% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
-% Morpology is the the application of various kernals, of any size and even
+% Morpology is the the application of various kernels, of any size and even
% shape, to a image in various ways (typically binary, but not always).
%
% Convolution (weighted sum or average) is just one specific type of
#include "magick/memory_.h"
#include "magick/monitor-private.h"
#include "magick/morphology.h"
+#include "magick/morphology-private.h"
#include "magick/option.h"
#include "magick/pixel-private.h"
#include "magick/prepress.h"
#include "magick/string_.h"
#include "magick/string-private.h"
#include "magick/token.h"
-
+\f
/*
- * The following test is for special floating point numbers of value NaN (not
- * a number), that may be used within a Kernel Definition. NaN's are defined
- * as part of the IEEE standard for floating point number representation.
- *
- * These are used a Kernel value of NaN means that that kernal position is not
- * part of the normal convolution or morphology process, and thus allowing the
- * use of 'shaped' kernels.
- *
- * Special Properities Two NaN's are never equal, even if they are from the
- * same variable That is the IsNaN() macro is only true if the value is NaN.
- */
+** The following test is for special floating point numbers of value NaN (not
+** a number), that may be used within a Kernel Definition. NaN's are defined
+** as part of the IEEE standard for floating point number representation.
+**
+** These are used as a Kernel value to mean that this kernel position is not
+** part of the kernel neighbourhood for convolution or morphology processing,
+** and thus should be ignored. This allows the use of 'shaped' kernels.
+**
+** The special properity that two NaN's are never equal, even if they are from
+** the same variable allow you to test if a value is special NaN value.
+**
+** This macro IsNaN() is thus is only true if the value given is NaN.
+*/
#define IsNan(a) ((a)!=(a))
/*
- * Other global definitions used by module
- */
+ Other global definitions used by module.
+*/
static inline double MagickMin(const double x,const double y)
{
return( x < y ? x : y);
/* Currently these are only internal to this module */
static void
- RotateKernelInfo(KernelInfo *, double),
- ScaleKernelInfo(KernelInfo *, const double, const MagickStatusType);
+ CalcKernelMetaData(KernelInfo *),
+ ExpandMirrorKernelInfo(KernelInfo *),
+ ExpandRotateKernelInfo(KernelInfo *, const double),
+ RotateKernelInfo(KernelInfo *, double);
+\f
+
+/* Quick function to find last kernel in a kernel list */
+static inline KernelInfo *LastKernelInfo(KernelInfo *kernel)
+{
+ while (kernel->next != (KernelInfo *) NULL)
+ kernel = kernel->next;
+ return(kernel);
+}
-static KernelInfo
- *CloneKernelInfo(const KernelInfo *);
-\f
/*
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %
% anywhere within that array of values.
%
% Previously IM was restricted to a square of odd size using the exact
-% center as origin, this is no longer the case, and any rectangular kernel
+% center as origin, this is no ssize_ter the case, and any rectangular kernel
% with any value being declared the origin. This in turn allows the use of
% highly asymmetrical kernels.
%
% shape. However at least one non-nan value must be provided for correct
% working of a kernel.
%
-% The returned kernel should be free using the DestroyKernelInfo() when you
-% are finished with it.
+% The returned kernel should be freed using the DestroyKernelInfo() when you
+% are finished with it. Do not free this memory yourself.
%
% Input kernel defintion strings can consist of any of three types.
%
-% "name:args"
+% "name:args[[@><]"
% Select from one of the built in kernels, using the name and
% geometry arguments supplied. See AcquireKernelBuiltIn()
%
-% "WxH[+X+Y]:num, num, num ..."
-% a kernal of size W by H, with W*H floating point numbers following.
+% "WxH[+X+Y][@><]:num, num, num ..."
+% a kernel of size W by H, with W*H floating point numbers following.
% the 'center' can be optionally be defined at +X+Y (such that +0+0
% is top left corner). If not defined the pixel in the center, for
% odd sizes, or to the immediate top or left of center for even sizes
% square kernel, 25 for a 5x5 square kernel, 49 for 7x7, etc.
% Values can be space or comma separated. This is not recommended.
%
+% You can define a 'list of kernels' which can be used by some morphology
+% operators A list is defined as a semi-colon seperated list kernels.
+%
+% " kernel ; kernel ; kernel ; "
+%
+% Any extra ';' characters, at start, end or between kernel defintions are
+% simply ignored.
+%
+% The special flags will expand a single kernel, into a list of rotated
+% kernels. A '@' flag will expand a 3x3 kernel into a list of 45-degree
+% cyclic rotations, while a '>' will generate a list of 90-degree rotations.
+% The '<' also exands using 90-degree rotates, but giving a 180-degree
+% reflected kernel before the +/- 90-degree rotations, which can be important
+% for Thinning operations.
+%
% Note that 'name' kernels will start with an alphabetic character while the
% new kernel specification has a ':' character in its specification string.
% If neither is the case, it is assumed an old style of a simple list of
%
*/
-MagickExport KernelInfo *AcquireKernelInfo(const char *kernel_string)
+/* This was separated so that it could be used as a separate
+** array input handling function, such as for -color-matrix
+*/
+static KernelInfo *ParseKernelArray(const char *kernel_string)
{
KernelInfo
*kernel;
char
token[MaxTextExtent];
- register long
+ const char
+ *p,
+ *end;
+
+ register ssize_t
i;
- const char
- *p;
+ double
+ nan = sqrt((double)-1.0); /* Special Value : Not A Number */
MagickStatusType
flags;
GeometryInfo
args;
- double
- nan = sqrt((double)-1.0); /* Special Value : Not A Number */
-
- assert(kernel_string != (const char *) NULL);
- SetGeometryInfo(&args);
-
- /* does it start with an alpha - Return a builtin kernel */
- GetMagickToken(kernel_string,&p,token);
- if ( isalpha((int)token[0]) )
- {
- long
- type;
-
- type=ParseMagickOption(MagickKernelOptions,MagickFalse,token);
- if ( type < 0 || type == UserDefinedKernel )
- return((KernelInfo *)NULL);
-
- while (((isspace((int) ((unsigned char) *p)) != 0) ||
- (*p == ',') || (*p == ':' )) && (*p != '\0'))
- p++;
- flags = ParseGeometry(p, &args);
-
- /* special handling of missing values in input string */
- switch( type ) {
- case RectangleKernel:
- if ( (flags & WidthValue) == 0 ) /* if no width then */
- args.rho = args.sigma; /* then width = height */
