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/*M///////////////////////////////////////////////////////////////////////////////////////
//
// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
//
// By downloading, copying, installing or using the software you agree to this license.
// If you do not agree to this license, do not download, install,
// copy or use the software.
//
//
// License Agreement
// For Open Source Computer Vision Library
//
// Copyright (C) 2000, Intel Corporation, all rights reserved.
// Third party copyrights are property of their respective owners.
//
// Redistribution and use in source and binary forms, with or without modification,
// are permitted provided that the following conditions are met:
//
// * Redistribution's of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
//
// * Redistribution's in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// * The name of OpenCV Foundation may not be used to endorse or promote products
// derived from this software without specific prior written permission.
//
// This software is provided by the copyright holders and contributors "as is" and
// any express or implied warranties, including, but not limited to, the implied
// warranties of merchantability and fitness for a particular purpose are disclaimed.
// In no event shall the OpenCV Foundation or contributors be liable for any direct,
// indirect, incidental, special, exemplary, or consequential damages
// (including, but not limited to, procurement of substitute goods or services;
// loss of use, data, or profits; or business interruption) however caused
// and on any theory of liability, whether in contract, strict liability,
// or tort (including negligence or otherwise) arising in any way out of
// the use of this software, even if advised of the possibility of such damage.
//
//M*/
#include "precomp.hpp"
namespace cv
{
struct MinAreaState
{
int bottom;
int left;
float height;
float width;
float base_a;
float base_b;
};
enum { CALIPERS_MAXHEIGHT=0, CALIPERS_MINAREARECT=1, CALIPERS_MAXDIST=2 };
/*F///////////////////////////////////////////////////////////////////////////////////////
// Name: rotatingCalipers
// Purpose:
// Rotating calipers algorithm with some applications
//
// Context:
// Parameters:
// points - convex hull vertices ( any orientation )
// n - number of vertices
// mode - concrete application of algorithm
// can be CV_CALIPERS_MAXDIST or
// CV_CALIPERS_MINAREARECT
// left, bottom, right, top - indexes of extremal points
// out - output info.
// In case CV_CALIPERS_MAXDIST it points to float value -
// maximal height of polygon.
// In case CV_CALIPERS_MINAREARECT
// ((CvPoint2D32f*)out)[0] - corner
// ((CvPoint2D32f*)out)[1] - vector1
// ((CvPoint2D32f*)out)[0] - corner2
//
// ^
// |
// vector2 |
// |
// |____________\
// corner /
// vector1
//
// Returns:
// Notes:
//F*/
/* we will use usual cartesian coordinates */
static void rotatingCalipers( const Point2f* points, int n, int mode, float* out )
{
float minarea = FLT_MAX;
float max_dist = 0;
char buffer[32] = {};
int i, k;
AutoBuffer<float> abuf(n*3);
float* inv_vect_length = abuf;
Point2f* vect = (Point2f*)(inv_vect_length + n);
int left = 0, bottom = 0, right = 0, top = 0;
