Delphi-OpenCV/source/ocv.calib3d_c.pas
Laentir Valetov 9a5de509ee FPC
Signed-off-by: Laentir Valetov <laex@bk.ru>
2019-09-16 15:29:05 +04:00

1012 lines
43 KiB
ObjectPascal

(*
**************************************************************************************************
Project Delphi-OpenCV
**************************************************************************************************
Contributor:
Laentir Valetov
email:laex@bk.ru
Mikhail Grigorev
email:sleuthhound@gmail.com
**************************************************************************************************
You may retrieve the latest version of this file at the GitHub,
located at git://github.com/Laex/Delphi-OpenCV.git
**************************************************************************************************
License:
The contents of this file are subject to the Mozilla Public License Version 1.1 (the "License");
you may not use this file except in compliance with the License. You may obtain a copy of the
License at http://www.mozilla.org/MPL/
Software distributed under the License is distributed on an "AS IS" basis, WITHOUT WARRANTY OF
ANY KIND, either express or implied. See the License for the specific language governing rights
and limitations under the License.
Alternatively, the contents of this file may be used under the terms of the
GNU Lesser General Public License (the "LGPL License"), in which case the
provisions of the LGPL License are applicable instead of those above.
If you wish to allow use of your version of this file only under the terms
of the LGPL License and not to allow others to use your version of this file
under the MPL, indicate your decision by deleting the provisions above and
replace them with the notice and other provisions required by the LGPL
License. If you do not delete the provisions above, a recipient may use
your version of this file under either the MPL or the LGPL License.
For more information about the LGPL: http://www.gnu.org/copyleft/lesser.html
**************************************************************************************************
Warning: Using Delphi XE3 syntax!
**************************************************************************************************
The Initial Developer of the Original Code:
OpenCV: open source computer vision library
Homepage: http://ocv.org
Online docs: http://docs.ocv.org
Q&A forum: http://answers.ocv.org
Dev zone: http://code.ocv.org
**************************************************************************************************
Original file:
opencv\modules\calib3d\include\opencv2\calib3d\calib3d_c.h
*************************************************************************************************
*)
unit ocv.calib3d_c;
{$I OpenCV.inc}
interface
uses
ocv.core.types_c,
ocv.compat;
(* ***************************************************************************************
* Camera Calibration, Pose Estimation and Stereo *
**************************************************************************************** *)
Type
// typedef struct CvPOSITObject CvPOSITObject;
PCvPOSITObject = ^TCvPOSITObject;
TCvPOSITObject = record
N: Integer;
inv_matr: PSingle;
obj_vecs: PSingle;
img_vecs: PSingle;
end;
(*
Allocates and initializes CvPOSITObject structure before doing cvPOSIT
CVAPI(CvPOSITObject* ) cvCreatePOSITObject( CvPoint3D32f* points, int point_count );
*)
{$IFDEF SAFELOADLIB}
Type
TcvCreatePOSITObject = function(points: pCvPoint3D32f; point_count: Integer): PCvPOSITObject; cdecl;
var
cvCreatePOSITObject: TcvCreatePOSITObject;
{$ELSE}
function cvCreatePOSITObject(points: pCvPoint3D32f; point_count: Integer): PCvPOSITObject; cdecl;
{$ENDIF}
(* Runs POSIT (POSe from ITeration) algorithm for determining 3d position of
an object given its model and projection in a weak-perspective case
CVAPI(void) cvPOSIT( CvPOSITObject* posit_object, CvPoint2D32f* image_points,
double focal_length, CvTermCriteria criteria,
float* rotation_matrix, float* translation_vector);
*)
{$IFDEF SAFELOADLIB}
Type
TcvPOSIT = procedure(posit_object: PCvPOSITObject; imagePoints: pCvPoint2D32f; focal_length: double; criteria: TCvTermCriteria; rotation_matrix: TCvMatr32f;
translation_vector: TCvVect32f); cdecl;
var
cvPOSIT: TcvPOSIT;
{$ELSE}
procedure cvPOSIT(posit_object: PCvPOSITObject; imagePoints: pCvPoint2D32f; focal_length: double; criteria: TCvTermCriteria; rotation_matrix: TCvMatr32f;
translation_vector: TCvVect32f); cdecl;
{$ENDIF}
(*
Releases CvPOSITObject structure
CVAPI(void) cvReleasePOSITObject( CvPOSITObject** posit_object );
*)
{$IFDEF SAFELOADLIB}
Type
TcvReleasePOSITObject = procedure(Var posit_object: PCvPOSITObject); cdecl;
var
cvReleasePOSITObject: TcvReleasePOSITObject;
{$ELSE}
procedure cvReleasePOSITObject(Var posit_object: PCvPOSITObject); cdecl;
{$ENDIF}
(* updates the number of RANSAC iterations
CVAPI(int) cvRANSACUpdateNumIters( double p, double err_prob,
int model_points, int max_iters );
*)
{$IFDEF SAFELOADLIB}
Type
TcvRANSACUpdateNumIters = function(p: double; err_prob: double; model_points: Integer; max_iters: Integer): Integer; cdecl;
var
cvRANSACUpdateNumIters: TcvRANSACUpdateNumIters;
{$ELSE}
function cvRANSACUpdateNumIters(p: double; err_prob: double; model_points: Integer; max_iters: Integer): Integer; cdecl;
{$ENDIF}
(* CVAPI(void) cvConvertPointsHomogeneous( const CvMat* src, CvMat* dst ); *)
{$IFDEF SAFELOADLIB}
type
TcvConvertPointsHomogeneous = procedure(const src: pCvMat; dst: pCvMat); cdecl;
var
cvConvertPointsHomogeneous: TcvConvertPointsHomogeneous;
{$ELSE}
