gocv

package module
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Published: Nov 21, 2022 License: Apache-2.0 Imports: 10 Imported by: 2

README

gocv fork from https://github.com/hybridgroup/gocv

简介

原项目对windows用户不太友好,特别是需要编译opencv,cmake时还需要从github下载其他依赖包,经常编译不成功。 本项目已经编译好了opencv,采用静态链接,go build出的包比较大

使用

引入包

go get gitee.com/jinzhongmin/gocv

构建应用,不需要其他tag,直接静态编译

go build

缺点

  • 第一次编译时间较长
  • 编译出的可执行文件较大

对于原项目修改

  • 删除cuda、contrib、openvino子包
  • 删除编译脚本、docker文件
  • 修改cgo.go文件,将cgo链接改为静态

Documentation

Overview

Package gocv is a wrapper around the OpenCV 4.x computer vision library. It provides a Go language interface to the latest version of OpenCV.

OpenCV (Open Source Computer Vision Library: http://opencv.org) is an open-source BSD-licensed library that includes several hundreds of computer vision algorithms.

For further details, please see: http://docs.opencv.org/master/d1/dfb/intro.html

Index

Examples

Constants

View Source
const (
	// MatChannels1 is a single channel Mat.
	MatChannels1 = 0

	// MatChannels2 is 2 channel Mat.
	MatChannels2 = 8

	// MatChannels3 is 3 channel Mat.
	MatChannels3 = 16

	// MatChannels4 is 4 channel Mat.
	MatChannels4 = 24
)
View Source
const (
	// MatTypeCV8U is a Mat of 8-bit unsigned int
	MatTypeCV8U MatType = 0

	// MatTypeCV8S is a Mat of 8-bit signed int
	MatTypeCV8S MatType = 1

	// MatTypeCV16U is a Mat of 16-bit unsigned int
	MatTypeCV16U MatType = 2

	// MatTypeCV16S is a Mat of 16-bit signed int
	MatTypeCV16S MatType = 3

	// MatTypeCV16SC2 is a Mat of 16-bit signed int with 2 channels
	MatTypeCV16SC2 = MatTypeCV16S + MatChannels2

	// MatTypeCV32S is a Mat of 32-bit signed int
	MatTypeCV32S MatType = 4

	// MatTypeCV32F is a Mat of 32-bit float
	MatTypeCV32F MatType = 5

	// MatTypeCV64F is a Mat of 64-bit float
	MatTypeCV64F MatType = 6

	// MatTypeCV8UC1 is a Mat of 8-bit unsigned int with a single channel
	MatTypeCV8UC1 = MatTypeCV8U + MatChannels1

	// MatTypeCV8UC2 is a Mat of 8-bit unsigned int with 2 channels
	MatTypeCV8UC2 = MatTypeCV8U + MatChannels2

	// MatTypeCV8UC3 is a Mat of 8-bit unsigned int with 3 channels
	MatTypeCV8UC3 = MatTypeCV8U + MatChannels3

	// MatTypeCV8UC4 is a Mat of 8-bit unsigned int with 4 channels
	MatTypeCV8UC4 = MatTypeCV8U + MatChannels4

	// MatTypeCV8SC1 is a Mat of 8-bit signed int with a single channel
	MatTypeCV8SC1 = MatTypeCV8S + MatChannels1

	// MatTypeCV8SC2 is a Mat of 8-bit signed int with 2 channels
	MatTypeCV8SC2 = MatTypeCV8S + MatChannels2

	// MatTypeCV8SC3 is a Mat of 8-bit signed int with 3 channels
	MatTypeCV8SC3 = MatTypeCV8S + MatChannels3

	// MatTypeCV8SC4 is a Mat of 8-bit signed int with 4 channels
	MatTypeCV8SC4 = MatTypeCV8S + MatChannels4

	// MatTypeCV16UC1 is a Mat of 16-bit unsigned int with a single channel
	MatTypeCV16UC1 = MatTypeCV16U + MatChannels1

	// MatTypeCV16UC2 is a Mat of 16-bit unsigned int with 2 channels
	MatTypeCV16UC2 = MatTypeCV16U + MatChannels2

	// MatTypeCV16UC3 is a Mat of 16-bit unsigned int with 3 channels
	MatTypeCV16UC3 = MatTypeCV16U + MatChannels3

	// MatTypeCV16UC4 is a Mat of 16-bit unsigned int with 4 channels
	MatTypeCV16UC4 = MatTypeCV16U + MatChannels4

	// MatTypeCV16SC1 is a Mat of 16-bit signed int with a single channel
	MatTypeCV16SC1 = MatTypeCV16S + MatChannels1

	// MatTypeCV16SC3 is a Mat of 16-bit signed int with 3 channels
	MatTypeCV16SC3 = MatTypeCV16S + MatChannels3

	// MatTypeCV16SC4 is a Mat of 16-bit signed int with 4 channels
	MatTypeCV16SC4 = MatTypeCV16S + MatChannels4

	// MatTypeCV32SC1 is a Mat of 32-bit signed int with a single channel
	MatTypeCV32SC1 = MatTypeCV32S + MatChannels1

	// MatTypeCV32SC2 is a Mat of 32-bit signed int with 2 channels
	MatTypeCV32SC2 = MatTypeCV32S + MatChannels2

	// MatTypeCV32SC3 is a Mat of 32-bit signed int with 3 channels
	MatTypeCV32SC3 = MatTypeCV32S + MatChannels3

	// MatTypeCV32SC4 is a Mat of 32-bit signed int with 4 channels
	MatTypeCV32SC4 = MatTypeCV32S + MatChannels4

	// MatTypeCV32FC1 is a Mat of 32-bit float int with a single channel
	MatTypeCV32FC1 = MatTypeCV32F + MatChannels1

	// MatTypeCV32FC2 is a Mat of 32-bit float int with 2 channels
	MatTypeCV32FC2 = MatTypeCV32F + MatChannels2

	// MatTypeCV32FC3 is a Mat of 32-bit float int with 3 channels
	MatTypeCV32FC3 = MatTypeCV32F + MatChannels3

	// MatTypeCV32FC4 is a Mat of 32-bit float int with 4 channels
	MatTypeCV32FC4 = MatTypeCV32F + MatChannels4

	// MatTypeCV64FC1 is a Mat of 64-bit float int with a single channel
	MatTypeCV64FC1 = MatTypeCV64F + MatChannels1

	// MatTypeCV64FC2 is a Mat of 64-bit float int with 2 channels
	MatTypeCV64FC2 = MatTypeCV64F + MatChannels2

	// MatTypeCV64FC3 is a Mat of 64-bit float int with 3 channels
	MatTypeCV64FC3 = MatTypeCV64F + MatChannels3

	// MatTypeCV64FC4 is a Mat of 64-bit float int with 4 channels
	MatTypeCV64FC4 = MatTypeCV64F + MatChannels4
)
View Source
const (
	//IMWriteJpegQuality is the quality from 0 to 100 for JPEG (the higher is the better). Default value is 95.
	IMWriteJpegQuality = 1

	// IMWriteJpegProgressive enables JPEG progressive feature, 0 or 1, default is False.
	IMWriteJpegProgressive = 2

	// IMWriteJpegOptimize enables JPEG optimization, 0 or 1, default is False.
	IMWriteJpegOptimize = 3

	// IMWriteJpegRstInterval is the JPEG restart interval, 0 - 65535, default is 0 - no restart.
	IMWriteJpegRstInterval = 4

	// IMWriteJpegLumaQuality separates luma quality level, 0 - 100, default is 0 - don't use.
	IMWriteJpegLumaQuality = 5

	// IMWriteJpegChromaQuality separates chroma quality level, 0 - 100, default is 0 - don't use.
	IMWriteJpegChromaQuality = 6

	// IMWritePngCompression is the compression level from 0 to 9 for PNG. A
	// higher value means a smaller size and longer compression time.
	// If specified, strategy is changed to IMWRITE_PNG_STRATEGY_DEFAULT (Z_DEFAULT_STRATEGY).
	// Default value is 1 (best speed setting).
	IMWritePngCompression = 16

	// IMWritePngStrategy is one of cv::IMWritePNGFlags, default is IMWRITE_PNG_STRATEGY_RLE.
	IMWritePngStrategy = 17

	// IMWritePngBilevel is the binary level PNG, 0 or 1, default is 0.
	IMWritePngBilevel = 18

	// IMWritePxmBinary for PPM, PGM, or PBM can be a binary format flag, 0 or 1. Default value is 1.
	IMWritePxmBinary = 32

	// IMWriteWebpQuality is the quality from 1 to 100 for WEBP (the higher is
	// the better). By default (without any parameter) and for quality above
	// 100 the lossless compression is used.
	IMWriteWebpQuality = 64

	// IMWritePamTupletype sets the TUPLETYPE field to the corresponding string
	// value that is defined for the format.
	IMWritePamTupletype = 128

	// IMWritePngStrategyDefault is the value to use for normal data.
	IMWritePngStrategyDefault = 0

	// IMWritePngStrategyFiltered is the value to use for data produced by a
	// filter (or predictor). Filtered data consists mostly of small values
	// with a somewhat random distribution. In this case, the compression
	// algorithm is tuned to compress them better.
	IMWritePngStrategyFiltered = 1

	// IMWritePngStrategyHuffmanOnly forces Huffman encoding only (no string match).
	IMWritePngStrategyHuffmanOnly = 2

	// IMWritePngStrategyRle is the value to use to limit match distances to
	// one (run-length encoding).
	IMWritePngStrategyRle = 3

	// IMWritePngStrategyFixed is the value to prevent the use of dynamic
	// Huffman codes, allowing for a simpler decoder for special applications.
	IMWritePngStrategyFixed = 4
)
View Source
const (
	OptflowUseInitialFlow    = 4
	OptflowLkGetMinEigenvals = 8
	OptflowFarnebackGaussian = 256
)

*

cv::OPTFLOW_USE_INITIAL_FLOW = 4,
cv::OPTFLOW_LK_GET_MIN_EIGENVALS = 8,
cv::OPTFLOW_FARNEBACK_GAUSSIAN = 256
For further details, please see: https://docs.opencv.org/master/dc/d6b/group__video__track.html#gga2c6cc144c9eee043575d5b311ac8af08a9d4430ac75199af0cf6fcdefba30eafe
View Source
const (
	MotionTranslation = 0
	MotionEuclidean   = 1
	MotionAffine      = 2
	MotionHomography  = 3
)

*

cv::MOTION_TRANSLATION = 0,
cv::MOTION_EUCLIDEAN = 1,
cv::MOTION_AFFINE = 2,
cv::MOTION_HOMOGRAPHY = 3
For further details, please see: https://docs.opencv.org/4.x/dc/d6b/group__video__track.html#ggaaedb1f94e6b143cef163622c531afd88a01106d6d20122b782ff25eaeffe9a5be
View Source
const GoCVVersion = "0.31.0"

GoCVVersion of this package, for display purposes.

Variables

View Source
var ErrEmptyByteSlice = errors.New("empty byte array")

Functions

func AbsDiff

func AbsDiff(src1, src2 Mat, dst *Mat)

AbsDiff calculates the per-element absolute difference between two arrays or between an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6fef31bc8c4071cbc114a758a2b79c14

func Accumulate

func Accumulate(src Mat, dst *Mat)

func AccumulateProduct

func AccumulateProduct(src1 Mat, src2 Mat, dst *Mat)

Adds the per-element product of two input images to the accumulator image.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#ga82518a940ecfda49460f66117ac82520

func AccumulateProductWithMask

func AccumulateProductWithMask(src1 Mat, src2 Mat, dst *Mat, mask Mat)

Adds the per-element product of two input images to the accumulator image with mask.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#ga82518a940ecfda49460f66117ac82520

func AccumulateSquare

func AccumulateSquare(src Mat, dst *Mat)

Adds the square of a source image to the accumulator image.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#gacb75e7ffb573227088cef9ceaf80be8c

func AccumulateSquareWithMask

func AccumulateSquareWithMask(src Mat, dst *Mat, mask Mat)

Adds the square of a source image to the accumulator image with mask.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#gacb75e7ffb573227088cef9ceaf80be8c

func AccumulateWithMask

func AccumulateWithMask(src Mat, dst *Mat, mask Mat)

Adds an image to the accumulator image with mask.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#ga1a567a79901513811ff3b9976923b199

func AccumulatedWeighted

func AccumulatedWeighted(src Mat, dst *Mat, alpha float64)

Updates a running average.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#ga4f9552b541187f61f6818e8d2d826bc7

func AccumulatedWeightedWithMask

func AccumulatedWeightedWithMask(src Mat, dst *Mat, alpha float64, mask Mat)

Updates a running average with mask.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#ga4f9552b541187f61f6818e8d2d826bc7

func AdaptiveThreshold

func AdaptiveThreshold(src Mat, dst *Mat, maxValue float32, adaptiveTyp AdaptiveThresholdType, typ ThresholdType, blockSize int, c float32)

AdaptiveThreshold applies a fixed-level threshold to each array element.

For further details, please see: https://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga72b913f352e4a1b1b397736707afcde3

func Add

func Add(src1, src2 Mat, dst *Mat)

Add calculates the per-element sum of two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga10ac1bfb180e2cfda1701d06c24fdbd6

func AddWeighted

func AddWeighted(src1 Mat, alpha float64, src2 Mat, beta float64, gamma float64, dst *Mat)

AddWeighted calculates the weighted sum of two arrays.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gafafb2513349db3bcff51f54ee5592a19

func ApplyColorMap

func ApplyColorMap(src Mat, dst *Mat, colormapType ColormapTypes)

ApplyColorMap applies a GNU Octave/MATLAB equivalent colormap on a given image.

For further details, please see: https://docs.opencv.org/master/d3/d50/group__imgproc__colormap.html#gadf478a5e5ff49d8aa24e726ea6f65d15

func ApplyCustomColorMap

func ApplyCustomColorMap(src Mat, dst *Mat, customColormap Mat)

ApplyCustomColorMap applies a custom defined colormap on a given image.

For further details, please see: https://docs.opencv.org/master/d3/d50/group__imgproc__colormap.html#gacb22288ddccc55f9bd9e6d492b409cae

func ArcLength

func ArcLength(curve PointVector, isClosed bool) float64

ArcLength calculates a contour perimeter or a curve length.

For further details, please see:

https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga8d26483c636be6b35c3ec6335798a47c

func ArrowedLine

func ArrowedLine(img *Mat, pt1 image.Point, pt2 image.Point, c color.RGBA, thickness int)

ArrowedLine draws a arrow segment pointing from the first point to the second one.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga0a165a3ca093fd488ac709fdf10c05b2

func BatchDistance

func BatchDistance(src1 Mat, src2 Mat, dist Mat, dtype MatType, nidx Mat, normType NormType, K int, mask Mat, update int, crosscheck bool)

BatchDistance is a naive nearest neighbor finder.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga4ba778a1c57f83233b1d851c83f5a622

func BilateralFilter

func BilateralFilter(src Mat, dst *Mat, diameter int, sigmaColor float64, sigmaSpace float64)

BilateralFilter applies a bilateral filter to an image.

Bilateral filtering is described here: http://www.dai.ed.ac.uk/CVonline/LOCAL_COPIES/MANDUCHI1/Bilateral_Filtering.html

BilateralFilter can reduce unwanted noise very well while keeping edges fairly sharp. However, it is very slow compared to most filters.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga9d7064d478c95d60003cf839430737ed

func BitwiseAnd

func BitwiseAnd(src1 Mat, src2 Mat, dst *Mat)

BitwiseAnd computes bitwise conjunction of the two arrays (dst = src1 & src2). Calculates the per-element bit-wise conjunction of two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga60b4d04b251ba5eb1392c34425497e14

func BitwiseAndWithMask

func BitwiseAndWithMask(src1 Mat, src2 Mat, dst *Mat, mask Mat)

BitwiseAndWithMask computes bitwise conjunction of the two arrays (dst = src1 & src2). Calculates the per-element bit-wise conjunction of two arrays or an array and a scalar. It has an additional parameter for a mask.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga60b4d04b251ba5eb1392c34425497e14

func BitwiseNot

func BitwiseNot(src1 Mat, dst *Mat)

BitwiseNot inverts every bit of an array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga0002cf8b418479f4cb49a75442baee2f

func BitwiseNotWithMask

func BitwiseNotWithMask(src1 Mat, dst *Mat, mask Mat)

BitwiseNotWithMask inverts every bit of an array. It has an additional parameter for a mask.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga0002cf8b418479f4cb49a75442baee2f

func BitwiseOr

func BitwiseOr(src1 Mat, src2 Mat, dst *Mat)

BitwiseOr calculates the per-element bit-wise disjunction of two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gab85523db362a4e26ff0c703793a719b4

func BitwiseOrWithMask

func BitwiseOrWithMask(src1 Mat, src2 Mat, dst *Mat, mask Mat)

BitwiseOrWithMask calculates the per-element bit-wise disjunction of two arrays or an array and a scalar. It has an additional parameter for a mask.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gab85523db362a4e26ff0c703793a719b4

func BitwiseXor

func BitwiseXor(src1 Mat, src2 Mat, dst *Mat)

BitwiseXor calculates the per-element bit-wise "exclusive or" operation on two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga84b2d8188ce506593dcc3f8cd00e8e2c

func BitwiseXorWithMask

func BitwiseXorWithMask(src1 Mat, src2 Mat, dst *Mat, mask Mat)

BitwiseXorWithMask calculates the per-element bit-wise "exclusive or" operation on two arrays or an array and a scalar. It has an additional parameter for a mask.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga84b2d8188ce506593dcc3f8cd00e8e2c

func BlobFromImages

func BlobFromImages(imgs []Mat, blob *Mat, scaleFactor float64, size image.Point, mean Scalar,
	swapRB bool, crop bool, ddepth MatType)

BlobFromImages Creates 4-dimensional blob from series of images. Optionally resizes and crops images from center, subtract mean values, scales values by scalefactor, swap Blue and Red channels.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga2b89ed84432e4395f5a1412c2926293c

func Blur

func Blur(src Mat, dst *Mat, ksize image.Point)

Blur blurs an image Mat using a normalized box filter.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga8c45db9afe636703801b0b2e440fce37

func BorderInterpolate

func BorderInterpolate(p int, len int, borderType CovarFlags) int

BorderInterpolate computes the source location of an extrapolated pixel.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga247f571aa6244827d3d798f13892da58

func BoundingRect

func BoundingRect(contour PointVector) image.Rectangle

BoundingRect calculates the up-right bounding rectangle of a point set.

For further details, please see: https://docs.opencv.org/3.3.0/d3/dc0/group__imgproc__shape.html#gacb413ddce8e48ff3ca61ed7cf626a366

func BoxFilter

func BoxFilter(src Mat, dst *Mat, depth int, ksize image.Point)

BoxFilter blurs an image using the box filter.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gad533230ebf2d42509547d514f7d3fbc3

func BoxPoints

func BoxPoints(rect RotatedRect, pts *Mat)

BoxPoints finds the four vertices of a rotated rect. Useful to draw the rotated rectangle.

For further Details, please see: https://docs.opencv.org/3.3.0/d3/dc0/group__imgproc__shape.html#gaf78d467e024b4d7936cf9397185d2f5c

func CalcBackProject

func CalcBackProject(src []Mat, channels []int, hist Mat, backProject *Mat, ranges []float64, uniform bool)

CalcBackProject calculates the back projection of a histogram.

For futher details, please see: https://docs.opencv.org/3.4/d6/dc7/group__imgproc__hist.html#ga3a0af640716b456c3d14af8aee12e3ca

func CalcCovarMatrix

func CalcCovarMatrix(samples Mat, covar *Mat, mean *Mat, flags CovarFlags, ctype MatType)

CalcCovarMatrix calculates the covariance matrix of a set of vectors.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga017122d912af19d7d0d2cccc2d63819f

func CalcHist

func CalcHist(src []Mat, channels []int, mask Mat, hist *Mat, size []int, ranges []float64, acc bool)

CalcHist Calculates a histogram of a set of images

For futher details, please see: https://docs.opencv.org/master/d6/dc7/group__imgproc__hist.html#ga6ca1876785483836f72a77ced8ea759a

func CalcOpticalFlowFarneback

func CalcOpticalFlowFarneback(prevImg Mat, nextImg Mat, flow *Mat, pyrScale float64, levels int, winsize int,
	iterations int, polyN int, polySigma float64, flags int)

CalcOpticalFlowFarneback computes a dense optical flow using Gunnar Farneback's algorithm.

For further details, please see: https://docs.opencv.org/master/dc/d6b/group__video__track.html#ga5d10ebbd59fe09c5f650289ec0ece5af

func CalcOpticalFlowPyrLK

func CalcOpticalFlowPyrLK(prevImg Mat, nextImg Mat, prevPts Mat, nextPts Mat, status *Mat, err *Mat)

CalcOpticalFlowPyrLK calculates an optical flow for a sparse feature set using the iterative Lucas-Kanade method with pyramids.

For further details, please see: https://docs.opencv.org/master/dc/d6b/group__video__track.html#ga473e4b886d0bcc6b65831eb88ed93323

func CalcOpticalFlowPyrLKWithParams

func CalcOpticalFlowPyrLKWithParams(prevImg Mat, nextImg Mat, prevPts Mat, nextPts Mat, status *Mat, err *Mat,
	winSize image.Point, maxLevel int, criteria TermCriteria, flags int, minEigThreshold float64)

CalcOpticalFlowPyrLKWithParams calculates an optical flow for a sparse feature set using the iterative Lucas-Kanade method with pyramids.

For further details, please see: https://docs.opencv.org/master/dc/d6b/group__video__track.html#ga473e4b886d0bcc6b65831eb88ed93323

func CalibrateCamera

func CalibrateCamera(objectPoints Points3fVector, imagePoints Points2fVector, imageSize image.Point,
	cameraMatrix *Mat, distCoeffs *Mat, rvecs *Mat, tvecs *Mat, calibFlag CalibFlag) float64

CalibrateCamera finds the camera intrinsic and extrinsic parameters from several views of a calibration pattern.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga3207604e4b1a1758aa66acb6ed5aa65d

func Canny

func Canny(src Mat, edges *Mat, t1 float32, t2 float32)

Canny finds edges in an image using the Canny algorithm. The function finds edges in the input image image and marks them in the output map edges using the Canny algorithm. The smallest value between threshold1 and threshold2 is used for edge linking. The largest value is used to find initial segments of strong edges. See http://en.wikipedia.org/wiki/Canny_edge_detector

For further details, please see: http://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga04723e007ed888ddf11d9ba04e2232de

func CartToPolar

func CartToPolar(x Mat, y Mat, magnitude *Mat, angle *Mat, angleInDegrees bool)

CartToPolar calculates the magnitude and angle of 2D vectors.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gac5f92f48ec32cacf5275969c33ee837d

func CheckRange

func CheckRange(src Mat) bool

CheckRange checks every element of an input array for invalid values.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga2bd19d89cae59361416736f87e3c7a64

func Circle

func Circle(img *Mat, center image.Point, radius int, c color.RGBA, thickness int)

Circle draws a circle.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#gaf10604b069374903dbd0f0488cb43670

func CircleWithParams

func CircleWithParams(img *Mat, center image.Point, radius int, c color.RGBA, thickness int, lineType LineType, shift int)

CircleWithParams draws a circle.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#gaf10604b069374903dbd0f0488cb43670

func ClipLine

func ClipLine(imgSize image.Point, pt1 image.Point, pt2 image.Point) bool

ClipLine clips the line against the image rectangle. For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#gaf483cb46ad6b049bc35ec67052ef1c2c

func ColorChange

func ColorChange(src, mask Mat, dst *Mat, red_mul, green_mul, blue_mul float32)

ColorChange mix two differently colored versions of an image seamlessly.

For further details, please see: https://docs.opencv.org/master/df/da0/group__photo__clone.html#ga6684f35dc669ff6196a7c340dc73b98e

func Compare

func Compare(src1 Mat, src2 Mat, dst *Mat, ct CompareType)

Compare performs the per-element comparison of two arrays or an array and scalar value.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga303cfb72acf8cbb36d884650c09a3a97

func CompareHist

func CompareHist(hist1 Mat, hist2 Mat, method HistCompMethod) float32

CompareHist Compares two histograms.

For further details, please see: https://docs.opencv.org/master/d6/dc7/group__imgproc__hist.html#gaf4190090efa5c47cb367cf97a9a519bd

func CompleteSymm

func CompleteSymm(m Mat, lowerToUpper bool)

CompleteSymm copies the lower or the upper half of a square matrix to its another half.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaa9d88dcd0e54b6d1af38d41f2a3e3d25

func ConnectedComponents

func ConnectedComponents(src Mat, labels *Mat) int

ConnectedComponents computes the connected components labeled image of boolean image.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#gaedef8c7340499ca391d459122e51bef5

func ConnectedComponentsWithParams

func ConnectedComponentsWithParams(src Mat, labels *Mat, conn int, ltype MatType,
	ccltype ConnectedComponentsAlgorithmType) int

ConnectedComponents computes the connected components labeled image of boolean image.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#gaedef8c7340499ca391d459122e51bef5

func ConnectedComponentsWithStats

func ConnectedComponentsWithStats(src Mat, labels *Mat, stats *Mat, centroids *Mat) int

ConnectedComponentsWithStats computes the connected components labeled image of boolean image and also produces a statistics output for each label.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga107a78bf7cd25dec05fb4dfc5c9e765f

func ConnectedComponentsWithStatsWithParams

func ConnectedComponentsWithStatsWithParams(src Mat, labels *Mat, stats *Mat, centroids *Mat,
	conn int, ltype MatType, ccltype ConnectedComponentsAlgorithmType) int

ConnectedComponentsWithStats computes the connected components labeled image of boolean image and also produces a statistics output for each label.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga107a78bf7cd25dec05fb4dfc5c9e765f

func ContourArea

func ContourArea(contour PointVector) float64

ContourArea calculates a contour area.

For further details, please see: https://docs.opencv.org/3.3.0/d3/dc0/group__imgproc__shape.html#ga2c759ed9f497d4a618048a2f56dc97f1

func ConvertScaleAbs

func ConvertScaleAbs(src Mat, dst *Mat, alpha float64, beta float64)

ConvertScaleAbs scales, calculates absolute values, and converts the result to 8-bit.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga3460e9c9f37b563ab9dd550c4d8c4e7d

func ConvexHull

func ConvexHull(points PointVector, hull *Mat, clockwise bool, returnPoints bool)

ConvexHull finds the convex hull of a point set.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga014b28e56cb8854c0de4a211cb2be656

func ConvexityDefects

func ConvexityDefects(contour PointVector, hull Mat, result *Mat)

ConvexityDefects finds the convexity defects of a contour.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#gada4437098113fd8683c932e0567f47ba

func CopyMakeBorder

func CopyMakeBorder(src Mat, dst *Mat, top int, bottom int, left int, right int, bt BorderType, value color.RGBA)

CopyMakeBorder forms a border around an image (applies padding).

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga2ac1049c2c3dd25c2b41bffe17658a36

func CornerSubPix

func CornerSubPix(img Mat, corners *Mat, winSize image.Point, zeroZone image.Point, criteria TermCriteria)

CornerSubPix Refines the corner locations. The function iterates to find the sub-pixel accurate location of corners or radial saddle points.

For further details, please see: https://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga354e0d7c86d0d9da75de9b9701a9a87e

func CountNonZero

func CountNonZero(src Mat) int

CountNonZero counts non-zero array elements.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaa4b89393263bb4d604e0fe5986723914

func CvtColor

func CvtColor(src Mat, dst *Mat, code ColorConversionCode)

CvtColor converts an image from one color space to another. It converts the src Mat image to the dst Mat using the code param containing the desired ColorConversionCode color space.