int seq[4] = { -1, -1, -1, -1 };
/* rotating calipers sides will always have coordinates
(a,b) (-b,a) (-a,-b) (b, -a)
*/
/* this is a first base bector (a,b) initialized by (1,0) */
float orientation = 0;
float base_a;
float base_b = 0;
float left_x, right_x, top_y, bottom_y;
Point2f pt0 = points[0];
left_x = right_x = pt0.x;
top_y = bottom_y = pt0.y;
for( i = 0; i < n; i++ )
{
double dx, dy;
if( pt0.x < left_x )
left_x = pt0.x, left = i;
if( pt0.x > right_x )
right_x = pt0.x, right = i;
if( pt0.y > top_y )
top_y = pt0.y, top = i;
if( pt0.y < bottom_y )
bottom_y = pt0.y, bottom = i;
Point2f pt = points[(i+1) & (i+1 < n ? -1 : 0)];
dx = pt.x - pt0.x;
dy = pt.y - pt0.y;
vect[i].x = (float)dx;
vect[i].y = (float)dy;
inv_vect_length[i] = (float)(1./std::sqrt(dx*dx + dy*dy));
pt0 = pt;
}
// find convex hull orientation
{
double ax = vect[n-1].x;
double ay = vect[n-1].y;
for( i = 0; i < n; i++ )
{
double bx = vect[i].x;
double by = vect[i].y;
double convexity = ax * by - ay * bx;
if( convexity != 0 )
{
orientation = (convexity > 0) ? 1.f : (-1.f);
break;
}
ax = bx;
ay = by;
}
CV_Assert( orientation != 0 );
}
base_a = orientation;
/*****************************************************************************************/
/* init calipers position */
seq[0] = bottom;
seq[1] = right;
seq[2] = top;
seq[3] = left;
/*****************************************************************************************/
/* Main loop - evaluate angles and rotate calipers */
/* all of edges will be checked while rotating calipers by 90 degrees */
for( k = 0; k < n; k++ )
{
/* sinus of minimal angle */
/*float sinus;*/
/* compute cosine of angle between calipers side and polygon edge */
/* dp - dot product */
float dp0 = base_a * vect[seq[0]].x + base_b * vect[seq[0]].y;
float dp1 = -base_b * vect[seq[1]].x + base_a * vect[seq[1]].y;
float dp2 = -base_a * vect[seq[2]].x - base_b * vect[seq[2]].y;
float dp3 = base_b * vect[seq[3]].x - base_a * vect[seq[3]].y;
float cosalpha = dp0 * inv_vect_length[seq[0]];
float maxcos = cosalpha;
/* number of calipers edges, that has minimal angle with edge */
int main_element = 0;
/* choose minimal angle */
cosalpha = dp1 * inv_vect_length[seq[1]];
maxcos = (cosalpha > maxcos) ? (main_element = 1, cosalpha) : maxcos;
cosalpha = dp2 * inv_vect_length[seq[2]];
maxcos = (cosalpha > maxcos) ? (main_element = 2, cosalpha) : maxcos;
cosalpha = dp3 * inv_vect_length[seq[3]];
maxcos = (cosalpha > maxcos) ? (main_element = 3, cosalpha) : maxcos;
/*rotate calipers*/
{
//get next base
int pindex = seq[main_element];
float lead_x = vect[pindex].x*inv_vect_length[pindex];
float lead_y = vect[pindex].y*inv_vect_length[pindex];
switch( main_element )
{
case 0:
base_a = lead_x;
base_b = lead_y;
break;
case 1:
base_a = lead_y;
base_b = -lead_x;
break;
case 2:
base_a = -lead_x;
base_b = -lead_y;
break;
case 3:
base_a = -lead_y;
base_b = lead_x;
break;
default:
CV_Error(CV_StsError, "main_element should be 0, 1, 2 or 3");
}
}
/* change base point of main edge */
seq[main_element] += 1;
seq[main_element] = (seq[main_element] == n) ? 0 : seq[main_element];
switch (mode)
{
case CALIPERS_MAXHEIGHT:
{
/* now main element lies on edge alligned to calipers side */
/* find opposite element i.e. transform */
/* 0->2, 1->3, 2->0, 3->1 */