procedure cvConvertPointsHomogeneous(const src: pCvMat; dst: pCvMat); cdecl;
{$ENDIF}
const
(* Calculates fundamental matrix given a set of corresponding points *)
CV_FM_7POINT = 1;
CV_FM_8POINT = 2;
CV_LMEDS = 4;
CV_RANSAC = 8;
CV_FM_LMEDS_ONLY = CV_LMEDS;
CV_FM_RANSAC_ONLY = CV_RANSAC;
CV_FM_LMEDS = CV_LMEDS;
CV_FM_RANSAC = CV_RANSAC;
CV_ITERATIVE = 0;
CV_EPNP = 1; // F.Moreno-Noguer, V.Lepetit and P.Fua "EPnP: Efficient Perspective-n-Point Camera Pose Estimation"
CV_P3P = 2;
// X.S. Gao, X.-R. Hou, J. Tang, H.-F. Chang; "Complete Solution Classification for the Perspective-Three-Point Problem"
(*
CVAPI(int) cvFindFundamentalMat( const CvMat* points1, const CvMat* points2,
CvMat* fundamental_matrix,
int method CV_DEFAULT(CV_FM_RANSAC),
double param1 CV_DEFAULT(3.), double param2 CV_DEFAULT(0.99),
CvMat* status CV_DEFAULT(NULL) );
*)
{$IFDEF SAFELOADLIB}
Type
TcvFindFundamentalMat = function(const points1: pCvMat; const points2: pCvMat; fundamental_matrix: pCvMat; method: Integer = CV_FM_RANSAC; param1: double = 3;
param2: double = 0.99; status: pCvMat = nil): Integer; cdecl;
Var
cvFindFundamentalMat: TcvFindFundamentalMat;
{$ELSE}
function cvFindFundamentalMat(const points1: pCvMat; const points2: pCvMat; fundamental_matrix: pCvMat; method: Integer = CV_FM_RANSAC; param1: double = 3;
param2: double = 0.99; status: pCvMat = nil): Integer; cdecl;
{$ENDIF}
(*
For each input point on one of images
computes parameters of the corresponding
epipolar line on the other image
CVAPI(void) cvComputeCorrespondEpilines( const CvMat* points,
int which_image,
const CvMat* fundamental_matrix,
CvMat* correspondent_lines );
*)
{$IFDEF SAFELOADLIB}
Type
TcvComputeCorrespondEpilines = procedure(const points: pCvMat; which_image: Integer; const fundamental_matrix: pCvMat; correspondent_lines: pCvMat); cdecl;
var
cvComputeCorrespondEpilines: TcvComputeCorrespondEpilines;
{$ELSE}
procedure cvComputeCorrespondEpilines(const points: pCvMat; which_image: Integer; const fundamental_matrix: pCvMat; correspondent_lines: pCvMat); cdecl;
{$ENDIF}
(*
Triangulation functions
CVAPI(void) cvTriangulatePoints(CvMat* projMatr1, CvMat* projMatr2,
CvMat* projPoints1, CvMat* projPoints2,
CvMat* points4D);
*)
{$IFDEF SAFELOADLIB}
Type
TcvTriangulatePoints = procedure(projMatr1: pCvMat; projMatr2: pCvMat; projPoints1: pCvMat; projPoints2: pCvMat; points4D: pCvMat); cdecl;
var
cvTriangulatePoints: TcvTriangulatePoints;
{$ELSE}
procedure cvTriangulatePoints(projMatr1: pCvMat; projMatr2: pCvMat; projPoints1: pCvMat; projPoints2: pCvMat; points4D: pCvMat); cdecl;
{$ENDIF}
(*
CVAPI(void) cvCorrectMatches(CvMat* F, CvMat* points1, CvMat* points2,
CvMat* new_points1, CvMat* new_points2);
*)
{$IFDEF SAFELOADLIB}
type
TcvCorrectMatches = procedure(F: pCvMat; points1: pCvMat; points2: pCvMat; new_points1: pCvMat; new_points2: pCvMat); cdecl;
var
cvCorrectMatches: TcvCorrectMatches;
{$ELSE}
procedure cvCorrectMatches(F: pCvMat; points1: pCvMat; points2: pCvMat; new_points1: pCvMat; new_points2: pCvMat); cdecl;
{$ENDIF}
(*
Computes the optimal new camera matrix according to the free scaling parameter alpha:
alpha=0 - only valid pixels will be retained in the undistorted image
alpha=1 - all the source image pixels will be retained in the undistorted image
CVAPI(void) cvGetOptimalNewCameraMatrix( const CvMat* camera_matrix,
const CvMat* dist_coeffs,
CvSize image_size, double alpha,
CvMat* new_camera_matrix,
CvSize new_imag_size CV_DEFAULT(cvSize(0,0)),
CvRect* valid_pixel_ROI CV_DEFAULT(0),
int center_principal_point CV_DEFAULT(0));
*)
{$IFDEF SAFELOADLIB}
Type
TcvGetOptimalNewCameraMatrix = procedure(const camera_matrix: pCvMat; const dist_coeffs: pCvMat; image_size: TCvSize; alpha: double;
new_camera_matrix: pCvMat; new_imag_size: TCvSize { = CV_DEFAULT(cvSize(0,0))) }; valid_pixel_ROI: PCvRect = nil;
center_principal_point: Integer = 0); cdecl;
var
cvGetOptimalNewCameraMatrix: TcvGetOptimalNewCameraMatrix;
{$ELSE}
procedure cvGetOptimalNewCameraMatrix(const camera_matrix: pCvMat; const dist_coeffs: pCvMat; image_size: TCvSize; alpha: double; new_camera_matrix: pCvMat;
new_imag_size: TCvSize { = CV_DEFAULT(cvSize(0,0))) }; valid_pixel_ROI: PCvRect = nil; center_principal_point: Integer = 0); cdecl;
{$ENDIF}
(*
Converts rotation vector to rotation matrix or vice versa
CVAPI(int) cvRodrigues2( const CvMat* src, CvMat* dst,
CvMat* jacobian CV_DEFAULT(0) );
*)
{$IFDEF SAFELOADLIB}
type
TcvRodrigues2 = function(const src: pCvMat; dst: pCvMat; jacobian: pCvMat = nil): Integer; cdecl;
var
cvRodrigues2: TcvRodrigues2;
{$ELSE}
function cvRodrigues2(const src: pCvMat; dst: pCvMat; jacobian: pCvMat = nil): Integer; cdecl;
{$ENDIF}
(*
Finds perspective transformation between the object plane and image (view) plane
CVAPI(int) cvFindHomography( const CvMat* src_points,
const CvMat* dst_points,
CvMat* homography,
int method CV_DEFAULT(0),
double ransacReprojThreshold CV_DEFAULT(3),
CvMat* mask CV_DEFAULT(0));
*)
{$IFDEF SAFELOADLIB}
type
TcvFindHomography = function(const src_points: pCvMat; const dst_points: pCvMat; homography: pCvMat; method: Integer = 0; ransacReprojThreshold: double = 3;
mask: pCvMat = nil): Integer; cdecl;
Var
cvFindHomography: TcvFindHomography;
{$ELSE}
function cvFindHomography(const src_points: pCvMat; const dst_points: pCvMat; homography: pCvMat; method: Integer = 0; ransacReprojThreshold: double = 3;
mask: pCvMat = nil): Integer; cdecl;
{$ENDIF}
(*
Computes RQ decomposition for 3x3 matrices
CVAPI(void) cvRQDecomp3x3( const CvMat *matrixM, CvMat *matrixR, CvMat *matrixQ,