For further details, please see: http://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga4e0972be5de079fed4e3a10e24ef5ef0

func DCT

func DCT(src Mat, dst *Mat, flags DftFlags)

DCT performs a forward or inverse discrete Cosine transform of 1D or 2D array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga85aad4d668c01fbd64825f589e3696d4

func DFT

func DFT(src Mat, dst *Mat, flags DftFlags)

DFT performs a forward or inverse Discrete Fourier Transform (DFT) of a 1D or 2D floating-point array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gadd6cf9baf2b8b704a11b5f04aaf4f39d

func DetailEnhance

func DetailEnhance(src Mat, dst *Mat, sigma_s, sigma_r float32)

DetailEnhance filter enhances the details of a particular image

For further details, please see: https://docs.opencv.org/4.x/df/dac/group__photo__render.html#gae5930dd822c713b36f8529b21ddebd0c

func Determinant

func Determinant(src Mat) float64

Determinant returns the determinant of a square floating-point matrix.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaf802bd9ca3e07b8b6170645ef0611d0c

func Dilate

func Dilate(src Mat, dst *Mat, kernel Mat)

Dilate dilates an image by using a specific structuring element.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga4ff0f3318642c4f469d0e11f242f3b6c

func DilateWithParams

func DilateWithParams(src Mat, dst *Mat, kernel Mat, anchor image.Point, iterations, borderType BorderType, borderValue color.RGBA)

DilateWithParams dilates an image by using a specific structuring element.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga4ff0f3318642c4f469d0e11f242f3b6c

func DistanceTransform

func DistanceTransform(src Mat, dst *Mat, labels *Mat, distType DistanceTypes, maskSize DistanceTransformMasks, labelType DistanceTransformLabelTypes)

DistanceTransform Calculates the distance to the closest zero pixel for each pixel of the source image.

For further details, please see: https://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga8a0b7fdfcb7a13dde018988ba3a43042

func Divide

func Divide(src1 Mat, src2 Mat, dst *Mat)

Divide performs the per-element division on two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6db555d30115642fedae0cda05604874

func DrawChessboardCorners

func DrawChessboardCorners(image *Mat, patternSize image.Point, corners Mat, patternWasFound bool)

DrawChessboardCorners renders the detected chessboard corners.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga6a10b0bb120c4907e5eabbcd22319022

func DrawContours

func DrawContours(img *Mat, contours PointsVector, contourIdx int, c color.RGBA, thickness int)

DrawContours draws contours outlines or filled contours.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga746c0625f1781f1ffc9056259103edbc

func DrawContoursWithParams

func DrawContoursWithParams(img *Mat, contours PointsVector, contourIdx int, c color.RGBA, thickness int, lineType LineType, hierarchy Mat, maxLevel int, offset image.Point)

DrawContoursWithParams draws contours outlines or filled contours.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga746c0625f1781f1ffc9056259103edbc

func DrawKeyPoints

func DrawKeyPoints(src Mat, keyPoints []KeyPoint, dst *Mat, color color.RGBA, flag DrawMatchesFlag)

DrawKeyPoints draws keypoints

For further details please see: https://docs.opencv.org/master/d4/d5d/group__features2d__draw.html#gab958f8900dd10f14316521c149a60433

func DrawMatches

func DrawMatches(img1 Mat, kp1 []KeyPoint, img2 Mat, kp2 []KeyPoint, matches1to2 []DMatch, outImg *Mat, matchColor color.RGBA, singlePointColor color.RGBA, matchesMask []byte, flags DrawMatchesFlag)

DrawMatches draws matches on combined train and querry images.

For further details, please see: https://docs.opencv.org/master/d4/d5d/group__features2d__draw.html#gad8f463ccaf0dc6f61083abd8717c261a

func EdgePreservingFilter

func EdgePreservingFilter(src Mat, dst *Mat, filter EdgeFilter, sigma_s, sigma_r float32)

EdgePreservingFilter filtering is the fundamental operation in image and video processing. Edge-preserving smoothing filters are used in many different applications.

For further details, please see: https://docs.opencv.org/4.x/df/dac/group__photo__render.html#gafaee2977597029bc8e35da6e67bd31f7

func Eigen

func Eigen(src Mat, eigenvalues *Mat, eigenvectors *Mat) bool

Eigen calculates eigenvalues and eigenvectors of a symmetric matrix.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga9fa0d58657f60eaa6c71f6fbb40456e3

func EigenNonSymmetric

func EigenNonSymmetric(src Mat, eigenvalues *Mat, eigenvectors *Mat)

EigenNonSymmetric calculates eigenvalues and eigenvectors of a non-symmetric matrix (real eigenvalues only).

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaf51987e03cac8d171fbd2b327cf966f6

func Ellipse

func Ellipse(img *Mat, center, axes image.Point, angle, startAngle, endAngle float64, c color.RGBA, thickness int)

Ellipse draws a simple or thick elliptic arc or fills an ellipse sector.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga28b2267d35786f5f890ca167236cbc69

func EllipseWithParams

func EllipseWithParams(img *Mat, center, axes image.Point, angle, startAngle, endAngle float64, c color.RGBA, thickness int, lineType LineType, shift int)

Ellipse draws a simple or thick elliptic arc or fills an ellipse sector.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga28b2267d35786f5f890ca167236cbc69

func EqualizeHist

func EqualizeHist(src Mat, dst *Mat)

EqualizeHist normalizes the brightness and increases the contrast of the image.

For further details, please see: https://docs.opencv.org/master/d6/dc7/group__imgproc__hist.html#ga7e54091f0c937d49bf84152a16f76d6e

func Erode

func Erode(src Mat, dst *Mat, kernel Mat)

Erode erodes an image by using a specific structuring element.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gaeb1e0c1033e3f6b891a25d0511362aeb

func ErodeWithParams

func ErodeWithParams(src Mat, dst *Mat, kernel Mat, anchor image.Point, iterations, borderType int)

ErodeWithParams erodes an image by using a specific structuring element.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gaeb1e0c1033e3f6b891a25d0511362aeb

func EstimateNewCameraMatrixForUndistortRectify

func EstimateNewCameraMatrixForUndistortRectify(k, d Mat, imgSize image.Point, r Mat, p *Mat, balance float64, newSize image.Point, fovScale float64)

EstimateNewCameraMatrixForUndistortRectify estimates new camera matrix for undistortion or rectification.

For further details, please see: https://docs.opencv.org/master/db/d58/group__calib3d__fisheye.html#ga384940fdf04c03e362e94b6eb9b673c9

func Exp

func Exp(src Mat, dst *Mat)

Exp calculates the exponent of every array element.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga3e10108e2162c338f1b848af619f39e5

func ExtractChannel

func ExtractChannel(src Mat, dst *Mat, coi int)

ExtractChannel extracts a single channel from src (coi is 0-based index).

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gacc6158574aa1f0281878c955bcf35642

func FP16BlobFromImage

func FP16BlobFromImage(img Mat, scaleFactor float32, size image.Point, mean float32,
	swapRB bool, crop bool) []byte

FP16BlobFromImage is an extended helper function to convert an Image to a half-float blob, as used by the Movidius Neural Compute Stick.

func FastNlMeansDenoising

func FastNlMeansDenoising(src Mat, dst *Mat)

FastNlMeansDenoising performs image denoising using Non-local Means Denoising algorithm http://www.ipol.im/pub/algo/bcm_non_local_means_denoising/

For further details, please see: https://docs.opencv.org/4.x/d1/d79/group__photo__denoise.html#ga4c6b0031f56ea3f98f768881279ffe93

func FastNlMeansDenoisingColored

func FastNlMeansDenoisingColored(src Mat, dst *Mat)

FastNlMeansDenoisingColored is a modification of fastNlMeansDenoising function for colored images.

For further details, please see: https://docs.opencv.org/4.x/d1/d79/group__photo__denoise.html#ga21abc1c8b0e15f78cd3eff672cb6c476

func FastNlMeansDenoisingColoredMulti

func FastNlMeansDenoisingColoredMulti(src []Mat, dst *Mat, imgToDenoiseIndex int, temporalWindowSize int)

FastNlMeansDenoisingColoredMulti denoises the selected images.

For further details, please see: https://docs.opencv.org/master/d1/d79/group__photo__denoise.html#gaa501e71f52fb2dc17ff8ca5e7d2d3619

func FastNlMeansDenoisingColoredMultiWithParams

func FastNlMeansDenoisingColoredMultiWithParams(src []Mat, dst *Mat, imgToDenoiseIndex int, temporalWindowSize int, h float32, hColor float32, templateWindowSize int, searchWindowSize int)

FastNlMeansDenoisingColoredMulti denoises the selected images.

For further details, please see: https://docs.opencv.org/master/d1/d79/group__photo__denoise.html#gaa501e71f52fb2dc17ff8ca5e7d2d3619

func FastNlMeansDenoisingColoredWithParams

func FastNlMeansDenoisingColoredWithParams(src Mat, dst *Mat, h float32, hColor float32, templateWindowSize int, searchWindowSize int)

FastNlMeansDenoisingColoredWithParams is a modification of fastNlMeansDenoising function for colored images.

For further details, please see: https://docs.opencv.org/4.x/d1/d79/group__photo__denoise.html#ga21abc1c8b0e15f78cd3eff672cb6c476

func FastNlMeansDenoisingWithParams

func FastNlMeansDenoisingWithParams(src Mat, dst *Mat, h float32, templateWindowSize int, searchWindowSize int)

FastNlMeansDenoisingWithParams performs image denoising using Non-local Means Denoising algorithm http://www.ipol.im/pub/algo/bcm_non_local_means_denoising/

For further details, please see: https://docs.opencv.org/4.x/d1/d79/group__photo__denoise.html#ga4c6b0031f56ea3f98f768881279ffe93

func FillPoly

func FillPoly(img *Mat, pts PointsVector, c color.RGBA)

FillPoly fills the area bounded by one or more polygons.

For more information, see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#gaf30888828337aa4c6b56782b5dfbd4b7

func FillPolyWithParams

func FillPolyWithParams(img *Mat, pts PointsVector, c color.RGBA, lineType LineType, shift int, offset image.Point)

FillPolyWithParams fills the area bounded by one or more polygons.

For more information, see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#gaf30888828337aa4c6b56782b5dfbd4b7

func Filter2D

func Filter2D(src Mat, dst *Mat, ddepth MatType, kernel Mat, anchor image.Point, delta float64, borderType BorderType)

Filter2D applies an arbitrary linear filter to an image.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga27c049795ce870216ddfb366086b5a04

func FindChessboardCorners

func FindChessboardCorners(image Mat, patternSize image.Point, corners *Mat, flags CalibCBFlag) bool

FindChessboardCorners finds the positions of internal corners of the chessboard.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga93efa9b0aa890de240ca32b11253dd4a

func FindChessboardCornersSB

func FindChessboardCornersSB(image Mat, patternSize image.Point, corners *Mat, flags CalibCBFlag) bool

FindChessboardCorners finds the positions of internal corners of the chessboard using a sector based approach.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#gadc5bcb05cb21cf1e50963df26986d7c9

func FindChessboardCornersSBWithMeta

func FindChessboardCornersSBWithMeta(image Mat, patternSize image.Point, corners *Mat, flags CalibCBFlag, meta *Mat) bool

FindChessboardCornersSBWithMeta finds the positions of internal corners of the chessboard using a sector based approach.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga93efa9b0aa890de240ca32b11253dd4a

func FindNonZero

func FindNonZero(src Mat, idx *Mat)

FindNonZero returns the list of locations of non-zero pixels.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaed7df59a3539b4cc0fe5c9c8d7586190

func FindTransformECC

func FindTransformECC(templateImage Mat, inputImage Mat, warpMatrix *Mat, motionType int, criteria TermCriteria, inputMask Mat, gaussFiltSize int) float64

FindTransformECC finds the geometric transform (warp) between two images in terms of the ECC criterion.

For futther details, please see: https://docs.opencv.org/4.x/dc/d6b/group__video__track.html#ga1aa357007eaec11e9ed03500ecbcbe47

func FisheyeUndistortImage

func FisheyeUndistortImage(distorted Mat, undistorted *Mat, k, d Mat)

FisheyeUndistortImage transforms an image to compensate for fisheye lens distortion

func FisheyeUndistortImageWithParams

func FisheyeUndistortImageWithParams(distorted Mat, undistorted *Mat, k, d, knew Mat, size image.Point)

FisheyeUndistortImageWithParams transforms an image to compensate for fisheye lens distortion with Knew matrix

func FisheyeUndistortPoints

func FisheyeUndistortPoints(distorted Mat, undistorted *Mat, k, d, r, p Mat)

FisheyeUndistortPoints transforms points to compensate for fisheye lens distortion

For further details, please see: https://docs.opencv.org/master/db/d58/group__calib3d__fisheye.html#gab738cdf90ceee97b2b52b0d0e7511541

func FitLine

func FitLine(pts PointVector, line *Mat, distType DistanceTypes, param, reps, aeps float64)

FitLine fits a line to a 2D or 3D point set.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#gaf849da1fdafa67ee84b1e9a23b93f91f

func Flip

func Flip(src Mat, dst *Mat, flipCode int)

Flip flips a 2D array around horizontal(0), vertical(1), or both axes(-1).

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaca7be533e3dac7feb70fc60635adf441

func GaussianBlur

func GaussianBlur(src Mat, dst *Mat, ksize image.Point, sigmaX float64,
	sigmaY float64, borderType BorderType)

GaussianBlur blurs an image Mat using a Gaussian filter. The function convolves the src Mat image into the dst Mat using the specified Gaussian kernel params.

For further details, please see: http://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gaabe8c836e97159a9193fb0b11ac52cf1

func Gemm

func Gemm(src1, src2 Mat, alpha float64, src3 Mat, beta float64, dst *Mat, flags int)

Gemm performs generalized matrix multiplication.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gacb6e64071dffe36434e1e7ee79e7cb35

func GetOptimalDFTSize

func GetOptimalDFTSize(vecsize int) int

GetOptimalDFTSize returns the optimal Discrete Fourier Transform (DFT) size for a given vector size.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6577a2e59968936ae02eb2edde5de299

func GetRectSubPix

func GetRectSubPix(src Mat, patchSize image.Point, center image.Point, dst *Mat)

GetRectSubPix retrieves a pixel rectangle from an image with sub-pixel accuracy.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga77576d06075c1a4b6ba1a608850cd614

func GetTextSize

func GetTextSize(text string, fontFace HersheyFont, fontScale float64, thickness int) image.Point

GetTextSize calculates the width and height of a text string. It returns an image.Point with the size required to draw text using a specific font face, scale, and thickness.

For further details, please see: http://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga3d2abfcb995fd2db908c8288199dba82

func GetTextSizeWithBaseline

func GetTextSizeWithBaseline(text string, fontFace HersheyFont, fontScale float64, thickness int) (image.Point, int)

GetTextSizeWithBaseline calculates the width and height of a text string including the basline of the text. It returns an image.Point with the size required to draw text using a specific font face, scale, and thickness as well as its baseline.

For further details, please see: http://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga3d2abfcb995fd2db908c8288199dba82

func GetTickCount

func GetTickCount() float64

GetTickCount returns the number of ticks.

For further details, please see: https://docs.opencv.org/master/db/de0/group__core__utils.html#gae73f58000611a1af25dd36d496bf4487

func GetTickFrequency

func GetTickFrequency() float64

GetTickFrequency returns the number of ticks per second.

For further details, please see: https://docs.opencv.org/master/db/de0/group__core__utils.html#ga705441a9ef01f47acdc55d87fbe5090c

func GoodFeaturesToTrack

func GoodFeaturesToTrack(img Mat, corners *Mat, maxCorners int, quality float64, minDist float64)

GoodFeaturesToTrack determines strong corners on an image. The function finds the most prominent corners in the image or in the specified image region.

For further details, please see: https://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga1d6bb77486c8f92d79c8793ad995d541

func GrabCut

func GrabCut(img Mat, mask *Mat, r image.Rectangle, bgdModel *Mat, fgdModel *Mat, iterCount int, mode GrabCutMode)

Grabcut runs the GrabCut algorithm. The function implements the GrabCut image segmentation algorithm. For further details, please see: https://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga909c1dda50efcbeaa3ce126be862b37f

func GroupRectangles

func GroupRectangles(rects []image.Rectangle, groupThreshold int, eps float64) []image.Rectangle

GroupRectangles groups the object candidate rectangles.

For further details, please see: https://docs.opencv.org/master/d5/d54/group__objdetect.html#ga3dba897ade8aa8227edda66508e16ab9

func Hconcat

func Hconcat(src1, src2 Mat, dst *Mat)

Hconcat applies horizontal concatenation to given matrices.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaab5ceee39e0580f879df645a872c6bf7

func HoughCircles

func HoughCircles(src Mat, circles *Mat, method HoughMode, dp, minDist float64)

HoughCircles finds circles in a grayscale image using the Hough transform. The only "method" currently supported is HoughGradient. If you want to pass more parameters, please see `HoughCirclesWithParams`.

For further details, please see: https://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga47849c3be0d0406ad3ca45db65a25d2d

func HoughCirclesWithParams

func HoughCirclesWithParams(src Mat, circles *Mat, method HoughMode, dp, minDist, param1, param2 float64, minRadius, maxRadius int)

HoughCirclesWithParams finds circles in a grayscale image using the Hough transform. The only "method" currently supported is HoughGradient.

For further details, please see: https://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga47849c3be0d0406ad3ca45db65a25d2d

func HoughLines

func HoughLines(src Mat, lines *Mat, rho float32, theta float32, threshold int)

HoughLines implements the standard or standard multi-scale Hough transform algorithm for line detection. For a good explanation of Hough transform, see: http://homepages.inf.ed.ac.uk/rbf/HIPR2/hough.htm

For further details, please see: http://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga46b4e588934f6c8dfd509cc6e0e4545a

func HoughLinesP

func HoughLinesP(src Mat, lines *Mat, rho float32, theta float32, threshold int)

HoughLinesP implements the probabilistic Hough transform algorithm for line detection. For a good explanation of Hough transform, see: http://homepages.inf.ed.ac.uk/rbf/HIPR2/hough.htm

For further details, please see: http://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga8618180a5948286384e3b7ca02f6feeb

func HoughLinesPWithParams

func HoughLinesPWithParams(src Mat, lines *Mat, rho float32, theta float32, threshold int, minLineLength float32, maxLineGap float32)

func HoughLinesPointSet

func HoughLinesPointSet(points Mat, lines *Mat, linesMax int, threshold int,
	minRho float32, maxRho float32, rhoStep float32,
	minTheta float32, maxTheta float32, thetaStep float32)

HoughLinesPointSet implements the Hough transform algorithm for line detection on a set of points. For a good explanation of Hough transform, see: http://homepages.inf.ed.ac.uk/rbf/HIPR2/hough.htm

For further details, please see: https://docs.opencv.org/master/dd/d1a/group__imgproc__feature.html#ga2858ef61b4e47d1919facac2152a160e

func IDCT

func IDCT(src Mat, dst *Mat, flags int)

IDCT calculates the inverse Discrete Cosine Transform of a 1D or 2D array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga77b168d84e564c50228b69730a227ef2

func IDFT

func IDFT(src Mat, dst *Mat, flags, nonzeroRows int)

IDFT calculates the inverse Discrete Fourier Transform of a 1D or 2D array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaa708aa2d2e57a508f968eb0f69aa5ff1

func IMWrite

func IMWrite(name string, img Mat) bool

IMWrite writes a Mat to an image file.

For further details, please see: http://docs.opencv.org/master/d4/da8/group__imgcodecs.html#gabbc7ef1aa2edfaa87772f1202d67e0ce

func IMWriteWithParams

func IMWriteWithParams(name string, img Mat, params []int) bool

IMWriteWithParams writes a Mat to an image file. With that func you can pass compression parameters.

For further details, please see: http://docs.opencv.org/master/d4/da8/group__imgcodecs.html#gabbc7ef1aa2edfaa87772f1202d67e0ce

func IlluminationChange

func IlluminationChange(src, mask Mat, dst *Mat, alpha, beta float32)

IlluminationChange modifies locally the apparent illumination of an image.

For further details, please see: https://docs.opencv.org/master/df/da0/group__photo__clone.html#gac5025767cf2febd8029d474278e886c7

func ImagesFromBlob

func ImagesFromBlob(blob Mat, imgs []Mat)

ImagesFromBlob Parse a 4D blob and output the images it contains as 2D arrays through a simpler data structure (std::vector<cv::Mat>).

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga4051b5fa2ed5f54b76c059a8625df9f5

func InRange

func InRange(src, lb, ub Mat, dst *Mat)

InRange checks if array elements lie between the elements of two Mat arrays.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga48af0ab51e36436c5d04340e036ce981

func InRangeWithScalar

func InRangeWithScalar(src Mat, lb, ub Scalar, dst *Mat)

InRangeWithScalar checks if array elements lie between the elements of two Scalars

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga48af0ab51e36436c5d04340e036ce981

func InitUndistortRectifyMap

func InitUndistortRectifyMap(cameraMatrix Mat, distCoeffs Mat, r Mat, newCameraMatrix Mat, size image.Point, m1type int, map1 Mat, map2 Mat)

InitUndistortRectifyMap computes the joint undistortion and rectification transformation and represents the result in the form of maps for remap

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga7dfb72c9cf9780a347fbe3d1c47e5d5a

func InsertChannel

func InsertChannel(src Mat, dst *Mat, coi int)

InsertChannel inserts a single channel to dst (coi is 0-based index) (it replaces channel i with another in dst).

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga1d4bd886d35b00ec0b764cb4ce6eb515

func Integral

func Integral(src Mat, sum *Mat, sqsum *Mat, tilted *Mat)

Integral calculates one or more integral images for the source image. For further details, please see: https://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga97b87bec26908237e8ba0f6e96d23e28

func Invert

func Invert(src Mat, dst *Mat, flags SolveDecompositionFlags) float64

Invert finds the inverse or pseudo-inverse of a matrix.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gad278044679d4ecf20f7622cc151aaaa2

func InvertAffineTransform

func InvertAffineTransform(src Mat, dst *Mat)

func KMeans

func KMeans(data Mat, k int, bestLabels *Mat, criteria TermCriteria, attempts int, flags KMeansFlags, centers *Mat) float64

KMeans finds centers of clusters and groups input samples around the clusters.

For further details, please see: https://docs.opencv.org/master/d5/d38/group__core__cluster.html#ga9a34dc06c6ec9460e90860f15bcd2f88

func KMeansPoints

func KMeansPoints(points PointVector, k int, bestLabels *Mat, criteria TermCriteria, attempts int, flags KMeansFlags, centers *Mat) float64

KMeansPoints finds centers of clusters and groups input samples around the clusters.

For further details, please see: https://docs.opencv.org/master/d5/d38/group__core__cluster.html#ga9a34dc06c6ec9460e90860f15bcd2f88

func LUT

func LUT(src, wbLUT Mat, dst *Mat)

LUT performs a look-up table transform of an array.

The function LUT fills the output array with values from the look-up table. Indices of the entries are taken from the input array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gab55b8d062b7f5587720ede032d34156f

func Laplacian

func Laplacian(src Mat, dst *Mat, dDepth MatType, size int, scale float64,
	delta float64, borderType BorderType)

Laplacian calculates the Laplacian of an image.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gad78703e4c8fe703d479c1860d76429e6

func Line

func Line(img *Mat, pt1 image.Point, pt2 image.Point, c color.RGBA, thickness int)

Line draws a line segment connecting two points.

For further details, please see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga7078a9fae8c7e7d13d24dac2520ae4a2

func LinearPolar

func LinearPolar(src Mat, dst *Mat, center image.Point, maxRadius float64, flags InterpolationFlags)

LinearPolar remaps an image to polar coordinates space.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#gaa38a6884ac8b6e0b9bed47939b5362f3

func Log

func Log(src Mat, dst *Mat)

Log calculates the natural logarithm of every array element.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga937ecdce4679a77168730830a955bea7

func LogPolar

func LogPolar(src Mat, dst *Mat, center image.Point, m float64, flags InterpolationFlags)

LogPolar remaps an image to semilog-polar coordinates space.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#gaec3a0b126a85b5ca2c667b16e0ae022d

func Magnitude

func Magnitude(x, y Mat, magnitude *Mat)

Magnitude calculates the magnitude of 2D vectors.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6d3b097586bca4409873d64a90fe64c3

func MatchTemplate

func MatchTemplate(image Mat, templ Mat, result *Mat, method TemplateMatchMode, mask Mat)

MatchTemplate compares a template against overlapped image regions.

For further details, please see: https://docs.opencv.org/master/df/dfb/group__imgproc__object.html#ga586ebfb0a7fb604b35a23d85391329be

func Max

func Max(src1, src2 Mat, dst *Mat)

Max calculates per-element maximum of two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gacc40fa15eac0fb83f8ca70b7cc0b588d

func MeanStdDev

func MeanStdDev(src Mat, dst *Mat, dstStdDev *Mat)

MeanStdDev calculates a mean and standard deviation of array elements.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga846c858f4004d59493d7c6a4354b301d

func MedianBlur

func MedianBlur(src Mat, dst *Mat, ksize int)

MedianBlur blurs an image using the median filter.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga564869aa33e58769b4469101aac458f9

func Merge

func Merge(mv []Mat, dst *Mat)

Merge creates one multi-channel array out of several single-channel ones.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga7d7b4d6c6ee504b30a20b1680029c7b4

func Min

func Min(src1, src2 Mat, dst *Mat)

Min calculates per-element minimum of two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga9af368f182ee76d0463d0d8d5330b764

func MinEnclosingCircle

func MinEnclosingCircle(pts PointVector) (x, y, radius float32)

MinEnclosingCircle finds a circle of the minimum area enclosing the input 2D point set.

For further details, please see: https://docs.opencv.org/3.4/d3/dc0/group__imgproc__shape.html#ga8ce13c24081bbc7151e9326f412190f1

func MinMaxIdx

func MinMaxIdx(input Mat) (minVal, maxVal float32, minIdx, maxIdx int)

MinMaxIdx finds the global minimum and maximum in an array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga7622c466c628a75d9ed008b42250a73f

func MinMaxLoc

func MinMaxLoc(input Mat) (minVal, maxVal float32, minLoc, maxLoc image.Point)

MinMaxLoc finds the global minimum and maximum in an array.

For further details, please see: https://docs.opencv.org/trunk/d2/de8/group__core__array.html#gab473bf2eb6d14ff97e89b355dac20707

func MixChannels

func MixChannels(src []Mat, dst []Mat, fromTo []int)

Copies specified channels from input arrays to the specified channels of output arrays.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga51d768c270a1cdd3497255017c4504be

func Moments

func Moments(src Mat, binaryImage bool) map[string]float64

Moments calculates all of the moments up to the third order of a polygon or rasterized shape.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga556a180f43cab22649c23ada36a8a139

func MorphologyEx

func MorphologyEx(src Mat, dst *Mat, op MorphType, kernel Mat)

MorphologyEx performs advanced morphological transformations.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga67493776e3ad1a3df63883829375201f

func MorphologyExWithParams

func MorphologyExWithParams(src Mat, dst *Mat, op MorphType, kernel Mat, iterations int, borderType BorderType)

MorphologyExWithParams performs advanced morphological transformations.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga67493776e3ad1a3df63883829375201f

func MulSpectrums

func MulSpectrums(a Mat, b Mat, dst *Mat, flags DftFlags)

Mulspectrums performs the per-element multiplication of two Fourier spectrums.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga3ab38646463c59bf0ce962a9d51db64f

func Multiply

func Multiply(src1 Mat, src2 Mat, dst *Mat)

Multiply calculates the per-element scaled product of two arrays. Both input arrays must be of the same size and the same type.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga979d898a58d7f61c53003e162e7ad89f

func MultiplyWithParams

func MultiplyWithParams(src1 Mat, src2 Mat, dst *Mat, scale float64, dtype MatType)

MultiplyWithParams calculates the per-element scaled product of two arrays. Both input arrays must be of the same size and the same type.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga979d898a58d7f61c53003e162e7ad89f

func NMSBoxes

func NMSBoxes(bboxes []image.Rectangle, scores []float32, scoreThreshold float32, nmsThreshold float32, indices []int)

NMSBoxes performs non maximum suppression given boxes and corresponding scores.

For futher details, please see: https://docs.opencv.org/4.4.0/d6/d0f/group__dnn.html#ga9d118d70a1659af729d01b10233213ee

func NMSBoxesWithParams

func NMSBoxesWithParams(bboxes []image.Rectangle, scores []float32, scoreThreshold float32, nmsThreshold float32, indices []int, eta float32, topK int)

NMSBoxesWithParams performs non maximum suppression given boxes and corresponding scores.