- if ( args.rho < 1.0 ) /* if width too small */
- args.rho = 3; /* then width = 3 */
- if ( args.sigma < 1.0 ) /* if height too small */
- args.sigma = args.rho; /* then height = width */
- if ( (flags & XValue) == 0 ) /* center offset if not defined */
- args.xi = (double)(((long)args.rho-1)/2);
- if ( (flags & YValue) == 0 )
- args.psi = (double)(((long)args.sigma-1)/2);
- break;
- case SquareKernel:
- case DiamondKernel:
- case DiskKernel:
- case PlusKernel:
- if ( (flags & HeightValue) == 0 ) /* if no scale */
- args.sigma = 1.0; /* then scale = 1.0 */
- break;
- default:
- break;
- }
-
- return(AcquireKernelBuiltIn((KernelInfoType)type, &args));
- }
-
kernel=(KernelInfo *) AcquireMagickMemory(sizeof(*kernel));
if (kernel == (KernelInfo *)NULL)
return(kernel);
(void) ResetMagickMemory(kernel,0,sizeof(*kernel));
+ kernel->minimum = kernel->maximum = kernel->angle = 0.0;
+ kernel->negative_range = kernel->positive_range = 0.0;
kernel->type = UserDefinedKernel;
+ kernel->next = (KernelInfo *) NULL;
kernel->signature = MagickSignature;
+ /* find end of this specific kernel definition string */
+ end = strchr(kernel_string, ';');
+ if ( end == (char *) NULL )
+ end = strchr(kernel_string, '\0');
+
+ /* clear flags - for Expanding kernal lists thorugh rotations */
+ flags = NoValue;
+
/* Has a ':' in argument - New user kernel specification */
p = strchr(kernel_string, ':');
- if ( p != (char *) NULL)
+ if ( p != (char *) NULL && p < end)
{
/* ParseGeometry() needs the geometry separated! -- Arrgghh */
memcpy(token, kernel_string, (size_t) (p-kernel_string));
token[p-kernel_string] = '\0';
+ SetGeometryInfo(&args);
flags = ParseGeometry(token, &args);
/* Size handling and checks of geometry settings */
args.rho = 1.0; /* then width = 1 */
if ( args.sigma < 1.0 ) /* if height too small */
args.sigma = args.rho; /* then height = width */
- kernel->width = (unsigned long)args.rho;
- kernel->height = (unsigned long)args.sigma;
+ kernel->width = (size_t)args.rho;
+ kernel->height = (size_t)args.sigma;
/* Offset Handling and Checks */
if ( args.xi < 0.0 || args.psi < 0.0 )
return(DestroyKernelInfo(kernel));
- kernel->x = ((flags & XValue)!=0) ? (long)args.xi
- : (long) (kernel->width-1)/2;
- kernel->y = ((flags & YValue)!=0) ? (long)args.psi
- : (long) (kernel->height-1)/2;
- if ( kernel->x >= (long) kernel->width ||
- kernel->y >= (long) kernel->height )
+ kernel->x = ((flags & XValue)!=0) ? (ssize_t)args.xi
+ : (ssize_t) (kernel->width-1)/2;
+ kernel->y = ((flags & YValue)!=0) ? (ssize_t)args.psi
+ : (ssize_t) (kernel->height-1)/2;
+ if ( kernel->x >= (ssize_t) kernel->width ||
+ kernel->y >= (ssize_t) kernel->height )
return(DestroyKernelInfo(kernel));
p++; /* advance beyond the ':' */
}
else
- { /* ELSE - Old old kernel specification, forming odd-square kernel */
+ { /* ELSE - Old old specification, forming odd-square kernel */
/* count up number of values given */
p=(const char *) kernel_string;
while ((isspace((int) ((unsigned char) *p)) != 0) || (*p == '\''))
p++; /* ignore "'" chars for convolve filter usage - Cristy */
- for (i=0; *p != '\0'; i++)
+ for (i=0; p < end; i++)
{
GetMagickToken(p,&p,token);
if (*token == ',')
GetMagickToken(p,&p,token);
}
/* set the size of the kernel - old sized square */
- kernel->width = kernel->height= (unsigned long) sqrt((double) i+1.0);
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height= (size_t) sqrt((double) i+1.0);
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
p=(const char *) kernel_string;
while ((isspace((int) ((unsigned char) *p)) != 0) || (*p == '\''))
p++; /* ignore "'" chars for convolve filter usage - Cristy */
kernel->minimum = +MagickHuge;
kernel->maximum = -MagickHuge;
kernel->negative_range = kernel->positive_range = 0.0;
- for (i=0; (i < (long) (kernel->width*kernel->height)) && (*p != '\0'); i++)
+
+ for (i=0; (i < (ssize_t) (kernel->width*kernel->height)) && (p < end); i++)
{
GetMagickToken(p,&p,token);
if (*token == ',')
GetMagickToken(p,&p,token);
if ( LocaleCompare("nan",token) == 0
- || LocaleCompare("-",token) == 0 ) {
+ || LocaleCompare("-",token) == 0 ) {
kernel->values[i] = nan; /* do not include this value in kernel */
}
else {
Maximize(kernel->maximum, kernel->values[i]);
}
}
- /* check that we recieved at least one real (non-nan) value! */
- if ( kernel->minimum == MagickHuge )
+
+ /* sanity check -- no more values in kernel definition */
+ GetMagickToken(p,&p,token);
+ if ( *token != '\0' && *token != ';' && *token != '\'' )
return(DestroyKernelInfo(kernel));
- /* This should not be needed for a fully defined kernel
- * Perhaps an error should be reported instead!
- * Kept for backward compatibility.
- */
- if ( i < (long) (kernel->width*kernel->height) ) {
+#if 0
+ /* this was the old method of handling a incomplete kernel */
+ if ( i < (ssize_t) (kernel->width*kernel->height) ) {
Minimize(kernel->minimum, kernel->values[i]);
Maximize(kernel->maximum, kernel->values[i]);
- for ( ; i < (long) (kernel->width*kernel->height); i++)
+ for ( ; i < (ssize_t) (kernel->width*kernel->height); i++)
kernel->values[i]=0.0;
}
+#else
+ /* Number of values for kernel was not enough - Report Error */
+ if ( i < (ssize_t) (kernel->width*kernel->height) )
+ return(DestroyKernelInfo(kernel));
+#endif
+
+ /* check that we recieved at least one real (non-nan) value! */
+ if ( kernel->minimum == MagickHuge )
+ return(DestroyKernelInfo(kernel));
+
+ if ( (flags & AreaValue) != 0 ) /* '@' symbol in kernel size */
+ ExpandRotateKernelInfo(kernel, 45.0); /* cyclic rotate 3x3 kernels */
+ else if ( (flags & GreaterValue) != 0 ) /* '>' symbol in kernel args */
+ ExpandRotateKernelInfo(kernel, 90.0); /* 90 degree rotate of kernel */
+ else if ( (flags & LessValue) != 0 ) /* '<' symbol in kernel args */
+ ExpandMirrorKernelInfo(kernel); /* 90 degree mirror rotate */
+
+ return(kernel);
+}
+
+static KernelInfo *ParseKernelName(const char *kernel_string)
+{
+ KernelInfo
+ *kernel;
+
+ char
+ token[MaxTextExtent];
+
+ ssize_t
+ type;
+
+ const char
+ *p,
+ *end;
+
+ MagickStatusType
+ flags;
+
+ GeometryInfo
+ args;
+
+ /* Parse special 'named' kernel */
+ GetMagickToken(kernel_string,&p,token);
+ type=ParseMagickOption(MagickKernelOptions,MagickFalse,token);
+ if ( type < 0 || type == UserDefinedKernel )
+ return((KernelInfo *)NULL); /* not a valid named kernel */
+
+ while (((isspace((int) ((unsigned char) *p)) != 0) ||
+ (*p == ',') || (*p == ':' )) && (*p != '\0') && (*p != ';'))
+ p++;
+
+ end = strchr(p, ';'); /* end of this kernel defintion */
+ if ( end == (char *) NULL )
+ end = strchr(p, '\0');