CvMat *matrixQx CV_DEFAULT(NULL),
CvMat *matrixQy CV_DEFAULT(NULL),
CvMat *matrixQz CV_DEFAULT(NULL),
CvPoint3D64f *eulerAngles CV_DEFAULT(NULL));
*)
{$IFDEF SAFELOADLIB}
type
TcvRQDecomp3x3 = procedure(const matrixM: pCvMat; matrixR: pCvMat; matrixQ: pCvMat; matrixQx: pCvMat = nil; matrixQy: pCvMat = nil; matrixQz: pCvMat = nil;
eulerAngles: PCvPoint3D64f = nil); cdecl;
Var
cvRQDecomp3x3: TcvRQDecomp3x3;
{$ELSE}
procedure cvRQDecomp3x3(const matrixM: pCvMat; matrixR: pCvMat; matrixQ: pCvMat; matrixQx: pCvMat = nil; matrixQy: pCvMat = nil; matrixQz: pCvMat = nil;
eulerAngles: PCvPoint3D64f = nil); cdecl;
{$ENDIF}
(*
Computes projection matrix decomposition
CVAPI(void) cvDecomposeProjectionMatrix( const CvMat *projMatr, CvMat *calibMatr,
CvMat *rotMatr, CvMat *posVect,
CvMat *rotMatrX CV_DEFAULT(NULL),
CvMat *rotMatrY CV_DEFAULT(NULL),
CvMat *rotMatrZ CV_DEFAULT(NULL),
CvPoint3D64f *eulerAngles CV_DEFAULT(NULL));
*)
{$IFDEF SAFELOADLIB}
Type
TcvDecomposeProjectionMatrix = procedure(const projMatr: pCvMat; calibMatr: pCvMat; rotMatr: pCvMat; posVect: pCvMat; rotMatrX: pCvMat = nil;
rotMatrY: pCvMat = nil; rotMatrZ: pCvMat = nil; eulerAngles: PCvPoint3D64f = nil); cdecl;
var
cvDecomposeProjectionMatrix: TcvDecomposeProjectionMatrix;
{$ELSE}
procedure cvDecomposeProjectionMatrix(const projMatr: pCvMat; calibMatr: pCvMat; rotMatr: pCvMat; posVect: pCvMat; rotMatrX: pCvMat = nil;
rotMatrY: pCvMat = nil; rotMatrZ: pCvMat = nil; eulerAngles: PCvPoint3D64f = nil); cdecl;
{$ENDIF}
(*
Computes d(AB)/dA and d(AB)/dB
CVAPI(void) cvCalcMatMulDeriv( const CvMat* A, const CvMat* B, CvMat* dABdA, CvMat* dABdB );
*)
{$IFDEF SAFELOADLIB}
type
TcvCalcMatMulDeriv = procedure(const A: pCvMat; const B: pCvMat; dABdA: pCvMat; dABdB: pCvMat); cdecl;
var
cvCalcMatMulDeriv: TcvCalcMatMulDeriv;
{$ELSE}
procedure cvCalcMatMulDeriv(const A: pCvMat; const B: pCvMat; dABdA: pCvMat; dABdB: pCvMat); cdecl;
{$ENDIF}
(*
Computes r3 = rodrigues(rodrigues(r2)*rodrigues(r1)),
t3 = rodrigues(r2)*t1 + t2 and the respective derivatives
CVAPI(void) cvComposeRT( const CvMat* _rvec1, const CvMat* _tvec1,
const CvMat* _rvec2, const CvMat* _tvec2,
CvMat* _rvec3, CvMat* _tvec3,
CvMat* dr3dr1 CV_DEFAULT(0), CvMat* dr3dt1 CV_DEFAULT(0),
CvMat* dr3dr2 CV_DEFAULT(0), CvMat* dr3dt2 CV_DEFAULT(0),
CvMat* dt3dr1 CV_DEFAULT(0), CvMat* dt3dt1 CV_DEFAULT(0),
CvMat* dt3dr2 CV_DEFAULT(0), CvMat* dt3dt2 CV_DEFAULT(0) );
*)
{$IFDEF SAFELOADLIB}
type
TcvComposeRT = procedure(const _rvec1: pCvMat; const _tvec1: pCvMat; const _rvec2: pCvMat; const _tvec2: pCvMat; _rvec3: pCvMat; _tvec3: pCvMat;
dr3dr1: pCvMat = nil; dr3dt1: pCvMat = nil; dr3dr2: pCvMat = nil; dr3dt2: pCvMat = nil; dt3dr1: pCvMat = nil; dt3dt1: pCvMat = nil; dt3dr2: pCvMat = nil;
dt3dt2: pCvMat = nil); cdecl;
var
cvComposeRT: TcvComposeRT;
{$ELSE}
procedure cvComposeRT(const _rvec1: pCvMat; const _tvec1: pCvMat; const _rvec2: pCvMat; const _tvec2: pCvMat; _rvec3: pCvMat; _tvec3: pCvMat;
dr3dr1: pCvMat = nil; dr3dt1: pCvMat = nil; dr3dr2: pCvMat = nil; dr3dt2: pCvMat = nil; dt3dr1: pCvMat = nil; dt3dt1: pCvMat = nil; dt3dr2: pCvMat = nil;
dt3dt2: pCvMat = nil); cdecl;
{$ENDIF}
(*
Projects object points to the view plane using
the specified extrinsic and intrinsic camera parameters
CVAPI(void) cvProjectPoints2( const CvMat* object_points, const CvMat* rotation_vector,
const CvMat* translation_vector, const CvMat* camera_matrix,
const CvMat* distortion_coeffs, CvMat* image_points,
CvMat* dpdrot CV_DEFAULT(NULL), CvMat* dpdt CV_DEFAULT(NULL),
CvMat* dpdf CV_DEFAULT(NULL), CvMat* dpdc CV_DEFAULT(NULL),
CvMat* dpddist CV_DEFAULT(NULL),
double aspect_ratio CV_DEFAULT(0));
*)
{$IFDEF SAFELOADLIB}
type
TcvProjectPoints2 = procedure(const object_points: pCvMat; const rotation_vector: pCvMat; const translation_vector: pCvMat; const camera_matrix: pCvMat;
const distortion_coeffs: pCvMat; image_points: pCvMat; dpdrot: pCvMat = nil; dpdt: pCvMat = nil; dpdf: pCvMat = nil; dpdc: pCvMat = nil;
dpddist: pCvMat = nil; aspect_ratio: double = 0); cdecl;
var
cvProjectPoints2: TcvProjectPoints2;
{$ELSE}
procedure cvProjectPoints2(const object_points: pCvMat; const rotation_vector: pCvMat; const translation_vector: pCvMat; const camera_matrix: pCvMat;
const distortion_coeffs: pCvMat; image_points: pCvMat; dpdrot: pCvMat = nil; dpdt: pCvMat = nil; dpdf: pCvMat = nil; dpdc: pCvMat = nil;
dpddist: pCvMat = nil; aspect_ratio: double = 0); cdecl;
{$ENDIF}
(* Finds extrinsic camera parameters from
a few known corresponding point pairs and intrinsic parameters
CVAPI(void) cvFindExtrinsicCameraParams2( const CvMat* object_points,
const CvMat* image_points,
const CvMat* camera_matrix,
const CvMat* distortion_coeffs,
CvMat* rotation_vector,
CvMat* translation_vector,
int use_extrinsic_guess CV_DEFAULT(0) );
*)
{$IFDEF SAFELOADLIB}
type
TcvFindExtrinsicCameraParams2 = procedure(const object_points: pCvMat; const image_points: pCvMat; const camera_matrix: pCvMat;
const distortion_coeffs: pCvMat; rotation_vector: pCvMat; translation_vector: pCvMat; use_extrinsic_guess: Integer = 0); cdecl;
var
cvFindExtrinsicCameraParams2: TcvFindExtrinsicCameraParams2;
{$ELSE}
procedure cvFindExtrinsicCameraParams2(const object_points: pCvMat; const image_points: pCvMat; const camera_matrix: pCvMat; const distortion_coeffs: pCvMat;
rotation_vector: pCvMat; translation_vector: pCvMat; use_extrinsic_guess: Integer = 0); cdecl;
{$ENDIF}
(* Computes initial estimate of the intrinsic camera parameters
in case of planar calibration target (e.g. chessboard)