For futher details, please see: https://docs.opencv.org/4.4.0/d6/d0f/group__dnn.html#ga9d118d70a1659af729d01b10233213ee

func Norm

func Norm(src1 Mat, normType NormType) float64

Norm calculates the absolute norm of an array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga7c331fb8dd951707e184ef4e3f21dd33

func NormWithMats

func NormWithMats(src1 Mat, src2 Mat, normType NormType) float64

Norm calculates the absolute difference/relative norm of two arrays.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga7c331fb8dd951707e184ef4e3f21dd33

func Normalize

func Normalize(src Mat, dst *Mat, alpha float64, beta float64, typ NormType)

Normalize normalizes the norm or value range of an array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga87eef7ee3970f86906d69a92cbf064bd

func OpenCVVersion

func OpenCVVersion() string

OpenCVVersion returns the current OpenCV lib version

func PencilSketch

func PencilSketch(src Mat, dst1, dst2 *Mat, sigma_s, sigma_r, shade_factor float32)

PencilSketch pencil-like non-photorealistic line drawing.

For further details, please see: https://docs.opencv.org/4.x/df/dac/group__photo__render.html#gae5930dd822c713b36f8529b21ddebd0c

func PerspectiveTransform

func PerspectiveTransform(src Mat, dst *Mat, tm Mat)

PerspectiveTransform performs the perspective matrix transformation of vectors.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gad327659ac03e5fd6894b90025e6900a7

func Phase

func Phase(x, y Mat, angle *Mat, angleInDegrees bool)

Phase calculates the rotation angle of 2D vectors.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga9db9ca9b4d81c3bde5677b8f64dc0137

func PointPolygonTest

func PointPolygonTest(pts PointVector, pt image.Point, measureDist bool) float64

PointPolygonTest performs a point-in-contour test.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga1a539e8db2135af2566103705d7a5722

func PolarToCart

func PolarToCart(magnitude Mat, degree Mat, x *Mat, y *Mat, angleInDegrees bool)

PolatToCart calculates x and y coordinates of 2D vectors from their magnitude and angle.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga581ff9d44201de2dd1b40a50db93d665

func Polylines

func Polylines(img *Mat, pts PointsVector, isClosed bool, c color.RGBA, thickness int)

Polylines draws several polygonal curves.

For more information, see: https://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga1ea127ffbbb7e0bfc4fd6fd2eb64263c

func Pow

func Pow(src Mat, power float64, dst *Mat)

Pow raises every array element to a power.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaf0d056b5bd1dc92500d6f6cf6bac41ef

func PutText

func PutText(img *Mat, text string, org image.Point, fontFace HersheyFont, fontScale float64, c color.RGBA, thickness int)

PutText draws a text string. It renders the specified text string into the img Mat at the location passed in the "org" param, using the desired font face, font scale, color, and line thinkness.

For further details, please see: http://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga5126f47f883d730f633d74f07456c576

func PutTextWithParams

func PutTextWithParams(img *Mat, text string, org image.Point, fontFace HersheyFont, fontScale float64, c color.RGBA, thickness int, lineType LineType, bottomLeftOrigin bool)

PutTextWithParams draws a text string. It renders the specified text string into the img Mat at the location passed in the "org" param, using the desired font face, font scale, color, and line thinkness.

For further details, please see: http://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga5126f47f883d730f633d74f07456c576

func PyrDown

func PyrDown(src Mat, dst *Mat, ksize image.Point, borderType BorderType)

PyrDown blurs an image and downsamples it.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gaf9bba239dfca11654cb7f50f889fc2ff

func PyrUp

func PyrUp(src Mat, dst *Mat, ksize image.Point, borderType BorderType)

PyrUp upsamples an image and then blurs it.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gada75b59bdaaca411ed6fee10085eb784

func RandN

func RandN(mat *Mat, mean, stddev Scalar)

RandN Fills the array with normally distributed random numbers.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaeff1f61e972d133a04ce3a5f81cf6808

func RandShuffle

func RandShuffle(mat *Mat)

RandShuffle Shuffles the array elements randomly.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6a789c8a5cb56c6dd62506179808f763

func RandShuffleWithParams

func RandShuffleWithParams(mat *Mat, iterFactor float64, rng RNG)

RandShuffleWithParams Shuffles the array elements randomly.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6a789c8a5cb56c6dd62506179808f763

func RandU

func RandU(mat *Mat, low, high Scalar)

RandU Generates a single uniformly-distributed random number or an array of random numbers.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga1ba1026dca0807b27057ba6a49d258c0

func Rectangle

func Rectangle(img *Mat, r image.Rectangle, c color.RGBA, thickness int)

Rectangle draws a simple, thick, or filled up-right rectangle. It renders a rectangle with the desired characteristics to the target Mat image.

For further details, please see: http://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga346ac30b5c74e9b5137576c9ee9e0e8c

func RectangleWithParams

func RectangleWithParams(img *Mat, r image.Rectangle, c color.RGBA, thickness int, lineType LineType, shift int)

RectangleWithParams draws a simple, thick, or filled up-right rectangle. It renders a rectangle with the desired characteristics to the target Mat image.

For further details, please see: http://docs.opencv.org/master/d6/d6e/group__imgproc__draw.html#ga346ac30b5c74e9b5137576c9ee9e0e8c

func Reduce

func Reduce(src Mat, dst *Mat, dim int, rType ReduceTypes, dType MatType)

Reduce reduces a matrix to a vector.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga4b78072a303f29d9031d56e5638da78e

func Remap

func Remap(src Mat, dst, map1, map2 *Mat, interpolation InterpolationFlags, borderMode BorderType, borderValue color.RGBA)

Remap applies a generic geometrical transformation to an image.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#gab75ef31ce5cdfb5c44b6da5f3b908ea4

func Repeat

func Repeat(src Mat, nY int, nX int, dst *Mat)

Repeat fills the output array with repeated copies of the input array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga496c3860f3ac44c40b48811333cfda2d

func Resize

func Resize(src Mat, dst *Mat, sz image.Point, fx, fy float64, interp InterpolationFlags)

Resize resizes an image. It resizes the image src down to or up to the specified size, storing the result in dst. Note that src and dst may be the same image. If you wish to scale by factor, an empty sz may be passed and non-zero fx and fy. Likewise, if you wish to scale to an explicit size, a non-empty sz may be passed with zero for both fx and fy.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga47a974309e9102f5f08231edc7e7529d

func Rotate

func Rotate(src Mat, dst *Mat, code RotateFlag)

Rotate rotates a 2D array in multiples of 90 degrees

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga4ad01c0978b0ce64baa246811deeac24

func SVDCompute

func SVDCompute(src Mat, w, u, vt *Mat)

SVDCompute decomposes matrix and stores the results to user-provided matrices

https://docs.opencv.org/4.1.2/df/df7/classcv_1_1SVD.html#a76f0b2044df458160292045a3d3714c6

func ScaleAdd

func ScaleAdd(src1 Mat, alpha float64, src2 Mat, dst *Mat)

Calculates the sum of a scaled array and another array.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga9e0845db4135f55dcf20227402f00d98

func Scharr

func Scharr(src Mat, dst *Mat, dDepth MatType, dx int, dy int, scale float64,
	delta float64, borderType BorderType)

Scharr calculates the first x- or y- image derivative using Scharr operator.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gaa13106761eedf14798f37aa2d60404c9

func SeamlessClone

func SeamlessClone(src, dst, mask Mat, p image.Point, blend *Mat, flags SeamlessCloneFlags)

SeamlessClone blend two image by Poisson Blending.

For further details, please see: https://docs.opencv.org/master/df/da0/group__photo__clone.html#ga2bf426e4c93a6b1f21705513dfeca49d

func SelectROI deprecated

func SelectROI(name string, img Mat) image.Rectangle

Deprecated: use Window.SelectROI instead

func SelectROIs deprecated

func SelectROIs(name string, img Mat) []image.Rectangle

Deprecated: use Window.SelectROIs instead

func SepFilter2D

func SepFilter2D(src Mat, dst *Mat, ddepth MatType, kernelX, kernelY Mat, anchor image.Point, delta float64, borderType BorderType)

SepFilter2D applies a separable linear filter to the image.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga910e29ff7d7b105057d1625a4bf6318d

func SetIdentity

func SetIdentity(src Mat, scalar float64)

SetIdentity initializes a scaled identity matrix. For further details, please see:

https://docs.opencv.org/master/d2/de8/group__core__array.html#ga388d7575224a4a277ceb98ccaa327c99

func SetRNGSeed

func SetRNGSeed(seed int)

TheRNG Sets state of default random number generator.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga757e657c037410d9e19e819569e7de0f

func Sobel

func Sobel(src Mat, dst *Mat, ddepth MatType, dx, dy, ksize int, scale, delta float64, borderType BorderType)

Sobel calculates the first, second, third, or mixed image derivatives using an extended Sobel operator

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gacea54f142e81b6758cb6f375ce782c8d

func Solve

func Solve(src1 Mat, src2 Mat, dst *Mat, flags SolveDecompositionFlags) bool

Solve solves one or more linear systems or least-squares problems.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga12b43690dbd31fed96f213eefead2373

func SolveCubic

func SolveCubic(coeffs Mat, roots *Mat) int

SolveCubic finds the real roots of a cubic equation.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga1c3b0b925b085b6e96931ee309e6a1da

func SolvePoly

func SolvePoly(coeffs Mat, roots *Mat, maxIters int) float64

SolvePoly finds the real or complex roots of a polynomial equation.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gac2f5e953016fabcdf793d762f4ec5dce

func Sort

func Sort(src Mat, dst *Mat, flags SortFlags)

Sort sorts each row or each column of a matrix.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga45dd56da289494ce874be2324856898f

func SortIdx

func SortIdx(src Mat, dst *Mat, flags SortFlags)

SortIdx sorts each row or each column of a matrix. Instead of reordering the elements themselves, it stores the indices of sorted elements in the output array

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gadf35157cbf97f3cb85a545380e383506

func SpatialGradient

func SpatialGradient(src Mat, dx, dy *Mat, ksize MatType, borderType BorderType)

SpatialGradient calculates the first order image derivative in both x and y using a Sobel operator.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga405d03b20c782b65a4daf54d233239a2

func SqBoxFilter

func SqBoxFilter(src Mat, dst *Mat, depth int, ksize image.Point)

SqBoxFilter calculates the normalized sum of squares of the pixel values overlapping the filter.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga045028184a9ef65d7d2579e5c4bff6c0

func Stylization

func Stylization(src Mat, dst *Mat, sigma_s, sigma_r float32)

Stylization aims to produce digital imagery with a wide variety of effects not focused on photorealism. Edge-aware filters are ideal for stylization, as they can abstract regions of low contrast while preserving, or enhancing, high-contrast features.

For further details, please see: https://docs.opencv.org/4.x/df/dac/group__photo__render.html#gacb0f7324017df153d7b5d095aed53206

func Subtract

func Subtract(src1 Mat, src2 Mat, dst *Mat)

Subtract calculates the per-element subtraction of two arrays or an array and a scalar.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaa0f00d98b4b5edeaeb7b8333b2de353b

func TextureFlattening

func TextureFlattening(src, mask Mat, dst *Mat, lowThreshold, highThreshold float32, kernelSize int)

TextureFlattening washes out the texture of the selected region, giving its contents a flat aspect.

For further details, please see: https://docs.opencv.org/master/df/da0/group__photo__clone.html#gad55df6aa53797365fa7cc23959a54004

func Threshold

func Threshold(src Mat, dst *Mat, thresh float32, maxvalue float32, typ ThresholdType) (threshold float32)

Threshold applies a fixed-level threshold to each array element.

For further details, please see: https://docs.opencv.org/3.3.0/d7/d1b/group__imgproc__misc.html#gae8a4a146d1ca78c626a53577199e9c57

func Transform

func Transform(src Mat, dst *Mat, tm Mat)

Transform performs the matrix transformation of every array element.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga393164aa54bb9169ce0a8cc44e08ff22

func Transpose

func Transpose(src Mat, dst *Mat)

Transpose transposes a matrix.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga46630ed6c0ea6254a35f447289bd7404

func Undistort

func Undistort(src Mat, dst *Mat, cameraMatrix Mat, distCoeffs Mat, newCameraMatrix Mat)

func UndistortPoints

func UndistortPoints(src Mat, dst *Mat, cameraMatrix, distCoeffs, rectificationTransform, newCameraMatrix Mat)

UndistortPoints transforms points to compensate for lens distortion

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga55c716492470bfe86b0ee9bf3a1f0f7e

func Vconcat

func Vconcat(src1, src2 Mat, dst *Mat)

Vconcat applies vertical concatenation to given matrices.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaab5ceee39e0580f879df645a872c6bf7

func Version

func Version() string

Version returns the current golang package version

func WaitKey

func WaitKey(delay int) int

WaitKey that is not attached to a specific Window. Only use when no Window exists in your application, e.g. command line app.

func WarpAffine

func WarpAffine(src Mat, dst *Mat, m Mat, sz image.Point)

WarpAffine applies an affine transformation to an image. For more parameters please check WarpAffineWithParams

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga0203d9ee5fcd28d40dbc4a1ea4451983

func WarpAffineWithParams

func WarpAffineWithParams(src Mat, dst *Mat, m Mat, sz image.Point, flags InterpolationFlags, borderType BorderType, borderValue color.RGBA)

WarpAffineWithParams applies an affine transformation to an image.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga0203d9ee5fcd28d40dbc4a1ea4451983

func WarpPerspective

func WarpPerspective(src Mat, dst *Mat, m Mat, sz image.Point)

WarpPerspective applies a perspective transformation to an image. For more parameters please check WarpPerspectiveWithParams.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#gaf73673a7e8e18ec6963e3774e6a94b87

func WarpPerspectiveWithParams

func WarpPerspectiveWithParams(src Mat, dst *Mat, m Mat, sz image.Point, flags InterpolationFlags, borderType BorderType, borderValue color.RGBA)

WarpPerspectiveWithParams applies a perspective transformation to an image.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#gaf73673a7e8e18ec6963e3774e6a94b87

func Watershed

func Watershed(image Mat, markers *Mat)

Watershed performs a marker-based image segmentation using the watershed algorithm.

For further details, please see: https://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga3267243e4d3f95165d55a618c65ac6e1

Types

type AKAZE

type AKAZE struct {
	// contains filtered or unexported fields
}

AKAZE is a wrapper around the cv::AKAZE algorithm.

func NewAKAZE

func NewAKAZE() AKAZE

NewAKAZE returns a new AKAZE algorithm

For further details, please see: https://docs.opencv.org/master/d8/d30/classcv_1_1AKAZE.html

func (*AKAZE) Close

func (a *AKAZE) Close() error

Close AKAZE.

func (*AKAZE) Detect

func (a *AKAZE) Detect(src Mat) []KeyPoint

Detect keypoints in an image using AKAZE.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

func (*AKAZE) DetectAndCompute

func (a *AKAZE) DetectAndCompute(src Mat, mask Mat) ([]KeyPoint, Mat)

DetectAndCompute keypoints and compute in an image using AKAZE.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#a8be0d1c20b08eb867184b8d74c15a677

type AdaptiveThresholdType

type AdaptiveThresholdType int

AdaptiveThresholdType type of adaptive threshold operation.

const (
	// AdaptiveThresholdMean threshold type
	AdaptiveThresholdMean AdaptiveThresholdType = 0

	// AdaptiveThresholdGaussian threshold type
	AdaptiveThresholdGaussian AdaptiveThresholdType = 1
)

func (AdaptiveThresholdType) String

func (c AdaptiveThresholdType) String() string

type AgastFeatureDetector

type AgastFeatureDetector struct {
	// contains filtered or unexported fields
}

AgastFeatureDetector is a wrapper around the cv::AgastFeatureDetector.

func NewAgastFeatureDetector

func NewAgastFeatureDetector() AgastFeatureDetector

NewAgastFeatureDetector returns a new AgastFeatureDetector algorithm

For further details, please see: https://docs.opencv.org/master/d7/d19/classcv_1_1AgastFeatureDetector.html

func (*AgastFeatureDetector) Close

func (a *AgastFeatureDetector) Close() error

Close AgastFeatureDetector.

func (*AgastFeatureDetector) Detect

func (a *AgastFeatureDetector) Detect(src Mat) []KeyPoint

Detect keypoints in an image using AgastFeatureDetector.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

type AlignMTB

type AlignMTB struct {
	// contains filtered or unexported fields
}

AlignMTB is a wrapper around the cv::AlignMTB.

func (*AlignMTB) Close

func (b *AlignMTB) Close() error

Close AlignMTB.

func (*AlignMTB) Process

func (b *AlignMTB) Process(src []Mat, dst *[]Mat)

Process computes an alignment using the current AlignMTB.

For further details, please see: https://docs.opencv.org/master/d7/db6/classcv_1_1AlignMTB.html#a37b3417d844f362d781f34155cbcb201

type BFMatcher

type BFMatcher struct {
	// contains filtered or unexported fields
}

BFMatcher is a wrapper around the the cv::BFMatcher algorithm

func NewBFMatcher

func NewBFMatcher() BFMatcher

NewBFMatcher returns a new BFMatcher

For further details, please see: https://docs.opencv.org/master/d3/da1/classcv_1_1BFMatcher.html#abe0bb11749b30d97f60d6ade665617bd

func NewBFMatcherWithParams

func NewBFMatcherWithParams(normType NormType, crossCheck bool) BFMatcher

NewBFMatcherWithParams creates a new BFMatchers but allows setting parameters to values other than just the defaults.

For further details, please see: https://docs.opencv.org/master/d3/da1/classcv_1_1BFMatcher.html#abe0bb11749b30d97f60d6ade665617bd

func (*BFMatcher) Close

func (b *BFMatcher) Close() error

Close BFMatcher

func (*BFMatcher) KnnMatch

func (b *BFMatcher) KnnMatch(query, train Mat, k int) [][]DMatch

KnnMatch Finds the k best matches for each descriptor from a query set.

For further details, please see: https://docs.opencv.org/master/db/d39/classcv_1_1DescriptorMatcher.html#aa880f9353cdf185ccf3013e08210483a

type BRISK

type BRISK struct {
	// contains filtered or unexported fields
}

BRISK is a wrapper around the cv::BRISK algorithm.

func NewBRISK

func NewBRISK() BRISK

NewBRISK returns a new BRISK algorithm

For further details, please see: https://docs.opencv.org/master/d8/d30/classcv_1_1AKAZE.html

func (*BRISK) Close

func (b *BRISK) Close() error

Close BRISK.

func (*BRISK) Detect

func (b *BRISK) Detect(src Mat) []KeyPoint

Detect keypoints in an image using BRISK.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

func (*BRISK) DetectAndCompute

func (b *BRISK) DetectAndCompute(src Mat, mask Mat) ([]KeyPoint, Mat)

DetectAndCompute keypoints and compute in an image using BRISK.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#a8be0d1c20b08eb867184b8d74c15a677

type BackgroundSubtractorKNN

type BackgroundSubtractorKNN struct {
	// contains filtered or unexported fields
}

BackgroundSubtractorKNN is a wrapper around the cv::BackgroundSubtractorKNN.

func NewBackgroundSubtractorKNN

func NewBackgroundSubtractorKNN() BackgroundSubtractorKNN

NewBackgroundSubtractorKNN returns a new BackgroundSubtractor algorithm of type KNN. K-Nearest Neighbors (KNN) uses a Background/Foreground Segmentation Algorithm

For further details, please see: https://docs.opencv.org/master/de/de1/group__video__motion.html#gac9be925771f805b6fdb614ec2292006d https://docs.opencv.org/master/db/d88/classcv_1_1BackgroundSubtractorKNN.html

func NewBackgroundSubtractorKNNWithParams

func NewBackgroundSubtractorKNNWithParams(history int, dist2Threshold float64, detectShadows bool) BackgroundSubtractorKNN

NewBackgroundSubtractorKNNWithParams returns a new BackgroundSubtractor algorithm of type KNN with customized parameters. K-Nearest Neighbors (KNN) uses a Background/Foreground Segmentation Algorithm

For further details, please see: https://docs.opencv.org/master/de/de1/group__video__motion.html#gac9be925771f805b6fdb614ec2292006d https://docs.opencv.org/master/db/d88/classcv_1_1BackgroundSubtractorKNN.html

func (*BackgroundSubtractorKNN) Apply

func (k *BackgroundSubtractorKNN) Apply(src Mat, dst *Mat)

Apply computes a foreground mask using the current BackgroundSubtractorKNN.

For further details, please see: https://docs.opencv.org/master/d7/df6/classcv_1_1BackgroundSubtractor.html#aa735e76f7069b3fa9c3f32395f9ccd21

func (*BackgroundSubtractorKNN) Close

func (k *BackgroundSubtractorKNN) Close() error

Close BackgroundSubtractorKNN.

type BackgroundSubtractorMOG2

type BackgroundSubtractorMOG2 struct {
	// contains filtered or unexported fields
}

BackgroundSubtractorMOG2 is a wrapper around the cv::BackgroundSubtractorMOG2.

func NewBackgroundSubtractorMOG2

func NewBackgroundSubtractorMOG2() BackgroundSubtractorMOG2

NewBackgroundSubtractorMOG2 returns a new BackgroundSubtractor algorithm of type MOG2. MOG2 is a Gaussian Mixture-based Background/Foreground Segmentation Algorithm.

For further details, please see: https://docs.opencv.org/master/de/de1/group__video__motion.html#ga2beb2dee7a073809ccec60f145b6b29c https://docs.opencv.org/master/d7/d7b/classcv_1_1BackgroundSubtractorMOG2.html

func NewBackgroundSubtractorMOG2WithParams

func NewBackgroundSubtractorMOG2WithParams(history int, varThreshold float64, detectShadows bool) BackgroundSubtractorMOG2

NewBackgroundSubtractorMOG2WithParams returns a new BackgroundSubtractor algorithm of type MOG2 with customized parameters. MOG2 is a Gaussian Mixture-based Background/Foreground Segmentation Algorithm.

For further details, please see: https://docs.opencv.org/master/de/de1/group__video__motion.html#ga2beb2dee7a073809ccec60f145b6b29c https://docs.opencv.org/master/d7/d7b/classcv_1_1BackgroundSubtractorMOG2.html

func (*BackgroundSubtractorMOG2) Apply

func (b *BackgroundSubtractorMOG2) Apply(src Mat, dst *Mat)

Apply computes a foreground mask using the current BackgroundSubtractorMOG2.

For further details, please see: https://docs.opencv.org/master/d7/df6/classcv_1_1BackgroundSubtractor.html#aa735e76f7069b3fa9c3f32395f9ccd21

func (*BackgroundSubtractorMOG2) Close

func (b *BackgroundSubtractorMOG2) Close() error

Close BackgroundSubtractorMOG2.

type BorderType

type BorderType int

BorderType type of border.

const (
	// BorderConstant border type
	BorderConstant BorderType = 0

	// BorderReplicate border type
	BorderReplicate BorderType = 1

	// BorderReflect border type
	BorderReflect BorderType = 2

	// BorderWrap border type
	BorderWrap BorderType = 3

	// BorderReflect101 border type
	BorderReflect101 BorderType = 4

	// BorderTransparent border type
	BorderTransparent BorderType = 5

	// BorderDefault border type
	BorderDefault = BorderReflect101

	// BorderIsolated border type
	BorderIsolated BorderType = 16
)

func (BorderType) String

func (c BorderType) String() string

type CLAHE

type CLAHE struct {
	// contains filtered or unexported fields
}

CLAHE is a wrapper around the cv::CLAHE algorithm.

func NewCLAHE

func NewCLAHE() CLAHE

NewCLAHE returns a new CLAHE algorithm

For further details, please see: https://docs.opencv.org/master/d6/db6/classcv_1_1CLAHE.html

func NewCLAHEWithParams

func NewCLAHEWithParams(clipLimit float64, tileGridSize image.Point) CLAHE

NewCLAHEWithParams returns a new CLAHE algorithm

For further details, please see: https://docs.opencv.org/master/d6/db6/classcv_1_1CLAHE.html

func (*CLAHE) Apply

func (c *CLAHE) Apply(src Mat, dst *Mat)

Apply CLAHE.

For further details, please see: https://docs.opencv.org/master/d6/db6/classcv_1_1CLAHE.html#a4e92e0e427de21be8d1fae8dcd862c5e

func (*CLAHE) Close

func (c *CLAHE) Close() error

Close CLAHE.

type CalibCBFlag

type CalibCBFlag int

CalibCBFlag value for chessboard calibration For more details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga93efa9b0aa890de240ca32b11253dd4a

const (
	// Various operation flags that can be zero or a combination of the following values:
	//  Use adaptive thresholding to convert the image to black and white, rather than a fixed threshold level (computed from the average image brightness).
	CalibCBAdaptiveThresh CalibCBFlag = 1 << iota
	//  Normalize the image gamma with equalizeHist before applying fixed or adaptive thresholding.
	CalibCBNormalizeImage
	//  Use additional criteria (like contour area, perimeter, square-like shape) to filter out false quads extracted at the contour retrieval stage.
	CalibCBFilterQuads
	//  Run a fast check on the image that looks for chessboard corners, and shortcut the call if none is found. This can drastically speed up the call in the degenerate condition when no chessboard is observed.
	CalibCBFastCheck
	//  Run an exhaustive search to improve detection rate.
	CalibCBExhaustive
	//  Up sample input image to improve sub-pixel accuracy due to aliasing effects.
	CalibCBAccuracy
	//  The detected pattern is allowed to be larger than patternSize (see description).
	CalibCBLarger
	//  The detected pattern must have a marker (see description). This should be used if an accurate camera calibration is required.
	CalibCBMarker
)

func (CalibCBFlag) String

func (c CalibCBFlag) String() string

type CalibFlag

type CalibFlag int32

CalibFlag value for calibration

const (
	// CalibUseIntrinsicGuess indicates that cameraMatrix contains valid initial values
	// of fx, fy, cx, cy that are optimized further. Otherwise, (cx, cy) is initially
	// set to the image center ( imageSize is used), and focal distances are computed
	// in a least-squares fashion.
	CalibUseIntrinsicGuess CalibFlag = 1 << iota

	// CalibRecomputeExtrinsic indicates that extrinsic will be recomputed after each
	// iteration of intrinsic optimization.
	CalibRecomputeExtrinsic

	// CalibCheckCond indicates that the functions will check validity of condition number
	CalibCheckCond

	// CalibFixSkew indicates that skew coefficient (alpha) is set to zero and stay zero
	CalibFixSkew

	// CalibFixK1 indicates that selected distortion coefficients are set to zeros and stay zero
	CalibFixK1

	// CalibFixK2 indicates that selected distortion coefficients are set to zeros and stay zero
	CalibFixK2

	// CalibFixK3 indicates that selected distortion coefficients are set to zeros and stay zero
	CalibFixK3

	// CalibFixK4 indicates that selected distortion coefficients are set to zeros and stay zero
	CalibFixK4

	// CalibFixIntrinsic indicates that fix K1, K2? and D1, D2? so that only R, T matrices are estimated
	CalibFixIntrinsic

	// CalibFixPrincipalPoint indicates that the principal point is not changed during the global optimization.
	// It stays at the center or at a different location specified when CalibUseIntrinsicGuess is set too.
	CalibFixPrincipalPoint
)

func (CalibFlag) String

func (c CalibFlag) String() string

type CascadeClassifier

type CascadeClassifier struct {
	// contains filtered or unexported fields
}

CascadeClassifier is a cascade classifier class for object detection.

For further details, please see: http://docs.opencv.org/master/d1/de5/classcv_1_1CascadeClassifier.html

func NewCascadeClassifier

func NewCascadeClassifier() CascadeClassifier

NewCascadeClassifier returns a new CascadeClassifier.

func (*CascadeClassifier) Close

func (c *CascadeClassifier) Close() error

Close deletes the CascadeClassifier's pointer.

func (*CascadeClassifier) DetectMultiScale

func (c *CascadeClassifier) DetectMultiScale(img Mat) []image.Rectangle

DetectMultiScale detects objects of different sizes in the input Mat image. The detected objects are returned as a slice of image.Rectangle structs.

