/**********************************************************************\ SUSAN Version 2l by Stephen Smith Oxford Centre for Functional Magnetic Resonance Imaging of the Brain, Department of Clinical Neurology, Oxford University, Oxford, UK (Previously in Computer Vision and Image Processing Group - now Computer Vision and Electro Optics Group - DERA Chertsey, UK) Email: steve@fmrib.ox.ac.uk WWW: http://www.fmrib.ox.ac.uk/~steve (C) Crown Copyright (1995-1999), Defence Evaluation and Research Agency, Farnborough, Hampshire, GU14 6TD, UK DERA WWW site: http://www.dera.gov.uk/ DERA Computer Vision and Electro Optics Group WWW site: http://www.dera.gov.uk/imageprocessing/dera/group_home.html DERA Computer Vision and Electro Optics Group point of contact: Dr. John Savage, jtsavage@dera.gov.uk, +44 1344 633203 A UK patent has been granted: "Method for digitally processing images to determine the position of edges and/or corners therein for guidance of unmanned vehicle", UK Patent 2272285. Proprietor: Secretary of State for Defence, UK. 15 January 1997 This code is issued for research purposes only and remains the property of the UK Secretary of State for Defence. This code must not be passed on without this header information being kept intact. This code must not be sold. \**********************************************************************/ /**********************************************************************\ SUSAN Version 2l SUSAN = Smallest Univalue Segment Assimilating Nucleus Email: steve@fmrib.ox.ac.uk WWW: http://www.fmrib.ox.ac.uk/~steve Related paper: @article{Smith97, author = "Smith, S.M. and Brady, J.M.", title = "{SUSAN} - A New Approach to Low Level Image Processing", journal = "Int. Journal of Computer Vision", pages = "45--78", volume = "23", number = "1", month = "May", year = 1997} To be registered for automatic (bug) updates of SUSAN, send an email. Compile with: gcc -O4 -o susan susan2l.c -lm See following section for different machine information. Please report any bugs (and fixes). There are a few optional changes that can be made in the "defines" section which follows shortly. Usage: type "susan" to get usage. Only PGM format files can be input and output. Utilities such as the netpbm package and XV can be used to convert to and from other formats. Any size of image can be processed. This code is written using an emacs folding mode, making moving around the different sections very easy. This is why there are various marks within comments and why comments are indented. SUSAN QUICK: This version of the SUSAN corner finder does not do all the false-corner suppression and thus is faster and produced some false positives, particularly on strong edges. However, because there are less stages involving thresholds etc., the corners that are correctly reported are usually more stable than those reported with the full algorithm. Thus I recommend at least TRYING this algorithm for applications where stability is important, e.g., tracking. THRESHOLDS: There are two thresholds which can be set at run-time. These are the brightness threshold (t) and the distance threshold (d). SPATIAL CONTROL: d In SUSAN smoothing d controls the size of the Gaussian mask; its default is 4.0. Increasing d gives more smoothing. In edge finding, a fixed flat mask is used, either 37 pixels arranged in a "circle" (default), or a 3 by 3 mask which gives finer detail. In corner finding, only the larger 37 pixel mask is used; d is not variable. In smoothing, the flat 3 by 3 mask can be used instead of a larger Gaussian mask; this gives low smoothing and fast operation. BRIGHTNESS CONTROL: t In all three algorithms, t can be varied (default=20); this is the main threshold to be varied. It determines the maximum difference in greylevels between two pixels which allows them to be considered part of the same "region" in the image. Thus it can be reduced to give more edges or corners, i.e. to be more sensitive, and vice versa. In smoothing, reducing t gives less smoothing, and vice versa. Set t=10 for the test