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ruby-opencv/ext/opencv/cvmoments.cpp
ser1zw ea55e0d42e added error handling to some methods
Added error handlings to the methods of following classes
 -CvBox2D
 -CvCapture
 -CvChain
 -CvCircle32f
 -CvConnectedComp
 -CvContour
 -CvFont
 -CvHaarclassifierCascade
 -CvHuMoments
 -CvLine
 -CvMoments
 -CvPoint
2011-07-22 00:47:54 +09:00

287 lines
7.1 KiB
C++

/************************************************************
cvmoments.cpp -
$Author: lsxi $
Copyright (C) 2007 Masakazu Yonekura
************************************************************/
#include "cvmoments.h"
/*
* Document-class: OpenCV::CvMoments
*
* moments
*/
__NAMESPACE_BEGIN_OPENCV
__NAMESPACE_BEGIN_CVMOMENTS
#define DEFINE_CVMOMENTS_ACCESSOR(elem) \
rb_define_method(rb_klass, #elem, RUBY_METHOD_FUNC(rb_##elem), 0)
#define CVMOMENTS_ACCESSOR(elem) \
VALUE rb_##elem(VALUE self) { return DBL2NUM(CVMOMENTS(self)->elem); }
VALUE rb_klass;
VALUE
rb_class()
{
return rb_klass;
}
void
define_ruby_class()
{
if (rb_klass)
return;
/*
* opencv = rb_define_module("OpenCV");
*
* note: this comment is used by rdoc.
*/
VALUE opencv = rb_module_opencv();
rb_klass = rb_define_class_under(opencv, "CvMoments", rb_cObject);
rb_define_alloc_func(rb_klass, rb_allocate);
rb_define_private_method(rb_klass, "initialize", RUBY_METHOD_FUNC(rb_initialize), -1);
rb_define_method(rb_klass, "spatial", RUBY_METHOD_FUNC(rb_spatial), 2);
rb_define_method(rb_klass, "central", RUBY_METHOD_FUNC(rb_central), 2);
rb_define_method(rb_klass, "normalized_central", RUBY_METHOD_FUNC(rb_normalized_central), 2);
rb_define_method(rb_klass, "hu", RUBY_METHOD_FUNC(rb_hu), 0);
rb_define_method(rb_klass, "gravity_center", RUBY_METHOD_FUNC(rb_gravity_center), 0);
rb_define_method(rb_klass, "angle", RUBY_METHOD_FUNC(rb_angle), 0);
DEFINE_CVMOMENTS_ACCESSOR(m00);
DEFINE_CVMOMENTS_ACCESSOR(m10);
DEFINE_CVMOMENTS_ACCESSOR(m01);
DEFINE_CVMOMENTS_ACCESSOR(m20);
DEFINE_CVMOMENTS_ACCESSOR(m11);
DEFINE_CVMOMENTS_ACCESSOR(m02);
DEFINE_CVMOMENTS_ACCESSOR(m30);
DEFINE_CVMOMENTS_ACCESSOR(m21);
DEFINE_CVMOMENTS_ACCESSOR(m12);
DEFINE_CVMOMENTS_ACCESSOR(m03);
DEFINE_CVMOMENTS_ACCESSOR(mu20);
DEFINE_CVMOMENTS_ACCESSOR(mu11);
DEFINE_CVMOMENTS_ACCESSOR(mu02);
DEFINE_CVMOMENTS_ACCESSOR(mu30);
DEFINE_CVMOMENTS_ACCESSOR(mu21);
DEFINE_CVMOMENTS_ACCESSOR(mu12);
DEFINE_CVMOMENTS_ACCESSOR(mu03);
DEFINE_CVMOMENTS_ACCESSOR(inv_sqrt_m00);
}
VALUE
rb_allocate(VALUE klass)
{
CvMoments *ptr;
return Data_Make_Struct(klass, CvMoments, 0, -1, ptr);
}
/*
* call-seq:
* CvMoments.new(<i>src[,is_binary = nil]</i>)
*
* Calculates all moments up to third order of a polygon or rasterized shape.
* <i>src</i> should be CvMat or CvPolygon.
*
* If is_binary = true, all the zero pixel values are treated as zeroes, all the others are treated as 1's.
*/
VALUE
rb_initialize(int argc, VALUE *argv, VALUE self)
{
VALUE src, is_binary;
rb_scan_args(argc, argv, "02", &src, &is_binary);
if (!NIL_P(src)) {
if (rb_obj_is_kind_of(src, cCvMat::rb_class()) || rb_obj_is_kind_of(src, cCvSeq::rb_class())) {
try {
cvMoments(CVARR(src), CVMOMENTS(self), TRUE_OR_FALSE(is_binary, 0));
}
catch (cv::Exception& e) {
raise_cverror(e);
}
}
else
rb_raise(rb_eTypeError, "argument 1 (src) should be %s or %s.",
rb_class2name(cCvMat::rb_class()), rb_class2name(cCvSeq::rb_class()));
}
return self;
}
CVMOMENTS_ACCESSOR(m00);
CVMOMENTS_ACCESSOR(m10);
CVMOMENTS_ACCESSOR(m01);
CVMOMENTS_ACCESSOR(m20);
CVMOMENTS_ACCESSOR(m11);
CVMOMENTS_ACCESSOR(m02);
CVMOMENTS_ACCESSOR(m30);
CVMOMENTS_ACCESSOR(m21);
CVMOMENTS_ACCESSOR(m12);
CVMOMENTS_ACCESSOR(m03);
CVMOMENTS_ACCESSOR(mu20);
CVMOMENTS_ACCESSOR(mu11);
CVMOMENTS_ACCESSOR(mu02);
CVMOMENTS_ACCESSOR(mu30);
CVMOMENTS_ACCESSOR(mu21);
CVMOMENTS_ACCESSOR(mu12);
CVMOMENTS_ACCESSOR(mu03);
CVMOMENTS_ACCESSOR(inv_sqrt_m00);
/*
* call-seq:
* spatial -> float
*
* Retrieves spatial moment.