For further details, please see: http://docs.opencv.org/master/d1/de5/classcv_1_1CascadeClassifier.html#aaf8181cb63968136476ec4204ffca498

func (*CascadeClassifier) DetectMultiScaleWithParams

func (c *CascadeClassifier) DetectMultiScaleWithParams(img Mat, scale float64,
	minNeighbors, flags int, minSize, maxSize image.Point) []image.Rectangle

DetectMultiScaleWithParams calls DetectMultiScale but allows setting parameters to values other than just the defaults.

For further details, please see: http://docs.opencv.org/master/d1/de5/classcv_1_1CascadeClassifier.html#aaf8181cb63968136476ec4204ffca498

func (*CascadeClassifier) Load

func (c *CascadeClassifier) Load(name string) bool

Load cascade classifier from a file.

For further details, please see: http://docs.opencv.org/master/d1/de5/classcv_1_1CascadeClassifier.html#a1a5884c8cc749422f9eb77c2471958bc

type ColorConversionCode

type ColorConversionCode int

ColorConversionCode is a color conversion code used on Mat.

For further details, please see: http://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#ga4e0972be5de079fed4e3a10e24ef5ef0

const (
	// ColorBGRToBGRA adds alpha channel to BGR image.
	ColorBGRToBGRA ColorConversionCode = 0

	// ColorBGRAToBGR removes alpha channel from BGR image.
	ColorBGRAToBGR ColorConversionCode = 1

	// ColorBGRToRGBA converts from BGR to RGB with alpha channel.
	ColorBGRToRGBA ColorConversionCode = 2

	// ColorRGBAToBGR converts from RGB with alpha to BGR color space.
	ColorRGBAToBGR ColorConversionCode = 3

	// ColorBGRToRGB converts from BGR to RGB without alpha channel.
	ColorBGRToRGB ColorConversionCode = 4

	// ColorBGRAToRGBA converts from BGR with alpha channel
	// to RGB with alpha channel.
	ColorBGRAToRGBA ColorConversionCode = 5

	// ColorBGRToGray converts from BGR to grayscale.
	ColorBGRToGray ColorConversionCode = 6

	// ColorRGBToGray converts from RGB to grayscale.
	ColorRGBToGray ColorConversionCode = 7

	// ColorGrayToBGR converts from grayscale to BGR.
	ColorGrayToBGR ColorConversionCode = 8

	// ColorGrayToBGRA converts from grayscale to BGR with alpha channel.
	ColorGrayToBGRA ColorConversionCode = 9

	// ColorBGRAToGray converts from BGR with alpha channel to grayscale.
	ColorBGRAToGray ColorConversionCode = 10

	// ColorRGBAToGray converts from RGB with alpha channel to grayscale.
	ColorRGBAToGray ColorConversionCode = 11

	// ColorBGRToBGR565 converts from BGR to BGR565 (16-bit images).
	ColorBGRToBGR565 ColorConversionCode = 12

	// ColorRGBToBGR565 converts from RGB to BGR565 (16-bit images).
	ColorRGBToBGR565 ColorConversionCode = 13

	// ColorBGR565ToBGR converts from BGR565 (16-bit images) to BGR.
	ColorBGR565ToBGR ColorConversionCode = 14

	// ColorBGR565ToRGB converts from BGR565 (16-bit images) to RGB.
	ColorBGR565ToRGB ColorConversionCode = 15

	// ColorBGRAToBGR565 converts from BGRA (with alpha channel)
	// to BGR565 (16-bit images).
	ColorBGRAToBGR565 ColorConversionCode = 16

	// ColorRGBAToBGR565 converts from RGBA (with alpha channel)
	// to BGR565 (16-bit images).
	ColorRGBAToBGR565 ColorConversionCode = 17

	// ColorBGR565ToBGRA converts from BGR565 (16-bit images)
	// to BGRA (with alpha channel).
	ColorBGR565ToBGRA ColorConversionCode = 18

	// ColorBGR565ToRGBA converts from BGR565 (16-bit images)
	// to RGBA (with alpha channel).
	ColorBGR565ToRGBA ColorConversionCode = 19

	// ColorGrayToBGR565 converts from grayscale
	// to BGR565 (16-bit images).
	ColorGrayToBGR565 ColorConversionCode = 20

	// ColorBGR565ToGray converts from BGR565 (16-bit images)
	// to grayscale.
	ColorBGR565ToGray ColorConversionCode = 21

	// ColorBGRToBGR555 converts from BGR to BGR555 (16-bit images).
	ColorBGRToBGR555 ColorConversionCode = 22

	// ColorRGBToBGR555 converts from RGB to BGR555 (16-bit images).
	ColorRGBToBGR555 ColorConversionCode = 23

	// ColorBGR555ToBGR converts from BGR555 (16-bit images) to BGR.
	ColorBGR555ToBGR ColorConversionCode = 24

	// ColorBGR555ToRGB converts from BGR555 (16-bit images) to RGB.
	ColorBGR555ToRGB ColorConversionCode = 25

	// ColorBGRAToBGR555 converts from BGRA (with alpha channel)
	// to BGR555 (16-bit images).
	ColorBGRAToBGR555 ColorConversionCode = 26

	// ColorRGBAToBGR555 converts from RGBA (with alpha channel)
	// to BGR555 (16-bit images).
	ColorRGBAToBGR555 ColorConversionCode = 27

	// ColorBGR555ToBGRA converts from BGR555 (16-bit images)
	// to BGRA (with alpha channel).
	ColorBGR555ToBGRA ColorConversionCode = 28

	// ColorBGR555ToRGBA converts from BGR555 (16-bit images)
	// to RGBA (with alpha channel).
	ColorBGR555ToRGBA ColorConversionCode = 29

	// ColorGrayToBGR555 converts from grayscale to BGR555 (16-bit images).
	ColorGrayToBGR555 ColorConversionCode = 30

	// ColorBGR555ToGRAY converts from BGR555 (16-bit images) to grayscale.
	ColorBGR555ToGRAY ColorConversionCode = 31

	// ColorBGRToXYZ converts from BGR to CIE XYZ.
	ColorBGRToXYZ ColorConversionCode = 32

	// ColorRGBToXYZ converts from RGB to CIE XYZ.
	ColorRGBToXYZ ColorConversionCode = 33

	// ColorXYZToBGR converts from CIE XYZ to BGR.
	ColorXYZToBGR ColorConversionCode = 34

	// ColorXYZToRGB converts from CIE XYZ to RGB.
	ColorXYZToRGB ColorConversionCode = 35

	// ColorBGRToYCrCb converts from BGR to luma-chroma (aka YCC).
	ColorBGRToYCrCb ColorConversionCode = 36

	// ColorRGBToYCrCb converts from RGB to luma-chroma (aka YCC).
	ColorRGBToYCrCb ColorConversionCode = 37

	// ColorYCrCbToBGR converts from luma-chroma (aka YCC) to BGR.
	ColorYCrCbToBGR ColorConversionCode = 38

	// ColorYCrCbToRGB converts from luma-chroma (aka YCC) to RGB.
	ColorYCrCbToRGB ColorConversionCode = 39

	// ColorBGRToHSV converts from BGR to HSV (hue saturation value).
	ColorBGRToHSV ColorConversionCode = 40

	// ColorRGBToHSV converts from RGB to HSV (hue saturation value).
	ColorRGBToHSV ColorConversionCode = 41

	// ColorBGRToLab converts from BGR to CIE Lab.
	ColorBGRToLab ColorConversionCode = 44

	// ColorRGBToLab converts from RGB to CIE Lab.
	ColorRGBToLab ColorConversionCode = 45

	// ColorBGRToLuv converts from BGR to CIE Luv.
	ColorBGRToLuv ColorConversionCode = 50

	// ColorRGBToLuv converts from RGB to CIE Luv.
	ColorRGBToLuv ColorConversionCode = 51

	// ColorBGRToHLS converts from BGR to HLS (hue lightness saturation).
	ColorBGRToHLS ColorConversionCode = 52

	// ColorRGBToHLS converts from RGB to HLS (hue lightness saturation).
	ColorRGBToHLS ColorConversionCode = 53

	// ColorHSVToBGR converts from HSV (hue saturation value) to BGR.
	ColorHSVToBGR ColorConversionCode = 54

	// ColorHSVToRGB converts from HSV (hue saturation value) to RGB.
	ColorHSVToRGB ColorConversionCode = 55

	// ColorLabToBGR converts from CIE Lab to BGR.
	ColorLabToBGR ColorConversionCode = 56

	// ColorLabToRGB converts from CIE Lab to RGB.
	ColorLabToRGB ColorConversionCode = 57

	// ColorLuvToBGR converts from CIE Luv to BGR.
	ColorLuvToBGR ColorConversionCode = 58

	// ColorLuvToRGB converts from CIE Luv to RGB.
	ColorLuvToRGB ColorConversionCode = 59

	// ColorHLSToBGR converts from HLS (hue lightness saturation) to BGR.
	ColorHLSToBGR ColorConversionCode = 60

	// ColorHLSToRGB converts from HLS (hue lightness saturation) to RGB.
	ColorHLSToRGB ColorConversionCode = 61

	// ColorBGRToHSVFull converts from BGR to HSV (hue saturation value) full.
	ColorBGRToHSVFull ColorConversionCode = 66

	// ColorRGBToHSVFull converts from RGB to HSV (hue saturation value) full.
	ColorRGBToHSVFull ColorConversionCode = 67

	// ColorBGRToHLSFull converts from BGR to HLS (hue lightness saturation) full.
	ColorBGRToHLSFull ColorConversionCode = 68

	// ColorRGBToHLSFull converts from RGB to HLS (hue lightness saturation) full.
	ColorRGBToHLSFull ColorConversionCode = 69

	// ColorHSVToBGRFull converts from HSV (hue saturation value) to BGR full.
	ColorHSVToBGRFull ColorConversionCode = 70

	// ColorHSVToRGBFull converts from HSV (hue saturation value) to RGB full.
	ColorHSVToRGBFull ColorConversionCode = 71

	// ColorHLSToBGRFull converts from HLS (hue lightness saturation) to BGR full.
	ColorHLSToBGRFull ColorConversionCode = 72

	// ColorHLSToRGBFull converts from HLS (hue lightness saturation) to RGB full.
	ColorHLSToRGBFull ColorConversionCode = 73

	// ColorLBGRToLab converts from LBGR to CIE Lab.
	ColorLBGRToLab ColorConversionCode = 74

	// ColorLRGBToLab converts from LRGB to CIE Lab.
	ColorLRGBToLab ColorConversionCode = 75

	// ColorLBGRToLuv converts from LBGR to CIE Luv.
	ColorLBGRToLuv ColorConversionCode = 76

	// ColorLRGBToLuv converts from LRGB to CIE Luv.
	ColorLRGBToLuv ColorConversionCode = 77

	// ColorLabToLBGR converts from CIE Lab to LBGR.
	ColorLabToLBGR ColorConversionCode = 78

	// ColorLabToLRGB converts from CIE Lab to LRGB.
	ColorLabToLRGB ColorConversionCode = 79

	// ColorLuvToLBGR converts from CIE Luv to LBGR.
	ColorLuvToLBGR ColorConversionCode = 80

	// ColorLuvToLRGB converts from CIE Luv to LRGB.
	ColorLuvToLRGB ColorConversionCode = 81

	// ColorBGRToYUV converts from BGR to YUV.
	ColorBGRToYUV ColorConversionCode = 82

	// ColorRGBToYUV converts from RGB to YUV.
	ColorRGBToYUV ColorConversionCode = 83

	// ColorYUVToBGR converts from YUV to BGR.
	ColorYUVToBGR ColorConversionCode = 84

	// ColorYUVToRGB converts from YUV to RGB.
	ColorYUVToRGB ColorConversionCode = 85

	// ColorYUVToRGBNV12 converts from YUV 4:2:0 to RGB NV12.
	ColorYUVToRGBNV12 ColorConversionCode = 90

	// ColorYUVToBGRNV12 converts from YUV 4:2:0 to BGR NV12.
	ColorYUVToBGRNV12 ColorConversionCode = 91

	// ColorYUVToRGBNV21 converts from YUV 4:2:0 to RGB NV21.
	ColorYUVToRGBNV21 ColorConversionCode = 92

	// ColorYUVToBGRNV21 converts from YUV 4:2:0 to BGR NV21.
	ColorYUVToBGRNV21 ColorConversionCode = 93

	// ColorYUVToRGBANV12 converts from YUV 4:2:0 to RGBA NV12.
	ColorYUVToRGBANV12 ColorConversionCode = 94

	// ColorYUVToBGRANV12 converts from YUV 4:2:0 to BGRA NV12.
	ColorYUVToBGRANV12 ColorConversionCode = 95

	// ColorYUVToRGBANV21 converts from YUV 4:2:0 to RGBA NV21.
	ColorYUVToRGBANV21 ColorConversionCode = 96

	// ColorYUVToBGRANV21 converts from YUV 4:2:0 to BGRA NV21.
	ColorYUVToBGRANV21 ColorConversionCode = 97

	ColorYUVToRGBYV12 ColorConversionCode = 98
	ColorYUVToBGRYV12 ColorConversionCode = 99
	ColorYUVToRGBIYUV ColorConversionCode = 100
	ColorYUVToBGRIYUV ColorConversionCode = 101

	ColorYUVToRGBAYV12 ColorConversionCode = 102
	ColorYUVToBGRAYV12 ColorConversionCode = 103
	ColorYUVToRGBAIYUV ColorConversionCode = 104
	ColorYUVToBGRAIYUV ColorConversionCode = 105

	ColorYUVToGRAY420 ColorConversionCode = 106

	// YUV 4:2:2 family to RGB
	ColorYUVToRGBUYVY ColorConversionCode = 107
	ColorYUVToBGRUYVY ColorConversionCode = 108

	ColorYUVToRGBAUYVY ColorConversionCode = 111
	ColorYUVToBGRAUYVY ColorConversionCode = 112

	ColorYUVToRGBYUY2 ColorConversionCode = 115
	ColorYUVToBGRYUY2 ColorConversionCode = 116
	ColorYUVToRGBYVYU ColorConversionCode = 117
	ColorYUVToBGRYVYU ColorConversionCode = 118

	ColorYUVToRGBAYUY2 ColorConversionCode = 119
	ColorYUVToBGRAYUY2 ColorConversionCode = 120
	ColorYUVToRGBAYVYU ColorConversionCode = 121
	ColorYUVToBGRAYVYU ColorConversionCode = 122

	ColorYUVToGRAYUYVY ColorConversionCode = 123
	ColorYUVToGRAYYUY2 ColorConversionCode = 124

	// alpha premultiplication
	ColorRGBATomRGBA ColorConversionCode = 125
	ColormRGBAToRGBA ColorConversionCode = 126

	// RGB to YUV 4:2:0 family
	ColorRGBToYUVI420 ColorConversionCode = 127
	ColorBGRToYUVI420 ColorConversionCode = 128

	ColorRGBAToYUVI420 ColorConversionCode = 129
	ColorBGRAToYUVI420 ColorConversionCode = 130
	ColorRGBToYUVYV12  ColorConversionCode = 131
	ColorBGRToYUVYV12  ColorConversionCode = 132
	ColorRGBAToYUVYV12 ColorConversionCode = 133
	ColorBGRAToYUVYV12 ColorConversionCode = 134

	// Demosaicing
	ColorBayerBGToBGR ColorConversionCode = 46
	ColorBayerGBToBGR ColorConversionCode = 47
	ColorBayerRGToBGR ColorConversionCode = 48
	ColorBayerGRToBGR ColorConversionCode = 49

	ColorBayerBGToGRAY ColorConversionCode = 86
	ColorBayerGBToGRAY ColorConversionCode = 87
	ColorBayerRGToGRAY ColorConversionCode = 88
	ColorBayerGRToGRAY ColorConversionCode = 89

	// Demosaicing using Variable Number of Gradients
	ColorBayerBGToBGRVNG ColorConversionCode = 62
	ColorBayerGBToBGRVNG ColorConversionCode = 63
	ColorBayerRGToBGRVNG ColorConversionCode = 64
	ColorBayerGRToBGRVNG ColorConversionCode = 65

	// Edge-Aware Demosaicing
	ColorBayerBGToBGREA ColorConversionCode = 135
	ColorBayerGBToBGREA ColorConversionCode = 136
	ColorBayerRGToBGREA ColorConversionCode = 137
	ColorBayerGRToBGREA ColorConversionCode = 138

	// Demosaicing with alpha channel
	ColorBayerBGToBGRA ColorConversionCode = 139
	ColorBayerGBToBGRA ColorConversionCode = 140
	ColorBayerRGToBGRA ColorConversionCode = 141
	ColorBayerGRToBGRA ColorConversionCode = 142

	ColorCOLORCVTMAX ColorConversionCode = 143
)

func (ColorConversionCode) String

func (c ColorConversionCode) String() string

type ColormapTypes

type ColormapTypes int

ColormapTypes are the 12 GNU Octave/MATLAB equivalent colormaps.

For further details, please see: https://docs.opencv.org/master/d3/d50/group__imgproc__colormap.html

const (
	ColormapAutumn  ColormapTypes = 0
	ColormapBone    ColormapTypes = 1
	ColormapJet     ColormapTypes = 2
	ColormapWinter  ColormapTypes = 3
	ColormapRainbow ColormapTypes = 4
	ColormapOcean   ColormapTypes = 5
	ColormapSummer  ColormapTypes = 6
	ColormapSpring  ColormapTypes = 7
	ColormapCool    ColormapTypes = 8
	ColormapHsv     ColormapTypes = 9
	ColormapPink    ColormapTypes = 10
	ColormapHot     ColormapTypes = 11
	ColormapParula  ColormapTypes = 12
)

List of the available color maps

For further details, please see: https://docs.opencv.org/master/d3/d50/group__imgproc__colormap.html#ga9a805d8262bcbe273f16be9ea2055a65

func (ColormapTypes) String

func (c ColormapTypes) String() string

type CompareType

type CompareType int

CompareType is used for Compare operations to indicate which kind of comparison to use.

const (
	// CompareEQ src1 is equal to src2.
	CompareEQ CompareType = 0

	// CompareGT src1 is greater than src2.
	CompareGT CompareType = 1

	// CompareGE src1 is greater than or equal to src2.
	CompareGE CompareType = 2

	// CompareLT src1 is less than src2.
	CompareLT CompareType = 3

	// CompareLE src1 is less than or equal to src2.
	CompareLE CompareType = 4

	// CompareNE src1 is unequal to src2.
	CompareNE CompareType = 5
)

func (CompareType) String

func (c CompareType) String() string

type ConnectedComponentsAlgorithmType

type ConnectedComponentsAlgorithmType int

ConnectedComponentsAlgorithmType specifies the type for ConnectedComponents

const (
	// SAUF algorithm for 8-way connectivity, SAUF algorithm for 4-way connectivity.
	CCL_WU ConnectedComponentsAlgorithmType = 0

	// BBDT algorithm for 8-way connectivity, SAUF algorithm for 4-way connectivity.
	CCL_DEFAULT ConnectedComponentsAlgorithmType = 1

	// BBDT algorithm for 8-way connectivity, SAUF algorithm for 4-way connectivity
	CCL_GRANA ConnectedComponentsAlgorithmType = 2
)

func (ConnectedComponentsAlgorithmType) String

type ConnectedComponentsTypes

type ConnectedComponentsTypes int

ConnectedComponentsTypes are the connected components algorithm output formats

const (
	//The leftmost (x) coordinate which is the inclusive start of the bounding box in the horizontal direction.
	CC_STAT_LEFT ConnectedComponentsTypes = 0

	//The topmost (y) coordinate which is the inclusive start of the bounding box in the vertical direction.
	CC_STAT_TOP ConnectedComponentsTypes = 1

	// The horizontal size of the bounding box.
	CC_STAT_WIDTH ConnectedComponentsTypes = 2

	// The vertical size of the bounding box.
	CC_STAT_HEIGHT ConnectedComponentsTypes = 3

	// The total area (in pixels) of the connected component.
	CC_STAT_AREA ConnectedComponentsTypes = 4

	CC_STAT_MAX ConnectedComponentsTypes = 5
)

func (ConnectedComponentsTypes) String

func (c ConnectedComponentsTypes) String() string

type ContourApproximationMode

type ContourApproximationMode int

ContourApproximationMode is the mode of the contour approximation algorithm.

const (
	// ChainApproxNone stores absolutely all the contour points. That is,
	// any 2 subsequent points (x1,y1) and (x2,y2) of the contour will be
	// either horizontal, vertical or diagonal neighbors, that is,
	// max(abs(x1-x2),abs(y2-y1))==1.
	ChainApproxNone ContourApproximationMode = 1

	// ChainApproxSimple compresses horizontal, vertical, and diagonal segments
	// and leaves only their end points.
	// For example, an up-right rectangular contour is encoded with 4 points.
	ChainApproxSimple ContourApproximationMode = 2

	// ChainApproxTC89L1 applies one of the flavors of the Teh-Chin chain
	// approximation algorithms.
	ChainApproxTC89L1 ContourApproximationMode = 3

	// ChainApproxTC89KCOS applies one of the flavors of the Teh-Chin chain
	// approximation algorithms.
	ChainApproxTC89KCOS ContourApproximationMode = 4
)

func (ContourApproximationMode) String

func (c ContourApproximationMode) String() string

type CovarFlags

type CovarFlags int

CovarFlags are the covariation flags used by functions such as BorderInterpolate.

For further details, please see: https://docs.opencv.org/master/d0/de1/group__core.html#ga719ebd4a73f30f4fab258ab7616d0f0f

const (
	// CovarScrambled indicates to scramble the results.
	CovarScrambled CovarFlags = 0

	// CovarNormal indicates to use normal covariation.
	CovarNormal CovarFlags = 1

	// CovarUseAvg indicates to use average covariation.
	CovarUseAvg CovarFlags = 2

	// CovarScale indicates to use scaled covariation.
	CovarScale CovarFlags = 4

	// CovarRows indicates to use covariation on rows.
	CovarRows CovarFlags = 8

	// CovarCols indicates to use covariation on columns.
	CovarCols CovarFlags = 16
)

func (CovarFlags) String

func (c CovarFlags) String() string

type DMatch

type DMatch struct {
	QueryIdx int
	TrainIdx int
	ImgIdx   int
	Distance float64
}

DMatch is data structure for matching keypoint descriptors.

For further details, please see: https://docs.opencv.org/master/d4/de0/classcv_1_1DMatch.html#a546ddb9a87898f06e510e015a6de596e

type DftFlags

type DftFlags int

DftFlags represents a DFT or DCT flag.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gaf4dde112b483b38175621befedda1f1c

const (
	// DftForward performs forward 1D or 2D dft or dct.
	DftForward DftFlags = 0

	// DftInverse performs an inverse 1D or 2D transform.
	DftInverse DftFlags = 1

	// DftScale scales the result: divide it by the number of array elements. Normally, it is combined with DFT_INVERSE.
	DftScale DftFlags = 2

	// DftRows performs a forward or inverse transform of every individual row of the input matrix.
	DftRows DftFlags = 4

	// DftComplexOutput performs a forward transformation of 1D or 2D real array; the result, though being a complex array, has complex-conjugate symmetry
	DftComplexOutput DftFlags = 16

	// DftRealOutput performs an inverse transformation of a 1D or 2D complex array; the result is normally a complex array of the same size,
	// however, if the input array has conjugate-complex symmetry (for example, it is a result of forward transformation with DFT_COMPLEX_OUTPUT flag),
	// the output is a real array.
	DftRealOutput DftFlags = 32

	// DftComplexInput specifies that input is complex input. If this flag is set, the input must have 2 channels.
	DftComplexInput DftFlags = 64

	// DctInverse performs an inverse 1D or 2D dct transform.
	DctInverse = DftInverse

	// DctRows performs a forward or inverse dct transform of every individual row of the input matrix.
	DctRows = DftRows
)

func (DftFlags) String

func (c DftFlags) String() string

type DistanceTransformLabelTypes

type DistanceTransformLabelTypes int

DistanceTransformLabelTypes are the types of the DistanceTransform algorithm flag

const (
	// DistanceLabelCComp assigns the same label to each connected component of zeros in the source image
	// (as well as all the non-zero pixels closest to the connected component).
	DistanceLabelCComp DistanceTransformLabelTypes = 0

	// DistanceLabelPixel assigns its own label to each zero pixel (and all the non-zero pixels closest to it).
	DistanceLabelPixel
)

func (DistanceTransformLabelTypes) String

type DistanceTransformMasks

type DistanceTransformMasks int

DistanceTransformMasks are the marsk sizes for distance transform

const (
	// DistanceMask3 is a mask of size 3
	DistanceMask3 DistanceTransformMasks = 0

	// DistanceMask5 is a mask of size 3
	DistanceMask5

	// DistanceMaskPrecise is not currently supported
	DistanceMaskPrecise
)

func (DistanceTransformMasks) String

func (c DistanceTransformMasks) String() string

type DistanceTypes

type DistanceTypes int

DistanceTypes types for Distance Transform and M-estimatorss

For further details, please see: https://docs.opencv.org/master/d7/d1b/group__imgproc__misc.html#gaa2bfbebbc5c320526897996aafa1d8eb

const (
	DistUser   DistanceTypes = 0
	DistL1     DistanceTypes = 1
	DistL2     DistanceTypes = 2
	DistC      DistanceTypes = 3
	DistL12    DistanceTypes = 4
	DistFair   DistanceTypes = 5
	DistWelsch DistanceTypes = 6
	DistHuber  DistanceTypes = 7
)

func (DistanceTypes) String

func (c DistanceTypes) String() string

type DrawMatchesFlag

type DrawMatchesFlag int

DrawMatchesFlag are the flags setting drawing feature

For further details please see: https://docs.opencv.org/master/de/d30/structcv_1_1DrawMatchesFlags.html

const (
	// DrawDefault creates new image and for each keypoint only the center point will be drawn
	DrawDefault DrawMatchesFlag = 0
	// DrawOverOutImg draws matches on existing content of image
	DrawOverOutImg DrawMatchesFlag = 1
	// NotDrawSinglePoints will not draw single points
	NotDrawSinglePoints DrawMatchesFlag = 2
	// DrawRichKeyPoints draws the circle around each keypoint with keypoint size and orientation
	DrawRichKeyPoints DrawMatchesFlag = 3
)

func (DrawMatchesFlag) String

func (c DrawMatchesFlag) String() string

type EdgeFilter

type EdgeFilter int
const (
	// RecursFilter Recursive Filtering.
	RecursFilter EdgeFilter = 1

	// NormconvFilter Normalized Convolution Filtering.
	NormconvFilter = 2
)

type FastFeatureDetector

type FastFeatureDetector struct {
	// contains filtered or unexported fields
}

FastFeatureDetector is a wrapper around the cv::FastFeatureDetector.

func NewFastFeatureDetector

func NewFastFeatureDetector() FastFeatureDetector

NewFastFeatureDetector returns a new FastFeatureDetector algorithm

For further details, please see: https://docs.opencv.org/master/df/d74/classcv_1_1FastFeatureDetector.html

func NewFastFeatureDetectorWithParams

func NewFastFeatureDetectorWithParams(threshold int, nonmaxSuppression bool, typ FastFeatureDetectorType) FastFeatureDetector

NewFastFeatureDetectorWithParams returns a new FastFeatureDetector algorithm with parameters

For further details, please see: https://docs.opencv.org/master/df/d74/classcv_1_1FastFeatureDetector.html#ab986f2ff8f8778aab1707e2642bc7f8e

func (*FastFeatureDetector) Close

func (f *FastFeatureDetector) Close() error

Close FastFeatureDetector.

func (*FastFeatureDetector) Detect

func (f *FastFeatureDetector) Detect(src Mat) []KeyPoint

Detect keypoints in an image using FastFeatureDetector.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

type FastFeatureDetectorType

type FastFeatureDetectorType int

FastFeatureDetectorType defines the detector type

For further details, please see: https://docs.opencv.org/master/df/d74/classcv_1_1FastFeatureDetector.html#a4654f6fb0aa4b8e9123b223bfa0e2a08

const (
	//FastFeatureDetectorType58 is an alias of FastFeatureDetector::TYPE_5_8
	FastFeatureDetectorType58 FastFeatureDetectorType = 0
	//FastFeatureDetectorType712 is an alias of FastFeatureDetector::TYPE_7_12
	FastFeatureDetectorType712 FastFeatureDetectorType = 1
	//FastFeatureDetectorType916 is an alias of FastFeatureDetector::TYPE_9_16
	FastFeatureDetectorType916 FastFeatureDetectorType = 2
)

func (FastFeatureDetectorType) String

func (c FastFeatureDetectorType) String() string

type FileExt

type FileExt string

FileExt represents a file extension.

const (
	// PNGFileExt is the file extension for PNG.
	PNGFileExt FileExt = ".png"
	// JPEGFileExt is the file extension for JPEG.
	JPEGFileExt FileExt = ".jpg"
	// GIFFileExt is the file extension for GIF.
	GIFFileExt FileExt = ".gif"
)

type FlannBasedMatcher

type FlannBasedMatcher struct {
	// contains filtered or unexported fields
}

FlannBasedMatcher is a wrapper around the the cv::FlannBasedMatcher algorithm

func NewFlannBasedMatcher

func NewFlannBasedMatcher() FlannBasedMatcher

NewFlannBasedMatcher returns a new FlannBasedMatcher

For further details, please see: https://docs.opencv.org/master/dc/de2/classcv_1_1FlannBasedMatcher.html#ab9114a6471e364ad221f89068ca21382

func (*FlannBasedMatcher) Close

func (f *FlannBasedMatcher) Close() error

Close FlannBasedMatcher

func (*FlannBasedMatcher) KnnMatch

func (f *FlannBasedMatcher) KnnMatch(query, train Mat, k int) [][]DMatch

KnnMatch Finds the k best matches for each descriptor from a query set.