image available from the SUSAN web page. ITERATIONS: With SUSAN smoothing, more smoothing can also be obtained by iterating the algorithm several times. This has a different effect from varying d or t. FIXED MASKS: 37 pixel mask: ooo 3 by 3 mask: ooo ooooo ooo ooooooo ooo ooooooo ooooooo ooooo ooo CORNER ATTRIBUTES dx, dy and I (Only read this if you are interested in the C implementation or in using corner attributes, e.g., for corner matching) Corners reported in the corner list have attributes associated with them as well as positions. This is useful, for example, when attempting to match corners from one image to another, as these attributes can often be fairly unchanged between images. The attributes are dx, dy and I. I is the value of image brightness at the position of the corner. In the case of susan_corners_quick, dx and dy are the first order derivatives (differentials) of the image brightness in the x and y directions respectively, at the position of the corner. In the case of normal susan corner finding, dx and dy are scaled versions of the position of the centre of gravity of the USAN with respect to the centre pixel (nucleus). BRIGHTNESS FUNCTION LUT IMPLEMENTATION: (Only read this if you are interested in the C implementation) The SUSAN brightness function is implemented as a LUT (Look-Up-Table) for speed. The resulting pointer-based code is a little hard to follow, so here is a brief explanation. In setup_brightness_lut() the LUT is setup. This mallocs enough space for *bp and then repositions the pointer to the centre of the malloced space. The SUSAN function e^-(x^6) or e^-(x^2) is calculated and converted to a uchar in the range 0-100, for all possible image brightness differences (including negative ones). Thus bp[23] is the output for a brightness difference of 23 greylevels. In the SUSAN algorithms this LUT is used as follows: p=in + (i-3)*x_size + j - 1; p points to the first image pixel in the circular mask surrounding point (x,y). cp=bp + in[i*x_size+j]; cp points to a position in the LUT corresponding to the brightness of the centre pixel (x,y). now for every pixel within the mask surrounding (x,y), n+=*(cp-*p++); the brightness difference function is found by moving the cp pointer down by an amount equal to the value of the pixel pointed to by p, thus subtracting the two brightness values and performing the exponential function. This value is added to n, the running USAN area. in SUSAN smoothing, the variable height mask is implemented by multiplying the above by the moving mask pointer, reset for each new centre pixel. tmp = *dpt++ * *(cp-brightness); \**********************************************************************/ /**********************************************************************\ Success has been reported with the following: MACHINE OS COMPILER Sun 4.1.4 bundled C, gcc Next SGI IRIX SGI cc DEC Unix V3.2+ IBM RISC AIX gcc PC Borland 5.0 PC Linux gcc-2.6.3 PC Win32 Visual C++ 4.0 (Console Application) PC Win95 Visual C++ 5.0 (Console Application) Thanks to Niu Yongsheng : Use the FOPENB option below PC DOS djgpp gnu C Thanks to Mark Pettovello : Use the FOPENB option below HP HP-UX bundled cc Thanks to Brian Dixon : in ksh: export CCOPTS="-Aa -D_HPUX_SOURCE | -lM" cc -O3 -o susan susan2l.c \**********************************************************************/ /**********************************************************************\ SUSAN Version 2l, 12/2/99 Changed GNUDOS option to FOPENB. (Thanks to Niu Yongsheng .) Took out redundant "sq=sq/2;". SUSAN Version 2k, 19/8/98: In corner finding: Changed if(yyx_size) etc. tests in smoothing. Added a couple of free() calls for cgx and cgy. (Thanks to geoffb@ucs.ed.ac.uk - Geoff Browitt.) SUSAN Version 2i, 21/7/97: Added information about corner attributes. SUSAN Version 2h, 16/12/96: Added principle (initial enhancement) option. SUSAN Version 2g, 2/7/96: Minor superficial changes to code. SUSAN Version 2f, 16/1/96: Added GNUDOS option (now called FOPENB; see options below). SUSAN Version 2e, 9/1/96: Added -b option. Fixed 1 pixel horizontal offset error for drawing edges. SUSAN Version 2d, 27/11/95: Fixed loading of certain PGM files in get_image (again!) SUSAN Version 2c, 22/11/95: Fixed loading of certain PGM files in get_image. (Thanks to qu@San-Jose.ate.slb.com - Gongyuan Qu.) SUSAN Version 2b, 9/11/95: removed "z==" error in edges routines. SUSAN Version 2a, 6/11/95: Removed a few unnecessary variable declarations. Added different machine information. Changed "header" in get_image to char. SUSAN Version 2, 1/11/95: first combined version able to take any image sizes. SUSAN "Versions 1", circa 1992: the various SUSAN algorithms were developed during my doctorate within different programs and for fixed image sizes. The algorithms themselves are virtually unaltered between "versions 1" and the combined program, version 2. \**********************************************************************/ #include "../extra.h" #include "wcclibm.h" #include "wccfile.h" #include "wccmalloc.h" #define EXP_A 184 #define EXP_C 16249 float susan_expf(float y) { union { float d; struct { #ifdef LITTLE_ENDIAN short j, i; #else short i, j; #endif } n; } eco; eco.n.i = EXP_A*(y) + (EXP_C); eco.n.j = 0; return eco.d; } float susan_sqrtf(float val) { float x = val/10; float dx; float diff; float min_tol = 0.00001f; int i, flag; flag = 0; if (val == 0 ) x = 0; else { for (i=1;i<20;i++) { if (!flag) { dx = (val - (x*x)) / (2.0f * x); x = x + dx; diff = val - (x*x); if (fabs(diff) <= min_tol) flag = 1; } } } return (x); } /* ********** Optional settings */ typedef int TOTAL_TYPE; #define SEVEN_SUPP /* size for non-max corner suppression; SEVEN_SUPP or FIVE_SUPP */ #define MAX_CORNERS 15000 /* max corners per frame */ #define FTOI(a) ( (a) < 0 ? ((int)(a-0.5)) : ((int)(a+0.5)) ) #define abs(a) ( (a) < 0 ? -a : a ) typedef unsigned char uchar; typedef struct {int x,y,info, dx, dy, I;} corner_rep; typedef corner_rep CORNER_LIST[MAX_CORNERS]; extern char susan_input[7292]; struct wccFILE susan_file; float susan_dt; int susan_bt; int susan_principle_conf; int susan_thin_post_proc; int susan_three_by_three; int susan_drawing_mode; int susan_susan_quick; int susan_max_no_corners; int susan_max_no_edges; int susan_getint( struct wccFILE *fd ) { int c, i; char dummy[10000]; c = susan_wccfgetc(fd); _Pragma( "loopbound min 1 max 4" ) while (1) { /* find next integer */ if (c=='#') /* if we're at a comment, read to end of line */ susan_wccfgets(dummy,9000,fd); if (c==EOFX) { /* "Image is not binary PGM." */ } if (c>='0' && c<='9') break; /* found what we were looking for */ c = susan_wccfgetc(fd); } /* we're at the start of a number, continue until we hit a non-number */ i = 0; _Pragma( "loopbound min 2 max 3" ) while (1) { i = (i*10) + (c - '0'); c = susan_wccfgetc(fd); if (c==EOFX) return (i); if (c<'0' || c>'9') break; } return (i); } void susan_get_image( struct wccFILE *fd, unsigned char **in, int *x_size, int *y_size ) { char header [100]; susan_wccfseek( fd, 0, WCCSEEK_SET ); /* {{{ read header */ header[0]=susan_wccfgetc( fd ); header[1]=susan_wccfgetc( fd ); if(!(header[0]=='P' && header[1]=='5')) { /* "Image does not have binary PGM header." */ } *x_size = susan_getint(fd); *y_size = susan_getint(fd); // dummy read susan_getint(fd); /* }}} */ *in = (uchar *) susan_wccmalloc(*x_size * *y_size); if (susan_wccfread(*in,1,*x_size * *y_size,fd) == 0) { /* "Image is wrong size.\n" */ } } void susan_put_image( int x_size, int y_size ) { int i; _Pragma( "loopbound min 7220 max 7220" ) for ( i = 0; i < x_size*y_size; i++ ) { ; } } void susan_int_to_uchar( char *r, uchar *in, int size ) { int i, max_r=r[0], min_r=r[0]; _Pragma( "loopbound min 0 max 0" ) for (i=0; i max_r ) max_r=r[i]; if ( r[i] < min_r ) min_r=r[i]; } if (max_r == min_r) { /* Should not occur in TACLeBench. */ _Pragma( "loopbound min 0 max 0" ) for (i=0; ip[l+1]) { tmp=p[l]; p[l]=p[l+1]; p[l+1]=tmp; } } } return( (p[3]+p[4]) / 2 ); } /* this enlarges "in" so that borders can be dealt with easily */ void susan_enlarge( uchar **in, uchar *tmp_image, int *x_size, int *y_size, int border ) { int i, j; _Pragma( "loopbound min 95 max 95" ) for(i=0; i<*y_size; i++) { /* copy *in into tmp_image */ susan_wccmemcpy( tmp_image+(i+border)*(*x_size+2*border)+border, *in+i* *x_size, *x_size); } _Pragma( "loopbound min 7 max 7" ) for(i=0; i15 ) { /* "Distance_thresh too big for integer arithmetic." */ // Either reduce it to <=15 or recompile with variable "total" // as a float: see top "defines" section. } if ( (2*mask_size+1>x_size) || (2*mask_size+1>y_size) ) { /* "Mask size too big for image." */ } tmp_image = (uchar *)susan_wccmalloc( (x_size+mask_size*2) * (y_size+mask_size*2) ); susan_enlarge(&in,tmp_image,&x_size,&y_size,mask_size); if (three_by_three==0) { /* large Gaussian masks */ /* {{{ setup distance lut */ n_max = (mask_size*2) + 1; increment = x_size - n_max; dp = (unsigned char *)susan_wccmalloc(n_max*n_max); dpt = dp; temp = -(dt*dt); _Pragma( "loopbound min 15 max 15" ) for(i=-mask_size; i<=mask_size; i++) { _Pragma( "loopbound min 15 max 15" ) for(j=-mask_size; j<=mask_size; j++) { x = (int) (100.0 * susan_expf( ((float)((i*i)+(j*j))) / temp )); *dpt++ = (unsigned char)x; } } /* {{{ main section */ _Pragma( "loopbound min 95 max 95" ) for (i=mask_size;im) { m=l[y+y+y+x]; a=y; b=x; } if (m>0) { if (mid[i*x_size+j]<4) mid[(i+a-1)*x_size+j+b-1] = 4; else mid[(i+a-1)*x_size+j+b-1] = mid[i*x_size+j]+1; if ( (a+a+b) < 3 ) { /* need to jump back in image */ i+=a-1; j+=b-2; if (i<4) i=4; if (j<4) j=4; } } } /* {{{ n==2 */ if (n==2) { /* put in a bit here to straighten edges */ b00 = mid[(i-1)*x_size+j-1]<8; /* corners of 3x3 */ b02 = mid[(i-1)*x_size+j+1]<8; b20 = mid[(i+1)*x_size+j-1]<8; b22 = mid[(i+1)*x_size+j+1]<8; if ( ((b00+b02+b20+b22)==2) && ((b00|b22)&(b02|b20))) { /* case: move a point back into line. e.g. X O X CAN become X X X O X O O O O O O O O O O */ if (b00) { if (b02) { x=0; y=-1; } else { x=-1; y=0; } } else { if (b02) { x=1; y=0; } else { x=0; y=1; } } if (((float)r[(i+y)*x_size+j+x]/(float)centre) > 0.7) { if ( ( (x==0) && (mid[(i+(2*y))*x_size+j]>7) && (mid[(i+(2*y))*x_size+j-1]>7) && (mid[(i+(2*y))*x_size+j+1]>7) ) || ( (y==0) && (mid[(i)*x_size+j+(2*x)]>7) && (mid[(i+1)*x_size+j+(2*x)]>7) && (mid[(i-1)*x_size+j+(2*x)]>7) ) ) { mid[(i)*x_size+j]=100; mid[(i+y)*x_size+j+x]=3; /* no jumping needed */ } } } else { b01 = mid[(i-1)*x_size+j ]<8; b12 = mid[(i )*x_size+j+1]<8; b21 = mid[(i+1)*x_size+j ]<8; b10 = mid[(i )*x_size+j-1]<8; /* {{{ right angle ends - not currently used */ #ifdef IGNORETHIS if ( (b00&b01)|(b00&b10)|(b02&b01)|(b02&b12)|(b20&b10)|(b20&b21)|(b22&b21)|(b22&b12) ) { /* case; right angle ends. clean up. e.g.; X X O CAN become X X O O X O O O O O O O O O O */ if ( ((b01)&(mid[(i-2)*x_size+j-1]>7)&(mid[(i-2)*x_size+j]>7)&(mid[(i-2)*x_size+j+1]>7)& ((b00&((2*r[(i-1)*x_size+j+1])>centre))|(b02&((2*r[(i-1)*x_size+j-1])>centre)))) | ((b10)&(mid[(i-1)*x_size+j-2]>7)&(mid[(i)*x_size+j-2]>7)&(mid[(i+1)*x_size+j-2]>7)& ((b00&((2*r[(i+1)*x_size+j-1])>centre))|(b20&((2*r[(i-1)*x_size+j-1])>centre)))) | ((b12)&(mid[(i-1)*x_size+j+2]>7)&(mid[(i)*x_size+j+2]>7)&(mid[(i+1)*x_size+j+2]>7)& ((b02&((2*r[(i+1)*x_size+j+1])>centre))|(b22&((2*r[(i-1)*x_size+j+1])>centre)))) | ((b21)&(mid[(i+2)*x_size+j-1]>7)&(mid[(i+2)*x_size+j]>7)&(mid[(i+2)*x_size+j+1]>7)& ((b20&((2*r[(i+1)*x_size+j+1])>centre))|(b22&((2*r[(i+1)*x_size+j-1])>centre)))) ) { mid[(i)*x_size+j]=100; if (b10&b20) j-=2; if (b00|b01|b02) { i--; j-=2; } } } #endif if ( ((b01+b12+b21+b10)==2) && ((b10|b12)&(b01|b21)) && ((b01&((mid[(i-2)*x_size+j-1]<8)|(mid[(i-2)*x_size+j+1]<8)))|(b10&((mid[(i-1)*x_size+j-2]<8)|(mid[(i+1)*x_size+j-2]<8)))| (b12&((mid[(i-1)*x_size+j+2]<8)|(mid[(i+1)*x_size+j+2]<8)))|(b21&((mid[(i+2)*x_size+j-1]<8)|(mid[(i+2)*x_size+j+1]<8)))) ) { /* case; clears odd right angles. e.g.; O O O becomes O O O X X O X O O O X O O X O */ mid[(i)*x_size+j]=100; i--; /* jump back */ j-=2; if (i<4) i=4; if (j<4) j=4; } } } /* {{{ n>2 the thinning is done here without breaking connectivity */ if (n>2) { b01 = mid[(i-1)*x_size+j ]<8; b12 = mid[(i )*x_size+j+1]<8; b21 = mid[(i+1)*x_size+j ]<8; b10 = mid[(i )*x_size+j-1]<8; if((b01+b12+b21+b10)>1) { b00 = mid[(i-1)*x_size+j-1]<8; b02 = mid[(i-1)*x_size+j+1]<8; b20 = mid[(i+1)*x_size+j-1]<8; b22 = mid[(i+1)*x_size+j+1]<8; p1 = b00 | b01; p2 = b02 | b12; p3 = b22 | b21; p4 = b20 | b10; if( ((p1 + p2 + p3 + p4) - ((b01 & p2)+(b12 & p3)+(b21 & p4)+(b10 & p1))) < 2) { mid[(i)*x_size+j]=100; i--; j-=2; if (i<4) i=4; if (j<4) j=4; } } } } } } } void susan_edges( uchar *in, char *r, uchar *mid, uchar *bp, int max_no, int x_size, int y_size ) { float z; int do_symmetry, i, j, m, n, a, b, x, y, w; uchar c,*p,*cp; susan_wccmemset(r,0,x_size * y_size); _Pragma( "loopbound min 89 max 89" ) for (i=3;i0) { m=r[i*x_size+j]; n=max_no - m; cp=bp + in[i*x_size+j]; if (n>600) { p=in + (i-3)*x_size + j - 1; x=0;y=0; c=*(cp-*p++);x-=c;y-=3*c; c=*(cp-*p++);y-=3*c; c=*(cp-*p);x+=c;y-=3*c; p+=x_size-3; c=*(cp-*p++);x-=2*c;y-=2*c; c=*(cp-*p++);x-=c;y-=2*c; c=*(cp-*p++);y-=2*c; c=*(cp-*p++);x+=c;y-=2*c; c=*(cp-*p);x+=2*c;y-=2*c; p+=x_size-5; c=*(cp-*p++);x-=3*c;y-=c; c=*(cp-*p++);x-=2*c;y-=c; c=*(cp-*p++);x-=c;y-=c; c=*(cp-*p++);y-=c; c=*(cp-*p++);x+=c;y-=c; c=*(cp-*p++);x+=2*c;y-=c; c=*(cp-*p);x+=3*c;y-=c; p+=x_size-6; c=*(cp-*p++);x-=3*c; c=*(cp-*p++);x-=2*c; c=*(cp-*p);x-=c; p+=2; c=*(cp-*p++);x+=c; c=*(cp-*p++);x+=2*c; c=*(cp-*p);x+=3*c; p+=x_size-6; c=*(cp-*p++);x-=3*c;y+=c; c=*(cp-*p++);x-=2*c;y+=c; c=*(cp-*p++);x-=c;y+=c; c=*(cp-*p++);y+=c; c=*(cp-*p++);x+=c;y+=c; c=*(cp-*p++);x+=2*c;y+=c; c=*(cp-*p);x+=3*c;y+=c; p+=x_size-5; c=*(cp-*p++);x-=2*c;y+=2*c; c=*(cp-*p++);x-=c;y+=2*c; c=*(cp-*p++);y+=2*c; c=*(cp-*p++);x+=c;y+=2*c; c=*(cp-*p);x+=2*c;y+=2*c; p+=x_size-3; c=*(cp-*p++);x-=c;y+=3*c; c=*(cp-*p++);y+=3*c; c=*(cp-*p);x+=c;y+=3*c; z = susan_sqrtf((float)((x*x) + (y*y))); if (z > (0.9*(float)n)) { /* 0.5 */ do_symmetry=0; if (x==0) z=1000000.0; else z=((float)y) / ((float)x); if (z < 0) { z=-z; w=-1; } else w=1; if (z < 0.5) { /* vert_edge */ a=0; b=1; } else { if (z > 2.0) { /* hor_edge */ a=1; b=0; } else { /* diag_edge */ if (w>0) { a=1; b=1; } else { a=-1; b=1; }}} if ( (m > r[(i+a)*x_size+j+b]) && (m >= r[(i-a)*x_size+j-b]) && (m > r[(i+(2*a))*x_size+j+(2*b)]) && (m >= r[(i-(2*a))*x_size+j-(2*b)]) ) mid[i*x_size+j] = 1; } else { do_symmetry=1; } } else { do_symmetry=1; } if (do_symmetry==1) { p=in + (i-3)*x_size + j - 1; x=0; y=0; w=0; /* | \ y -x- w | \ */ c=*(cp-*p++);x+=c;y+=9*c;w+=3*c; c=*(cp-*p++);y+=9*c; c=*(cp-*p);x+=c;y+=9*c;w-=3*c; p+=x_size-3; c=*(cp-*p++);x+=4*c;y+=4*c;w+=4*c; c=*(cp-*p++);x+=c;y+=4*c;w+=2*c; c=*(cp-*p++);y+=4*c; c=*(cp-*p++);x+=c;y+=4*c;w-=2*c; c=*(cp-*p);x+=4*c;y+=4*c;w-=4*c; p+=x_size-5; c=*(cp-*p++);x+=9*c;y+=c;w+=3*c; c=*(cp-*p++);x+=4*c;y+=c;w+=2*c; c=*(cp-*p++);x+=c;y+=c;w+=c; c=*(cp-*p++);y+=c; c=*(cp-*p++);x+=c;y+=c;w-=c; c=*(cp-*p++);x+=4*c;y+=c;w-=2*c; c=*(cp-*p);x+=9*c;y+=c;w-=3*c; p+=x_size-6; c=*(cp-*p++);x+=9*c; c=*(cp-*p++);x+=4*c; c=*(cp-*p);x+=c; p+=2; c=*(cp-*p++);x+=c; c=*(cp-*p++);x+=4*c; c=*(cp-*p);x+=9*c; p+=x_size-6; c=*(cp-*p++);x+=9*c;y+=c;w-=3*c; c=*(cp-*p++);x+=4*c;y+=c;w-=2*c; c=*(cp-*p++);x+=c;y+=c;w-=c; c=*(cp-*p++);y+=c; c=*(cp-*p++);x+=c;y+=c;w+=c; c=*(cp-*p++);x+=4*c;y+=c;w+=2*c; c=*(cp-*p);x+=9*c;y+=c;w+=3*c; p+=x_size-5; c=*(cp-*p++);x+=4*c;y+=4*c;w-=4*c; c=*(cp-*p++);x+=c;y+=4*c;w-=2*c; c=*(cp-*p++);y+=4*c; c=*(cp-*p++);x+=c;y+=4*c;w+=2*c; c=*(cp-*p);x+=4*c;y+=4*c;w+=4*c; p+=x_size-3; c=*(cp-*p++);x+=c;y+=9*c;w-=3*c; c=*(cp-*p++);y+=9*c; c=*(cp-*p);x+=c;y+=9*c;w+=3*c; if (y==0) z = 1000000.0; else z = ((float)x) / ((float)y); if (z < 0.5) { /* vertical */ a=0; b=1; } else { if (z > 2.0) { /* horizontal */ a=1; b=0; } else { /* diagonal */ if (w>0) { a=-1; b=1; } else { a=1; b=1; }}} if ( (m > r[(i+a)*x_size+j+b]) && (m >= r[(i-a)*x_size+j-b]) && (m > r[(i+(2*a))*x_size+j+(2*b)]) && (m >= r[(i-(2*a))*x_size+j-(2*b)]) ) mid[i*x_size+j] = 2; } } } } } void susan_edges_small( uchar *in, char *r, uchar *mid, uchar *bp, int max_no, int x_size, int y_size ) { float z; int do_symmetry, i, j, m, n, a, b, x, y, w; uchar c,*p,*cp; susan_wccmemset(r,0,x_size * y_size); _Pragma( "loopbound min 0 max 0" ) for (i=1;i0) { m=r[i*x_size+j]; n=max_no - m; cp=bp + in[i*x_size+j]; if (n>250) { p=in + (i-1)*x_size + j - 1; x=0;y=0; c=*(cp-*p++);x-=c;y-=c; c=*(cp-*p++);y-=c; c=*(cp-*p);x+=c;y-=c; p+=x_size-2; c=*(cp-*p);x-=c; p+=2; c=*(cp-*p);x+=c; p+=x_size-2; c=*(cp-*p++);x-=c;y+=c; c=*(cp-*p++);y+=c; c=*(cp-*p);x+=c;y+=c; z = susan_sqrtf((float)((x*x) + (y*y))); if (z > (0.4*(float)n)) { /* 0.6 */ do_symmetry=0; if (x==0) z=1000000.0; else z=((float)y) / ((float)x); if (z < 0) { z=-z; w=-1; } else w=1; if (z < 0.5) { /* vert_edge */ a=0; b=1; } else { if (z > 2.0) { /* hor_edge */ a=1; b=0; } else { /* diag_edge */ if (w>0) { a=1; b=1; } else { a=-1; b=1; } } } if ( (m > r[(i+a)*x_size+j+b]) && (m >= r[(i-a)*x_size+j-b]) ) { mid[i*x_size+j] = 1; } } else { do_symmetry=1; } } else { do_symmetry=1; } if (do_symmetry==1) { p=in + (i-1)*x_size + j - 1; x=0; y=0; w=0; /* | \ y -x- w | \ */ c=*(cp-*p++);x+=c;y+=c;w+=c; c=*(cp-*p++);y+=c; c=*(cp-*p);x+=c;y+=c;w-=c; p+=x_size-2; c=*(cp-*p);x+=c; p+=2; c=*(cp-*p);x+=c; p+=x_size-2; c=*(cp-*p++);x+=c;y+=c;w-=c; c=*(cp-*p++);y+=c; c=*(cp-*p);x+=c;y+=c;w+=c; if (y==0) z = 1000000.0; else z = ((float)x) / ((float)y); if (z < 0.5) { /* vertical */ a=0; b=1; } else { if (z > 2.0) { /* horizontal */ a=1; b=0; } else { /* diagonal */ if (w>0) { a=-1; b=1; } else { a=1; b=1; } } } if ( (m > r[(i+a)*x_size+j+b]) && (m >= r[(i-a)*x_size+j-b]) ) { mid[i*x_size+j] = 2; } } } } } } void susan_corner_draw( uchar *in, CORNER_LIST corner_list, int x_size, int drawing_mode) { uchar *p; int n=0; _Pragma( "loopbound min 0 max 0" ) while(corner_list[n].info != 7) { if (drawing_mode==0) { p = in + (corner_list[n].y-1)*x_size + corner_list[n].x - 1; *p++=255; *p++=255; *p=255; p+=x_size-2; *p++=255; *p++=0; *p=255; p+=x_size-2; *p++=255; *p++=255; *p=255; n++; } else { p = in + corner_list[n].y*x_size + corner_list[n].x; *p=0; n++; } } } void susan_corners( uchar *in, char *r, uchar *bp, int max_no, CORNER_LIST corner_list, int x_size, int y_size) { int n,x,y,sq,xx,yy, i,j; float divide; uchar c,*p,*cp; char *cgx,*cgy; susan_wccmemset(r,0,x_size * y_size); cgx=(char *)susan_wccmalloc(x_size*y_size); cgy=(char *)susan_wccmalloc(x_size*y_size); _Pragma( "loopbound min 85 max 85" ) for (i=5;i ((n*n)/2) ) { if(yy290){ r[i*x_size+j] = max_no-n; cgx[i*x_size+j] = (51*x)/n; cgy[i*x_size+j] = (51*y)/n; } } } }}}}}}}}}}}}}}}}}} } } /* to locate the local maxima */ n=0; _Pragma( "loopbound min 85 max 85" ) for (i=5;i0) { /* 5x5 mask */ #ifdef FIVE_SUPP if ((x>r[(i-1)*x_size+j+2]) && (x>r[(i )*x_size+j+1]) && (x>r[(i )*x_size+j+2]) && (x>r[(i+1)*x_size+j-1]) && (x>r[(i+1)*x_size+j ]) && (x>r[(i+1)*x_size+j+1]) && (x>r[(i+1)*x_size+j+2]) && (x>r[(i+2)*x_size+j-2]) && (x>r[(i+2)*x_size+j-1]) && (x>r[(i+2)*x_size+j ]) && (x>r[(i+2)*x_size+j+1]) && (x>r[(i+2)*x_size+j+2]) && (x>=r[(i-2)*x_size+j-2]) && (x>=r[(i-2)*x_size+j-1]) && (x>=r[(i-2)*x_size+j ]) && (x>=r[(i-2)*x_size+j+1]) && (x>=r[(i-2)*x_size+j+2]) && (x>=r[(i-1)*x_size+j-2]) && (x>=r[(i-1)*x_size+j-1]) && (x>=r[(i-1)*x_size+j ]) && (x>=r[(i-1)*x_size+j+1]) && (x>=r[(i )*x_size+j-2]) && (x>=r[(i )*x_size+j-1]) && (x>=r[(i+1)*x_size+j-2]) ) #endif #ifdef SEVEN_SUPP if ((x>r[(i-3)*x_size+j-3]) && (x>r[(i-3)*x_size+j-2]) && (x>r[(i-3)*x_size+j-1]) && (x>r[(i-3)*x_size+j ]) && (x>r[(i-3)*x_size+j+1]) && (x>r[(i-3)*x_size+j+2]) && (x>r[(i-3)*x_size+j+3]) && (x>r[(i-2)*x_size+j-3]) && (x>r[(i-2)*x_size+j-2]) && (x>r[(i-2)*x_size+j-1]) && (x>r[(i-2)*x_size+j ]) && (x>r[(i-2)*x_size+j+1]) && (x>r[(i-2)*x_size+j+2]) && (x>r[(i-2)*x_size+j+3]) && (x>r[(i-1)*x_size+j-3]) && (x>r[(i-1)*x_size+j-2]) && (x>r[(i-1)*x_size+j-1]) && (x>r[(i-1)*x_size+j ]) && (x>r[(i-1)*x_size+j+1]) && (x>r[(i-1)*x_size+j+2]) && (x>r[(i-1)*x_size+j+3]) && (x>r[(i)*x_size+j-3]) && (x>r[(i)*x_size+j-2]) && (x>r[(i)*x_size+j-1]) && (x>=r[(i)*x_size+j+1]) && (x>=r[(i)*x_size+j+2]) && (x>=r[(i)*x_size+j+3]) && (x>=r[(i+1)*x_size+j-3]) && (x>=r[(i+1)*x_size+j-2]) && (x>=r[(i+1)*x_size+j-1]) && (x>=r[(i+1)*x_size+j ]) && (x>=r[(i+1)*x_size+j+1]) && (x>=r[(i+1)*x_size+j+2]) && (x>=r[(i+1)*x_size+j+3]) && (x>=r[(i+2)*x_size+j-3]) && (x>=r[(i+2)*x_size+j-2]) && (x>=r[(i+2)*x_size+j-1]) && (x>=r[(i+2)*x_size+j ]) && (x>=r[(i+2)*x_size+j+1]) && (x>=r[(i+2)*x_size+j+2]) && (x>=r[(i+2)*x_size+j+3]) && (x>=r[(i+3)*x_size+j-3]) && (x>=r[(i+3)*x_size+j-2]) && (x>=r[(i+3)*x_size+j-1]) && (x>=r[(i+3)*x_size+j ]) && (x>=r[(i+3)*x_size+j+1]) && (x>=r[(i+3)*x_size+j+2]) && (x>=r[(i+3)*x_size+j+3]) ) #endif { corner_list[n].info=0; corner_list[n].x=j; corner_list[n].y=i; corner_list[n].dx=cgx[i*x_size+j]; corner_list[n].dy=cgy[i*x_size+j]; corner_list[n].I=in[i*x_size+j]; n++; if(n==MAX_CORNERS){ /* "Too many corners." */ } } } } } corner_list[n].info=7; } void susan_corners_quick( uchar *in, char *r, uchar *bp, int max_no, CORNER_LIST corner_list, int x_size, int y_size ) { int n,x,y,i,j; uchar *p,*cp; susan_wccmemset(r,0,x_size * y_size); _Pragma( "loopbound min 0 max 0" ) for (i=7;i0) { /* 5x5 mask */ #ifdef FIVE_SUPP if ((x>r[(i-1)*x_size+j+2]) && (x>r[(i )*x_size+j+1]) && (x>r[(i )*x_size+j+2]) && (x>r[(i+1)*x_size+j-1]) && (x>r[(i+1)*x_size+j ]) && (x>r[(i+1)*x_size+j+1]) && (x>r[(i+1)*x_size+j+2]) && (x>r[(i+2)*x_size+j-2]) && (x>r[(i+2)*x_size+j-1]) && (x>r[(i+2)*x_size+j ]) && (x>r[(i+2)*x_size+j+1]) && (x>r[(i+2)*x_size+j+2]) && (x>=r[(i-2)*x_size+j-2]) && (x>=r[(i-2)*x_size+j-1]) && (x>=r[(i-2)*x_size+j ]) && (x>=r[(i-2)*x_size+j+1]) && (x>=r[(i-2)*x_size+j+2]) && (x>=r[(i-1)*x_size+j-2]) && (x>=r[(i-1)*x_size+j-1]) && (x>=r[(i-1)*x_size+j ]) && (x>=r[(i-1)*x_size+j+1]) && (x>=r[(i )*x_size+j-2]) && (x>=r[(i )*x_size+j-1]) && (x>=r[(i+1)*x_size+j-2]) ) #endif #ifdef SEVEN_SUPP if ((x>r[(i-3)*x_size+j-3]) && (x>r[(i-3)*x_size+j-2]) && (x>r[(i-3)*x_size+j-1]) && (x>r[(i-3)*x_size+j ]) && (x>r[(i-3)*x_size+j+1]) && (x>r[(i-3)*x_size+j+2]) && (x>r[(i-3)*x_size+j+3]) && (x>r[(i-2)*x_size+j-3]) && (x>r[(i-2)*x_size+j-2]) && (x>r[(i-2)*x_size+j-1]) && (x>r[(i-2)*x_size+j ]) && (x>r[(i-2)*x_size+j+1]) && (x>r[(i-2)*x_size+j+2]) && (x>r[(i-2)*x_size+j+3]) && (x>r[(i-1)*x_size+j-3]) && (x>r[(i-1)*x_size+j-2]) && (x>r[(i-1)*x_size+j-1]) && (x>r[(i-1)*x_size+j ]) && (x>r[(i-1)*x_size+j+1]) && (x>r[(i-1)*x_size+j+2]) && (x>r[(i-1)*x_size+j+3]) && (x>r[(i)*x_size+j-3]) && (x>r[(i)*x_size+j-2]) && (x>r[(i)*x_size+j-1]) && (x>=r[(i)*x_size+j+1]) && (x>=r[(i)*x_size+j+2]) && (x>=r[(i)*x_size+j+3]) && (x>=r[(i+1)*x_size+j-3]) && (x>=r[(i+1)*x_size+j-2]) && (x>=r[(i+1)*x_size+j-1]) && (x>=r[(i+1)*x_size+j ]) && (x>=r[(i+1)*x_size+j+1]) && (x>=r[(i+1)*x_size+j+2]) && (x>=r[(i+1)*x_size+j+3]) && (x>=r[(i+2)*x_size+j-3]) && (x>=r[(i+2)*x_size+j-2]) && (x>=r[(i+2)*x_size+j-1]) && (x>=r[(i+2)*x_size+j ]) && (x>=r[(i+2)*x_size+j+1]) && (x>=r[(i+2)*x_size+j+2]) && (x>=r[(i+2)*x_size+j+3]) && (x>=r[(i+3)*x_size+j-3]) && (x>=r[(i+3)*x_size+j-2]) && (x>=r[(i+3)*x_size+j-1]) && (x>=r[(i+3)*x_size+j ]) && (x>=r[(i+3)*x_size+j+1]) && (x>=r[(i+3)*x_size+j+2]) && (x>=r[(i+3)*x_size+j+3]) ) #endif { corner_list[n].info=0; corner_list[n].x=j; corner_list[n].y=i; x = in[(i-2)*x_size+j-2] + in[(i-2)*x_size+j-1] + in[(i-2)*x_size+j] + in[(i-2)*x_size+j+1] + in[(i-2)*x_size+j+2] + in[(i-1)*x_size+j-2] + in[(i-1)*x_size+j-1] + in[(i-1)*x_size+j] + in[(i-1)*x_size+j+1] + in[(i-1)*x_size+j+2] + in[(i )*x_size+j-2] + in[(i )*x_size+j-1] + in[(i )*x_size+j] + in[(i )*x_size+j+1] + in[(i )*x_size+j+2] + in[(i+1)*x_size+j-2] + in[(i+1)*x_size+j-1] + in[(i+1)*x_size+j] + in[(i+1)*x_size+j+1] + in[(i+1)*x_size+j+2] + in[(i+2)*x_size+j-2] + in[(i+2)*x_size+j-1] + in[(i+2)*x_size+j] + in[(i+2)*x_size+j+1] + in[(i+2)*x_size+j+2]; corner_list[n].I=x/25; /*corner_list[n].I=in[i*x_size+j];*/ x = in[(i-2)*x_size+j+2] + in[(i-1)*x_size+j+2] + in[(i)*x_size+j+2] + in[(i+1)*x_size+j+2] + in[(i+2)*x_size+j+2] - (in[(i-2)*x_size+j-2] + in[(i-1)*x_size+j-2] + in[(i)*x_size+j-2] + in[(i+1)*x_size+j-2] + in[(i+2)*x_size+j-2]); x += x + in[(i-2)*x_size+j+1] + in[(i-1)*x_size+j+1] + in[(i)*x_size+j+1] + in[(i+1)*x_size+j+1] + in[(i+2)*x_size+j+1] - (in[(i-2)*x_size+j-1] + in[(i-1)*x_size+j-1] + in[(i)*x_size+j-1] + in[(i+1)*x_size+j-1] + in[(i+2)*x_size+j-1]); y = in[(i+2)*x_size+j-2] + in[(i+2)*x_size+j-1] + in[(i+2)*x_size+j] + in[(i+2)*x_size+j+1] + in[(i+2)*x_size+j+2] - (in[(i-2)*x_size+j-2] + in[(i-2)*x_size+j-1] + in[(i-2)*x_size+j] + in[(i-2)*x_size+j+1] + in[(i-2)*x_size+j+2]); y += y + in[(i+1)*x_size+j-2] + in[(i+1)*x_size+j-1] + in[(i+1)*x_size+j] + in[(i+1)*x_size+j+1] + in[(i+1)*x_size+j+2] - (in[(i-1)*x_size+j-2] + in[(i-1)*x_size+j-1] + in[(i-1)*x_size+j] + in[(i-1)*x_size+j+1] + in[(i-1)*x_size+j+2]); corner_list[n].dx=x/15; corner_list[n].dy=y/15; n++; if(n==MAX_CORNERS){ /* "Too many corners." */ } } } } } corner_list[n].info=7; } void susan_call_susan( struct wccFILE *inputFile, int mode ) { uchar *in, *bp, *mid; int x_size, y_size; char *r; CORNER_LIST corner_list; susan_get_image( inputFile, &in, &x_size, &y_size ); if (susan_dt<0) susan_three_by_three=1; if ( (susan_principle_conf==1) && (mode==0) ) mode=1; switch (mode) { case 0: /* {{{ smoothing */ susan_setup_brightness_lut(&bp,susan_bt,2); susan_smoothing(susan_three_by_three,in,susan_dt,x_size,y_size,bp); break; case 1: /* {{{ edges */ r = (char *) susan_wccmalloc(x_size * y_size); susan_setup_brightness_lut(&bp,susan_bt,6); if (susan_principle_conf) { if (susan_three_by_three) susan_principle_small(in,r,bp,susan_max_no_edges,x_size,y_size); else susan_principle(in,r,bp,susan_max_no_edges,x_size,y_size); susan_int_to_uchar(r,in,x_size*y_size); } else { mid = (uchar *)susan_wccmalloc(x_size*y_size); susan_wccmemset(mid,100,x_size * y_size); /* note not set to zero */ if (susan_three_by_three) susan_edges_small(in,r,mid,bp,susan_max_no_edges,x_size,y_size); else susan_edges(in,r,mid,bp,susan_max_no_edges,x_size,y_size); if(susan_thin_post_proc) susan_thin(r,mid,x_size,y_size); susan_edge_draw(in,mid,x_size,y_size,susan_drawing_mode); } break; case 2: /* {{{ corners */ r = (char *) susan_wccmalloc(x_size * y_size); susan_setup_brightness_lut(&bp,susan_bt,6); if (susan_principle_conf) { susan_principle(in,r,bp,susan_max_no_corners,x_size,y_size); susan_int_to_uchar(r,in,x_size*y_size); } else { if(susan_susan_quick) susan_corners_quick(in,r,bp,susan_max_no_corners,corner_list,x_size,y_size); else susan_corners(in,r,bp,susan_max_no_corners,corner_list,x_size,y_size); susan_corner_draw(in,corner_list,x_size,susan_drawing_mode); } break; } susan_put_image(x_size,y_size); } void susan_init( void ) { volatile int a = 0; susan_file.data = susan_input; susan_file.size = 7292; susan_file.size += a; susan_file.cur_pos = 0; susan_file.cur_pos += a; susan_dt = 4.0; susan_dt += a; susan_bt = 20; susan_bt += a; susan_principle_conf = 0; susan_principle_conf += a; susan_thin_post_proc = 1; susan_thin_post_proc += a; susan_three_by_three = 0; susan_three_by_three += a; susan_drawing_mode = 0; susan_drawing_mode += a; susan_susan_quick = 0; susan_susan_quick += a; susan_max_no_corners = 50; susan_max_no_corners += a; susan_max_no_edges = 50; susan_max_no_edges += a; // mode=0; /* Smoothing mode */ // mode=1; /* Edges mode */ // mode=2; /* Corners mode */ // principle=1; /* Output initial enhancement image only; corners or edges mode (default is edges mode) */ // thin_post_proc=0; /* No post-processing on the binary edge map (runs much faster); edges mode */ // drawing_mode=1; /* Mark corners/edges with single black points instead of black with white border; corners or edges mode */ // three_by_three=1; /* Use flat 3x3 mask, edges or smoothing mode */ // susan_quick=1; /* Use faster (and usually stabler) corner mode; edge-like corner suppression not carried out; corners mode */ // dt=10.0; /* Distance threshold, smoothing mode, (default=4) */ // bt=50; /* Brightness threshold, all modes, (default=20) */ } void susan_main( void ) { susan_call_susan( &susan_file, 0 ); susan_wccfreeall(); susan_call_susan( &susan_file, 1 ); susan_wccfreeall(); susan_call_susan( &susan_file, 2 ); susan_wccfreeall(); } int susan_return( void ) { return 0; } int main( int argc, char **argv ) { SET_UP for (jobsComplete=-1; jobsComplete