CVAPI(void) cvInitIntrinsicParams2D( const CvMat* object_points,
const CvMat* image_points,
const CvMat* npoints, CvSize image_size,
CvMat* camera_matrix,
double aspect_ratio CV_DEFAULT(1.));
*)
{$IFDEF SAFELOADLIB}
Type
TcvInitIntrinsicParams2D = procedure(const object_points: pCvMat; const image_points: pCvMat; const npoints: pCvMat; image_size: TCvSize;
camera_matrix: pCvMat; aspect_ratio: double = 1); cdecl;
var
cvInitIntrinsicParams2D: TcvInitIntrinsicParams2D;
{$ELSE}
procedure cvInitIntrinsicParams2D(const object_points: pCvMat; const image_points: pCvMat; const npoints: pCvMat; image_size: TCvSize; camera_matrix: pCvMat;
aspect_ratio: double = 1); cdecl;
{$ENDIF}
const
CV_CALIB_CB_ADAPTIVE_THRESH = 1;
CV_CALIB_CB_NORMALIZE_IMAGE = 2;
CV_CALIB_CB_FILTER_QUADS = 4;
CV_CALIB_CB_FAST_CHECK = 8;
(* Performs a fast check if a chessboard is in the input image. This is a workaround to
a problem of cvFindChessboardCorners being slow on images with no chessboard
- src: input image
- size: chessboard size
Returns 1 if a chessboard can be in this image and findChessboardCorners should be called,
0 if there is no chessboard, -1 in case of error
CVAPI(int) cvCheckChessboard(IplImage* src, CvSize size);
*)
{$IFDEF SAFELOADLIB}
Type
TcvCheckChessboard = function(const image: pCvArr; size: TCvSize): Integer; cdecl;
var
cvCheckChessboard: TcvCheckChessboard;
{$ELSE}
function cvCheckChessboard(const image: pCvArr; size: TCvSize): Integer; cdecl;
{$ENDIF}
(*
Detects corners on a chessboard calibration pattern
CVAPI(int) cvFindChessboardCorners(
const void* image,
CvSize pattern_size,
CvPoint2D32f* corners,
int* corner_count CV_DEFAULT(NULL),
int flags CV_DEFAULT(CV_CALIB_CB_ADAPTIVE_THRESH+CV_CALIB_CB_NORMALIZE_IMAGE) );
*)
{$IFDEF SAFELOADLIB}
type
TcvFindChessboardCorners = function(const image: Pointer; pattern_size: TCvSize; corners: pCvPoint2D32f; corner_count: pInteger = nil;
flags: Integer = CV_CALIB_CB_ADAPTIVE_THRESH + CV_CALIB_CB_NORMALIZE_IMAGE): Integer; cdecl;
var
cvFindChessboardCorners: TcvFindChessboardCorners;
{$ELSE}
function cvFindChessboardCorners(const image: Pointer; pattern_size: TCvSize; corners: pCvPoint2D32f; corner_count: pInteger = nil;
flags: Integer = CV_CALIB_CB_ADAPTIVE_THRESH + CV_CALIB_CB_NORMALIZE_IMAGE): Integer; cdecl;
{$ENDIF}
const
CV_CALIB_USE_INTRINSIC_GUESS = 1;
CV_CALIB_FIX_ASPECT_RATIO = 2;
CV_CALIB_FIX_PRINCIPAL_POINT = 4;
CV_CALIB_ZERO_TANGENT_DIST = 8;
CV_CALIB_FIX_FOCAL_LENGTH = 16;
CV_CALIB_FIX_K1 = 32;
CV_CALIB_FIX_K2 = 64;
CV_CALIB_FIX_K3 = 128;
CV_CALIB_FIX_K4 = 2048;
CV_CALIB_FIX_K5 = 4096;
CV_CALIB_FIX_K6 = 8192;
CV_CALIB_RATIONAL_MODEL = 16384;
CV_CALIB_THIN_PRISM_MODEL = 32768;
CV_CALIB_FIX_S1_S2_S3_S4 = 65536;
(*
Draws individual chessboard corners or the whole chessboard detected
CVAPI(void) cvDrawChessboardCorners(
CvArr* image,
CvSize pattern_size,
CvPoint2D32f* corners,
int count,
int pattern_was_found );
*)
{$IFDEF SAFELOADLIB}
type
TcvDrawChessboardCorners = procedure(image: pIplImage; pattern_size: TCvSize; corners: pCvPoint2D32f; count: Integer; pattern_was_found: Integer); cdecl;
var
cvDrawChessboardCorners: TcvDrawChessboardCorners;
{$ELSE}
procedure cvDrawChessboardCorners(image: pIplImage; pattern_size: TCvSize; corners: pCvPoint2D32f; count: Integer; pattern_was_found: Integer); cdecl;
{$ENDIF}
{
/* Finds intrinsic and extrinsic camera parameters
from a few views of known calibration pattern *)
CVAPI(double) cvCalibrateCamera2(
const CvMat* object_points,
const CvMat* image_points,
const CvMat* point_counts,
CvSize image_size,
CvMat* camera_matrix,
CvMat* distortion_coeffs,
CvMat* rotation_vectors CV_DEFAULT(NULL),
CvMat* translation_vectors CV_DEFAULT(NULL),
int flags CV_DEFAULT(0),
CvTermCriteria term_crit CV_DEFAULT(cvTermCriteria(CV_TERMCRIT_ITER+CV_TERMCRIT_EPS,30,DBL_EPSILON)) );
}
{$IFDEF SAFELOADLIB}
type
TcvCalibrateCamera2 = function(
{ } const object_points: pCvMat;
{ } const image_points: pCvMat;
{ } const point_counts: pCvMat;
{ } image_size: TCvSize;
{ } camera_matrix: pCvMat;
{ } distortion_coeffs: pCvMat;
{ } rotation_vectors: pCvMat { =nil };
{ } translation_vectors: pCvMat { =nil };
{ } flags: Integer { =0 };
{ } term_crit: TCvTermCriteria { =cvTermCriteria(CV_TERMCRIT_ITER+CV_TERMCRIT_EPS,30,DBL_EPSILON) }
): double; cdecl;
var
cvCalibrateCamera2: TcvCalibrateCamera2;
{$ELSE}
function cvCalibrateCamera2(
{ } const object_points: pCvMat;
{ } const image_points: pCvMat;
{ } const point_counts: pCvMat;
{ } image_size: TCvSize;
{ } camera_matrix: pCvMat;
{ } distortion_coeffs: pCvMat;
{ } rotation_vectors: pCvMat { =nil };
{ } translation_vectors: pCvMat { =nil };
{ } flags: Integer { =0 };
{ } term_crit: TCvTermCriteria { =cvTermCriteria(CV_TERMCRIT_ITER+CV_TERMCRIT_EPS,30,DBL_EPSILON) }
): double; cdecl;
{$ENDIF}
(* Computes various useful characteristics of the camera from the data computed by
cvCalibrateCamera2
CVAPI(void) cvCalibrationMatrixValues( const CvMat *camera_matrix,
CvSize image_size,
double aperture_width CV_DEFAULT(0),
double aperture_height CV_DEFAULT(0),
double *fovx CV_DEFAULT(NULL),
double *fovy CV_DEFAULT(NULL),
double *focal_length CV_DEFAULT(NULL),
CvPoint2D64f *principal_point CV_DEFAULT(NULL),
double *pixel_aspect_ratio CV_DEFAULT(NULL));
*)
{$IFDEF SAFELOADLIB}
type
TcvCalibrationMatrixValues = procedure(const camera_matrix: pCvMat; image_size: TCvSize; aperture_width: double = 0; aperture_height: double = 0;
fovx: PDouble = nil; fovy: PDouble = nil; focal_length: PDouble = nil; principal_point: PCvPoint2D64f = nil; pixel_aspect_ratio: PDouble = nil); cdecl;