+
+ /* ParseGeometry() needs the geometry separated! -- Arrgghh */
+ memcpy(token, p, (size_t) (end-p));
+ token[end-p] = '\0';
+ SetGeometryInfo(&args);
+ flags = ParseGeometry(token, &args);
+
+#if 0
+ /* For Debugging Geometry Input */
+ fprintf(stderr, "Geometry = 0x%04X : %lg x %lg %+lg %+lg\n",
+ flags, args.rho, args.sigma, args.xi, args.psi );
+#endif
+
+ /* special handling of missing values in input string */
+ switch( type ) {
+ case RectangleKernel:
+ if ( (flags & WidthValue) == 0 ) /* if no width then */
+ args.rho = args.sigma; /* then width = height */
+ if ( args.rho < 1.0 ) /* if width too small */
+ args.rho = 3; /* then width = 3 */
+ if ( args.sigma < 1.0 ) /* if height too small */
+ args.sigma = args.rho; /* then height = width */
+ if ( (flags & XValue) == 0 ) /* center offset if not defined */
+ args.xi = (double)(((ssize_t)args.rho-1)/2);
+ if ( (flags & YValue) == 0 )
+ args.psi = (double)(((ssize_t)args.sigma-1)/2);
+ break;
+ case SquareKernel:
+ case DiamondKernel:
+ case DiskKernel:
+ case PlusKernel:
+ case CrossKernel:
+ /* If no scale given (a 0 scale is valid! - set it to 1.0 */
+ if ( (flags & HeightValue) == 0 )
+ args.sigma = 1.0;
+ break;
+ case RingKernel:
+ if ( (flags & XValue) == 0 )
+ args.xi = 1.0;
+ break;
+ case ChebyshevKernel:
+ case ManhattanKernel:
+ case EuclideanKernel:
+ if ( (flags & HeightValue) == 0 ) /* no distance scale */
+ args.sigma = 100.0; /* default distance scaling */
+ else if ( (flags & AspectValue ) != 0 ) /* '!' flag */
+ args.sigma = QuantumRange/(args.sigma+1); /* maximum pixel distance */
+ else if ( (flags & PercentValue ) != 0 ) /* '%' flag */
+ args.sigma *= QuantumRange/100.0; /* percentage of color range */
+ break;
+ default:
+ break;
+ }
+
+ kernel = AcquireKernelBuiltIn((KernelInfoType)type, &args);
+
+ /* global expand to rotated kernel list - only for single kernels */
+ if ( kernel->next == (KernelInfo *) NULL ) {
+ if ( (flags & AreaValue) != 0 ) /* '@' symbol in kernel args */
+ ExpandRotateKernelInfo(kernel, 45.0);
+ else if ( (flags & GreaterValue) != 0 ) /* '>' symbol in kernel args */
+ ExpandRotateKernelInfo(kernel, 90.0);
+ else if ( (flags & LessValue) != 0 ) /* '<' symbol in kernel args */
+ ExpandMirrorKernelInfo(kernel);
+ }
+
+ return(kernel);
+}
+
+MagickExport KernelInfo *AcquireKernelInfo(const char *kernel_string)
+{
+
+ KernelInfo
+ *kernel,
+ *new_kernel;
+
+ char
+ token[MaxTextExtent];
+
+ const char
+ *p;
+
+ size_t
+ kernel_number;
+
+ p = kernel_string;
+ kernel = NULL;
+ kernel_number = 0;
+
+ while ( GetMagickToken(p,NULL,token), *token != '\0' ) {
+
+ /* ignore extra or multiple ';' kernel seperators */
+ if ( *token != ';' ) {
+
+ /* tokens starting with alpha is a Named kernel */
+ if (isalpha((int) *token) != 0)
+ new_kernel = ParseKernelName(p);
+ else /* otherwise a user defined kernel array */
+ new_kernel = ParseKernelArray(p);
+
+ /* Error handling -- this is not proper error handling! */
+ if ( new_kernel == (KernelInfo *) NULL ) {
+ fprintf(stderr, "Failed to parse kernel number #%.20g\n",(double)
+ kernel_number);
+ if ( kernel != (KernelInfo *) NULL )
+ kernel=DestroyKernelInfo(kernel);
+ return((KernelInfo *) NULL);
+ }
+ /* initialise or append the kernel list */
+ if ( kernel == (KernelInfo *) NULL )
+ kernel = new_kernel;
+ else
+ LastKernelInfo(kernel)->next = new_kernel;
+ }
+
+ /* look for the next kernel in list */
+ p = strchr(p, ';');
+ if ( p == (char *) NULL )
+ break;
+ p++;
+
+ }
return(kernel);
}
+
\f
/*
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
% Convolution Kernels
%
-% Gaussian "{radius},{sigma}"
-% Generate a two-dimentional gaussian kernel, as used by -gaussian
-% A sigma is required, (with the 'x'), due to historical reasons.
+% Unity
+% the No-Op kernel, also requivelent to Gaussian of sigma zero.
+% Basically a 3x3 kernel of a 1 surrounded by zeros.
+%
+% Gaussian:{radius},{sigma}
+% Generate a two-dimentional gaussian kernel, as used by -gaussian.
+% The sigma for the curve is required. The resulting kernel is
+% normalized,
+%
+% If 'sigma' is zero, you get a single pixel on a field of zeros.
%
% NOTE: that the 'radius' is optional, but if provided can limit (clip)
% the final size of the resulting kernel to a square 2*radius+1 in size.
% radius will be determined so as to produce the best minimal error
% result, which is usally much larger than is normally needed.
%
-% Blur "{radius},{sigma},{angle}"
-% As per Gaussian, but generates a 1 dimensional or linear gaussian
-% blur, at the angle given (current restricted to orthogonal angles).
-% If a 'radius' is given the kernel is clipped to a width of 2*radius+1.
+% LoG:{radius},{sigma}
+% "Laplacian of a Gaussian" or "Mexician Hat" Kernel.
+% The supposed ideal edge detection, zero-summing kernel.
+%
+% An alturnative to this kernel is to use a "DoG" with a sigma ratio of
+% approx 1.6 (according to wikipedia).
+%
+% DoG:{radius},{sigma1},{sigma2}
+% "Difference of Gaussians" Kernel.
+% As "Gaussian" but with a gaussian produced by 'sigma2' subtracted
+% from the gaussian produced by 'sigma1'. Typically sigma2 > sigma1.
+% The result is a zero-summing kernel.
+%
+% Blur:{radius},{sigma}[,{angle}]
+% Generates a 1 dimensional or linear gaussian blur, at the angle given
+% (current restricted to orthogonal angles). If a 'radius' is given the
+% kernel is clipped to a width of 2*radius+1. Kernel can be rotated
+% by a 90 degree angle.
%
-% NOTE that two such blurs perpendicular to each other is equivelent to
-% -blur and the previous gaussian, but is often 10 or more times faster.
+% If 'sigma' is zero, you get a single pixel on a field of zeros.
%
-% Comet "{width},{sigma},{angle}"
-% Blur in one direction only, mush like how a bright object leaves
+% Note that two convolutions with two "Blur" kernels perpendicular to
+% each other, is equivelent to a far larger "Gaussian" kernel with the
+% same sigma value, However it is much faster to apply. This is how the
+% "-blur" operator actually works.
+%
+% Comet:{width},{sigma},{angle}
+% Blur in one direction only, much like how a bright object leaves
% a comet like trail. The Kernel is actually half a gaussian curve,
-% Adding two such blurs in oppiste directions produces a Linear Blur.
+% Adding two such blurs in opposite directions produces a Blur Kernel.
+% Angle can be rotated in multiples of 90 degrees.
%
-% NOTE: that the first argument is the width of the kernel and not the
+% Note that the first argument is the width of the kernel and not the
% radius of the kernel.
%
% # Still to be implemented...