For further details, please see: https://docs.opencv.org/master/db/d39/classcv_1_1DescriptorMatcher.html#aa880f9353cdf185ccf3013e08210483a

type GFTTDetector

type GFTTDetector struct {
	// contains filtered or unexported fields
}

GFTTDetector is a wrapper around the cv::GFTTDetector algorithm.

func NewGFTTDetector

func NewGFTTDetector() GFTTDetector

NewGFTTDetector returns a new GFTTDetector algorithm

For further details, please see: https://docs.opencv.org/master/df/d21/classcv_1_1GFTTDetector.html

func (*GFTTDetector) Close

func (a *GFTTDetector) Close() error

Close GFTTDetector.

func (*GFTTDetector) Detect

func (a *GFTTDetector) Detect(src Mat) []KeyPoint

Detect keypoints in an image using GFTTDetector.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

type GrabCutMode

type GrabCutMode int

GrabCutMode is the flag for GrabCut algorithm.

const (
	// GCInitWithRect makes the function initialize the state and the mask using the provided rectangle.
	// After that it runs the itercount iterations of the algorithm.
	GCInitWithRect GrabCutMode = 0
	// GCInitWithMask makes the function initialize the state using the provided mask.
	// GCInitWithMask and GCInitWithRect can be combined.
	// Then all the pixels outside of the ROI are automatically initialized with GC_BGD.
	GCInitWithMask GrabCutMode = 1
	// GCEval means that the algorithm should just resume.
	GCEval GrabCutMode = 2
	// GCEvalFreezeModel means that the algorithm should just run a single iteration of the GrabCut algorithm
	// with the fixed model
	GCEvalFreezeModel GrabCutMode = 3
)

func (GrabCutMode) String

func (c GrabCutMode) String() string

type HOGDescriptor

type HOGDescriptor struct {
	// contains filtered or unexported fields
}

HOGDescriptor is a Histogram Of Gradiants (HOG) for object detection.

For further details, please see: https://docs.opencv.org/master/d5/d33/structcv_1_1HOGDescriptor.html#a723b95b709cfd3f95cf9e616de988fc8

func NewHOGDescriptor

func NewHOGDescriptor() HOGDescriptor

NewHOGDescriptor returns a new HOGDescriptor.

func (*HOGDescriptor) Close

func (h *HOGDescriptor) Close() error

Close deletes the HOGDescriptor's pointer.

func (*HOGDescriptor) DetectMultiScale

func (h *HOGDescriptor) DetectMultiScale(img Mat) []image.Rectangle

DetectMultiScale detects objects in the input Mat image. The detected objects are returned as a slice of image.Rectangle structs.

For further details, please see: https://docs.opencv.org/master/d5/d33/structcv_1_1HOGDescriptor.html#a660e5cd036fd5ddf0f5767b352acd948

func (*HOGDescriptor) DetectMultiScaleWithParams

func (h *HOGDescriptor) DetectMultiScaleWithParams(img Mat, hitThresh float64,
	winStride, padding image.Point, scale, finalThreshold float64, useMeanshiftGrouping bool) []image.Rectangle

DetectMultiScaleWithParams calls DetectMultiScale but allows setting parameters to values other than just the defaults.

For further details, please see: https://docs.opencv.org/master/d5/d33/structcv_1_1HOGDescriptor.html#a660e5cd036fd5ddf0f5767b352acd948

func (*HOGDescriptor) SetSVMDetector

func (h *HOGDescriptor) SetSVMDetector(det Mat) error

SetSVMDetector sets the data for the HOGDescriptor.

For further details, please see: https://docs.opencv.org/master/d5/d33/structcv_1_1HOGDescriptor.html#a09e354ad701f56f9c550dc0385dc36f1

type HersheyFont

type HersheyFont int

HersheyFont are the font libraries included in OpenCV. Only a subset of the available Hershey fonts are supported by OpenCV.

For more information, see: http://sources.isc.org/utils/misc/hershey-font.txt

const (
	// FontHersheySimplex is normal size sans-serif font.
	FontHersheySimplex HersheyFont = 0
	// FontHersheyPlain issmall size sans-serif font.
	FontHersheyPlain HersheyFont = 1
	// FontHersheyDuplex normal size sans-serif font
	// (more complex than FontHersheySIMPLEX).
	FontHersheyDuplex HersheyFont = 2
	// FontHersheyComplex i a normal size serif font.
	FontHersheyComplex HersheyFont = 3
	// FontHersheyTriplex is a normal size serif font
	// (more complex than FontHersheyCOMPLEX).
	FontHersheyTriplex HersheyFont = 4
	// FontHersheyComplexSmall is a smaller version of FontHersheyCOMPLEX.
	FontHersheyComplexSmall HersheyFont = 5
	// FontHersheyScriptSimplex is a hand-writing style font.
	FontHersheyScriptSimplex HersheyFont = 6
	// FontHersheyScriptComplex is a more complex variant of FontHersheyScriptSimplex.
	FontHersheyScriptComplex HersheyFont = 7
	// FontItalic is the flag for italic font.
	FontItalic HersheyFont = 16
)

func (HersheyFont) String

func (c HersheyFont) String() string

type HistCompMethod

type HistCompMethod int

HistCompMethod is the method for Histogram comparison For more information, see https://docs.opencv.org/master/d6/dc7/group__imgproc__hist.html#ga994f53817d621e2e4228fc646342d386

const (
	// HistCmpCorrel calculates the Correlation
	HistCmpCorrel HistCompMethod = 0

	// HistCmpChiSqr calculates the Chi-Square
	HistCmpChiSqr HistCompMethod = 1

	// HistCmpIntersect calculates the Intersection
	HistCmpIntersect HistCompMethod = 2

	// HistCmpBhattacharya applies the HistCmpBhattacharya by calculating the Bhattacharya distance.
	HistCmpBhattacharya HistCompMethod = 3

	// HistCmpHellinger applies the HistCmpBhattacharya comparison. It is a synonym to HistCmpBhattacharya.
	HistCmpHellinger = HistCmpBhattacharya

	// HistCmpChiSqrAlt applies the Alternative Chi-Square (regularly used for texture comparsion).
	HistCmpChiSqrAlt HistCompMethod = 4

	// HistCmpKlDiv applies the Kullback-Liebler divergence comparison.
	HistCmpKlDiv HistCompMethod = 5
)

func (HistCompMethod) String

func (c HistCompMethod) String() string

type HomographyMethod

type HomographyMethod int
const (
	HomograpyMethodAllPoints HomographyMethod = 0
	HomograpyMethodLMEDS     HomographyMethod = 4
	HomograpyMethodRANSAC    HomographyMethod = 8
)

type HoughMode

type HoughMode int

HoughMode is the type for Hough transform variants.

const (
	// HoughStandard is the classical or standard Hough transform.
	HoughStandard HoughMode = 0
	// HoughProbabilistic is the probabilistic Hough transform (more efficient
	// in case if the picture contains a few long linear segments).
	HoughProbabilistic HoughMode = 1
	// HoughMultiScale is the multi-scale variant of the classical Hough
	// transform.
	HoughMultiScale HoughMode = 2
	// HoughGradient is basically 21HT, described in: HK Yuen, John Princen,
	// John Illingworth, and Josef Kittler. Comparative study of hough
	// transform methods for circle finding. Image and Vision Computing,
	// 8(1):71–77, 1990.
	HoughGradient HoughMode = 3
)

func (HoughMode) String

func (c HoughMode) String() string

type IMReadFlag

type IMReadFlag int

IMReadFlag is one of the valid flags to use for the IMRead function.

const (
	// IMReadUnchanged return the loaded image as is (with alpha channel,
	// otherwise it gets cropped).
	IMReadUnchanged IMReadFlag = -1

	// IMReadGrayScale always convert image to the single channel
	// grayscale image.
	IMReadGrayScale IMReadFlag = 0

	// IMReadColor always converts image to the 3 channel BGR color image.
	IMReadColor IMReadFlag = 1

	// IMReadAnyDepth returns 16-bit/32-bit image when the input has the corresponding
	// depth, otherwise convert it to 8-bit.
	IMReadAnyDepth IMReadFlag = 2

	// IMReadAnyColor the image is read in any possible color format.
	IMReadAnyColor IMReadFlag = 4

	// IMReadLoadGDAL uses the gdal driver for loading the image.
	IMReadLoadGDAL IMReadFlag = 8

	// IMReadReducedGrayscale2 always converts image to the single channel grayscale image
	// and the image size reduced 1/2.
	IMReadReducedGrayscale2 IMReadFlag = 16

	// IMReadReducedColor2 always converts image to the 3 channel BGR color image and the
	// image size reduced 1/2.
	IMReadReducedColor2 IMReadFlag = 17

	// IMReadReducedGrayscale4 always converts image to the single channel grayscale image and
	// the image size reduced 1/4.
	IMReadReducedGrayscale4 IMReadFlag = 32

	// IMReadReducedColor4 always converts image to the 3 channel BGR color image and
	// the image size reduced 1/4.
	IMReadReducedColor4 IMReadFlag = 33

	// IMReadReducedGrayscale8 always convert image to the single channel grayscale image and
	// the image size reduced 1/8.
	IMReadReducedGrayscale8 IMReadFlag = 64

	// IMReadReducedColor8 always convert image to the 3 channel BGR color image and the
	// image size reduced 1/8.
	IMReadReducedColor8 IMReadFlag = 65

	// IMReadIgnoreOrientation do not rotate the image according to EXIF's orientation flag.
	IMReadIgnoreOrientation IMReadFlag = 128
)

type InterpolationFlags

type InterpolationFlags int

InterpolationFlags are bit flags that control the interpolation algorithm that is used.

const (
	// InterpolationNearestNeighbor is nearest neighbor. (fast but low quality)
	InterpolationNearestNeighbor InterpolationFlags = 0

	// InterpolationLinear is bilinear interpolation.
	InterpolationLinear InterpolationFlags = 1

	// InterpolationCubic is bicube interpolation.
	InterpolationCubic InterpolationFlags = 2

	// InterpolationArea uses pixel area relation. It is preferred for image
	// decimation as it gives moire-free results.
	InterpolationArea InterpolationFlags = 3

	// InterpolationLanczos4 is Lanczos interpolation over 8x8 neighborhood.
	InterpolationLanczos4 InterpolationFlags = 4

	// InterpolationDefault is an alias for InterpolationLinear.
	InterpolationDefault = InterpolationLinear

	// InterpolationMax indicates use maximum interpolation.
	InterpolationMax InterpolationFlags = 7

	// WarpFillOutliers fills all of the destination image pixels. If some of them correspond to outliers in the source image, they are set to zero.
	WarpFillOutliers = 8

	// WarpInverseMap, inverse transformation.
	WarpInverseMap = 16
)

func (InterpolationFlags) String

func (c InterpolationFlags) String() string

type KAZE

type KAZE struct {
	// contains filtered or unexported fields
}

KAZE is a wrapper around the cv::KAZE algorithm.

func NewKAZE

func NewKAZE() KAZE

NewKAZE returns a new KAZE algorithm

For further details, please see: https://docs.opencv.org/master/d3/d61/classcv_1_1KAZE.html

func (*KAZE) Close

func (a *KAZE) Close() error

Close KAZE.

func (*KAZE) Detect

func (a *KAZE) Detect(src Mat) []KeyPoint

Detect keypoints in an image using KAZE.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

func (*KAZE) DetectAndCompute

func (a *KAZE) DetectAndCompute(src Mat, mask Mat) ([]KeyPoint, Mat)

DetectAndCompute keypoints and compute in an image using KAZE.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#a8be0d1c20b08eb867184b8d74c15a677

type KMeansFlags

type KMeansFlags int

KMeansFlags for kmeans center selection

For further details, please see: https://docs.opencv.org/master/d0/de1/group__core.html#ga276000efe55ee2756e0c471c7b270949

const (
	// KMeansRandomCenters selects random initial centers in each attempt.
	KMeansRandomCenters KMeansFlags = 0
	// KMeansPPCenters uses kmeans++ center initialization by Arthur and Vassilvitskii [Arthur2007].
	KMeansPPCenters KMeansFlags = 1
	// KMeansUseInitialLabels uses the user-supplied lables during the first (and possibly the only) attempt
	// instead of computing them from the initial centers. For the second and further attempts, use the random or semi-random     // centers. Use one of KMEANS_*_CENTERS flag to specify the exact method.
	KMeansUseInitialLabels KMeansFlags = 2
)

func (KMeansFlags) String

func (c KMeansFlags) String() string

type KeyPoint

type KeyPoint struct {
	X, Y                  float64
	Size, Angle, Response float64
	Octave, ClassID       int
}

KeyPoint is data structure for salient point detectors.

For further details, please see: https://docs.opencv.org/master/d2/d29/classcv_1_1KeyPoint.html

type Layer

type Layer struct {
	// contains filtered or unexported fields
}

Layer is a wrapper around the cv::dnn::Layer algorithm.

func (*Layer) Close

func (l *Layer) Close() error

Close Layer

func (*Layer) GetName

func (l *Layer) GetName() string

GetName returns name for this layer.

func (*Layer) GetType

func (l *Layer) GetType() string

GetType returns type for this layer.

func (*Layer) InputNameToIndex

func (l *Layer) InputNameToIndex(name string) int

InputNameToIndex returns index of input blob in input array.

For further details, please see: https://docs.opencv.org/master/d3/d6c/classcv_1_1dnn_1_1Layer.html#a60ffc8238f3fa26cd3f49daa7ac0884b

func (*Layer) OutputNameToIndex

func (l *Layer) OutputNameToIndex(name string) int

OutputNameToIndex returns index of output blob in output array.

For further details, please see: https://docs.opencv.org/master/d3/d6c/classcv_1_1dnn_1_1Layer.html#a60ffc8238f3fa26cd3f49daa7ac0884b

type LineType

type LineType int

LineType are the line libraries included in OpenCV.

For more information, see: https://vovkos.github.io/doxyrest-showcase/opencv/sphinx_rtd_theme/enum_cv_LineTypes.html

const (
	// Filled line
	Filled LineType = -1
	// Line4 4-connected line
	Line4 LineType = 4
	// Line8 8-connected line
	Line8 LineType = 8
	// LineAA antialiased line
	LineAA LineType = 16
)

func (LineType) String

func (c LineType) String() string

type MSER

type MSER struct {
	// contains filtered or unexported fields
}

MSER is a wrapper around the cv::MSER algorithm.

func NewMSER

func NewMSER() MSER

NewMSER returns a new MSER algorithm

For further details, please see: https://docs.opencv.org/master/d3/d28/classcv_1_1MSER.html

func (*MSER) Close

func (a *MSER) Close() error

Close MSER.

func (*MSER) Detect

func (a *MSER) Detect(src Mat) []KeyPoint

Detect keypoints in an image using MSER.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

type Mat

type Mat struct {
	// contains filtered or unexported fields
}

Mat represents an n-dimensional dense numerical single-channel or multi-channel array. It can be used to store real or complex-valued vectors and matrices, grayscale or color images, voxel volumes, vector fields, point clouds, tensors, and histograms.

For further details, please see: http://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html

func BlobFromImage

func BlobFromImage(img Mat, scaleFactor float64, size image.Point, mean Scalar,
	swapRB bool, crop bool) Mat

BlobFromImage creates 4-dimensional blob from image. Optionally resizes and crops image from center, subtract mean values, scales values by scalefactor, swap Blue and Red channels.

For further details, please see: https://docs.opencv.org/trunk/d6/d0f/group__dnn.html#ga152367f253c81b53fe6862b299f5c5cd

func EstimateAffine2D

func EstimateAffine2D(from, to Point2fVector) Mat

EstimateAffine2D Computes an optimal affine transformation between two 2D point sets.

For further details, please see: https://docs.opencv.org/4.0.0/d9/d0c/group__calib3d.html#ga27865b1d26bac9ce91efaee83e94d4dd

func EstimateAffine2DWithParams

func EstimateAffine2DWithParams(from Point2fVector, to Point2fVector, inliers Mat, method int, ransacReprojThreshold float64, maxIters uint, confidence float64, refineIters uint) Mat

EstimateAffine2DWithParams Computes an optimal affine transformation between two 2D point sets with additional optional parameters.

For further details, please see: https://docs.opencv.org/4.0.0/d9/d0c/group__calib3d.html#ga27865b1d26bac9ce91efaee83e94d4dd

func EstimateAffinePartial2D

func EstimateAffinePartial2D(from, to Point2fVector) Mat

EstimateAffinePartial2D computes an optimal limited affine transformation with 4 degrees of freedom between two 2D point sets.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#gad767faff73e9cbd8b9d92b955b50062d

func Eye

func Eye(rows int, cols int, mt MatType) Mat

Returns an identity matrix of the specified size and type.

The method returns a Matlab-style identity matrix initializer, similarly to Mat::zeros. Similarly to Mat::ones. For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#a2cf9b9acde7a9852542bbc20ef851ed2

func FindHomography

func FindHomography(srcPoints Mat, dstPoints *Mat, method HomographyMethod, ransacReprojThreshold float64, mask *Mat, maxIters int, confidence float64) Mat

FindHomography finds an optimal homography matrix using 4 or more point pairs (as opposed to GetPerspectiveTransform, which uses exactly 4)

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga4abc2ece9fab9398f2e560d53c8c9780

func GetAffineTransform

func GetAffineTransform(src, dst PointVector) Mat

GetAffineTransform returns a 2x3 affine transformation matrix for the corresponding 3 point pairs as image.Point.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga8f6d378f9f8eebb5cb55cd3ae295a999

func GetAffineTransform2f

func GetAffineTransform2f(src, dst Point2fVector) Mat

GetAffineTransform2f returns a 2x3 affine transformation matrix for the corresponding 3 point pairs as gocv.Point2f.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga8f6d378f9f8eebb5cb55cd3ae295a999

func GetBlobChannel

func GetBlobChannel(blob Mat, imgidx int, chnidx int) Mat

GetBlobChannel extracts a single (2d)channel from a 4 dimensional blob structure (this might e.g. contain the results of a SSD or YOLO detection,

a bones structure from pose detection, or a color plane from Colorization)

func GetGaussianKernel

func GetGaussianKernel(ksize int, sigma float64) Mat

GetGaussianKernel returns Gaussian filter coefficients.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gac05a120c1ae92a6060dd0db190a61afa

func GetGaussianKernelWithParams

func GetGaussianKernelWithParams(ksize int, sigma float64, ktype MatType) Mat

GetGaussianKernelWithParams returns Gaussian filter coefficients.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gac05a120c1ae92a6060dd0db190a61afa

func GetOptimalNewCameraMatrixWithParams

func GetOptimalNewCameraMatrixWithParams(cameraMatrix Mat, distCoeffs Mat, imageSize image.Point, alpha float64, newImgSize image.Point, centerPrincipalPoint bool) (Mat, image.Rectangle)

GetOptimalNewCameraMatrixWithParams computes and returns the optimal new camera matrix based on the free scaling parameter.

For further details, please see: https://docs.opencv.org/master/d9/d0c/group__calib3d.html#ga7a6c4e032c97f03ba747966e6ad862b1

func GetPerspectiveTransform

func GetPerspectiveTransform(src, dst PointVector) Mat

GetPerspectiveTransform returns 3x3 perspective transformation for the corresponding 4 point pairs as image.Point.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga8c1ae0e3589a9d77fffc962c49b22043

func GetPerspectiveTransform2f

func GetPerspectiveTransform2f(src, dst Point2fVector) Mat

GetPerspectiveTransform2f returns 3x3 perspective transformation for the corresponding 4 point pairs as gocv.Point2f.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#ga8c1ae0e3589a9d77fffc962c49b22043

func GetRotationMatrix2D

func GetRotationMatrix2D(center image.Point, angle, scale float64) Mat

GetRotationMatrix2D calculates an affine matrix of 2D rotation.

For further details, please see: https://docs.opencv.org/master/da/d54/group__imgproc__transform.html#gafbbc470ce83812914a70abfb604f4326

func GetStructuringElement

func GetStructuringElement(shape MorphShape, ksize image.Point) Mat

GetStructuringElement returns a structuring element of the specified size and shape for morphological operations.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#gac342a1bb6eabf6f55c803b09268e36dc

func HOGDefaultPeopleDetector

func HOGDefaultPeopleDetector() Mat

HOGDefaultPeopleDetector returns a new Mat with the HOG DefaultPeopleDetector.

For further details, please see: https://docs.opencv.org/master/d5/d33/structcv_1_1HOGDescriptor.html#a660e5cd036fd5ddf0f5767b352acd948

func IMDecode

func IMDecode(buf []byte, flags IMReadFlag) (Mat, error)

IMDecode reads an image from a buffer in memory. The function IMDecode reads an image from the specified buffer in memory. If the buffer is too short or contains invalid data, the function returns an empty matrix.

For further details, please see: https://docs.opencv.org/master/d4/da8/group__imgcodecs.html#ga26a67788faa58ade337f8d28ba0eb19e

func IMRead

func IMRead(name string, flags IMReadFlag) Mat

IMRead reads an image from a file into a Mat. The flags param is one of the IMReadFlag flags. If the image cannot be read (because of missing file, improper permissions, unsupported or invalid format), the function returns an empty Mat.

For further details, please see: http://docs.opencv.org/master/d4/da8/group__imgcodecs.html#ga288b8b3da0892bd651fce07b3bbd3a56

func ImageGrayToMatGray

func ImageGrayToMatGray(img *image.Gray) (Mat, error)

ImageGrayToMatGray converts image.Gray to gocv.Mat, which represents grayscale image 8bit. Type of Mat is gocv.MatTypeCV8UC1.

func ImageToMatRGB

func ImageToMatRGB(img image.Image) (Mat, error)

ImageToMatRGB converts image.Image to gocv.Mat, which represents RGB image having 8bit for each component. Type of Mat is gocv.MatTypeCV8UC3.

func ImageToMatRGBA

func ImageToMatRGBA(img image.Image) (Mat, error)

ImageToMatRGBA converts image.Image to gocv.Mat, which represents RGBA image having 8bit for each component. Type of Mat is gocv.MatTypeCV8UC4.

func NewMat

func NewMat() Mat

NewMat returns a new empty Mat.

func NewMatFromBytes

func NewMatFromBytes(rows int, cols int, mt MatType, data []byte) (Mat, error)

NewMatFromBytes returns a new Mat with a specific size and type, initialized from a []byte.

func NewMatFromScalar

func NewMatFromScalar(s Scalar, mt MatType) Mat

NewMatFromScalar returns a new Mat for a specific Scalar value

func NewMatWithSize

func NewMatWithSize(rows int, cols int, mt MatType) Mat

NewMatWithSize returns a new Mat with a specific size and type.

func NewMatWithSizeFromScalar

func NewMatWithSizeFromScalar(s Scalar, rows int, cols int, mt MatType) Mat

NewMatWithSizeFromScalar returns a new Mat for a specific Scala value with a specific size and type This simplifies creation of specific color filters or creating Mats of specific colors and sizes

func NewMatWithSizes

func NewMatWithSizes(sizes []int, mt MatType) Mat

NewMatWithSizes returns a new multidimensional Mat with a specific size and type.

func NewMatWithSizesFromBytes

func NewMatWithSizesFromBytes(sizes []int, mt MatType, data []byte) (Mat, error)

NewMatWithSizesWithScalar returns a new multidimensional Mat with a specific size, type and preexisting data.

func NewMatWithSizesWithScalar

func NewMatWithSizesWithScalar(sizes []int, mt MatType, s Scalar) Mat

NewMatWithSizesWithScalar returns a new multidimensional Mat with a specific size, type and scalar value.

func Ones

func Ones(rows int, cols int, mt MatType) Mat

Returns an array of all 1's of the specified size and type.

The method returns a Matlab-style 1's array initializer For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#a69ae0402d116fc9c71908d8508dc2f09

func Split

func Split(src Mat) (mv []Mat)

Split creates an array of single channel images from a multi-channel image Created images should be closed manualy to avoid memory leaks.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga0547c7fed86152d7e9d0096029c8518a

func Zeros

func Zeros(rows int, cols int, mt MatType) Mat

Returns a zero array of the specified size and type.

The method returns a Matlab-style zero array initializer. For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#a0b57b6a326c8876d944d188a46e0f556

func (*Mat) AddFloat

func (m *Mat) AddFloat(val float32)

AddFloat adds a float value to each element in the Mat. Performs a mat += val operation.

func (*Mat) AddUChar

func (m *Mat) AddUChar(val uint8)

AddUChar adds a uchar value to each element in the Mat. Performs a mat += val operation.

func (*Mat) Channels

func (m *Mat) Channels() int

Channels returns the number of channels for this Mat.

func (*Mat) Clone

func (m *Mat) Clone() Mat

Clone returns a cloned full copy of the Mat.

func (*Mat) Close

func (m *Mat) Close() error

Close the Mat object.

func (*Mat) ColRange

func (m *Mat) ColRange(start, end int) Mat

ColRange creates a matrix header for the specified column span.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#aadc8f9210fe4dec50513746c246fa8d9

func (*Mat) Cols

func (m *Mat) Cols() int

Cols returns the number of columns for this Mat.

func (*Mat) ConvertFp16

func (m *Mat) ConvertFp16() Mat

ConvertFp16 converts a Mat to half-precision floating point.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga9c25d9ef44a2a48ecc3774b30cb80082

func (*Mat) ConvertTo

func (m *Mat) ConvertTo(dst *Mat, mt MatType)

ConvertTo converts Mat into destination Mat.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#adf88c60c5b4980e05bb556080916978b

func (*Mat) ConvertToWithParams

func (m *Mat) ConvertToWithParams(dst *Mat, mt MatType, alpha, beta float32)

func (*Mat) CopyTo

func (m *Mat) CopyTo(dst *Mat)

CopyTo copies Mat into destination Mat.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#a33fd5d125b4c302b0c9aa86980791a77

func (*Mat) CopyToWithMask

func (m *Mat) CopyToWithMask(dst *Mat, mask Mat)

CopyToWithMask copies Mat into destination Mat after applying the mask Mat.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#a626fe5f96d02525e2604d2ad46dd574f

func (*Mat) DataPtrFloat32

func (m *Mat) DataPtrFloat32() ([]float32, error)

DataPtrFloat32 returns a slice that references the OpenCV allocated data.

The data is no longer valid once the Mat has been closed. Any data that needs to be accessed after the Mat is closed must be copied into Go memory.

func (*Mat) DataPtrFloat64

func (m *Mat) DataPtrFloat64() ([]float64, error)

DataPtrFloat64 returns a slice that references the OpenCV allocated data.