Var
cvCalibrationMatrixValues: TcvCalibrationMatrixValues;
{$ELSE}
procedure cvCalibrationMatrixValues(const camera_matrix: pCvMat; image_size: TCvSize; aperture_width: double = 0; aperture_height: double = 0;
fovx: PDouble = nil; fovy: PDouble = nil; focal_length: PDouble = nil; principal_point: PCvPoint2D64f = nil; pixel_aspect_ratio: PDouble = nil); cdecl;
{$ENDIF}
const
CV_CALIB_FIX_INTRINSIC = 256;
CV_CALIB_SAME_FOCAL_LENGTH = 512;
(* Computes the transformation from one camera coordinate system to another one
from a few correspondent views of the same calibration target. Optionally, calibrates
both cameras
CVAPI(double) cvStereoCalibrate( const CvMat* object_points, const CvMat* image_points1,
const CvMat* image_points2, const CvMat* npoints,
CvMat* camera_matrix1, CvMat* dist_coeffs1,
CvMat* camera_matrix2, CvMat* dist_coeffs2,
CvSize image_size, CvMat* R, CvMat* T,
CvMat* E CV_DEFAULT(0), CvMat* F CV_DEFAULT(0),
CvTermCriteria term_crit CV_DEFAULT(cvTermCriteria(
CV_TERMCRIT_ITER+CV_TERMCRIT_EPS,30,1e-6)),
int flags CV_DEFAULT(CV_CALIB_FIX_INTRINSIC));
*)
{$IFDEF SAFELOADLIB}
type
TcvStereoCalibrate = function(const object_points: pCvMat; const image_points1: pCvMat; const image_points2: pCvMat; const npoints: pCvMat;
camera_matrix1: pCvMat; dist_coeffs1: pCvMat; camera_matrix2: pCvMat; dist_coeffs2: pCvMat; image_size: TCvSize; R: pCvMat; T: pCvMat; E: pCvMat { = nil };
F: pCvMat { = nil }; term_crit: TCvTermCriteria { = CV_DEFAULT(cvTermCriteria(CV_TERMCRIT_ITER + CV_TERMCRIT_EPS, 30, 1E-6)) };
flags: Integer { = CV_DEFAULT(CV_CALIB_FIX_INTRINSIC) } ): double; cdecl;
var
cvStereoCalibrate: TcvStereoCalibrate;
{$ELSE}
function cvStereoCalibrate(const object_points: pCvMat; const image_points1: pCvMat; const image_points2: pCvMat; const npoints: pCvMat; camera_matrix1: pCvMat;
dist_coeffs1: pCvMat; camera_matrix2: pCvMat; dist_coeffs2: pCvMat; image_size: TCvSize; R: pCvMat; T: pCvMat; E: pCvMat { = nil }; F: pCvMat { = nil };
term_crit: TCvTermCriteria { = CV_DEFAULT(cvTermCriteria(CV_TERMCRIT_ITER + CV_TERMCRIT_EPS, 30, 1E-6)) };
flags: Integer { = CV_DEFAULT(CV_CALIB_FIX_INTRINSIC) } ): double; cdecl;
{$ENDIF}
const
CV_CALIB_ZERO_DISPARITY = 1024;
(*
Computes 3D rotations (+ optional shift) for each camera coordinate system to make both
views parallel (=> to make all the epipolar lines horizontal or vertical)
CVAPI(void) cvStereoRectify( const CvMat* camera_matrix1, const CvMat* camera_matrix2,
const CvMat* dist_coeffs1, const CvMat* dist_coeffs2,
CvSize image_size, const CvMat* R, const CvMat* T,
CvMat* R1, CvMat* R2, CvMat* P1, CvMat* P2,
CvMat* Q CV_DEFAULT(0),
int flags CV_DEFAULT(CV_CALIB_ZERO_DISPARITY),
double alpha CV_DEFAULT(-1),
CvSize new_image_size CV_DEFAULT(cvSize(0,0)),
CvRect* valid_pix_ROI1 CV_DEFAULT(0),
CvRect* valid_pix_ROI2 CV_DEFAULT(0));
*)
{$IFDEF SAFELOADLIB}
type
TcvStereoRectify = procedure(const camera_matrix1: pCvMat; const camera_matrix2: pCvMat; const dist_coeffs1: pCvMat; const dist_coeffs2: pCvMat;
image_size: TCvSize; const R: pCvMat; const T: pCvMat; R1: pCvMat; R2: pCvMat; P1: pCvMat; P2: pCvMat; Q: pCvMat { = nil };
flags: Integer { = CV_CALIB_ZERO_DISPARITY }; alpha: double { = -1 }; new_image_size: TCvSize { =CV_DEFAULT(cvSize(0,0)) };
valid_pix_ROI1: PCvRect { =nil }; valid_pix_ROI2: PCvRect { =nil } ); cdecl;
var
cvStereoRectify: TcvStereoRectify;
{$ELSE}
procedure cvStereoRectify(const camera_matrix1: pCvMat; const camera_matrix2: pCvMat; const dist_coeffs1: pCvMat; const dist_coeffs2: pCvMat;
image_size: TCvSize; const R: pCvMat; const T: pCvMat; R1: pCvMat; R2: pCvMat; P1: pCvMat; P2: pCvMat; Q: pCvMat { = nil };
flags: Integer { = CV_CALIB_ZERO_DISPARITY }; alpha: double { = -1 }; new_image_size: TCvSize { =CV_DEFAULT(cvSize(0,0)) }; valid_pix_ROI1: PCvRect { =nil };
valid_pix_ROI2: PCvRect { =nil } ); cdecl;
{$ENDIF}
(*
Computes rectification transformations for uncalibrated pair of images using a set
of point correspondences
CVAPI(int) cvStereoRectifyUncalibrated( const CvMat* points1, const CvMat* points2,
const CvMat* F, CvSize img_size,
CvMat* H1, CvMat* H2,
double threshold CV_DEFAULT(5));
*)
{$IFDEF SAFELOADLIB}
Type
TcvStereoRectifyUncalibrated = function(const points1: pCvMat; const points2: pCvMat; const F: pCvMat; img_size: TCvSize; H1: pCvMat; H2: pCvMat;
threshold: double = 5): Integer; cdecl;
var
cvStereoRectifyUncalibrated: TcvStereoRectifyUncalibrated;
{$ELSE}
function cvStereoRectifyUncalibrated(const points1: pCvMat; const points2: pCvMat; const F: pCvMat; img_size: TCvSize; H1: pCvMat; H2: pCvMat;
threshold: double = 5): Integer; cdecl;
{$ENDIF}
(* stereo correspondence parameters and functions *)
const
CV_STEREO_BM_NORMALIZED_RESPONSE = 0;
CV_STEREO_BM_XSOBEL = 1;
Type
(* Block matching algorithm structure *)
(* typedef struct CvStereoBMState
{
// pre-filtering (normalization of input images)
int preFilterType; // =CV_STEREO_BM_NORMALIZED_RESPONSE now
int preFilterSize; // averaging window size: ~5x5..21x21
int preFilterCap; // the output of pre-filtering is clipped by [-preFilterCap,preFilterCap]
// correspondence using Sum of Absolute Difference (SAD)
int SADWindowSize; // ~5x5..21x21
int minDisparity; // minimum disparity (can be negative)
int numberOfDisparities; // maximum disparity - minimum disparity (> 0)
// post-filtering
int textureThreshold; // the disparity is only computed for pixels
// with textured enough neighborhood
int uniquenessRatio; // accept the computed disparity d* only if
// SAD(d) >= SAD(d* )*(1 + uniquenessRatio/100.)