% #
-% # Sharpen "{radius},{sigma}
-% # Negated Gaussian (center zeroed and re-normalized),
-% # with a 2 unit positive peak. -- Check On line documentation
-% #
-% # Laplacian "{radius},{sigma}"
-% # Laplacian (a mexican hat like) Function
-% #
-% # LOG "{radius},{sigma1},{sigma2}
-% # Laplacian of Gaussian
-% #
-% # DOG "{radius},{sigma1},{sigma2}
-% # Difference of two Gaussians
-% #
% # Filter2D
% # Filter1D
% # Set kernel values using a resize filter, and given scale (sigma)
% # Cylindrical or Linear. Is this posible with an image?
% #
%
-% Boolean Kernels
-%
-% Rectangle "{geometry}"
-% Simply generate a rectangle of 1's with the size given. You can also
-% specify the location of the 'control point', otherwise the closest
-% pixel to the center of the rectangle is selected.
+% Named Constant Convolution Kernels
+%
+% All these are unscaled, zero-summing kernels by default. As such for
+% non-HDRI version of ImageMagick some form of normalization, user scaling,
+% and biasing the results is recommended, to prevent the resulting image
+% being 'clipped'.
+%
+% The 3x3 kernels (most of these) can be circularly rotated in multiples of
+% 45 degrees to generate the 8 angled varients of each of the kernels.
+%
+% Laplacian:{type}
+% Discrete Lapacian Kernels, (without normalization)
+% Type 0 : 3x3 with center:8 surounded by -1 (8 neighbourhood)
+% Type 1 : 3x3 with center:4 edge:-1 corner:0 (4 neighbourhood)
+% Type 2 : 3x3 with center:4 edge:1 corner:-2
+% Type 3 : 3x3 with center:4 edge:-2 corner:1
+% Type 5 : 5x5 laplacian
+% Type 7 : 7x7 laplacian
+% Type 15 : 5x5 LoG (sigma approx 1.4)
+% Type 19 : 9x9 LoG (sigma approx 1.4)
+%
+% Sobel:{angle}
+% Sobel 'Edge' convolution kernel (3x3)
+% | -1, 0, 1 |
+% | -2, 0,-2 |
+% | -1, 0, 1 |
+%
+% Sobel:{type},{angle}
+% Type 0: default un-nomalized version shown above.
+%
+% Type 1: As default but pre-normalized
+% | 1, 0, -1 |
+% | 2, 0, -2 | / 4
+% | 1, 0, -1 |
+%
+% Type 2: Diagonal version with same normalization as 1
+% | 1, 0, -1 |
+% | 2, 0, -2 | / 4
+% | 1, 0, -1 |
+%
+% Roberts:{angle}
+% Roberts convolution kernel (3x3)
+% | 0, 0, 0 |
+% | -1, 1, 0 |
+% | 0, 0, 0 |
+%
+% Prewitt:{angle}
+% Prewitt Edge convolution kernel (3x3)
+% | -1, 0, 1 |
+% | -1, 0, 1 |
+% | -1, 0, 1 |
+%
+% Compass:{angle}
+% Prewitt's "Compass" convolution kernel (3x3)
+% | -1, 1, 1 |
+% | -1,-2, 1 |
+% | -1, 1, 1 |
+%
+% Kirsch:{angle}
+% Kirsch's "Compass" convolution kernel (3x3)
+% | -3,-3, 5 |
+% | -3, 0, 5 |
+% | -3,-3, 5 |
+%
+% FreiChen:{angle}
+% Frei-Chen Edge Detector is based on a kernel that is similar to
+% the Sobel Kernel, but is designed to be isotropic. That is it takes
+% into account the distance of the diagonal in the kernel.
+%
+% | 1, 0, -1 |
+% | sqrt(2), 0, -sqrt(2) |
+% | 1, 0, -1 |
+%
+% FreiChen:{type},{angle}
+%
+% Frei-Chen Pre-weighted kernels...
+%
+% Type 0: default un-nomalized version shown above.
+%
+% Type 1: Orthogonal Kernel (same as type 11 below)
+% | 1, 0, -1 |
+% | sqrt(2), 0, -sqrt(2) | / 2*sqrt(2)
+% | 1, 0, -1 |
+%
+% Type 2: Diagonal form of Kernel...
+% | 1, sqrt(2), 0 |
+% | sqrt(2), 0, -sqrt(2) | / 2*sqrt(2)
+% | 0, -sqrt(2) -1 |
+%
+% However this kernel is als at the heart of the FreiChen Edge Detection
+% Process which uses a set of 9 specially weighted kernel. These 9
+% kernels not be normalized, but directly applied to the image. The
+% results is then added together, to produce the intensity of an edge in
+% a specific direction. The square root of the pixel value can then be
+% taken as the cosine of the edge, and at least 2 such runs at 90 degrees
+% from each other, both the direction and the strength of the edge can be
+% determined.
+%
+% Type 10: All 9 of the following pre-weighted kernels...
+%
+% Type 11: | 1, 0, -1 |
+% | sqrt(2), 0, -sqrt(2) | / 2*sqrt(2)
+% | 1, 0, -1 |
+%
+% Type 12: | 1, sqrt(2), 1 |
+% | 0, 0, 0 | / 2*sqrt(2)
+% | 1, sqrt(2), 1 |
+%
+% Type 13: | sqrt(2), -1, 0 |
+% | -1, 0, 1 | / 2*sqrt(2)
+% | 0, 1, -sqrt(2) |
+%
+% Type 14: | 0, 1, -sqrt(2) |
+% | -1, 0, 1 | / 2*sqrt(2)
+% | sqrt(2), -1, 0 |
+%
+% Type 15: | 0, -1, 0 |
+% | 1, 0, 1 | / 2
+% | 0, -1, 0 |
+%
+% Type 16: | 1, 0, -1 |
+% | 0, 0, 0 | / 2
+% | -1, 0, 1 |
+%
+% Type 17: | 1, -2, 1 |
+% | -2, 4, -2 | / 6
+% | -1, -2, 1 |
+%
+% Type 18: | -2, 1, -2 |
+% | 1, 4, 1 | / 6
+% | -2, 1, -2 |
+%
+% Type 19: | 1, 1, 1 |
+% | 1, 1, 1 | / 3
+% | 1, 1, 1 |
+%
+% The first 4 are for edge detection, the next 4 are for line detection
+% and the last is to add a average component to the results.
+%
+% Using a special type of '-1' will return all 9 pre-weighted kernels
+% as a multi-kernel list, so that you can use them directly (without
+% normalization) with the special "-set option:morphology:compose Plus"
+% setting to apply the full FreiChen Edge Detection Technique.
+%
+% If 'type' is large it will be taken to be an actual rotation angle for
+% the default FreiChen (type 0) kernel. As such FreiChen:45 will look
+% like a Sobel:45 but with 'sqrt(2)' instead of '2' values.
+%
+% WARNING: The above was layed out as per
+% http://www.math.tau.ac.il/~turkel/notes/edge_detectors.pdf
+% But rotated 90 degrees so direction is from left rather than the top.
+% I have yet to find any secondary confirmation of the above. The only
+% other source found was actual source code at
+% http://ltswww.epfl.ch/~courstiv/exos_labos/sol3.pdf
+% Neigher paper defineds the kernels in a way that looks locical or
+% correct when taken as a whole.
%
-% Properly centered and odd sized rectangles work the best.
+% Boolean Kernels
%
-% Diamond "[{radius}[,{scale}]]"
-% Generate a diamond shaped kernal with given radius to the points.
+% Diamond:[{radius}[,{scale}]]
+% Generate a diamond shaped kernel with given radius to the points.