*
* which in case of image moments is defined as:
* Mx_order,y_order=sumx,y(I(x,y)*xx_order*yy_order)
* where I(x,y) is the intensity of the pixel (x, y).
*/
VALUE
rb_spatial(VALUE self, VALUE x_order, VALUE y_order)
{
double result = 0;
try {
result = cvGetSpatialMoment(CVMOMENTS(self), NUM2INT(x_order), NUM2INT(y_order));
}
catch (cv::Exception& e) {
raise_cverror(e);
}
return rb_float_new(result);
}
/*
* call-seq:
* central -> float
*
* Retrieves central moment.
*
* which in case of image moments is defined as:
* μx_order,y_order=sumx,y(I(x,y)*(x-xc)x_order*(y-yc)y_order),
* where xc=M10/M00, yc=M01/M00 - coordinates of the gravity center
*/
VALUE
rb_central(VALUE self, VALUE x_order, VALUE y_order)
{
double result = 0;
try {
result = cvGetCentralMoment(CVMOMENTS(self), NUM2INT(x_order), NUM2INT(y_order));
}
catch (cv::Exception& e) {
raise_cverror(e);
}
return rb_float_new(result);
}
/*
* call-seq:
* normalized_central -> float
*
* Retrieves normalized central moment.
*
* ηx_order,y_order= μx_order,y_order/M00((y_order+x_order)/2+1)
*/
VALUE
rb_normalized_central(VALUE self, VALUE x_order, VALUE y_order)
{
double result = 0;
try {
result = cvGetNormalizedCentralMoment(CVMOMENTS(self), NUM2INT(x_order), NUM2INT(y_order));
}
catch (cv::Exception& e) {
raise_cverror(e);
}
return rb_float_new(result);
}
/*
* call-seq:
* hu -> cvhumoments
*
* Calculates seven Hu invariants.
*
* seven Hu invariants that are defined as:
* h1=η20+η02
* h2=(η20-η02)²+4η11²
* h3=(η30-3η12)²+ (3η21-η03)²
* h4=(η30+η12)²+ (η21+η03)²
* h5=(η30-3η12)(η30+η12)[(η30+η12)²-3(η21+η03)²]+(3η21-η03)(η21+η03)[3(η30+η12)²-(η21+η03)²]
* h6=(η20-η02)[(η30+η12)²- (η21+η03)²]+4η11(η30+η12)(η21+η03)
* h7=(3η21-η03)(η21+η03)[3(η30+η12)²-(η21+η03)²]-(η30-3η12)(η21+η03)[3(η30+η12)²-(η21+η03)²]
* where ηi,j are normalized central moments of 2-nd and 3-rd orders. The computed values are proved to be invariant to the image scaling, rotation, and reflection except the seventh one, whose sign is changed by reflection.
*/
VALUE
rb_hu(VALUE self)
{
return cCvHuMoments::new_object(CVMOMENTS(self));
}
/*
* call-seq:
* gravity_center -> cvpoint2d32f
*
* Return gravity center.
*/
VALUE
rb_gravity_center(VALUE self)
{
CvMoments *moments = CVMOMENTS(self);
CvPoint2D32f point;
double m00 = 0, m01 = 0, m10 = 0;
try {
m00 = cvGetSpatialMoment(moments, 0, 0);
m10 = cvGetSpatialMoment(moments, 1, 0);
m01 = cvGetSpatialMoment(moments, 0, 1);
point = cvPoint2D32f(m10 / m00, m01 / m00);
}
catch (cv::Exception& e) {
raise_cverror(e);
}
return cCvPoint2D32f::new_object(point);
}
/*
* call-seq:
* angle -> float
*
* Return angle.
*/
VALUE
rb_angle(VALUE self)
{
CvMoments *moments = CVMOMENTS(self);
double m11 = 0, m20 = 0, m02 = 0;
try {
m11 = cvGetCentralMoment(moments, 1, 1);
m20 = cvGetCentralMoment(moments, 2, 0);
m02 = cvGetCentralMoment(moments, 0, 2);
}
catch (cv::Exception& e) {
raise_cverror(e);
}
double mangle = 0.5 * atan(2 * m11 / (m20 - m02));
if (cvIsNaN(mangle) || cvIsInf(mangle))
return Qnil;
else
return rb_float_new(mangle);
}
VALUE
new_object(CvArr *arr, int is_binary = 0)
{
VALUE object = rb_allocate(rb_klass);
try {
cvMoments(arr, CVMOMENTS(object), is_binary);
}
catch (cv::Exception& e) {
raise_cverror(e);
}
return object;
}
__NAMESPACE_END_CVMOMENTS
__NAMESPACE_END_OPENCV