// for any d != d*+/-1 within the search range.
int speckleWindowSize; // disparity variation window
int speckleRange; // acceptable range of variation in window
int trySmallerWindows; // if 1, the results may be more accurate,
// at the expense of slower processing
CvRect roi1, roi2;
int disp12MaxDiff;
// temporary buffers
CvMat* preFilteredImg0;
CvMat* preFilteredImg1;
CvMat* slidingSumBuf;
CvMat* cost;
CvMat* disp;
} CvStereoBMState;
*)
pCvStereoBMState = ^TCvStereoBMState;
TCvStereoBMState = record
// pre-filtering (normalization of input images)
preFilterType: Integer; // =CV_STEREO_BM_NORMALIZED_RESPONSE now
preFilterSize: Integer; // averaging window size: ~5x5..21x21
preFilterCap: Integer; // the output of pre-filtering is clipped by [-preFilterCap,preFilterCap]
// correspondence using Sum of Absolute Difference (SAD)
SADWindowSize: Integer; // ~5x5..21x21
minDisparity: Integer; // minimum disparity (can be negative)
numberOfDisparities: Integer; // maximum disparity - minimum disparity (> 0)
// post-filtering
textureThreshold: Integer; // the disparity is only computed for pixels
// with textured enough neighborhood
uniquenessRatio: Integer; // accept the computed disparity d* only if
// SAD(d) >= SAD(d*)*(1 + uniquenessRatio/100.)
// for any d != d*+/-1 within the search range.
speckleWindowSize: Integer; // disparity variation window
speckleRange: Integer; // acceptable range of variation in window
trySmallerWindows: Integer; // if 1, the results may be more accurate,
// at the expense of slower processing
roi1, roi2: TCvRect;
disp12MaxDiff: Integer;
// temporary buffers
preFilteredImg0: pCvMat;
preFilteredImg1: pCvMat;
slidingSumBuf: pCvMat;
cost: pCvMat;
disp: pCvMat;
end;
const
CV_STEREO_BM_BASIC = 0;
CV_STEREO_BM_FISH_EYE = 1;
CV_STEREO_BM_NARROW = 2;
(*
CVAPI(CvStereoBMState* ) cvCreateStereoBMState(int preset CV_DEFAULT(CV_STEREO_BM_BASIC),
int numberOfDisparities CV_DEFAULT(0));
*)
{$IFDEF SAFELOADLIB}
type
TcvCreateStereoBMState = function(preset: Integer = CV_STEREO_BM_BASIC; numberOfDisparities: Integer = 0): pCvStereoBMState; cdecl;
var
cvCreateStereoBMState: TcvCreateStereoBMState;
{$ELSE}
function cvCreateStereoBMState(preset: Integer = CV_STEREO_BM_BASIC; numberOfDisparities: Integer = 0): pCvStereoBMState; cdecl;
{$ENDIF}
(*
CVAPI(void) cvReleaseStereoBMState( CvStereoBMState** state );
*)
{$IFDEF SAFELOADLIB}
type
TcvReleaseStereoBMState = procedure(Var state: pCvStereoBMState); cdecl;
var
cvReleaseStereoBMState: TcvReleaseStereoBMState;
{$ELSE}
procedure cvReleaseStereoBMState(Var state: pCvStereoBMState); cdecl;
{$ENDIF}
(*
CVAPI(void) cvFindStereoCorrespondenceBM( const CvArr* left, const CvArr* right,
CvArr* disparity, CvStereoBMState* state );
*)
{$IFDEF SAFELOADLIB}
type
TcvFindStereoCorrespondenceBM = procedure(const left: pCvArr; const right: pCvArr; disparity: pCvArr; state: pCvStereoBMState); cdecl;
var
cvFindStereoCorrespondenceBM: TcvFindStereoCorrespondenceBM;
{$ELSE}
procedure cvFindStereoCorrespondenceBM(const left: pCvArr; const right: pCvArr; disparity: pCvArr; state: pCvStereoBMState); cdecl;
{$ENDIF}
(*
CVAPI(CvRect) cvGetValidDisparityROI( CvRect roi1, CvRect roi2, int minDisparity,
int numberOfDisparities, int SADWindowSize );
*)
{$IFDEF SAFELOADLIB}
type
TcvGetValidDisparityROI = function(roi1: TCvRect; roi2: TCvRect; minDisparity: Integer; numberOfDisparities: Integer; SADWindowSize: Integer): TCvRect; cdecl;
var
cvGetValidDisparityROI: TcvGetValidDisparityROI;
{$ELSE}
function cvGetValidDisparityROI(roi1: TCvRect; roi2: TCvRect; minDisparity: Integer; numberOfDisparities: Integer; SADWindowSize: Integer): TCvRect; cdecl;
{$ENDIF}
(*
CVAPI(void) cvValidateDisparity( CvArr* disparity, const CvArr* cost,
int minDisparity, int numberOfDisparities,
int disp12MaxDiff CV_DEFAULT(1) );
*)
{$IFDEF SAFELOADLIB}
type
TcvValidateDisparity = procedure(disparity: pCvArr; const cost: pCvArr; minDisparity: Integer; numberOfDisparities: Integer;
disp12MaxDiff: Integer = 1); cdecl;
var
cvValidateDisparity: TcvValidateDisparity;
{$ELSE}
procedure cvValidateDisparity(disparity: pCvArr; const cost: pCvArr; minDisparity: Integer; numberOfDisparities: Integer; disp12MaxDiff: Integer = 1); cdecl;
{$ENDIF}
(*
Reprojects the computed disparity image to the 3D space using the specified 4x4 matrix
CVAPI(void) cvReprojectImageTo3D(
const CvArr* disparityImage,
CvArr* _3dImage,
const CvMat* Q,
int handleMissingValues CV_DEFAULT(0) );
*)
{$IFDEF SAFELOADLIB}
Type
TcvReprojectImageTo3D = procedure(
{ } const disparityImage: pCvMat;
{ } _3dImage: pIplImage;
{ } const Q: pCvMat;
{ } handleMissingValues: Integer = 0); cdecl;
var
cvReprojectImageTo3D: TcvReprojectImageTo3D;
{$ELSE}
procedure cvReprojectImageTo3D(
{ } const disparityImage: pCvMat;
{ } _3dImage: pIplImage;
{ } const Q: pCvMat;
{ } handleMissingValues: Integer = 0); cdecl;
{$ENDIF}
// ------------------------------------
{$IF DEFINED(SAFELOADLIB) AND DEFINED(DEBUG)}
procedure Init_opencv_calib3d_lib;
{$ENDIF}
implementation
uses ocv.lib;
{$IFDEF SAFELOADLIB}