The data is no longer valid once the Mat has been closed. Any data that needs to be accessed after the Mat is closed must be copied into Go memory.

func (*Mat) DataPtrInt16

func (m *Mat) DataPtrInt16() ([]int16, error)

DataPtrInt16 returns a slice that references the OpenCV allocated data.

The data is no longer valid once the Mat has been closed. Any data that needs to be accessed after the Mat is closed must be copied into Go memory.

func (*Mat) DataPtrInt8

func (m *Mat) DataPtrInt8() ([]int8, error)

DataPtrInt8 returns a slice that references the OpenCV allocated data.

The data is no longer valid once the Mat has been closed. Any data that needs to be accessed after the Mat is closed must be copied into Go memory.

func (*Mat) DataPtrUint16

func (m *Mat) DataPtrUint16() ([]uint16, error)

DataPtrUint16 returns a slice that references the OpenCV allocated data.

The data is no longer valid once the Mat has been closed. Any data that needs to be accessed after the Mat is closed must be copied into Go memory.

func (*Mat) DataPtrUint8

func (m *Mat) DataPtrUint8() ([]uint8, error)

DataPtrUint8 returns a slice that references the OpenCV allocated data.

The data is no longer valid once the Mat has been closed. Any data that needs to be accessed after the Mat is closed must be copied into Go memory.

func (*Mat) DivideFloat

func (m *Mat) DivideFloat(val float32)

DivideFloat divides each element in the Mat by a float value. Performs a mat /= val operation.

func (*Mat) DivideUChar

func (m *Mat) DivideUChar(val uint8)

DivideUChar divides each element in the Mat by a uint value. Performs a mat /= val operation.

func (*Mat) ElemSize

func (m *Mat) ElemSize() int

ElemSize returns the matrix element size in bytes.

func (*Mat) Empty

func (m *Mat) Empty() bool

Empty determines if the Mat is empty or not.

func (*Mat) FromPtr

func (m *Mat) FromPtr(rows int, cols int, mt MatType, prow int, pcol int) (Mat, error)

FromPtr returns a new Mat with a specific size and type, initialized from a Mat Ptr.

func (*Mat) GetDoubleAt

func (m *Mat) GetDoubleAt(row int, col int) float64

GetDoubleAt returns a value from a specific row/col in this Mat expecting it to be of type double aka CV_64F.

func (*Mat) GetDoubleAt3

func (m *Mat) GetDoubleAt3(x, y, z int) float64

GetDoubleAt3 returns a value from a specific x, y, z coordinate location in this Mat expecting it to be of type double aka CV_64F.

func (*Mat) GetFloatAt

func (m *Mat) GetFloatAt(row int, col int) float32

GetFloatAt returns a value from a specific row/col in this Mat expecting it to be of type float aka CV_32F.

func (*Mat) GetFloatAt3

func (m *Mat) GetFloatAt3(x, y, z int) float32

GetFloatAt3 returns a value from a specific x, y, z coordinate location in this Mat expecting it to be of type float aka CV_32F.

func (*Mat) GetIntAt

func (m *Mat) GetIntAt(row int, col int) int32

GetIntAt returns a value from a specific row/col in this Mat expecting it to be of type int aka CV_32S.

func (*Mat) GetIntAt3

func (m *Mat) GetIntAt3(x, y, z int) int32

GetIntAt3 returns a value from a specific x, y, z coordinate location in this Mat expecting it to be of type int aka CV_32S.

func (*Mat) GetSCharAt

func (m *Mat) GetSCharAt(row int, col int) int8

GetSCharAt returns a value from a specific row/col in this Mat expecting it to be of type schar aka CV_8S.

func (*Mat) GetSCharAt3

func (m *Mat) GetSCharAt3(x, y, z int) int8

GetSCharAt3 returns a value from a specific x, y, z coordinate location in this Mat expecting it to be of type schar aka CV_8S.

func (*Mat) GetShortAt

func (m *Mat) GetShortAt(row int, col int) int16

GetShortAt returns a value from a specific row/col in this Mat expecting it to be of type short aka CV_16S.

func (*Mat) GetShortAt3

func (m *Mat) GetShortAt3(x, y, z int) int16

GetShortAt3 returns a value from a specific x, y, z coordinate location in this Mat expecting it to be of type short aka CV_16S.

func (*Mat) GetUCharAt

func (m *Mat) GetUCharAt(row int, col int) uint8

GetUCharAt returns a value from a specific row/col in this Mat expecting it to be of type uchar aka CV_8U.

func (*Mat) GetUCharAt3

func (m *Mat) GetUCharAt3(x, y, z int) uint8

GetUCharAt3 returns a value from a specific x, y, z coordinate location in this Mat expecting it to be of type uchar aka CV_8U.

func (*Mat) GetVecbAt

func (m *Mat) GetVecbAt(row int, col int) Vecb

GetVecbAt returns a vector of bytes. Its size corresponds to the number of channels of the Mat.

func (*Mat) GetVecdAt

func (m *Mat) GetVecdAt(row int, col int) Vecd

GetVecdAt returns a vector of float64s. Its size corresponds to the number of channels of the Mat.

func (*Mat) GetVecfAt

func (m *Mat) GetVecfAt(row int, col int) Vecf

GetVecfAt returns a vector of floats. Its size corresponds to the number of channels of the Mat.

func (*Mat) GetVeciAt

func (m *Mat) GetVeciAt(row int, col int) Veci

GetVeciAt returns a vector of integers. Its size corresponds to the number of channels of the Mat.

func (*Mat) IsContinuous

func (m *Mat) IsContinuous() bool

IsContinuous determines if the Mat is continuous.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#aa90cea495029c7d1ee0a41361ccecdf3

func (*Mat) Mean

func (m *Mat) Mean() Scalar

Mean calculates the mean value M of array elements, independently for each channel, and return it as Scalar For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga191389f8a0e58180bb13a727782cd461

func (*Mat) MeanWithMask

func (m *Mat) MeanWithMask(mask Mat) Scalar

MeanWithMask calculates the mean value M of array elements,independently for each channel, and returns it as Scalar vector while applying the mask. https://docs.opencv.org/master/d2/de8/group__core__array.html#ga191389f8a0e58180bb13a727782cd461

func (*Mat) MultiplyFloat

func (m *Mat) MultiplyFloat(val float32)

MultiplyFloat multiplies each element in the Mat by a float value. Performs a mat *= val operation.

func (*Mat) MultiplyMatrix

func (m *Mat) MultiplyMatrix(x Mat) Mat

MultiplyMatrix multiplies matrix (m*x)

func (*Mat) MultiplyUChar

func (m *Mat) MultiplyUChar(val uint8)

MultiplyUChar multiplies each element in the Mat by a uint value. Performs a mat *= val operation.

func (*Mat) PatchNaNs

func (m *Mat) PatchNaNs()

PatchNaNs converts NaN's to zeros.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga62286befb7cde3568ff8c7d14d5079da

func (*Mat) Ptr

func (m *Mat) Ptr() C.Mat

Ptr returns the Mat's underlying object pointer.

func (*Mat) Region

func (m *Mat) Region(rio image.Rectangle) Mat

Region returns a new Mat that points to a region of this Mat. Changes made to the region Mat will affect the original Mat, since they are pointers to the underlying OpenCV Mat object.

func (*Mat) Reshape

func (m *Mat) Reshape(cn int, rows int) Mat

Reshape changes the shape and/or the number of channels of a 2D matrix without copying the data.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#a4eb96e3251417fa88b78e2abd6cfd7d8

func (*Mat) RowRange

func (m *Mat) RowRange(start, end int) Mat

RowRange creates a matrix header for the specified row span.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#aa6542193430356ad631a9beabc624107

func (*Mat) Rows

func (m *Mat) Rows() int

Rows returns the number of rows for this Mat.

func (*Mat) SetDoubleAt

func (m *Mat) SetDoubleAt(row int, col int, val float64)

SetDoubleAt sets a value at a specific row/col in this Mat expecting it to be of type double aka CV_64F.

func (*Mat) SetDoubleAt3

func (m *Mat) SetDoubleAt3(x, y, z int, val float64)

SetDoubleAt3 sets a value at a specific x, y, z coordinate location in this Mat expecting it to be of type double aka CV_64F.

func (*Mat) SetFloatAt

func (m *Mat) SetFloatAt(row int, col int, val float32)

SetFloatAt sets a value at a specific row/col in this Mat expecting it to be of type float aka CV_32F.

func (*Mat) SetFloatAt3

func (m *Mat) SetFloatAt3(x, y, z int, val float32)

SetFloatAt3 sets a value at a specific x, y, z coordinate location in this Mat expecting it to be of type float aka CV_32F.

func (*Mat) SetIntAt

func (m *Mat) SetIntAt(row int, col int, val int32)

SetIntAt sets a value at a specific row/col in this Mat expecting it to be of type int aka CV_32S.

func (*Mat) SetIntAt3

func (m *Mat) SetIntAt3(x, y, z int, val int32)

SetIntAt3 sets a value at a specific x, y, z coordinate location in this Mat expecting it to be of type int aka CV_32S.

func (*Mat) SetSCharAt

func (m *Mat) SetSCharAt(row int, col int, val int8)

SetSCharAt sets a value at a specific row/col in this Mat expecting it to be of type schar aka CV_8S.

func (*Mat) SetSCharAt3

func (m *Mat) SetSCharAt3(x, y, z int, val int8)

SetSCharAt3 sets a value at a specific x, y, z coordinate location in this Mat expecting it to be of type schar aka CV_8S.

func (*Mat) SetShortAt

func (m *Mat) SetShortAt(row int, col int, val int16)

SetShortAt sets a value at a specific row/col in this Mat expecting it to be of type short aka CV_16S.

func (*Mat) SetShortAt3

func (m *Mat) SetShortAt3(x, y, z int, val int16)

SetShortAt3 sets a value at a specific x, y, z coordinate location in this Mat expecting it to be of type short aka CV_16S.

func (*Mat) SetTo

func (m *Mat) SetTo(s Scalar)

SetTo sets all or some of the array elements to the specified scalar value.

func (*Mat) SetUCharAt

func (m *Mat) SetUCharAt(row int, col int, val uint8)

SetUCharAt sets a value at a specific row/col in this Mat expecting it to be of type uchar aka CV_8U.

func (*Mat) SetUCharAt3

func (m *Mat) SetUCharAt3(x, y, z int, val uint8)

SetUCharAt3 sets a value at a specific x, y, z coordinate location in this Mat expecting it to be of type uchar aka CV_8U.

func (*Mat) Size

func (m *Mat) Size() (dims []int)

Size returns an array with one element for each dimension containing the size of that dimension for the Mat.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#aa4d317d43fb0cba9c2503f3c61b866c8

func (*Mat) Sqrt

func (m *Mat) Sqrt() Mat

Sqrt calculates a square root of array elements.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga186222c3919657890f88df5a1f64a7d7

func (*Mat) Step

func (m *Mat) Step() int

Step returns the number of bytes each matrix row occupies.

func (*Mat) SubtractFloat

func (m *Mat) SubtractFloat(val float32)

SubtractFloat subtracts a float value from each element in the Mat. Performs a mat -= val operation.

func (*Mat) SubtractUChar

func (m *Mat) SubtractUChar(val uint8)

SubtractUChar subtracts a uchar value from each element in the Mat. Performs a mat -= val operation.

func (*Mat) Sum

func (m *Mat) Sum() Scalar

Sum calculates the per-channel pixel sum of an image.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga716e10a2dd9e228e4d3c95818f106722

func (*Mat) ToBytes

func (m *Mat) ToBytes() []byte

ToBytes copies the underlying Mat data to a byte array.

For further details, please see: https://docs.opencv.org/3.3.1/d3/d63/classcv_1_1Mat.html#a4d33bed1c850265370d2af0ff02e1564

func (*Mat) ToImage

func (m *Mat) ToImage() (image.Image, error)

ToImage converts a Mat to a image.Image.

func (*Mat) ToImageYUV

func (m *Mat) ToImageYUV() (*image.YCbCr, error)

ToImageYUV converts a Mat to a image.YCbCr using image.YCbCrSubsampleRatio420 as default subsampling param.

func (*Mat) ToImageYUVWithParams

func (m *Mat) ToImageYUVWithParams(ratio image.YCbCrSubsampleRatio) (*image.YCbCr, error)

ToImageYUV converts a Mat to a image.YCbCr using provided YUV subsample ratio param.

func (*Mat) Total

func (m *Mat) Total() int

Total returns the total number of array elements.

For further details, please see: https://docs.opencv.org/master/d3/d63/classcv_1_1Mat.html#aa4d317d43fb0cba9c2503f3c61b866c8

func (*Mat) Type

func (m *Mat) Type() MatType

Type returns the type for this Mat.

type MatType

type MatType int

MatType is the type for the various different kinds of Mat you can create.

func (MatType) String

func (c MatType) String() string

type MergeMertens

type MergeMertens struct {
	// contains filtered or unexported fields
}

MergeMertens is a wrapper around the cv::MergeMertens.

func NewMergeMertens

func NewMergeMertens() MergeMertens

NewMergeMertens returns returns a new MergeMertens white LDR merge algorithm. of type MergeMertens with default parameters. MergeMertens algorithm merge the ldr image should result in a HDR image.

For further details, please see: https://docs.opencv.org/master/d6/df5/group__photo__hdr.html https://docs.opencv.org/master/d7/dd6/classcv_1_1MergeMertens.html https://docs.opencv.org/master/d6/df5/group__photo__hdr.html#ga79d59aa3cb3a7c664e59a4b5acc1ccb6

func NewMergeMertensWithParams

func NewMergeMertensWithParams(contrast_weight float32, saturation_weight float32, exposure_weight float32) MergeMertens

NewMergeMertensWithParams returns a new MergeMertens white LDR merge algorithm of type MergeMertens with customized parameters. MergeMertens algorithm merge the ldr image should result in a HDR image.

For further details, please see: https://docs.opencv.org/master/d6/df5/group__photo__hdr.html https://docs.opencv.org/master/d7/dd6/classcv_1_1MergeMertens.html https://docs.opencv.org/master/d6/df5/group__photo__hdr.html#ga79d59aa3cb3a7c664e59a4b5acc1ccb6

func (*MergeMertens) Close

func (b *MergeMertens) Close() error

Close MergeMertens.

func (*MergeMertens) Process

func (b *MergeMertens) Process(src []Mat, dst *Mat)

BalanceWhite computes merge LDR images using the current MergeMertens. Return a image MAT : 8bits 3 channel image ( RGB 8 bits ) For further details, please see: https://docs.opencv.org/master/d7/dd6/classcv_1_1MergeMertens.html#a2d2254b2aab722c16954de13a663644d

type MorphShape

type MorphShape int

MorphShape is the shape of the structuring element used for Morphing operations.

const (
	// MorphRect is the rectangular morph shape.
	MorphRect MorphShape = 0

	// MorphCross is the cross morph shape.
	MorphCross MorphShape = 1

	// MorphEllipse is the ellipse morph shape.
	MorphEllipse MorphShape = 2
)

func (MorphShape) String

func (c MorphShape) String() string

type MorphType

type MorphType int

MorphType type of morphological operation.

const (
	// MorphErode operation
	MorphErode MorphType = 0

	// MorphDilate operation
	MorphDilate MorphType = 1

	// MorphOpen operation
	MorphOpen MorphType = 2

	// MorphClose operation
	MorphClose MorphType = 3

	// MorphGradient operation
	MorphGradient MorphType = 4

	// MorphTophat operation
	MorphTophat MorphType = 5

	// MorphBlackhat operation
	MorphBlackhat MorphType = 6

	// MorphHitmiss operation
	MorphHitmiss MorphType = 7
)

func (MorphType) String

func (c MorphType) String() string

type NativeByteBuffer

type NativeByteBuffer struct {
	// contains filtered or unexported fields
}

func IMEncode

func IMEncode(fileExt FileExt, img Mat) (buf *NativeByteBuffer, err error)

IMEncode encodes an image Mat into a memory buffer. This function compresses the image and stores it in the returned memory buffer, using the image format passed in in the form of a file extension string.

For further details, please see: http://docs.opencv.org/master/d4/da8/group__imgcodecs.html#ga461f9ac09887e47797a54567df3b8b63

func IMEncodeWithParams

func IMEncodeWithParams(fileExt FileExt, img Mat, params []int) (buf *NativeByteBuffer, err error)

IMEncodeWithParams encodes an image Mat into a memory buffer. This function compresses the image and stores it in the returned memory buffer, using the image format passed in in the form of a file extension string.

Usage example:

buffer, err := gocv.IMEncodeWithParams(gocv.JPEGFileExt, img, []int{gocv.IMWriteJpegQuality, quality})

For further details, please see: http://docs.opencv.org/master/d4/da8/group__imgcodecs.html#ga461f9ac09887e47797a54567df3b8b63

Example
img := IMRead(path.Join(os.Getenv("GOPATH"), "src/gocv.io/x/gocv/images/face-detect.jpg"), IMReadColor)
if img.Empty() {
	log.Fatal("Invalid Mat")
}

imgHandler := func(w http.ResponseWriter, req *http.Request) {
	quality := 75
	if q, err := strconv.Atoi(req.URL.Query().Get("q")); err == nil {
		quality = q
	}
	buffer, err := IMEncodeWithParams(JPEGFileExt, img, []int{IMWriteJpegQuality, quality})
	if err != nil {
		w.WriteHeader(http.StatusInternalServerError)
		io.WriteString(w, err.Error())
		return
	}
	defer buffer.Close()
	w.Header().Set("Content-Type", "image/jpeg")
	w.WriteHeader(http.StatusOK)
	w.Write(buffer.GetBytes())
}

http.HandleFunc("/img", imgHandler)
fmt.Println("Open in browser http://127.0.0.1:8080/img?q=10 where q is a JPEG quality parameter")
log.Fatal(http.ListenAndServe("127.0.0.1:8080", nil))
Output:

func (*NativeByteBuffer) Close

func (buffer *NativeByteBuffer) Close()

Close the buffer releasing all its resources

func (*NativeByteBuffer) GetBytes

func (buffer *NativeByteBuffer) GetBytes() []byte

GetBytes returns slice of bytes backed by native buffer

func (*NativeByteBuffer) Len

func (buffer *NativeByteBuffer) Len() int

Len - returns length in bytes of underlying buffer

type Net

type Net struct {
	// contains filtered or unexported fields
}

Net allows you to create and manipulate comprehensive artificial neural networks.

For further details, please see: https://docs.opencv.org/master/db/d30/classcv_1_1dnn_1_1Net.html

func ReadNet

func ReadNet(model string, config string) Net

ReadNet reads a deep learning network represented in one of the supported formats.

For further details, please see: https://docs.opencv.org/3.4/d6/d0f/group__dnn.html#ga3b34fe7a29494a6a4295c169a7d32422

func ReadNetBytes

func ReadNetBytes(framework string, model []byte, config []byte) (Net, error)

ReadNetBytes reads a deep learning network represented in one of the supported formats.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga138439da76f26266fdefec9723f6c5cd

func ReadNetFromCaffe

func ReadNetFromCaffe(prototxt string, caffeModel string) Net

ReadNetFromCaffe reads a network model stored in Caffe framework's format.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga29d0ea5e52b1d1a6c2681e3f7d68473a

func ReadNetFromCaffeBytes

func ReadNetFromCaffeBytes(prototxt []byte, caffeModel []byte) (Net, error)

ReadNetFromCaffeBytes reads a network model stored in Caffe model in memory.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga946b342af1355185a7107640f868b64a

func ReadNetFromONNX

func ReadNetFromONNX(model string) Net

ReadNetFromONNX reads a network model stored in ONNX framework's format.

check net.Empty() for read failure

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga7faea56041d10c71dbbd6746ca854197

func ReadNetFromONNXBytes

func ReadNetFromONNXBytes(model []byte) (Net, error)

ReadNetFromONNXBytes reads a network model stored in ONNX framework's format.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#ga9198ecaac7c32ddf0aa7a1bcbd359567

func ReadNetFromTensorflow

func ReadNetFromTensorflow(model string) Net

ReadNetFromTensorflow reads a network model stored in Tensorflow framework's format.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#gad820b280978d06773234ba6841e77e8d

func ReadNetFromTensorflowBytes

func ReadNetFromTensorflowBytes(model []byte) (Net, error)

ReadNetFromTensorflowBytes reads a network model stored in Tensorflow framework's format.

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#gacdba30a7c20db2788efbf5bb16a7884d

func ReadNetFromTorch

func ReadNetFromTorch(model string) Net

ReadNetFromTorch reads a network model stored in Torch framework's format (t7).

check net.Empty() for read failure

For further details, please see: https://docs.opencv.org/master/d6/d0f/group__dnn.html#gaaaed8c8530e9e92fe6647700c13d961e

func (*Net) Close

func (net *Net) Close() error

Close Net

func (*Net) Empty

func (net *Net) Empty() bool

Empty returns true if there are no layers in the network.

For further details, please see: https://docs.opencv.org/master/db/d30/classcv_1_1dnn_1_1Net.html#a6a5778787d5b8770deab5eda6968e66c

func (*Net) Forward

func (net *Net) Forward(outputName string) Mat

Forward runs forward pass to compute output of layer with name outputName.

For further details, please see: https://docs.opencv.org/trunk/db/d30/classcv_1_1dnn_1_1Net.html#a98ed94cb6ef7063d3697259566da310b

func (*Net) ForwardLayers

func (net *Net) ForwardLayers(outBlobNames []string) (blobs []Mat)

ForwardLayers forward pass to compute outputs of layers listed in outBlobNames.

For further details, please see: https://docs.opencv.org/3.4.1/db/d30/classcv_1_1dnn_1_1Net.html#adb34d7650e555264c7da3b47d967311b

func (*Net) GetLayer

func (net *Net) GetLayer(layer int) Layer

GetLayer returns pointer to layer with specified id from the network.

For further details, please see: https://docs.opencv.org/master/db/d30/classcv_1_1dnn_1_1Net.html#a70aec7f768f38c32b1ee25f3a56526df

func (*Net) GetLayerNames

func (net *Net) GetLayerNames() (names []string)

GetLayerNames returns all layer names.

For furtherdetails, please see: https://docs.opencv.org/master/db/d30/classcv_1_1dnn_1_1Net.html#ae8be9806024a0d1d41aba687cce99e6b

func (*Net) GetPerfProfile

func (net *Net) GetPerfProfile() float64

GetPerfProfile returns overall time for inference and timings (in ticks) for layers

For further details, please see: https://docs.opencv.org/master/db/d30/classcv_1_1dnn_1_1Net.html#a06ce946f675f75d1c020c5ddbc78aedc

func (*Net) GetUnconnectedOutLayers

func (net *Net) GetUnconnectedOutLayers() (ids []int)

GetUnconnectedOutLayers returns indexes of layers with unconnected outputs.

For further details, please see: https://docs.opencv.org/master/db/d30/classcv_1_1dnn_1_1Net.html#ae62a73984f62c49fd3e8e689405b056a

func (*Net) SetInput

func (net *Net) SetInput(blob Mat, name string)

SetInput sets the new value for the layer output blob.

For further details, please see: https://docs.opencv.org/trunk/db/d30/classcv_1_1dnn_1_1Net.html#a672a08ae76444d75d05d7bfea3e4a328

func (*Net) SetPreferableBackend

func (net *Net) SetPreferableBackend(backend NetBackendType) error

SetPreferableBackend ask network to use specific computation backend.

For further details, please see: https://docs.opencv.org/3.4/db/d30/classcv_1_1dnn_1_1Net.html#a7f767df11386d39374db49cd8df8f59e

func (*Net) SetPreferableTarget

func (net *Net) SetPreferableTarget(target NetTargetType) error

SetPreferableTarget ask network to make computations on specific target device.

For further details, please see: https://docs.opencv.org/3.4/db/d30/classcv_1_1dnn_1_1Net.html#a9dddbefbc7f3defbe3eeb5dc3d3483f4

type NetBackendType

type NetBackendType int

NetBackendType is the type for the various different kinds of DNN backends.

const (
	// NetBackendDefault is the default backend.
	NetBackendDefault NetBackendType = 0

	// NetBackendHalide is the Halide backend.
	NetBackendHalide NetBackendType = 1

	// NetBackendOpenVINO is the OpenVINO backend.
	NetBackendOpenVINO NetBackendType = 2

	// NetBackendOpenCV is the OpenCV backend.
	NetBackendOpenCV NetBackendType = 3

	// NetBackendVKCOM is the Vulkan backend.
	NetBackendVKCOM NetBackendType = 4

	// NetBackendCUDA is the Cuda backend.
	NetBackendCUDA NetBackendType = 5
)

func ParseNetBackend

func ParseNetBackend(backend string) NetBackendType

ParseNetBackend returns a valid NetBackendType given a string. Valid values are: - halide - openvino - opencv - vulkan - cuda - default

func (NetBackendType) String

func (c NetBackendType) String() string

type NetTargetType

type NetTargetType int

NetTargetType is the type for the various different kinds of DNN device targets.

const (
	// NetTargetCPU is the default CPU device target.
	NetTargetCPU NetTargetType = 0

	// NetTargetFP32 is the 32-bit OpenCL target.
	NetTargetFP32 NetTargetType = 1

	// NetTargetFP16 is the 16-bit OpenCL target.
	NetTargetFP16 NetTargetType = 2

	// NetTargetVPU is the Movidius VPU target.
	NetTargetVPU NetTargetType = 3

	// NetTargetVulkan is the NVIDIA Vulkan target.
	NetTargetVulkan NetTargetType = 4

	// NetTargetFPGA is the FPGA target.
	NetTargetFPGA NetTargetType = 5

	// NetTargetCUDA is the CUDA target.
	NetTargetCUDA NetTargetType = 6

	// NetTargetCUDAFP16 is the CUDA target.
	NetTargetCUDAFP16 NetTargetType = 7
)

func ParseNetTarget

func ParseNetTarget(target string) NetTargetType

ParseNetTarget returns a valid NetTargetType given a string. Valid values are: - cpu - fp32 - fp16 - vpu - vulkan - fpga - cuda - cudafp16

func (NetTargetType) String

func (c NetTargetType) String() string

type NormType

type NormType int

NormType for normalization operations.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#gad12cefbcb5291cf958a85b4b67b6149f

const (
	// NormInf indicates use infinite normalization.
	NormInf NormType = 1

	// NormL1 indicates use L1 normalization.
	NormL1 NormType = 2

	// NormL2 indicates use L2 normalization.
	NormL2 NormType = 4

	// NormL2Sqr indicates use L2 squared normalization.
	NormL2Sqr NormType = 5

	// NormHamming indicates use Hamming normalization.
	NormHamming NormType = 6

	// NormHamming2 indicates use Hamming 2-bit normalization.
	NormHamming2 NormType = 7

	// NormTypeMask indicates use type mask for normalization.
	NormTypeMask NormType = 7

	// NormRelative indicates use relative normalization.
	NormRelative NormType = 8

	// NormMinMax indicates use min/max normalization.
	NormMinMax NormType = 32
)

func (NormType) String

func (c NormType) String() string

type ORB

type ORB struct {
	// contains filtered or unexported fields
}

ORB is a wrapper around the cv::ORB.

func NewORB

func NewORB() ORB

NewORB returns a new ORB algorithm

For further details, please see: https://docs.opencv.org/master/db/d95/classcv_1_1ORB.html

func NewORBWithParams

func NewORBWithParams(nFeatures int, scaleFactor float32, nLevels int, edgeThreshold int, firstLevel int, WTAK int, scoreType ORBScoreType, patchSize int, fastThreshold int) ORB

NewORBWithParams returns a new ORB algorithm with parameters

For further details, please see: https://docs.opencv.org/master/db/d95/classcv_1_1ORB.html#aeff0cbe668659b7ca14bb85ff1c4073b

func (*ORB) Close

func (o *ORB) Close() error

Close ORB.

func (*ORB) Detect

func (o *ORB) Detect(src Mat) []KeyPoint

Detect keypoints in an image using ORB.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

func (*ORB) DetectAndCompute

func (o *ORB) DetectAndCompute(src Mat, mask Mat) ([]KeyPoint, Mat)

DetectAndCompute detects keypoints and computes from an image using ORB.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#a8be0d1c20b08eb867184b8d74c15a677

type ORBScoreType

type ORBScoreType int
const (
	ORBScoreTypeHarris ORBScoreType = 0
	ORBScoreTypeFAST   ORBScoreType = 1
)

type Point2f

type Point2f struct {
	X float32
	Y float32
}

func NewPoint2f

func NewPoint2f(x, y float32) Point2f

func PhaseCorrelate

func PhaseCorrelate(src1, src2, window Mat) (phaseShift Point2f, response float64)

Apply phaseCorrelate.