% Kernel size will again be radius*2+1 square and defaults to radius 1,
% generating a 3x3 kernel that is slightly larger than a square.
%
-% Square "[{radius}[,{scale}]]"
+% Square:[{radius}[,{scale}]]
% Generate a square shaped kernel of size radius*2+1, and defaulting
% to a 3x3 (radius 1).
%
-% Note that using a larger radius for the "Square" or the "Diamond"
-% is also equivelent to iterating the basic morphological method
-% that many times. However However iterating with the smaller radius 1
-% default is actually faster than using a larger kernel radius.
+% Note that using a larger radius for the "Square" or the "Diamond" is
+% also equivelent to iterating the basic morphological method that many
+% times. However iterating with the smaller radius is actually faster
+% than using a larger kernel radius.
%
-% Disk "[{radius}[,{scale}]]
+% Rectangle:{geometry}
+% Simply generate a rectangle of 1's with the size given. You can also
+% specify the location of the 'control point', otherwise the closest
+% pixel to the center of the rectangle is selected.
+%
+% Properly centered and odd sized rectangles work the best.
+%
+% Disk:[{radius}[,{scale}]]
% Generate a binary disk of the radius given, radius may be a float.
% Kernel size will be ceil(radius)*2+1 square.
% NOTE: Here are some disk shapes of specific interest
-% "disk:1" => "diamond" or "cross:1"
-% "disk:1.5" => "square"
-% "disk:2" => "diamond:2"
-% "disk:2.5" => a general disk shape of radius 2
-% "disk:2.9" => "square:2"
-% "disk:3.5" => default - octagonal/disk shape of radius 3
-% "disk:4.2" => roughly octagonal shape of radius 4
-% "disk:4.3" => a general disk shape of radius 4
+% "Disk:1" => "diamond" or "cross:1"
+% "Disk:1.5" => "square"
+% "Disk:2" => "diamond:2"
+% "Disk:2.5" => a general disk shape of radius 2
+% "Disk:2.9" => "square:2"
+% "Disk:3.5" => default - octagonal/disk shape of radius 3
+% "Disk:4.2" => roughly octagonal shape of radius 4
+% "Disk:4.3" => a general disk shape of radius 4
% After this all the kernel shape becomes more and more circular.
%
% Because a "disk" is more circular when using a larger radius, using a
% larger radius is preferred over iterating the morphological operation.
%
-% Plus "[{radius}[,{scale}]]"
-% Generate a kernel in the shape of a 'plus' sign. The length of each
-% arm is also the radius, which defaults to 2.
+% Symbol Dilation Kernels
+%
+% These kernel is not a good general morphological kernel, but is used
+% more for highlighting and marking any single pixels in an image using,
+% a "Dilate" method as appropriate.
+%
+% For the same reasons iterating these kernels does not produce the
+% same result as using a larger radius for the symbol.
%
-% This kernel is not a good general morphological kernel, but is used
-% more for highlighting and marking any single pixels in an image using,
-% a "Dilate" or "Erode" method as appropriate.
+% Plus:[{radius}[,{scale}]]
+% Cross:[{radius}[,{scale}]]
+% Generate a kernel in the shape of a 'plus' or a 'cross' with
+% a each arm the length of the given radius (default 2).
%
% NOTE: "plus:1" is equivelent to a "Diamond" kernel.
%
-% Note that unlike other kernels iterating a plus does not produce the
-% same result as using a larger radius for the cross.
+% Ring:{radius1},{radius2}[,{scale}]
+% A ring of the values given that falls between the two radii.
+% Defaults to a ring of approximataly 3 radius in a 7x7 kernel.
+% This is the 'edge' pixels of the default "Disk" kernel,
+% More specifically, "Ring" -> "Ring:2.5,3.5,1.0"
+%
+% Hit and Miss Kernels
+%
+% Peak:radius1,radius2
+% Find any peak larger than the pixels the fall between the two radii.
+% The default ring of pixels is as per "Ring".
+% Edges
+% Find flat orthogonal edges of a binary shape
+% Corners
+% Find 90 degree corners of a binary shape
+% LineEnds:type
+% Find end points of lines (for pruning a skeletion)
+% Two types of lines ends (default to both) can be searched for
+% Type 0: All line ends
+% Type 1: single kernel for 4-conneected line ends
+% Type 2: single kernel for simple line ends
+% LineJunctions
+% Find three line junctions (within a skeletion)
+% Type 0: all line junctions
+% Type 1: Y Junction kernel
+% Type 2: Diagonal T Junction kernel
+% Type 3: Orthogonal T Junction kernel
+% Type 4: Diagonal X Junction kernel
+% Type 5: Orthogonal + Junction kernel
+% Ridges:type
+% Find single pixel ridges or thin lines
+% Type 1: Fine single pixel thick lines and ridges
+% Type 2: Find two pixel thick lines and ridges
+% ConvexHull
+% Octagonal thicken kernel, to generate convex hulls of 45 degrees
+% Skeleton:type
+% Traditional skeleton generating kernels.
+% Type 1: Tradional Skeleton kernel (4 connected skeleton)
+% Type 2: HIPR2 Skeleton kernel (8 connected skeleton)
+% Type 3: Experimental Variation to try to present left-right symmetry
+% Type 4: Experimental Variation to preserve left-right symmetry
%
% Distance Measuring Kernels
%
-% Chebyshev "[{radius}][x{scale}]" largest x or y distance (default r=1)
-% Manhatten "[{radius}][x{scale}]" square grid distance (default r=1)
-% Euclidean "[{radius}][x{scale}]" direct distance (default r=1)
+% Different types of distance measuring methods, which are used with the
+% a 'Distance' morphology method for generating a gradient based on
+% distance from an edge of a binary shape, though there is a technique
+% for handling a anti-aliased shape.
%
-% Different types of distance measuring methods, which are used with the
-% a 'Distance' morphology method for generating a gradient based on
-% distance from an edge of a binary shape, though there is a technique
-% for handling a anti-aliased shape.
+% See the 'Distance' Morphological Method, for information of how it is
+% applied.
%
+% Chebyshev:[{radius}][x{scale}[%!]]
% Chebyshev Distance (also known as Tchebychev Distance) is a value of
% one to any neighbour, orthogonal or diagonal. One why of thinking of
% it is the number of squares a 'King' or 'Queen' in chess needs to
% 'square' like distance function, but one where diagonals are closer
% than expected.
%
-% Manhatten Distance (also known as Rectilinear Distance, or the Taxi
+% Manhattan:[{radius}][x{scale}[%!]]
+% Manhattan Distance (also known as Rectilinear Distance, or the Taxi
% Cab metric), is the distance needed when you can only travel in
% orthogonal (horizontal or vertical) only. It is the distance a 'Rook'
% in chess would travel. It results in a diamond like distances, where
% diagonals are further than expected.
%
+% Euclidean:[{radius}][x{scale}[%!]]
% Euclidean Distance is the 'direct' or 'as the crow flys distance.
% However by default the kernel size only has a radius of 1, which
% limits the distance to 'Knight' like moves, with only orthogonal and
% To allow the use of fractional distances that you get with diagonals
% the actual distance is scaled by a fixed value which the user can
% provide. This is not actually nessary for either ""Chebyshev" or
-% "Manhatten" distance kernels, but is done for all three distance
+% "Manhattan" distance kernels, but is done for all three distance
% kernels. If no scale is provided it is set to a value of 100,
% allowing for a maximum distance measurement of 655 pixels using a Q16
% version of IM, from any edge. However for small images this can
% result in quite a dark gradient.