Var
calib3dDLL: Cardinal;
procedure Init_opencv_calib3d_lib;
begin
calib3dDLL := ocvLoadLibrary(calib3d_lib);
Assert(calib3dDLL <> 0, 'Can not init ' + calib3d_lib);
cvCreatePOSITObject := ocvGetProcAddress('cvCreatePOSITObject', calib3dDLL);
cvPOSIT := ocvGetProcAddress('cvPOSIT', calib3dDLL);
cvReleasePOSITObject := ocvGetProcAddress('cvReleasePOSITObject', calib3dDLL);
cvRANSACUpdateNumIters := ocvGetProcAddress('cvRANSACUpdateNumIters', calib3dDLL);
cvConvertPointsHomogeneous := ocvGetProcAddress('cvConvertPointsHomogeneous', calib3dDLL);
cvFindFundamentalMat := ocvGetProcAddress('cvFindFundamentalMat', calib3dDLL);
cvComputeCorrespondEpilines := ocvGetProcAddress('cvComputeCorrespondEpilines', calib3dDLL);
cvTriangulatePoints := ocvGetProcAddress('cvTriangulatePoints', calib3dDLL);
cvCorrectMatches := ocvGetProcAddress('cvCorrectMatches', calib3dDLL);
cvGetOptimalNewCameraMatrix := ocvGetProcAddress('cvGetOptimalNewCameraMatrix', calib3dDLL);
cvRodrigues2 := ocvGetProcAddress('cvRodrigues2', calib3dDLL);
cvFindHomography := ocvGetProcAddress('cvFindHomography', calib3dDLL);
cvRQDecomp3x3 := ocvGetProcAddress('cvRQDecomp3x3', calib3dDLL);
cvDecomposeProjectionMatrix := ocvGetProcAddress('cvDecomposeProjectionMatrix', calib3dDLL);
cvCalcMatMulDeriv := ocvGetProcAddress('cvCalcMatMulDeriv', calib3dDLL);
cvComposeRT := ocvGetProcAddress('cvComposeRT', calib3dDLL);
cvProjectPoints2 := ocvGetProcAddress('cvProjectPoints2', calib3dDLL);
cvFindExtrinsicCameraParams2 := ocvGetProcAddress('cvFindExtrinsicCameraParams2', calib3dDLL);
cvInitIntrinsicParams2D := ocvGetProcAddress('cvInitIntrinsicParams2D', calib3dDLL);
cvCheckChessboard := ocvGetProcAddress('cvCheckChessboard', calib3dDLL);
cvFindChessboardCorners := ocvGetProcAddress('cvFindChessboardCorners', calib3dDLL);
cvDrawChessboardCorners := ocvGetProcAddress('cvDrawChessboardCorners', calib3dDLL);
cvCalibrateCamera2 := ocvGetProcAddress('cvCalibrateCamera2', calib3dDLL);
cvCalibrationMatrixValues := ocvGetProcAddress('cvCalibrationMatrixValues', calib3dDLL);
cvStereoCalibrate := ocvGetProcAddress('cvStereoCalibrate', calib3dDLL);
cvStereoRectify := ocvGetProcAddress('cvStereoRectify', calib3dDLL);
cvStereoRectifyUncalibrated := ocvGetProcAddress('cvStereoRectifyUncalibrated', calib3dDLL);
cvCreateStereoBMState := ocvGetProcAddress('cvCreateStereoBMState', calib3dDLL);
cvReleaseStereoBMState := ocvGetProcAddress('cvReleaseStereoBMState', calib3dDLL);
cvFindStereoCorrespondenceBM := ocvGetProcAddress('cvFindStereoCorrespondenceBM', calib3dDLL);
cvGetValidDisparityROI := ocvGetProcAddress('cvGetValidDisparityROI', calib3dDLL);
cvValidateDisparity := ocvGetProcAddress('cvValidateDisparity', calib3dDLL);
cvReprojectImageTo3D := ocvGetProcAddress('cvReprojectImageTo3D', calib3dDLL);
end;
initialization
Init_opencv_calib3d_lib;
{$ELSE}
function cvCreatePOSITObject(points: pCvPoint3D32f; point_count: Integer): PCvPOSITObject; cdecl; external calib3d_lib;
procedure cvPOSIT(posit_object: PCvPOSITObject; imagePoints: pCvPoint2D32f; focal_length: double; criteria: TCvTermCriteria; rotation_matrix: TCvMatr32f;
translation_vector: TCvVect32f); cdecl; external calib3d_lib;
procedure cvReleasePOSITObject(Var posit_object: PCvPOSITObject); cdecl; external calib3d_lib;
function cvRANSACUpdateNumIters(p: double; err_prob: double; model_points: Integer; max_iters: Integer): Integer; cdecl; external calib3d_lib;
procedure cvConvertPointsHomogeneous(const src: pCvMat; dst: pCvMat); cdecl; external calib3d_lib;
function cvFindFundamentalMat(const points1: pCvMat; const points2: pCvMat; fundamental_matrix: pCvMat; method: Integer = CV_FM_RANSAC; param1: double = 3;
param2: double = 0.99; status: pCvMat = nil): Integer; cdecl; external calib3d_lib;
procedure cvComputeCorrespondEpilines(const points: pCvMat; which_image: Integer; const fundamental_matrix: pCvMat; correspondent_lines: pCvMat); cdecl;
external calib3d_lib;
procedure cvTriangulatePoints(projMatr1: pCvMat; projMatr2: pCvMat; projPoints1: pCvMat; projPoints2: pCvMat; points4D: pCvMat); cdecl; external calib3d_lib;
procedure cvCorrectMatches(F: pCvMat; points1: pCvMat; points2: pCvMat; new_points1: pCvMat; new_points2: pCvMat); cdecl; external calib3d_lib;
procedure cvGetOptimalNewCameraMatrix(const camera_matrix: pCvMat; const dist_coeffs: pCvMat; image_size: TCvSize; alpha: double; new_camera_matrix: pCvMat;
new_imag_size: TCvSize { = CV_DEFAULT(cvSize(0,0))) }; valid_pixel_ROI: PCvRect = nil; center_principal_point: Integer = 0); cdecl; external calib3d_lib;
function cvRodrigues2(const src: pCvMat; dst: pCvMat; jacobian: pCvMat = nil): Integer; cdecl; external calib3d_lib;
function cvFindHomography(const src_points: pCvMat; const dst_points: pCvMat; homography: pCvMat; method: Integer = 0; ransacReprojThreshold: double = 3;
mask: pCvMat = nil): Integer; cdecl; external calib3d_lib;
procedure cvRQDecomp3x3(const matrixM: pCvMat; matrixR: pCvMat; matrixQ: pCvMat; matrixQx: pCvMat = nil; matrixQy: pCvMat = nil; matrixQz: pCvMat = nil;