int opposite_el = main_element ^ 2;
float dx = points[seq[opposite_el]].x - points[seq[main_element]].x;
float dy = points[seq[opposite_el]].y - points[seq[main_element]].y;
float dist;
if( main_element & 1 )
dist = (float)fabs(dx * base_a + dy * base_b);
else
dist = (float)fabs(dx * (-base_b) + dy * base_a);
if( dist > max_dist )
max_dist = dist;
}
break;
case CALIPERS_MINAREARECT:
/* find area of rectangle */
{
float height;
float area;
/* find vector left-right */
float dx = points[seq[1]].x - points[seq[3]].x;
float dy = points[seq[1]].y - points[seq[3]].y;
/* dotproduct */
float width = dx * base_a + dy * base_b;
/* find vector left-right */
dx = points[seq[2]].x - points[seq[0]].x;
dy = points[seq[2]].y - points[seq[0]].y;
/* dotproduct */
height = -dx * base_b + dy * base_a;
area = width * height;
if( area <= minarea )
{
float *buf = (float *) buffer;
minarea = area;
/* leftist point */
((int *) buf)[0] = seq[3];
buf[1] = base_a;
buf[2] = width;
buf[3] = base_b;
buf[4] = height;
/* bottom point */
((int *) buf)[5] = seq[0];
buf[6] = area;
}
}
break;
} /*switch */
} /* for */
switch (mode)
{
case CALIPERS_MINAREARECT:
{
float *buf = (float *) buffer;
float A1 = buf[1];
float B1 = buf[3];
float A2 = -buf[3];
float B2 = buf[1];
float C1 = A1 * points[((int *) buf)[0]].x + points[((int *) buf)[0]].y * B1;
float C2 = A2 * points[((int *) buf)[5]].x + points[((int *) buf)[5]].y * B2;
float idet = 1.f / (A1 * B2 - A2 * B1);
float px = (C1 * B2 - C2 * B1) * idet;
float py = (A1 * C2 - A2 * C1) * idet;
out[0] = px;
out[1] = py;
out[2] = A1 * buf[2];
out[3] = B1 * buf[2];
out[4] = A2 * buf[4];
out[5] = B2 * buf[4];
}
break;
case CALIPERS_MAXHEIGHT:
{
out[0] = max_dist;
}
break;
}
}
}
cv::RotatedRect cv::minAreaRect( InputArray _points )
{
Mat hull;
Point2f out[3];
RotatedRect box;
convexHull(_points, hull, true, true);
if( hull.depth() != CV_32F )
{
Mat temp;
hull.convertTo(temp, CV_32F);
hull = temp;
}
int n = hull.checkVector(2);
const Point2f* hpoints = hull.ptr<Point2f>();
if( n > 2 )
{
rotatingCalipers( hpoints, n, CALIPERS_MINAREARECT, (float*)out );
box.center.x = out[0].x + (out[1].x + out[2].x)*0.5f;
box.center.y = out[0].y + (out[1].y + out[2].y)*0.5f;
box.size.width = (float)std::sqrt((double)out[1].x*out[1].x + (double)out[1].y*out[1].y);
box.size.height = (float)std::sqrt((double)out[2].x*out[2].x + (double)out[2].y*out[2].y);
box.angle = (float)atan2( (double)out[1].y, (double)out[1].x );
}
else if( n == 2 )
{
box.center.x = (hpoints[0].x + hpoints[1].x)*0.5f;
box.center.y = (hpoints[0].y + hpoints[1].y)*0.5f;
double dx = hpoints[1].x - hpoints[0].x;
double dy = hpoints[1].y - hpoints[0].y;
box.size.width = (float)std::sqrt(dx*dx + dy*dy);
box.size.height = 0;
box.angle = (float)atan2( dy, dx );
}
else
{
if( n == 1 )
box.center = hpoints[0];
}
box.angle = (float)(box.angle*180/CV_PI);
return box;
}
CV_IMPL CvBox2D
cvMinAreaRect2( const CvArr* array, CvMemStorage* /*storage*/ )
{
cv::AutoBuffer<double> abuf;
cv::Mat points = cv::cvarrToMat(array, false, false, 0, &abuf);
cv::RotatedRect rr = cv::minAreaRect(points);
return (CvBox2D)rr;
}
void cv::boxPoints(cv::RotatedRect box, OutputArray _pts)
{
_pts.create(4, 2, CV_32F);
Mat pts = _pts.getMat();
box.points(pts.ptr<Point2f>());
}