%
-% See the 'Distance' Morphological Method, for information of how it is
-% applied.
-%
-% # Hit-n-Miss Kernel-Lists -- Still to be implemented
-% #
-% # specifically for Pruning, Thinning, Thickening
-% #
*/
MagickExport KernelInfo *AcquireKernelBuiltIn(const KernelInfoType type,
KernelInfo
*kernel;
- register long
+ register ssize_t
i;
- register long
+ register ssize_t
u,
v;
double
nan = sqrt((double)-1.0); /* Special Value : Not A Number */
- kernel=(KernelInfo *) AcquireMagickMemory(sizeof(*kernel));
- if (kernel == (KernelInfo *) NULL)
- return(kernel);
- (void) ResetMagickMemory(kernel,0,sizeof(*kernel));
- kernel->minimum = kernel->maximum = 0.0;
- kernel->negative_range = kernel->positive_range = 0.0;
- kernel->type = type;
- kernel->signature = MagickSignature;
+ /* Generate a new empty kernel if needed */
+ kernel=(KernelInfo *) NULL;
+ switch(type) {
+ case UndefinedKernel: /* These should not call this function */
+ case UserDefinedKernel:
+ case TestKernel:
+ break;
+ case UnityKernel: /* Named Descrete Convolution Kernels */
+ case LaplacianKernel:
+ case SobelKernel:
+ case RobertsKernel:
+ case PrewittKernel:
+ case CompassKernel:
+ case KirschKernel:
+ case FreiChenKernel:
+ case EdgesKernel: /* Hit and Miss kernels */
+ case CornersKernel:
+ case LineEndsKernel:
+ case LineJunctionsKernel:
+ case RidgesKernel:
+ case ConvexHullKernel:
+ case SkeletonKernel:
+ break; /* A pre-generated kernel is not needed */
+#if 0
+ /* set to 1 to do a compile-time check that we haven't missed anything */
+ case GaussianKernel:
+ case DoGKernel:
+ case LoGKernel:
+ case BlurKernel:
+ case CometKernel:
+ case DiamondKernel:
+ case SquareKernel:
+ case RectangleKernel:
+ case DiskKernel:
+ case PlusKernel:
+ case CrossKernel:
+ case RingKernel:
+ case PeaksKernel:
+ case ChebyshevKernel:
+ case ManhattanKernel:
+ case EuclideanKernel:
+#else
+ default:
+#endif
+ /* Generate the base Kernel Structure */
+ kernel=(KernelInfo *) AcquireMagickMemory(sizeof(*kernel));
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ (void) ResetMagickMemory(kernel,0,sizeof(*kernel));
+ kernel->minimum = kernel->maximum = kernel->angle = 0.0;
+ kernel->negative_range = kernel->positive_range = 0.0;
+ kernel->type = type;
+ kernel->next = (KernelInfo *) NULL;
+ kernel->signature = MagickSignature;
+ break;
+ }
switch(type) {
/* Convolution Kernels */
case GaussianKernel:
+ case DoGKernel:
+ case LoGKernel:
{ double
- sigma = fabs(args->sigma);
-
- sigma = (sigma <= MagickEpsilon) ? 1.0 : sigma;
-
- kernel->width = kernel->height =
- GetOptimalKernelWidth2D(args->rho,sigma);
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
- kernel->negative_range = kernel->positive_range = 0.0;
+ sigma = fabs(args->sigma),
+ sigma2 = fabs(args->xi),
+ A, B, R;
+
+ if ( args->rho >= 1.0 )
+ kernel->width = (size_t)args->rho*2+1;
+ else if ( (type != DoGKernel) || (sigma >= sigma2) )
+ kernel->width = GetOptimalKernelWidth2D(args->rho,sigma);
+ else
+ kernel->width = GetOptimalKernelWidth2D(args->rho,sigma2);
+ kernel->height = kernel->width;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- sigma = 2.0*sigma*sigma; /* simplify the expression */
- for ( i=0, v=-kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
- kernel->positive_range += (
- kernel->values[i] =
- exp(-((double)(u*u+v*v))/sigma)
- /* / (MagickPI*sigma) */ );
- kernel->minimum = 0;
- kernel->maximum = kernel->values[
- kernel->y*kernel->width+kernel->x ];
+ /* WARNING: The following generates a 'sampled gaussian' kernel.
+ * What we really want is a 'discrete gaussian' kernel.
+ *
+ * How to do this is currently not known, but appears to be
+ * basied on the Error Function 'erf()' (intergral of a gaussian)
+ */
+
+ if ( type == GaussianKernel || type == DoGKernel )
+ { /* Calculate a Gaussian, OR positive half of a DoG */
+ if ( sigma > MagickEpsilon )
+ { A = 1.0/(2.0*sigma*sigma); /* simplify loop expressions */
+ B = 1.0/(Magick2PI*sigma*sigma);
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ kernel->values[i] = exp(-((double)(u*u+v*v))*A)*B;
+ }
+ else /* limiting case - a unity (normalized Dirac) kernel */
+ { (void) ResetMagickMemory(kernel->values,0, (size_t)
+ kernel->width*kernel->height*sizeof(double));
+ kernel->values[kernel->x+kernel->y*kernel->width] = 1.0;
+ }
+ }
+
+ if ( type == DoGKernel )
+ { /* Subtract a Negative Gaussian for "Difference of Gaussian" */
+ if ( sigma2 > MagickEpsilon )
+ { sigma = sigma2; /* simplify loop expressions */
+ A = 1.0/(2.0*sigma*sigma);
+ B = 1.0/(Magick2PI*sigma*sigma);
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ kernel->values[i] -= exp(-((double)(u*u+v*v))*A)*B;
+ }
+ else /* limiting case - a unity (normalized Dirac) kernel */
+ kernel->values[kernel->x+kernel->y*kernel->width] -= 1.0;
+ }
- ScaleKernelInfo(kernel, 1.0, NormalizeValue); /* Normalize */
+ if ( type == LoGKernel )
+ { /* Calculate a Laplacian of a Gaussian - Or Mexician Hat */
+ if ( sigma > MagickEpsilon )
+ { A = 1.0/(2.0*sigma*sigma); /* simplify loop expressions */
+ B = 1.0/(MagickPI*sigma*sigma*sigma*sigma);
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ { R = ((double)(u*u+v*v))*A;
+ kernel->values[i] = (1-R)*exp(-R)*B;
+ }
+ }
+ else /* special case - generate a unity kernel */
+ { (void) ResetMagickMemory(kernel->values,0, (size_t)
+ kernel->width*kernel->height*sizeof(double));
+ kernel->values[kernel->x+kernel->y*kernel->width] = 1.0;
+ }
+ }
+
+ /* Note the above kernels may have been 'clipped' by a user defined
+ ** radius, producing a smaller (darker) kernel. Also for very small
+ ** sigma's (> 0.1) the central value becomes larger than one, and thus
+ ** producing a very bright kernel.
+ **
+ ** Normalization will still be needed.
+ */
+
+ /* Normalize the 2D Gaussian Kernel
+ **
+ ** NB: a CorrelateNormalize performs a normal Normalize if
+ ** there are no negative values.