eulerAngles: PCvPoint3D64f = nil); cdecl; external calib3d_lib;
procedure cvDecomposeProjectionMatrix(const projMatr: pCvMat; calibMatr: pCvMat; rotMatr: pCvMat; posVect: pCvMat; rotMatrX: pCvMat = nil;
rotMatrY: pCvMat = nil; rotMatrZ: pCvMat = nil; eulerAngles: PCvPoint3D64f = nil); cdecl; external calib3d_lib;
procedure cvCalcMatMulDeriv(const A: pCvMat; const B: pCvMat; dABdA: pCvMat; dABdB: pCvMat); cdecl; external calib3d_lib;
procedure cvComposeRT(const _rvec1: pCvMat; const _tvec1: pCvMat; const _rvec2: pCvMat; const _tvec2: pCvMat; _rvec3: pCvMat; _tvec3: pCvMat;
dr3dr1: pCvMat = nil; dr3dt1: pCvMat = nil; dr3dr2: pCvMat = nil; dr3dt2: pCvMat = nil; dt3dr1: pCvMat = nil; dt3dt1: pCvMat = nil; dt3dr2: pCvMat = nil;
dt3dt2: pCvMat = nil); cdecl; external calib3d_lib;
procedure cvProjectPoints2(const object_points: pCvMat; const rotation_vector: pCvMat; const translation_vector: pCvMat; const camera_matrix: pCvMat;
const distortion_coeffs: pCvMat; image_points: pCvMat; dpdrot: pCvMat = nil; dpdt: pCvMat = nil; dpdf: pCvMat = nil; dpdc: pCvMat = nil;
dpddist: pCvMat = nil; aspect_ratio: double = 0); cdecl; external calib3d_lib;
procedure cvFindExtrinsicCameraParams2(const object_points: pCvMat; const image_points: pCvMat; const camera_matrix: pCvMat; const distortion_coeffs: pCvMat;
rotation_vector: pCvMat; translation_vector: pCvMat; use_extrinsic_guess: Integer = 0); cdecl; external calib3d_lib;
procedure cvInitIntrinsicParams2D(const object_points: pCvMat; const image_points: pCvMat; const npoints: pCvMat; image_size: TCvSize; camera_matrix: pCvMat;
aspect_ratio: double = 1); cdecl; external calib3d_lib;
function cvCheckChessboard(const image: pCvArr; size: TCvSize): Integer; cdecl; external calib3d_lib;
function cvFindChessboardCorners(const image: Pointer; pattern_size: TCvSize; corners: pCvPoint2D32f; corner_count: pInteger = nil;
flags: Integer = CV_CALIB_CB_ADAPTIVE_THRESH + CV_CALIB_CB_NORMALIZE_IMAGE): Integer; cdecl; external calib3d_lib;
procedure cvDrawChessboardCorners(image: pIplImage; pattern_size: TCvSize; corners: pCvPoint2D32f; count: Integer; pattern_was_found: Integer); cdecl;
external calib3d_lib;
function cvCalibrateCamera2(const object_points: pCvMat; const image_points: pCvMat; const point_counts: pCvMat; image_size: TCvSize; camera_matrix: pCvMat;
distortion_coeffs: pCvMat; rotation_vectors: pCvMat { =nil }; translation_vectors: pCvMat { =nil }; flags: Integer { =0 };
term_crit: TCvTermCriteria { =cvTermCriteria(CV_TERMCRIT_ITER+CV_TERMCRIT_EPS,30,DBL_EPSILON) }
): double; cdecl; external calib3d_lib;
procedure cvCalibrationMatrixValues(const camera_matrix: pCvMat; image_size: TCvSize; aperture_width: double = 0; aperture_height: double = 0;
fovx: PDouble = nil; fovy: PDouble = nil; focal_length: PDouble = nil; principal_point: PCvPoint2D64f = nil; pixel_aspect_ratio: PDouble = nil); cdecl;
external calib3d_lib;
function cvStereoCalibrate(const object_points: pCvMat; const image_points1: pCvMat; const image_points2: pCvMat; const npoints: pCvMat; camera_matrix1: pCvMat;
dist_coeffs1: pCvMat; camera_matrix2: pCvMat; dist_coeffs2: pCvMat; image_size: TCvSize; R: pCvMat; T: pCvMat; E: pCvMat { = nil }; F: pCvMat { = nil };
term_crit: TCvTermCriteria { = CV_DEFAULT(cvTermCriteria(CV_TERMCRIT_ITER + CV_TERMCRIT_EPS, 30, 1E-6)) };
flags: Integer { = CV_DEFAULT(CV_CALIB_FIX_INTRINSIC) } ): double; cdecl; external calib3d_lib;
procedure cvStereoRectify(const camera_matrix1: pCvMat; const camera_matrix2: pCvMat; const dist_coeffs1: pCvMat; const dist_coeffs2: pCvMat;
image_size: TCvSize; const R: pCvMat; const T: pCvMat; R1: pCvMat; R2: pCvMat; P1: pCvMat; P2: pCvMat; Q: pCvMat { = nil };
flags: Integer { = CV_CALIB_ZERO_DISPARITY }; alpha: double { = -1 }; new_image_size: TCvSize { =CV_DEFAULT(cvSize(0,0)) }; valid_pix_ROI1: PCvRect { =nil };
valid_pix_ROI2: PCvRect { =nil } ); cdecl; external calib3d_lib;
function cvStereoRectifyUncalibrated(const points1: pCvMat; const points2: pCvMat; const F: pCvMat; img_size: TCvSize; H1: pCvMat; H2: pCvMat;
threshold: double = 5): Integer; cdecl; external calib3d_lib;
function cvCreateStereoBMState(preset: Integer = CV_STEREO_BM_BASIC; numberOfDisparities: Integer = 0): pCvStereoBMState; cdecl; external calib3d_lib;
procedure cvReleaseStereoBMState(Var state: pCvStereoBMState); cdecl; external calib3d_lib;
procedure cvFindStereoCorrespondenceBM(const left: pCvArr; const right: pCvArr; disparity: pCvArr; state: pCvStereoBMState); cdecl; external calib3d_lib;
function cvGetValidDisparityROI(roi1: TCvRect; roi2: TCvRect; minDisparity: Integer; numberOfDisparities: Integer; SADWindowSize: Integer): TCvRect; cdecl;
external calib3d_lib;
procedure cvValidateDisparity(disparity: pCvArr; const cost: pCvArr; minDisparity: Integer; numberOfDisparities: Integer; disp12MaxDiff: Integer = 1); cdecl;
external calib3d_lib;
procedure cvReprojectImageTo3D(const disparityImage: pCvMat; _3dImage: pIplImage; const Q: pCvMat; handleMissingValues: Integer = 0); cdecl;
external calib3d_lib;
{$ENDIF}
end.