()];
m1.get (0, 0, m1_array);
string dump_str = """";
foreach (var i in m1_array){
dump_str += i + "", "";
}
Debug.Log (""m1_array="" + dump_str);
// another faster way. (use Utils.copyFromMat())
Utils.copyFromMat (m1, m1_array);
dump_str = """";
foreach (var i in m1_array) {
dump_str += i + "", "";
}
Debug.Log (""m1_array (use Utils.copyFromMat())="" + dump_str);
// put an element value in a matrix.
Mat m2 = m1.clone ();
m2.put (1, 1, 5,6,7,8);
Debug.Log (""m2="" + m2.dump ());
// put an array of element values in a matrix.
byte[] m2_arr = new byte[]{5,6,7,8,5,6,7,8,5,6,7,8,5,6,7,8,5,6,7,8,5,6,7,8,5,6,7,8,5,6,7,8,5,6,7,8};
m2.put (0, 0, m2_arr);
Debug.Log (""m2="" + m2.dump ());
// another faster way. (use Utils.copyToMat())
Utils.copyToMat (m2_arr, m2);
Debug.Log (""m2 (use Utils.copyToMat())="" + m2.dump ());
// fill element values (setTo method)
m2.setTo(new Scalar(100,100,100,100));
Debug.Log (""m2="" + m2.dump ());
";
UpdateScrollRect ();
}
public void OnAccessingPixelValueExampleButtonClick ()
{
//
// accessing pixel value example
//
// How access pixel value in an OpenCV Mat.
// channels=4 10x10 matrix (RGBA color image)
Mat src_img = new Mat (10, 10, CvType.CV_8UC4, new Scalar (0, 0, 0, 255));
Mat dst_img = new Mat (10, 10, CvType.CV_8UC4);
Debug.Log ("src_img=" + src_img.dump ());
executionResultText.text = "src_img=" + src_img.dump () + "\n";
// Copies an OpenCV Mat data to a pixel data Array.
byte[] img_array = new byte[src_img.total () * src_img.channels ()];
Utils.copyFromMat (src_img, img_array);
int pixel_i = 0;
int channels = src_img.channels ();
int total = (int)src_img.total ();
for (int i = 0; i < total; i++) {
img_array [pixel_i] = (byte)i;
img_array [pixel_i + 1] = (byte)i;
img_array [pixel_i + 2] = (byte)i;
// Advance to next pixel
pixel_i += channels;
}
// Copies a pixel data Array to an OpenCV Mat data.
Utils.copyToMat (img_array, dst_img);
Debug.Log ("dst_img=" + dst_img.dump ());
executionResultText.text += "dst_img=" + dst_img.dump () + "\n";
exampleCodeText.text = @"
//
// accessing pixel value example
//
// How access pixel value in an OpenCV Mat.
// channels=4 10x10 matrix (RGBA color image)
Mat src_img = new Mat (10, 10, CvType.CV_8UC4, new Scalar (0, 0, 0, 255));
Mat dst_img = new Mat (10, 10, CvType.CV_8UC4);
Debug.Log (""src_img="" + src_img.dump ());
// Copies an OpenCV Mat data to a pixel data Array.
byte[] img_array = new byte[src_img.total () * src_img.channels()];
Utils.copyFromMat (src_img, img_array);
int pixel_i = 0;
int channels = src_img.channels();
int total = (int)src_img.total();
for (int i = 0; i < total; i++) {
img_array [pixel_i] = (byte)i;
img_array [pixel_i + 1] = (byte)i;
img_array [pixel_i + 2] = (byte)i;
// Advance to next pixel
pixel_i += channels;
}
// Copies a pixel data Array to an OpenCV Mat data.
Utils.copyToMat (img_array, dst_img);
Debug.Log (""dst_img="" + dst_img.dump ());
";
UpdateScrollRect ();
}
}
}