+ */
+ CalcKernelMetaData(kernel); /* the other kernel meta-data */
+ ScaleKernelInfo(kernel, 1.0, CorrelateNormalizeValue);
break;
}
case BlurKernel:
{ double
- sigma = fabs(args->sigma);
+ sigma = fabs(args->sigma),
+ alpha, beta;
- sigma = (sigma <= MagickEpsilon) ? 1.0 : sigma;
-
- kernel->width = GetOptimalKernelWidth1D(args->rho,sigma);
- kernel->x = (long) (kernel->width-1)/2;
+ if ( args->rho >= 1.0 )
+ kernel->width = (size_t)args->rho*2+1;
+ else
+ kernel->width = GetOptimalKernelWidth1D(args->rho,sigma);
kernel->height = 1;
+ kernel->x = (ssize_t) (kernel->width-1)/2;
kernel->y = 0;
kernel->negative_range = kernel->positive_range = 0.0;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
** As such while wierd it is prefered.
**
** I am told this method originally came from Photoshop.
+ **
+ ** A properly normalized curve is generated (apart from edge clipping)
+ ** even though we later normalize the result (for edge clipping)
+ ** to allow the correct generation of a "Difference of Blurs".
*/
- sigma *= KernelRank; /* simplify expanded curve */
- v = (long) (kernel->width*KernelRank-1)/2; /* start/end points to fit range */
+
+ /* initialize */
+ v = (ssize_t) (kernel->width*KernelRank-1)/2; /* start/end points to fit range */
(void) ResetMagickMemory(kernel->values,0, (size_t)
- kernel->width*sizeof(double));
- for ( u=-v; u <= v; u++) {
- kernel->values[(u+v)/KernelRank] +=
- exp(-((double)(u*u))/(2.0*sigma*sigma))
- /* / (MagickSQ2PI*sigma/KernelRank) */ ;
- }
- for (i=0; i < (long) kernel->width; i++)
- kernel->positive_range += kernel->values[i];
+ kernel->width*kernel->height*sizeof(double));
+ /* Calculate a Positive 1D Gaussian */
+ if ( sigma > MagickEpsilon )
+ { sigma *= KernelRank; /* simplify loop expressions */
+ alpha = 1.0/(2.0*sigma*sigma);
+ beta= 1.0/(MagickSQ2PI*sigma );
+ for ( u=-v; u <= v; u++) {
+ kernel->values[(u+v)/KernelRank] +=
+ exp(-((double)(u*u))*alpha)*beta;
+ }
+ }
+ else /* special case - generate a unity kernel */
+ kernel->values[kernel->x+kernel->y*kernel->width] = 1.0;
#else
- for ( i=0, u=-kernel->x; i < kernel->width; i++, u++)
- kernel->positive_range += (
- kernel->values[i] =
- exp(-((double)(u*u))/(2.0*sigma*sigma))
- /* / (MagickSQ2PI*sigma) */ );
+ /* Direct calculation without curve averaging */
+
+ /* Calculate a Positive Gaussian */
+ if ( sigma > MagickEpsilon )
+ { alpha = 1.0/(2.0*sigma*sigma); /* simplify loop expressions */
+ beta = 1.0/(MagickSQ2PI*sigma);
+ for ( i=0, u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ kernel->values[i] = exp(-((double)(u*u))*alpha)*beta;
+ }
+ else /* special case - generate a unity kernel */
+ { (void) ResetMagickMemory(kernel->values,0, (size_t)
+ kernel->width*kernel->height*sizeof(double));
+ kernel->values[kernel->x+kernel->y*kernel->width] = 1.0;
+ }
#endif
- kernel->minimum = 0;
- kernel->maximum = kernel->values[ kernel->x ];
- /* Note that neither methods above generate a normalized kernel,
- ** though it gets close. The kernel may be 'clipped' by a user defined
+ /* Note the above kernel may have been 'clipped' by a user defined
** radius, producing a smaller (darker) kernel. Also for very small
** sigma's (> 0.1) the central value becomes larger than one, and thus
** producing a very bright kernel.
+ **
+ ** Normalization will still be needed.
*/
/* Normalize the 1D Gaussian Kernel
**
- ** Because of this the divisor in the above kernel generator is
- ** not needed, so is not done above.
+ ** NB: a CorrelateNormalize performs a normal Normalize if
+ ** there are no negative values.
*/
- ScaleKernelInfo(kernel, 1.0, NormalizeValue); /* Normalize */
+ CalcKernelMetaData(kernel); /* the other kernel meta-data */
+ ScaleKernelInfo(kernel, 1.0, CorrelateNormalizeValue);
- /* rotate the kernel by given angle */
- RotateKernelInfo(kernel, args->xi);
+ /* rotate the 1D kernel by given angle */
+ RotateKernelInfo(kernel, args->xi );
break;
}
case CometKernel:
{ double
- sigma = fabs(args->sigma);
-
- sigma = (sigma <= MagickEpsilon) ? 1.0 : sigma;
+ sigma = fabs(args->sigma),
+ A;
if ( args->rho < 1.0 )
- kernel->width = GetOptimalKernelWidth1D(args->rho,sigma);
+ kernel->width = (GetOptimalKernelWidth1D(args->rho,sigma)-1)/2+1;
else
- kernel->width = (unsigned long)args->rho;
+ kernel->width = (size_t)args->rho;
kernel->x = kernel->y = 0;
kernel->height = 1;
kernel->negative_range = kernel->positive_range = 0.0;
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- /* A comet blur is half a gaussian curve, so that the object is
+ /* A comet blur is half a 1D gaussian curve, so that the object is
** blurred in one direction only. This may not be quite the right
- ** curve so may change in the future. The function must be normalised.
+ ** curve to use so may change in the future. The function must be
+ ** normalised after generation, which also resolves any clipping.