For further details, please see: https://docs.opencv.org/master/d7/df3/group__imgproc__motion.html#ga552420a2ace9ef3fb053cd630fdb4952

type Point2fVector

type Point2fVector struct {
	// contains filtered or unexported fields
}

Point2fVector is a wrapper around a std::vector< cv::Point2f >* This is needed anytime that you need to pass or receive a collection of points.

func NewPoint2fVector

func NewPoint2fVector() Point2fVector

NewPoint2fVector returns a new empty Point2fVector.

func NewPoint2fVectorFromMat

func NewPoint2fVectorFromMat(mat Mat) Point2fVector

NewPoint2fVectorFromMat returns a new Point2fVector that has been wrapped around a Mat of type CV_32FC2 with a single columm.

func NewPoint2fVectorFromPoints

func NewPoint2fVectorFromPoints(pts []Point2f) Point2fVector

NewPoint2fVectorFromPoints returns a new Point2fVector that has been initialized to a slice of image.Point.

func (Point2fVector) At

func (pfv Point2fVector) At(idx int) Point2f

At returns the image.Point

func (Point2fVector) Close

func (pfv Point2fVector) Close()

Close closes and frees memory for this Point2fVector.

func (Point2fVector) IsNil

func (pfv Point2fVector) IsNil() bool

IsNil checks the CGo pointer in the Point2fVector.

func (Point2fVector) Size

func (pfv Point2fVector) Size() int

Size returns how many Point are in the PointVector.

func (Point2fVector) ToPoints

func (pfv Point2fVector) ToPoints() []Point2f

ToPoints returns a slice of image.Point for the data in this PointVector.

type Point3f

type Point3f struct {
	X float32
	Y float32
	Z float32
}

func NewPoint3f

func NewPoint3f(x, y, z float32) Point3f

type Point3fVector

type Point3fVector struct {
	// contains filtered or unexported fields
}

Point3fVector is a wrapper around a std::vector< cv::Point3f >*

func NewPoint3fVector

func NewPoint3fVector() Point3fVector

NewPoint3fVector returns a new empty Point3fVector.

func NewPoint3fVectorFromMat

func NewPoint3fVectorFromMat(mat Mat) Point3fVector

NewPoint3fVectorFromMat returns a new Point3fVector that has been wrapped around a Mat of type CV_32FC3 with a single columm.

func NewPoint3fVectorFromPoints

func NewPoint3fVectorFromPoints(pts []Point3f) Point3fVector

NewPoint3fVectorFromPoints returns a new Point3fVector that has been initialized to a slice of image.Point.

func (Point3fVector) Append

func (pfv Point3fVector) Append(point Point3f)

func (Point3fVector) At

func (pfv Point3fVector) At(idx int) Point3f

At returns the Point3f

func (Point3fVector) Close

func (pfv Point3fVector) Close()

Close closes and frees memory for this Point3fVector.

func (Point3fVector) IsNil

func (pfv Point3fVector) IsNil() bool

IsNil checks the CGo pointer in the Point3fVector.

func (Point3fVector) Size

func (pfv Point3fVector) Size() int

Size returns how many Point are in the Point3fVector.

func (Point3fVector) ToPoints

func (pfv Point3fVector) ToPoints() []Point3f

ToPoints returns a slice of Point3f for the data in this Point3fVector.

type PointVector

type PointVector struct {
	// contains filtered or unexported fields
}

PointVector is a wrapper around a std::vector< cv::Point >* This is needed anytime that you need to pass or receive a collection of points.

func ApproxPolyDP

func ApproxPolyDP(curve PointVector, epsilon float64, closed bool) PointVector

ApproxPolyDP approximates a polygonal curve(s) with the specified precision.

For further details, please see:

https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga0012a5fdaea70b8a9970165d98722b4c

func NewPointVector

func NewPointVector() PointVector

NewPointVector returns a new empty PointVector.

func NewPointVectorFromMat

func NewPointVectorFromMat(mat Mat) PointVector

NewPointVectorFromMat returns a new PointVector that has been wrapped around a Mat of type CV_32SC2 with a single columm.

func NewPointVectorFromPoints

func NewPointVectorFromPoints(pts []image.Point) PointVector

NewPointVectorFromPoints returns a new PointVector that has been initialized to a slice of image.Point.

func (PointVector) Append

func (pv PointVector) Append(point image.Point)

Append appends an image.Point at end of the PointVector.

func (PointVector) At

func (pv PointVector) At(idx int) image.Point

At returns the image.Point

func (PointVector) Close

func (pv PointVector) Close()

Close closes and frees memory for this PointVector.

func (PointVector) IsNil

func (pv PointVector) IsNil() bool

IsNil checks the CGo pointer in the PointVector.

func (PointVector) Size

func (pv PointVector) Size() int

Size returns how many Point are in the PointVector.

func (PointVector) ToPoints

func (pv PointVector) ToPoints() []image.Point

ToPoints returns a slice of image.Point for the data in this PointVector.

type Points2fVector

type Points2fVector struct {
	// contains filtered or unexported fields
}

Points2fVector is a wrapper around a std::vector< std::vector< cv::Point2f > >*

func NewPoints2fVector

func NewPoints2fVector() Points2fVector

NewPoints2fVector returns a new empty Points2fVector.

func NewPoints2fVectorFromPoints

func NewPoints2fVectorFromPoints(pts [][]Point2f) Points2fVector

NewPoints2fVectorFromPoints returns a new Points2fVector that has been initialized to a slice of slices of Point2f.

func (Points2fVector) Append

func (pvs Points2fVector) Append(pv Point2fVector)

Append appends a Point2fVector at end of the Points2fVector.

func (Points2fVector) At

func (pvs Points2fVector) At(idx int) Point2fVector

At returns the Point2fVector at that index of the Points2fVector.

func (Points2fVector) Close

func (pvs Points2fVector) Close()

Close closes and frees memory for this Points2fVector.

func (Points2fVector) IsNil

func (pvs Points2fVector) IsNil() bool

IsNil checks the CGo pointer in the Points2fVector.

func (Points2fVector) P

func (Points2fVector) Size

func (pvs Points2fVector) Size() int

Size returns how many vectors of Points are in the Points2fVector.

func (Points2fVector) ToPoints

func (pvs Points2fVector) ToPoints() [][]Point2f

ToPoints returns a slice of slices of Point2f for the data in this Points2fVector.

type Points3fVector

type Points3fVector struct {
	// contains filtered or unexported fields
}

Points3fVector is a wrapper around a std::vector< std::vector< cv::Point3f > >*

func NewPoints3fVector

func NewPoints3fVector() Points3fVector

NewPoints3fVector returns a new empty Points3fVector.

func NewPoints3fVectorFromPoints

func NewPoints3fVectorFromPoints(pts [][]Point3f) Points3fVector

NewPoints3fVectorFromPoints returns a new Points3fVector that has been initialized to a slice of slices of Point3f.

func (Points3fVector) Append

func (pvs Points3fVector) Append(pv Point3fVector)

Append appends a Point3fVector at end of the Points3fVector.

func (Points3fVector) At

func (pvs Points3fVector) At(idx int) Point3fVector

At returns the Point3fVector at that index of the Points3fVector.

func (Points3fVector) Close

func (pvs Points3fVector) Close()

Close closes and frees memory for this Points3fVector.

func (Points3fVector) IsNil

func (pvs Points3fVector) IsNil() bool

IsNil checks the CGo pointer in the Points3fVector.

func (Points3fVector) Size

func (pvs Points3fVector) Size() int

Size returns how many vectors of Points are in the Points3fVector.

func (Points3fVector) ToPoints

func (pvs Points3fVector) ToPoints() [][]Point3f

ToPoints returns a slice of slices of Point3f for the data in this Points3fVector.

type PointsVector

type PointsVector struct {
	// contains filtered or unexported fields
}

PointsVector is a wrapper around a std::vector< std::vector< cv::Point > >*

func FindContours

func FindContours(src Mat, mode RetrievalMode, method ContourApproximationMode) PointsVector

FindContours finds contours in a binary image.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga95f5b48d01abc7c2e0732db24689837b

func FindContoursWithParams

func FindContoursWithParams(src Mat, hierarchy *Mat, mode RetrievalMode, method ContourApproximationMode) PointsVector

FindContoursWithParams finds contours in a binary image.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga17ed9f5d79ae97bd4c7cf18403e1689a

func NewPointsVector

func NewPointsVector() PointsVector

NewPointsVector returns a new empty PointsVector.

func NewPointsVectorFromPoints

func NewPointsVectorFromPoints(pts [][]image.Point) PointsVector

NewPointsVectorFromPoints returns a new PointsVector that has been initialized to a slice of slices of image.Point.

func (PointsVector) Append

func (pvs PointsVector) Append(pv PointVector)

Append appends a PointVector at end of the PointsVector.

func (PointsVector) At

func (pvs PointsVector) At(idx int) PointVector

At returns the PointVector at that index of the PointsVector.

func (PointsVector) Close

func (pvs PointsVector) Close()

Close closes and frees memory for this PointsVector.

func (PointsVector) IsNil

func (pvs PointsVector) IsNil() bool

IsNil checks the CGo pointer in the PointsVector.

func (PointsVector) P

func (pvs PointsVector) P() C.PointsVector

func (PointsVector) Size

func (pvs PointsVector) Size() int

Size returns how many vectors of Points are in the PointsVector.

func (PointsVector) ToPoints

func (pvs PointsVector) ToPoints() [][]image.Point

ToPoints returns a slice of slices of image.Point for the data in this PointsVector.

type QRCodeDetector

type QRCodeDetector struct {
	// contains filtered or unexported fields
}

QRCodeDetector groups the object candidate rectangles.

For further details, please see: https://docs.opencv.org/master/de/dc3/classcv_1_1QRCodeDetector.html

func NewQRCodeDetector

func NewQRCodeDetector() QRCodeDetector

func (*QRCodeDetector) Close

func (a *QRCodeDetector) Close() error

func (*QRCodeDetector) Decode

func (a *QRCodeDetector) Decode(input Mat, points Mat, straight_qrcode *Mat) string

Decode decodes QR code in image once it's found by the detect() method. Returns UTF8-encoded output string or empty string if the code cannot be decoded.

For further details, please see: https://docs.opencv.org/master/de/dc3/classcv_1_1QRCodeDetector.html#a4172c2eb4825c844fb1b0ae67202d329

func (*QRCodeDetector) Detect

func (a *QRCodeDetector) Detect(input Mat, points *Mat) bool

Detect detects QR code in image and returns the quadrangle containing the code.

For further details, please see: https://docs.opencv.org/master/de/dc3/classcv_1_1QRCodeDetector.html#a64373f7d877d27473f64fe04bb57d22b

func (*QRCodeDetector) DetectAndDecode

func (a *QRCodeDetector) DetectAndDecode(input Mat, points *Mat, straight_qrcode *Mat) string

DetectAndDecode Both detects and decodes QR code.

Returns true as long as some QR code was detected even in case where the decoding failed For further details, please see: https://docs.opencv.org/master/de/dc3/classcv_1_1QRCodeDetector.html#a7290bd6a5d59b14a37979c3a14fbf394

func (*QRCodeDetector) DetectAndDecodeMulti

func (a *QRCodeDetector) DetectAndDecodeMulti(input Mat, decoded *[]string, points *Mat, qrCodes *[]Mat) bool

Detects QR codes in image and finds of the quadrangles containing the codes and decode the decode the QRCodes to strings.

Each quadrangle would be returned as a row in the `points` Mat and each point is a Vecf. Returns true as long as some QR code was detected even in case where the decoding failed For usage please see TestQRCodeDetector For further details, please see: https://docs.opencv.org/master/de/dc3/classcv_1_1QRCodeDetector.html#a188b63ffa17922b2c65d8a0ab7b70775

func (*QRCodeDetector) DetectMulti

func (a *QRCodeDetector) DetectMulti(input Mat, points *Mat) bool

Detects QR codes in image and finds of the quadrangles containing the codes.

Each quadrangle would be returned as a row in the `points` Mat and each point is a Vecf. Returns true if QR code was detected For usage please see TestQRCodeDetector For further details, please see: https://docs.opencv.org/master/de/dc3/classcv_1_1QRCodeDetector.html#aaf2b6b2115b8e8fbc9acf3a8f68872b6

type RNG

type RNG struct {
	// contains filtered or unexported fields
}

RNG Random Number Generator. It encapsulates the state (currently, a 64-bit integer) and has methods to return scalar random values and to fill arrays with random values

For further details, please see: https://docs.opencv.org/master/d1/dd6/classcv_1_1RNG.html

func TheRNG

func TheRNG() RNG

TheRNG Returns the default random number generator.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga75843061d150ad6564b5447e38e57722

func (*RNG) Fill

func (r *RNG) Fill(mat *Mat, distType RNGDistType, a, b float64, saturateRange bool)

Fill Fills arrays with random numbers.

For further details, please see: https://docs.opencv.org/master/d1/dd6/classcv_1_1RNG.html#ad26f2b09d9868cf108e84c9814aa682d

func (*RNG) Gaussian

func (r *RNG) Gaussian(sigma float64) float64

Gaussian Returns the next random number sampled from the Gaussian distribution.

For further details, please see: https://docs.opencv.org/master/d1/dd6/classcv_1_1RNG.html#a8df8ce4dc7d15916cee743e5a884639d

func (*RNG) Next

func (r *RNG) Next() uint

Next The method updates the state using the MWC algorithm and returns the next 32-bit random number.

For further details, please see: https://docs.opencv.org/master/d1/dd6/classcv_1_1RNG.html#a8df8ce4dc7d15916cee743e5a884639d

type RNGDistType

type RNGDistType int
const (
	// Uniform distribution
	RNGDistUniform RNGDistType = 0
	// Normal distribution
	RNGDistNormal RNGDistType = 1
)

type ReduceTypes

type ReduceTypes int
const (
	// The output is the sum of all rows/columns of the matrix.
	ReduceSum ReduceTypes = 0

	// The output is the mean vector of all rows/columns of the matrix.
	ReduceAvg ReduceTypes = 1

	// The output is the maximum (column/row-wise) of all rows/columns of the matrix.
	ReduceMax ReduceTypes = 2

	// The output is the minimum (column/row-wise) of all rows/columns of the matrix.
	ReduceMin ReduceTypes = 3
)

func (ReduceTypes) String

func (c ReduceTypes) String() string

type RetrievalMode

type RetrievalMode int

RetrievalMode is the mode of the contour retrieval algorithm.

const (
	// RetrievalExternal retrieves only the extreme outer contours.
	// It sets `hierarchy[i][2]=hierarchy[i][3]=-1` for all the contours.
	RetrievalExternal RetrievalMode = 0

	// RetrievalList retrieves all of the contours without establishing
	// any hierarchical relationships.
	RetrievalList RetrievalMode = 1

	// RetrievalCComp retrieves all of the contours and organizes them into
	// a two-level hierarchy. At the top level, there are external boundaries
	// of the components. At the second level, there are boundaries of the holes.
	// If there is another contour inside a hole of a connected component, it
	// is still put at the top level.
	RetrievalCComp RetrievalMode = 2

	// RetrievalTree retrieves all of the contours and reconstructs a full
	// hierarchy of nested contours.
	RetrievalTree RetrievalMode = 3

	// RetrievalFloodfill lacks a description in the original header.
	RetrievalFloodfill RetrievalMode = 4
)

func (RetrievalMode) String

func (c RetrievalMode) String() string

type RotateFlag

type RotateFlag int

RotateFlag for image rotation

For further details please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga6f45d55c0b1cc9d97f5353a7c8a7aac2

const (
	// Rotate90Clockwise allows to rotate image 90 degrees clockwise
	Rotate90Clockwise RotateFlag = 0
	// Rotate180Clockwise allows to rotate image 180 degrees clockwise
	Rotate180Clockwise RotateFlag = 1
	// Rotate90CounterClockwise allows to rotate 270 degrees clockwise
	Rotate90CounterClockwise RotateFlag = 2
)

func (RotateFlag) String

func (c RotateFlag) String() string

type RotatedRect

type RotatedRect struct {
	Points       []image.Point
	BoundingRect image.Rectangle
	Center       image.Point
	Width        int
	Height       int
	Angle        float64
}

func FitEllipse

func FitEllipse(pts PointVector) RotatedRect

FitEllipse Fits an ellipse around a set of 2D points.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#gaf259efaad93098103d6c27b9e4900ffa

func MinAreaRect

func MinAreaRect(points PointVector) RotatedRect

MinAreaRect finds a rotated rectangle of the minimum area enclosing the input 2D point set.

For further details, please see: https://docs.opencv.org/master/d3/dc0/group__imgproc__shape.html#ga3d476a3417130ae5154aea421ca7ead9

type SIFT

type SIFT struct {
	// contains filtered or unexported fields
}

SIFT is a wrapper around the cv::SIFT algorithm. Due to the patent having expired, this is now in the main OpenCV code modules.

func NewSIFT

func NewSIFT() SIFT

NewSIFT returns a new SIFT algorithm.

For further details, please see: https://docs.opencv.org/master/d5/d3c/classcv_1_1xfeatures2d_1_1SIFT.html

func (*SIFT) Close

func (d *SIFT) Close() error

Close SIFT.

func (*SIFT) Detect

func (d *SIFT) Detect(src Mat) []KeyPoint

Detect keypoints in an image using SIFT.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

func (*SIFT) DetectAndCompute

func (d *SIFT) DetectAndCompute(src Mat, mask Mat) ([]KeyPoint, Mat)

DetectAndCompute detects and computes keypoints in an image using SIFT.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#a8be0d1c20b08eb867184b8d74c15a677

type Scalar

type Scalar struct {
	Val1 float64
	Val2 float64
	Val3 float64
	Val4 float64
}

Scalar is a 4-element vector widely used in OpenCV to pass pixel values.

For further details, please see: http://docs.opencv.org/master/d1/da0/classcv_1_1Scalar__.html

func GetBlobSize

func GetBlobSize(blob Mat) Scalar

GetBlobSize retrieves the 4 dimensional size information in (N,C,H,W) order

func MorphologyDefaultBorderValue

func MorphologyDefaultBorderValue() Scalar

MorphologyDefaultBorder returns "magic" border value for erosion and dilation. It is automatically transformed to Scalar::all(-DBL_MAX) for dilation.

For further details, please see: https://docs.opencv.org/master/d4/d86/group__imgproc__filter.html#ga94756fad83d9d24d29c9bf478558c40a

func NewScalar

func NewScalar(v1 float64, v2 float64, v3 float64, v4 float64) Scalar

NewScalar returns a new Scalar. These are usually colors typically being in BGR order.

func Trace

func Trace(src Mat) Scalar

Trace returns the trace of a matrix.

For further details, please see: https://docs.opencv.org/master/d2/de8/group__core__array.html#ga3419ac19c7dcd2be4bd552a23e147dd8

type SeamlessCloneFlags

type SeamlessCloneFlags int

SeamlessCloneFlags seamlessClone algorithm flags

const (
	// NormalClone The power of the method is fully expressed when inserting objects with complex outlines into a new background.
	NormalClone SeamlessCloneFlags = iota

	// MixedClone The classic method, color-based selection and alpha masking might be time consuming and often leaves an undesirable halo. Seamless cloning, even averaged with the original image, is not effective. Mixed seamless cloning based on a loose selection proves effective.
	MixedClone

	// MonochromeTransfer Monochrome transfer allows the user to easily replace certain features of one object by alternative features.
	MonochromeTransfer
)

func (SeamlessCloneFlags) String

func (c SeamlessCloneFlags) String() string

type SimpleBlobDetector

type SimpleBlobDetector struct {
	// contains filtered or unexported fields
}

SimpleBlobDetector is a wrapper around the cv::SimpleBlobDetector.

func NewSimpleBlobDetector

func NewSimpleBlobDetector() SimpleBlobDetector

NewSimpleBlobDetector returns a new SimpleBlobDetector algorithm

For further details, please see: https://docs.opencv.org/master/d0/d7a/classcv_1_1SimpleBlobDetector.html

func NewSimpleBlobDetectorWithParams

func NewSimpleBlobDetectorWithParams(params SimpleBlobDetectorParams) SimpleBlobDetector

NewSimpleBlobDetectorWithParams returns a new SimpleBlobDetector with custom parameters

For further details, please see: https://docs.opencv.org/master/d0/d7a/classcv_1_1SimpleBlobDetector.html

func (*SimpleBlobDetector) Close

func (b *SimpleBlobDetector) Close() error

Close SimpleBlobDetector.

func (*SimpleBlobDetector) Detect

func (b *SimpleBlobDetector) Detect(src Mat) []KeyPoint

Detect keypoints in an image using SimpleBlobDetector.

For further details, please see: https://docs.opencv.org/master/d0/d13/classcv_1_1Feature2D.html#aa4e9a7082ec61ebc108806704fbd7887

type SimpleBlobDetectorParams

type SimpleBlobDetectorParams struct {
	// contains filtered or unexported fields
}

SimpleBlobDetector_Params is a wrapper around the cv::SimpleBlobdetector::Params

func NewSimpleBlobDetectorParams

func NewSimpleBlobDetectorParams() SimpleBlobDetectorParams

NewSimpleBlobDetectorParams returns the default parameters for the SimpleBobDetector

func (*SimpleBlobDetectorParams) GetBlobColor

func (p *SimpleBlobDetectorParams) GetBlobColor() int

GetBlobColor gets the blobColor field

func (*SimpleBlobDetectorParams) GetFilterByArea

func (p *SimpleBlobDetectorParams) GetFilterByArea() bool

GetFilterByArea gets the filterByArea field

func (*SimpleBlobDetectorParams) GetFilterByCircularity

func (p *SimpleBlobDetectorParams) GetFilterByCircularity() bool

GetFilterByCircularity gets the filterByCircularity field

func (*SimpleBlobDetectorParams) GetFilterByColor

func (p *SimpleBlobDetectorParams) GetFilterByColor() bool

GetFilterByColor gets the filterByColor field

func (*SimpleBlobDetectorParams) GetFilterByConvexity

func (p *SimpleBlobDetectorParams) GetFilterByConvexity() bool

GetFilterByConvexity gets the filterByConvexity field

func (*SimpleBlobDetectorParams) GetFilterByInertia

func (p *SimpleBlobDetectorParams) GetFilterByInertia() bool

GetFilterByInertia gets the filterByInertia field

func (*SimpleBlobDetectorParams) GetMaxArea

func (p *SimpleBlobDetectorParams) GetMaxArea() float64

GetMaxArea sets the maxArea parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMaxCircularity

func (p *SimpleBlobDetectorParams) GetMaxCircularity() float64

GetMaxCircularity sets the maxCircularity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMaxConvexity

func (p *SimpleBlobDetectorParams) GetMaxConvexity() float64

GetMaxConvexity sets the maxConvexity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMaxInertiaRatio

func (p *SimpleBlobDetectorParams) GetMaxInertiaRatio() float64

GetMaxInertiaRatio sets the maxCConvexity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMaxThreshold

func (p *SimpleBlobDetectorParams) GetMaxThreshold() float64

GetMaxThreshold sets the maxCConvexity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinArea

func (p *SimpleBlobDetectorParams) GetMinArea() float64

GetMinArea sets theinArea parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinCircularity

func (p *SimpleBlobDetectorParams) GetMinCircularity() float64

GetMinCircularity sets the minCircularity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinConvexity

func (p *SimpleBlobDetectorParams) GetMinConvexity() float64

GetMinConvexity sets the minConvexity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinDistBetweenBlobs

func (p *SimpleBlobDetectorParams) GetMinDistBetweenBlobs() float64

GetMinDistBetweenBlobs sets the minDistBetweenBlobs parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinInertiaRatio

func (p *SimpleBlobDetectorParams) GetMinInertiaRatio() float64

GetMinInertiaRatio sets the minInertiaRatio parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinRepeatability

func (p *SimpleBlobDetectorParams) GetMinRepeatability() int

GetMinInertiaRatio sets the minRepeatability parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetMinThreshold

func (p *SimpleBlobDetectorParams) GetMinThreshold() float64

GetMinThreshold sets the minInertiaRatio parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) GetThresholdStep

func (p *SimpleBlobDetectorParams) GetThresholdStep() float64

GetMinThreshold sets the minInertiaRatio parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetBlobColor

func (p *SimpleBlobDetectorParams) SetBlobColor(blobColor int)

SetBlobColor sets the blobColor field

func (*SimpleBlobDetectorParams) SetFilterByArea

func (p *SimpleBlobDetectorParams) SetFilterByArea(filterByArea bool)

SetFilterByArea sets the filterByArea field

func (*SimpleBlobDetectorParams) SetFilterByCircularity

func (p *SimpleBlobDetectorParams) SetFilterByCircularity(filterByCircularity bool)

SetFilterByCircularity sets the filterByCircularity field

func (*SimpleBlobDetectorParams) SetFilterByColor

func (p *SimpleBlobDetectorParams) SetFilterByColor(filterByColor bool)

SetFilterByColor sets the filterByColor field

func (*SimpleBlobDetectorParams) SetFilterByConvexity

func (p *SimpleBlobDetectorParams) SetFilterByConvexity(filterByConvexity bool)

SetFilterByConvexity sets the filterByConvexity field

func (*SimpleBlobDetectorParams) SetFilterByInertia

func (p *SimpleBlobDetectorParams) SetFilterByInertia(filterByInertia bool)

SetFilterByInertia sets the filterByInertia field

func (*SimpleBlobDetectorParams) SetMaxArea

func (p *SimpleBlobDetectorParams) SetMaxArea(maxArea float64)

SetMaxArea sets the maxArea parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMaxCircularity

func (p *SimpleBlobDetectorParams) SetMaxCircularity(maxCircularity float64)

SetMaxCircularity sets the maxCircularity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMaxConvexity

func (p *SimpleBlobDetectorParams) SetMaxConvexity(maxConvexity float64)

SetMaxConvexity sets the maxConvexity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMaxInertiaRatio

func (p *SimpleBlobDetectorParams) SetMaxInertiaRatio(maxInertiaRatio float64)

SetMaxInertiaRatio sets the maxInertiaRatio parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMaxThreshold

func (p *SimpleBlobDetectorParams) SetMaxThreshold(maxThreshold float64)

SetMaxThreshold sets the maxThreshold parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinArea

func (p *SimpleBlobDetectorParams) SetMinArea(minArea float64)

SetMinArea sets the minArea parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinCircularity

func (p *SimpleBlobDetectorParams) SetMinCircularity(minCircularity float64)

SetMinCircularity sets the minCircularity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinConvexity

func (p *SimpleBlobDetectorParams) SetMinConvexity(minConvexity float64)

SetMinConvexity sets the minConvexity parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinDistBetweenBlobs

func (p *SimpleBlobDetectorParams) SetMinDistBetweenBlobs(minDistBetweenBlobs float64)

SetMinDistBetweenBlobs sets the minDistBetweenBlobs parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinInertiaRatio

func (p *SimpleBlobDetectorParams) SetMinInertiaRatio(minInertiaRatio float64)

SetMinInertiaRatio sets the minInertiaRatio parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinRepeatability

func (p *SimpleBlobDetectorParams) SetMinRepeatability(minRepeatability int)

SetMinRepeatability sets the minRepeatability parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetMinThreshold

func (p *SimpleBlobDetectorParams) SetMinThreshold(minThreshold float64)

SetMinThreshold sets the minThreshold parameter for SimpleBlobDetector_Params

func (*SimpleBlobDetectorParams) SetThresholdStep

func (p *SimpleBlobDetectorParams) SetThresholdStep(thresholdStep float64)

SetMinThreshold sets the minThreshold parameter for SimpleBlobDetector_Params

type SolveDecompositionFlags

type SolveDecompositionFlags int
const (
	// Gaussian elimination with the optimal pivot element chosen.
	SolveDecompositionLu SolveDecompositionFlags = 0

	// Singular value decomposition (SVD) method. The system can be over-defined and/or the matrix src1 can be singular.
	SolveDecompositionSvd SolveDecompositionFlags = 1

	// Eigenvalue decomposition. The matrix src1 must be symmetrical.
	SolveDecompositionEing SolveDecompositionFlags = 2

	// Cholesky LL^T factorization. The matrix src1 must be symmetrical and positively defined.
	SolveDecompositionCholesky SolveDecompositionFlags = 3

	// QR factorization. The system can be over-defined and/or the matrix src1 can be singular.
	SolveDecompositionQr SolveDecompositionFlags = 4

	// While all the previous flags are mutually exclusive, this flag can be used together with any of the previous.
	// It means that the normal equations 𝚜𝚛𝚌𝟷^T⋅𝚜𝚛𝚌𝟷⋅𝚍𝚜𝚝=𝚜𝚛𝚌𝟷^T𝚜𝚛𝚌𝟸 are solved instead of the original system
	// 𝚜𝚛𝚌𝟷⋅𝚍𝚜𝚝=𝚜𝚛𝚌𝟸.
	SolveDecompositionNormal SolveDecompositionFlags = 5
)

func (SolveDecompositionFlags) String

func (c SolveDecompositionFlags) String() string

type SortFlags

type SortFlags int
const (
	// Each matrix row is sorted independently
	SortEveryRow SortFlags = 0

	// Each matrix column is sorted independently; this flag and the previous one are mutually exclusive.
	SortEveryColumn SortFlags = 1

	// Each matrix row is sorted in the ascending order.
	SortAscending SortFlags = 0

	// Each matrix row is sorted in the descending order; this flag and the previous one are also mutually exclusive.
	SortDescending SortFlags = 16
)

func (SortFlags) String

func (c SortFlags) String() string

type TemplateMatchMode

type TemplateMatchMode int

TemplateMatchMode is the type of the template matching operation.

const (
	// TmSqdiff maps to TM_SQDIFF
	TmSqdiff TemplateMatchMode = 0
	// TmSqdiffNormed maps to TM_SQDIFF_NORMED
	TmSqdiffNormed TemplateMatchMode = 1
	// TmCcorr maps to TM_CCORR
	TmCcorr TemplateMatchMode = 2
	// TmCcorrNormed maps to TM_CCORR_NORMED
	TmCcorrNormed TemplateMatchMode = 3
	// TmCcoeff maps to TM_CCOEFF
	TmCcoeff TemplateMatchMode = 4
	// TmCcoeffNormed maps to TM_CCOEFF_NORMED
	TmCcoeffNormed TemplateMatchMode = 5
)

func (TemplateMatchMode) String

func (c TemplateMatchMode) String() string

type TermCriteria

type TermCriteria struct {
	// contains filtered or unexported fields
}

TermCriteria is the criteria for iterative algorithms.

For further details, please see: https://docs.opencv.org/master/d9/d5d/classcv_1_1TermCriteria.html

func NewTermCriteria

func NewTermCriteria(typ TermCriteriaType, maxCount int, epsilon float64) TermCriteria

NewTermCriteria returns a new TermCriteria.

type TermCriteriaType

type TermCriteriaType int

TermCriteriaType for TermCriteria.

For further details, please see: https://docs.opencv.org/master/d9/d5d/classcv_1_1TermCriteria.html#a56fecdc291ccaba8aad27d67ccf72c57

const (
	// Count is the maximum number of iterations or elements to compute.
	Count TermCriteriaType = 1

	// MaxIter is the maximum number of iterations or elements to compute.
	MaxIter TermCriteriaType = 1

	// EPS is the desired accuracy or change in parameters at which the
	// iterative algorithm stops.
	EPS TermCriteriaType = 2
)

func (TermCriteriaType) String

func (c TermCriteriaType) String() string

type ThresholdType

type ThresholdType int

ThresholdType type of threshold operation.

const (
	// ThresholdBinary threshold type
	ThresholdBinary ThresholdType = 0

	// ThresholdBinaryInv threshold type
	ThresholdBinaryInv ThresholdType = 1

	// ThresholdTrunc threshold type
	ThresholdTrunc ThresholdType = 2

	// ThresholdToZero threshold type
	ThresholdToZero ThresholdType = 3

	// ThresholdToZeroInv threshold type
	ThresholdToZeroInv ThresholdType = 4

	// ThresholdMask threshold type
	ThresholdMask ThresholdType = 7

	// ThresholdOtsu threshold type
	ThresholdOtsu ThresholdType = 8

	// ThresholdTriangle threshold type
	ThresholdTriangle ThresholdType = 16
)

func (ThresholdType) String

func (c ThresholdType) String() string

type Trackbar

type Trackbar struct {
	// contains filtered or unexported fields
}

Trackbar is a wrapper around OpenCV's "HighGUI" window Trackbars.

func (*Trackbar) GetPos

func (t *Trackbar) GetPos() int

GetPos returns the trackbar position.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga122632e9e91b9ec06943472c55d9cda8

func (*Trackbar) SetMax

func (t *Trackbar) SetMax(pos int)

SetMax sets the trackbar maximum position.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga7e5437ccba37f1154b65210902fc4480

func (*Trackbar) SetMin

func (t *Trackbar) SetMin(pos int)

SetMin sets the trackbar minimum position.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#gabe26ffe8d2b60cc678895595a581b7aa

func (*Trackbar) SetPos

func (t *Trackbar) SetPos(pos int)

SetPos sets the trackbar position.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga67d73c4c9430f13481fd58410d01bd8d

type Tracker

type Tracker interface {
	// Close closes, as Trackers need to be Closed manually.
	//
	Close() error

	// Init initializes the tracker with a known bounding box that surrounded the target.
	// Note: this can only be called once. If you lose the object, you have to Close() the instance,
	// create a new one, and call Init() on it again.
	//
	// see: https://docs.opencv.org/master/d0/d0a/classcv_1_1Tracker.html#a4d285747589b1bdd16d2e4f00c3255dc
	//
	Init(image Mat, boundingBox image.Rectangle) bool

	// Update updates the tracker, returns a new bounding box and a boolean determining whether the tracker lost the target.
	//
	// see: https://docs.opencv.org/master/d0/d0a/classcv_1_1Tracker.html#a549159bd0553e6a8de356f3866df1f18
	//
	Update(image Mat) (image.Rectangle, bool)
}

Tracker is the base interface for object tracking.

see: https://docs.opencv.org/master/d0/d0a/classcv_1_1Tracker.html

func NewTrackerMIL

func NewTrackerMIL() Tracker

NewTrackerMIL returns a new TrackerMIL.

type TrackerMIL

type TrackerMIL struct {
	// contains filtered or unexported fields
}

TrackerMIL is a Tracker that uses the MIL algorithm. MIL trains a classifier in an online manner to separate the object from the background. Multiple Instance Learning avoids the drift problem for a robust tracking.

For further details, please see: https://docs.opencv.org/master/d0/d26/classcv_1_1TrackerMIL.html

func (TrackerMIL) Close

func (trk TrackerMIL) Close() error

Close closes the TrackerMIL.

func (TrackerMIL) Init

func (trk TrackerMIL) Init(img Mat, boundingBox image.Rectangle) bool

Init initializes the TrackerMIL.

func (TrackerMIL) Update

func (trk TrackerMIL) Update(img Mat) (image.Rectangle, bool)

Update updates the TrackerMIL.

type Vecb

type Vecb []uint8

Vecb is a generic vector of bytes.

type Vecd

type Vecd []float64

Vecd is a generic vector of float64/doubles.

type Vecf

type Vecf []float32

Vecf is a generic vector of floats.

type Veci

type Veci []int32

Veci is a generic vector of integers.

type VideoCapture

type VideoCapture struct {
	// contains filtered or unexported fields
}

VideoCapture is a wrapper around the OpenCV VideoCapture class.

For further details, please see: http://docs.opencv.org/master/d8/dfe/classcv_1_1VideoCapture.html

func OpenVideoCapture

func OpenVideoCapture(v interface{}) (*VideoCapture, error)

OpenVideoCapture return VideoCapture specified by device ID if v is a number. Return VideoCapture created from video file, URL, or GStreamer pipeline if v is a string.

func OpenVideoCaptureWithAPI

func OpenVideoCaptureWithAPI(v interface{}, apiPreference VideoCaptureAPI) (*VideoCapture, error)

func VideoCaptureDevice

func VideoCaptureDevice(device int) (vc *VideoCapture, err error)

VideoCaptureDevice opens a VideoCapture from a device and prepares to start capturing. It returns error if it fails to open the video device.

func VideoCaptureDeviceWithAPI

func VideoCaptureDeviceWithAPI(device int, apiPreference VideoCaptureAPI) (vc *VideoCapture, err error)

VideoCaptureDevice opens a VideoCapture from a device with the api preference. It returns error if it fails to open the video device.

func VideoCaptureFile

func VideoCaptureFile(uri string) (vc *VideoCapture, err error)

VideoCaptureFile opens a VideoCapture from a file and prepares to start capturing. It returns error if it fails to open the file stored in uri path.

func VideoCaptureFileWithAPI

func VideoCaptureFileWithAPI(uri string, apiPreference VideoCaptureAPI) (vc *VideoCapture, err error)

VideoCaptureFile opens a VideoCapture from a file and prepares to start capturing. It returns error if it fails to open the file stored in uri path.

func (*VideoCapture) Close

func (v *VideoCapture) Close() error

Close VideoCapture object.

func (*VideoCapture) CodecString

func (v *VideoCapture) CodecString() string

CodecString returns a string representation of FourCC bytes, i.e. the name of a codec

func (VideoCapture) Get

Get parameter with property (=key).

func (*VideoCapture) Grab

func (v *VideoCapture) Grab(skip int)

Grab skips a specific number of frames.

func (*VideoCapture) IsOpened

func (v *VideoCapture) IsOpened() bool

IsOpened returns if the VideoCapture has been opened to read from a file or capture device.

func (*VideoCapture) Read

func (v *VideoCapture) Read(m *Mat) bool

Read reads the next frame from the VideoCapture to the Mat passed in as the param. It returns false if the VideoCapture cannot read frame.

func (*VideoCapture) Set

func (v *VideoCapture) Set(prop VideoCaptureProperties, param float64)

Set parameter with property (=key).

func (*VideoCapture) ToCodec

func (v *VideoCapture) ToCodec(codec string) float64

ToCodec returns an float64 representation of FourCC bytes

type VideoCaptureAPI

type VideoCaptureAPI int

Select preferred API for a capture object. Note: Backends are available only if they have been built with your OpenCV binaries

const (
	// Auto detect == 0
	VideoCaptureAny VideoCaptureAPI = 0

	// Video For Windows (obsolete, removed)
	VideoCaptureVFW VideoCaptureAPI = 200

	// V4L/V4L2 capturing support
	VideoCaptureV4L VideoCaptureAPI = 200

	// Same as VideoCaptureV4L
	VideoCaptureV4L2 VideoCaptureAPI = 200

	// IEEE 1394 drivers
	VideoCaptureFirewire VideoCaptureAPI = 300

	// Same value as VideoCaptureFirewire
	VideoCaptureFireware VideoCaptureAPI = 300

	// Same value as VideoCaptureFirewire
	VideoCaptureIEEE1394 VideoCaptureAPI = 300

	// Same value as VideoCaptureFirewire
	VideoCaptureDC1394 VideoCaptureAPI = 300

	// Same value as VideoCaptureFirewire
	VideoCaptureCMU1394 VideoCaptureAPI = 300

	// QuickTime (obsolete, removed)
	VideoCaptureQT VideoCaptureAPI = 500

	// Unicap drivers (obsolete, removed)
	VideoCaptureUnicap VideoCaptureAPI = 600

	// DirectShow (via videoInput)
	VideoCaptureDshow VideoCaptureAPI = 700

	// PvAPI, Prosilica GigE SDK
	VideoCapturePvAPI VideoCaptureAPI = 800

	// OpenNI (for Kinect)
	VideoCaptureOpenNI VideoCaptureAPI = 900

	// OpenNI (for Asus Xtion)
	VideoCaptureOpenNIAsus VideoCaptureAPI = 910

	// Android - not used
	VideoCaptureAndroid VideoCaptureAPI = 1000

	// XIMEA Camera API
	VideoCaptureXiAPI VideoCaptureAPI = 1100

	// AVFoundation framework for iOS (OS X Lion will have the same API)
	VideoCaptureAVFoundation VideoCaptureAPI = 1200

	// Smartek Giganetix GigEVisionSDK
	VideoCaptureGiganetix VideoCaptureAPI = 1300

	// Microsoft Media Foundation (via videoInput)
	VideoCaptureMSMF VideoCaptureAPI = 1400

	// Microsoft Windows Runtime using Media Foundation
	VideoCaptureWinRT VideoCaptureAPI = 1410

	// RealSense (former Intel Perceptual Computing SDK)
	VideoCaptureIntelPerc VideoCaptureAPI = 1500

	// Synonym for VideoCaptureIntelPerc
	VideoCaptureRealsense VideoCaptureAPI = 1500

	// OpenNI2 (for Kinect)
	VideoCaptureOpenNI2 VideoCaptureAPI = 1600

	// OpenNI2 (for Asus Xtion and Occipital Structure sensors)
	VideoCaptureOpenNI2Asus VideoCaptureAPI = 1610

	// gPhoto2 connection
	VideoCaptureGPhoto2 VideoCaptureAPI = 1700

	// GStreamer
	VideoCaptureGstreamer VideoCaptureAPI = 1800

	// Open and record video file or stream using the FFMPEG library
	VideoCaptureFFmpeg VideoCaptureAPI = 1900

	// OpenCV Image Sequence (e.g. img_%02d.jpg)
	VideoCaptureImages VideoCaptureAPI = 2000

	// Aravis SDK
	VideoCaptureAravis VideoCaptureAPI = 2100

	// Built-in OpenCV MotionJPEG codec
	VideoCaptureOpencvMjpeg VideoCaptureAPI = 2200

	// Intel MediaSDK
	VideoCaptureIntelMFX VideoCaptureAPI = 2300

	// XINE engine (Linux)
	VideoCaptureXINE VideoCaptureAPI = 2400
)

func (VideoCaptureAPI) String

func (c VideoCaptureAPI) String() string

type VideoCaptureProperties

type VideoCaptureProperties int

VideoCaptureProperties are the properties used for VideoCapture operations.

const (
	// VideoCapturePosMsec contains current position of the
	// video file in milliseconds.
	VideoCapturePosMsec VideoCaptureProperties = 0

	// VideoCapturePosFrames 0-based index of the frame to be
	// decoded/captured next.
	VideoCapturePosFrames VideoCaptureProperties = 1

	// VideoCapturePosAVIRatio relative position of the video file:
	// 0=start of the film, 1=end of the film.
	VideoCapturePosAVIRatio VideoCaptureProperties = 2

	// VideoCaptureFrameWidth is width of the frames in the video stream.
	VideoCaptureFrameWidth VideoCaptureProperties = 3

	// VideoCaptureFrameHeight controls height of frames in the video stream.
	VideoCaptureFrameHeight VideoCaptureProperties = 4

	// VideoCaptureFPS controls capture frame rate.
	VideoCaptureFPS VideoCaptureProperties = 5

	// VideoCaptureFOURCC contains the 4-character code of codec.
	// see VideoWriter::fourcc for details.
	VideoCaptureFOURCC VideoCaptureProperties = 6

	// VideoCaptureFrameCount contains number of frames in the video file.
	VideoCaptureFrameCount VideoCaptureProperties = 7

	// VideoCaptureFormat format of the Mat objects returned by
	// VideoCapture::retrieve().
	VideoCaptureFormat VideoCaptureProperties = 8

	// VideoCaptureMode contains backend-specific value indicating
	// the current capture mode.
	VideoCaptureMode VideoCaptureProperties = 9

	// VideoCaptureBrightness is brightness of the image
	// (only for those cameras that support).
	VideoCaptureBrightness VideoCaptureProperties = 10

	// VideoCaptureContrast is contrast of the image
	// (only for cameras that support it).
	VideoCaptureContrast VideoCaptureProperties = 11

	// VideoCaptureSaturation saturation of the image
	// (only for cameras that support).
	VideoCaptureSaturation VideoCaptureProperties = 12

	// VideoCaptureHue hue of the image (only for cameras that support).
	VideoCaptureHue VideoCaptureProperties = 13

	// VideoCaptureGain is the gain of the capture image.
	// (only for those cameras that support).
	VideoCaptureGain VideoCaptureProperties = 14

	// VideoCaptureExposure is the exposure of the capture image.
	// (only for those cameras that support).
	VideoCaptureExposure VideoCaptureProperties = 15

	// VideoCaptureConvertRGB is a boolean flags indicating whether
	// images should be converted to RGB.
	VideoCaptureConvertRGB VideoCaptureProperties = 16

	// VideoCaptureWhiteBalanceBlueU is currently unsupported.
	VideoCaptureWhiteBalanceBlueU VideoCaptureProperties = 17

	// VideoCaptureRectification is the rectification flag for stereo cameras.
	// Note: only supported by DC1394 v 2.x backend currently.
	VideoCaptureRectification VideoCaptureProperties = 18

	// VideoCaptureMonochrome indicates whether images should be
	// converted to monochrome.
	VideoCaptureMonochrome VideoCaptureProperties = 19

	// VideoCaptureSharpness controls image capture sharpness.
	VideoCaptureSharpness VideoCaptureProperties = 20

	// VideoCaptureAutoExposure controls the DC1394 exposure control
	// done by camera, user can adjust reference level using this feature.
	VideoCaptureAutoExposure VideoCaptureProperties = 21

	// VideoCaptureGamma controls video capture gamma.
	VideoCaptureGamma VideoCaptureProperties = 22

	// VideoCaptureTemperature controls video capture temperature.
	VideoCaptureTemperature VideoCaptureProperties = 23

	// VideoCaptureTrigger controls video capture trigger.
	VideoCaptureTrigger VideoCaptureProperties = 24

	// VideoCaptureTriggerDelay controls video capture trigger delay.
	VideoCaptureTriggerDelay VideoCaptureProperties = 25

	// VideoCaptureWhiteBalanceRedV controls video capture setting for
	// white balance.
	VideoCaptureWhiteBalanceRedV VideoCaptureProperties = 26

	// VideoCaptureZoom controls video capture zoom.
	VideoCaptureZoom VideoCaptureProperties = 27

	// VideoCaptureFocus controls video capture focus.
	VideoCaptureFocus VideoCaptureProperties = 28

	// VideoCaptureGUID controls video capture GUID.
	VideoCaptureGUID VideoCaptureProperties = 29

	// VideoCaptureISOSpeed controls video capture ISO speed.
	VideoCaptureISOSpeed VideoCaptureProperties = 30

	// VideoCaptureBacklight controls video capture backlight.
	VideoCaptureBacklight VideoCaptureProperties = 32

	// VideoCapturePan controls video capture pan.
	VideoCapturePan VideoCaptureProperties = 33

	// VideoCaptureTilt controls video capture tilt.
	VideoCaptureTilt VideoCaptureProperties = 34

	// VideoCaptureRoll controls video capture roll.
	VideoCaptureRoll VideoCaptureProperties = 35

	// VideoCaptureIris controls video capture iris.
	VideoCaptureIris VideoCaptureProperties = 36

	// VideoCaptureSettings is the pop up video/camera filter dialog. Note:
	// only supported by DSHOW backend currently. The property value is ignored.
	VideoCaptureSettings VideoCaptureProperties = 37

	// VideoCaptureBufferSize controls video capture buffer size.
	VideoCaptureBufferSize VideoCaptureProperties = 38

	// VideoCaptureAutoFocus controls video capture auto focus..
	VideoCaptureAutoFocus VideoCaptureProperties = 39

	// VideoCaptureSarNumerator controls the sample aspect ratio: num/den (num)
	VideoCaptureSarNumerator VideoCaptureProperties = 40

	// VideoCaptureSarDenominator controls the sample aspect ratio: num/den (den)
	VideoCaptureSarDenominator VideoCaptureProperties = 41

	// VideoCaptureBackend is the current api backend (VideoCaptureAPI). Read-only property.
	VideoCaptureBackend VideoCaptureProperties = 42

	// VideoCaptureChannel controls the video input or channel number (only for those cameras that support).
	VideoCaptureChannel VideoCaptureProperties = 43

	// VideoCaptureAutoWB controls the auto white-balance.
	VideoCaptureAutoWB VideoCaptureProperties = 44

	// VideoCaptureWBTemperature controls the white-balance color temperature
	VideoCaptureWBTemperature VideoCaptureProperties = 45

	// VideoCaptureCodecPixelFormat shows the the codec's pixel format (4-character code). Read-only property.
	// Subset of AV_PIX_FMT_* or -1 if unknown.
	VideoCaptureCodecPixelFormat VideoCaptureProperties = 46

	// VideoCaptureBitrate displays the video bitrate in kbits/s. Read-only property.
	VideoCaptureBitrate VideoCaptureProperties = 47
)

func (VideoCaptureProperties) String

func (c VideoCaptureProperties) String() string

type VideoWriter

type VideoWriter struct {
	// contains filtered or unexported fields
}

VideoWriter is a wrapper around the OpenCV VideoWriter`class.

For further details, please see: http://docs.opencv.org/master/dd/d9e/classcv_1_1VideoWriter.html

func VideoWriterFile

func VideoWriterFile(name string, codec string, fps float64, width int, height int, isColor bool) (vw *VideoWriter, err error)

VideoWriterFile opens a VideoWriter with a specific output file. The "codec" param should be the four-letter code for the desired output codec, for example "MJPG".

For further details, please see: http://docs.opencv.org/master/dd/d9e/classcv_1_1VideoWriter.html#a0901c353cd5ea05bba455317dab81130

func (*VideoWriter) Close

func (vw *VideoWriter) Close() error

Close VideoWriter object.

func (*VideoWriter) IsOpened

func (vw *VideoWriter) IsOpened() bool

IsOpened checks if the VideoWriter is open and ready to be written to.

For further details, please see: http://docs.opencv.org/master/dd/d9e/classcv_1_1VideoWriter.html#a9a40803e5f671968ac9efa877c984d75

func (*VideoWriter) Write

func (vw *VideoWriter) Write(img Mat) error

Write the next video frame from the Mat image to the open VideoWriter.

For further details, please see: http://docs.opencv.org/master/dd/d9e/classcv_1_1VideoWriter.html#a3115b679d612a6a0b5864a0c88ed4b39

type Window

type Window struct {
	// contains filtered or unexported fields
}

Window is a wrapper around OpenCV's "HighGUI" named windows. While OpenCV was designed for use in full-scale applications and can be used within functionally rich UI frameworks (such as Qt*, WinForms*, or Cocoa*) or without any UI at all, sometimes there it is required to try functionality quickly and visualize the results. This is what the HighGUI module has been designed for.

For further details, please see: http://docs.opencv.org/master/d7/dfc/group__highgui.html

func NewWindow

func NewWindow(name string) *Window

NewWindow creates a new named OpenCV window

For further details, please see: http://docs.opencv.org/master/d7/dfc/group__highgui.html#ga5afdf8410934fd099df85c75b2e0888b

func (*Window) Close

func (w *Window) Close() error

Close closes and deletes a named OpenCV Window.

For further details, please see: http://docs.opencv.org/master/d7/dfc/group__highgui.html#ga851ccdd6961022d1d5b4c4f255dbab34

func (*Window) CreateTrackbar

func (w *Window) CreateTrackbar(name string, max int) *Trackbar

CreateTrackbar creates a trackbar and attaches it to the specified window.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#gaf78d2155d30b728fc413803745b67a9b

func (*Window) CreateTrackbarWithValue

func (w *Window) CreateTrackbarWithValue(name string, value *int, max int) *Trackbar

CreateTrackbarWithValue works like CreateTrackbar but also assigns a variable value to be a position synchronized with the trackbar.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#gaf78d2155d30b728fc413803745b67a9b

func (*Window) GetWindowProperty

func (w *Window) GetWindowProperty(flag WindowPropertyFlag) float64

GetWindowProperty returns properties of a window.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#gaaf9504b8f9cf19024d9d44a14e461656

func (*Window) IMShow

func (w *Window) IMShow(img Mat)

IMShow displays an image Mat in the specified window. This function should be followed by the WaitKey function which displays the image for specified milliseconds. Otherwise, it won't display the image.

For further details, please see: http://docs.opencv.org/master/d7/dfc/group__highgui.html#ga453d42fe4cb60e5723281a89973ee563

func (*Window) IsOpen

func (w *Window) IsOpen() bool

IsOpen checks to see if the Window seems to be open.

func (*Window) MoveWindow

func (w *Window) MoveWindow(x, y int)

MoveWindow moves window to the specified position.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga8d86b207f7211250dbe6e28f76307ffb

func (*Window) ResizeWindow

func (w *Window) ResizeWindow(width, height int)

ResizeWindow resizes window to the specified size.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga9e80e080f7ef33f897e415358aee7f7e

func (*Window) SelectROI

func (w *Window) SelectROI(img Mat) image.Rectangle

SelectROI selects a Region Of Interest (ROI) on the given image. It creates a window and allows user to select a ROI using mouse.

Controls: use space or enter to finish selection, use key c to cancel selection (function will return a zero Rect).

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga8daf4730d3adf7035b6de9be4c469af5

func (*Window) SelectROIs

func (w *Window) SelectROIs(img Mat) []image.Rectangle

SelectROIs selects multiple Regions Of Interest (ROI) on the given image. It creates a window and allows user to select ROIs using mouse.

Controls: use space or enter to finish current selection and start a new one use esc to terminate multiple ROI selection process

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga0f11fad74a6432b8055fb21621a0f893

func (*Window) SetWindowProperty

func (w *Window) SetWindowProperty(flag WindowPropertyFlag, value WindowFlag)

SetWindowProperty changes parameters of a window dynamically.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga66e4a6db4d4e06148bcdfe0d70a5df27

func (*Window) SetWindowTitle

func (w *Window) SetWindowTitle(title string)

SetWindowTitle updates window title.

For further details, please see: https://docs.opencv.org/master/d7/dfc/group__highgui.html#ga56f8849295fd10d0c319724ddb773d96

func (*Window) WaitKey

func (w *Window) WaitKey(delay int) int

WaitKey waits for a pressed key. This function is the only method in OpenCV's HighGUI that can fetch and handle events, so it needs to be called periodically for normal event processing

For further details, please see: http://docs.opencv.org/master/d7/dfc/group__highgui.html#ga5628525ad33f52eab17feebcfba38bd7

type WindowFlag

type WindowFlag float32

WindowFlag value for SetWindowProperty / GetWindowProperty.

const (
	// WindowNormal indicates a normal window.
	WindowNormal WindowFlag = 0x00000000

	// WindowAutosize indicates a window sized based on the contents.
	WindowAutosize WindowFlag = 0x00000001

	// WindowFullscreen indicates a full-screen window.
	WindowFullscreen WindowFlag = 1

	// WindowFreeRatio indicates allow the user to resize without maintaining aspect ratio.
	WindowFreeRatio WindowFlag = 0x00000100

	// WindowKeepRatio indicates always maintain an aspect ratio that matches the contents.
	WindowKeepRatio WindowFlag = 0x00000000
)

func (WindowFlag) String

func (c WindowFlag) String() string

type WindowPropertyFlag

type WindowPropertyFlag int

WindowPropertyFlag flags for SetWindowProperty / GetWindowProperty.

const (
	// WindowPropertyFullscreen fullscreen property
	// (can be WINDOW_NORMAL or WINDOW_FULLSCREEN).
	WindowPropertyFullscreen WindowPropertyFlag = 0

	// WindowPropertyAutosize is autosize property
	// (can be WINDOW_NORMAL or WINDOW_AUTOSIZE).
	WindowPropertyAutosize WindowPropertyFlag = 1

	// WindowPropertyAspectRatio window's aspect ration
	// (can be set to WINDOW_FREERATIO or WINDOW_KEEPRATIO).
	WindowPropertyAspectRatio WindowPropertyFlag = 2

	// WindowPropertyOpenGL opengl support.
	WindowPropertyOpenGL WindowPropertyFlag = 3

	// WindowPropertyVisible or not.
	WindowPropertyVisible WindowPropertyFlag = 4
)

func (WindowPropertyFlag) String

func (c WindowPropertyFlag) String() string

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