+ **
+ ** As we are normalizing and not subtracting gaussians,
+ ** there is no need for a divisor in the gaussian formula
+ **
+ ** It is less comples
*/
+ if ( sigma > MagickEpsilon )
+ {
#if 1
#define KernelRank 3
- sigma *= KernelRank; /* simplify expanded curve */
- v = (long) kernel->width*KernelRank; /* start/end points to fit range */
- (void) ResetMagickMemory(kernel->values,0, (size_t)
- kernel->width*sizeof(double));
- for ( u=0; u < v; u++) {
- kernel->values[u/KernelRank] +=
- exp(-((double)(u*u))/(2.0*sigma*sigma))
- /* / (MagickSQ2PI*sigma/KernelRank) */ ;
- }
- for (i=0; i < (long) kernel->width; i++)
- kernel->positive_range += kernel->values[i];
+ v = (ssize_t) kernel->width*KernelRank; /* start/end points */
+ (void) ResetMagickMemory(kernel->values,0, (size_t)
+ kernel->width*sizeof(double));
+ sigma *= KernelRank; /* simplify the loop expression */
+ A = 1.0/(2.0*sigma*sigma);
+ /* B = 1.0/(MagickSQ2PI*sigma); */
+ for ( u=0; u < v; u++) {
+ kernel->values[u/KernelRank] +=
+ exp(-((double)(u*u))*A);
+ /* exp(-((double)(i*i))/2.0*sigma*sigma)/(MagickSQ2PI*sigma); */
+ }
+ for (i=0; i < (ssize_t) kernel->width; i++)
+ kernel->positive_range += kernel->values[i];
#else
- for ( i=0; i < (long) kernel->width; i++)
- kernel->positive_range += (
- kernel->values[i] =
- exp(-((double)(i*i))/(2.0*sigma*sigma))
- /* / (MagickSQ2PI*sigma) */ );
+ A = 1.0/(2.0*sigma*sigma); /* simplify the loop expression */
+ /* B = 1.0/(MagickSQ2PI*sigma); */
+ for ( i=0; i < (ssize_t) kernel->width; i++)
+ kernel->positive_range +=
+ kernel->values[i] =
+ exp(-((double)(i*i))*A);
+ /* exp(-((double)(i*i))/2.0*sigma*sigma)/(MagickSQ2PI*sigma); */
#endif
- kernel->minimum = 0;
+ }
+ else /* special case - generate a unity kernel */
+ { (void) ResetMagickMemory(kernel->values,0, (size_t)
+ kernel->width*kernel->height*sizeof(double));
+ kernel->values[kernel->x+kernel->y*kernel->width] = 1.0;
+ kernel->positive_range = 1.0;
+ }
+
+ kernel->minimum = 0.0;
kernel->maximum = kernel->values[0];
+ kernel->negative_range = 0.0;
ScaleKernelInfo(kernel, 1.0, NormalizeValue); /* Normalize */
RotateKernelInfo(kernel, args->xi); /* Rotate by angle */
break;
}
- /* Boolean Kernels */
- case RectangleKernel:
- case SquareKernel:
- {
- double scale;
- if ( type == SquareKernel )
- {
- if (args->rho < 1.0)
+
+ /* Convolution Kernels - Well Known Constants */
+ case LaplacianKernel:
+ { switch ( (int) args->rho ) {
+ case 0:
+ default: /* laplacian square filter -- default */
+ kernel=ParseKernelArray("3: -1,-1,-1 -1,8,-1 -1,-1,-1");
+ break;
+ case 1: /* laplacian diamond filter */
+ kernel=ParseKernelArray("3: 0,-1,0 -1,4,-1 0,-1,0");
+ break;
+ case 2:
+ kernel=ParseKernelArray("3: -2,1,-2 1,4,1 -2,1,-2");
+ break;
+ case 3:
+ kernel=ParseKernelArray("3: 1,-2,1 -2,4,-2 1,-2,1");
+ break;
+ case 5: /* a 5x5 laplacian */
+ kernel=ParseKernelArray(
+ "5: -4,-1,0,-1,-4 -1,2,3,2,-1 0,3,4,3,0 -1,2,3,2,-1 -4,-1,0,-1,-4");
+ break;
+ case 7: /* a 7x7 laplacian */
+ kernel=ParseKernelArray(
+ "7:-10,-5,-2,-1,-2,-5,-10 -5,0,3,4,3,0,-5 -2,3,6,7,6,3,-2 -1,4,7,8,7,4,-1 -2,3,6,7,6,3,-2 -5,0,3,4,3,0,-5 -10,-5,-2,-1,-2,-5,-10" );
+ break;
+ case 15: /* a 5x5 LoG (sigma approx 1.4) */
+ kernel=ParseKernelArray(
+ "5: 0,0,-1,0,0 0,-1,-2,-1,0 -1,-2,16,-2,-1 0,-1,-2,-1,0 0,0,-1,0,0");
+ break;
+ case 19: /* a 9x9 LoG (sigma approx 1.4) */
+ /* http://www.cscjournals.org/csc/manuscript/Journals/IJIP/volume3/Issue1/IJIP-15.pdf */
+ kernel=ParseKernelArray(
+ "9: 0,-1,-1,-2,-2,-2,-1,-1,0 -1,-2,-4,-5,-5,-5,-4,-2,-1 -1,-4,-5,-3,-0,-3,-5,-4,-1 -2,-5,-3,12,24,12,-3,-5,-2 -2,-5,-0,24,40,24,-0,-5,-2 -2,-5,-3,12,24,12,-3,-5,-2 -1,-4,-5,-3,-0,-3,-5,-4,-1 -1,-2,-4,-5,-5,-5,-4,-2,-1 0,-1,-1,-2,-2,-2,-1,-1,0");
+ break;
+ }
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ }
+ case SobelKernel:
+#if 0
+ { /* Sobel with optional 'sub-types' */
+ switch ( (int) args->rho ) {
+ default:
+ case 0:
+ kernel=ParseKernelArray("3: 1,0,-1 2,0,-2 1,0,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ case 1:
+ kernel=ParseKernelArray("3: 1,0,-1 2,0,-2 1,0,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 0.25, NoValue);
+ break;
+ case 2:
+ kernel=ParseKernelArray("3: 1,2,0 2,0,-2 0,-2,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 0.25, NoValue);
+ break;
+ }
+ if ( fabs(args->sigma) > MagickEpsilon )
+ /* Rotate by correctly supplied 'angle' */
+ RotateKernelInfo(kernel, args->sigma);
+ else if ( args->rho > 30.0 || args->rho < -30.0 )
+ /* Rotate by out of bounds 'type' */
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+#else
+ { /* Simple Sobel Kernel */
+ kernel=ParseKernelArray("3: 1,0,-1 2,0,-2 1,0,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+#endif
+ case RobertsKernel:
+ {
+ kernel=ParseKernelArray("3: 0,0,0 1,-1,0 0,0,0");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+ case PrewittKernel:
+ {
+ kernel=ParseKernelArray("3: 1,0,-1 1,0,-1 1,0,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+ case CompassKernel:
+ {
+ kernel=ParseKernelArray("3: 1,1,-1 1,-2,-1 1,1,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+ case KirschKernel:
+ {
+ kernel=ParseKernelArray("3: 5,-3,-3 5,0,-3 5,-3,-3");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+ case FreiChenKernel:
+ /* Direction is set to be left to right positive */
+ /* http://www.math.tau.ac.il/~turkel/notes/edge_detectors.pdf -- RIGHT? */
+ /* http://ltswww.epfl.ch/~courstiv/exos_labos/sol3.pdf -- WRONG? */
+ { switch ( (int) args->rho ) {
+ default:
+ case 0:
+ kernel=ParseKernelArray("3: 1,0,-1 2,0,-2 1,0,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ kernel->values[3] = +MagickSQ2;
+ kernel->values[5] = -MagickSQ2;
+ CalcKernelMetaData(kernel); /* recalculate meta-data */
+ break;
+ case 2:
+ kernel=ParseKernelArray("3: 1,2,0 2,0,-2 0,-2,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ kernel->values[1] = kernel->values[3] = +MagickSQ2;
+ kernel->values[5] = kernel->values[7] = -MagickSQ2;
+ CalcKernelMetaData(kernel); /* recalculate meta-data */
+ ScaleKernelInfo(kernel, 1.0/2.0*MagickSQ2, NoValue);
+ break;
+ case 10:
+ kernel=AcquireKernelInfo("FreiChen:11;FreiChen:12;FreiChen:13;FreiChen:14;FreiChen:15;FreiChen:16;FreiChen:17;FreiChen:18;FreiChen:19");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ break;
+ case 1:
+ case 11:
+ kernel=ParseKernelArray("3: 1,0,-1 2,0,-2 1,0,-1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ kernel->values[3] = +MagickSQ2;
+ kernel->values[5] = -MagickSQ2;
+ CalcKernelMetaData(kernel); /* recalculate meta-data */
+ ScaleKernelInfo(kernel, 1.0/2.0*MagickSQ2, NoValue);
+ break;
+ case 12:
+ kernel=ParseKernelArray("3: 1,2,1 0,0,0 1,2,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ kernel->values[1] = +MagickSQ2;
+ kernel->values[7] = +MagickSQ2;
+ CalcKernelMetaData(kernel);
+ ScaleKernelInfo(kernel, 1.0/2.0*MagickSQ2, NoValue);
+ break;
+ case 13:
+ kernel=ParseKernelArray("3: 2,-1,0 -1,0,1 0,1,-2");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ kernel->values[0] = +MagickSQ2;
+ kernel->values[8] = -MagickSQ2;
+ CalcKernelMetaData(kernel);
+ ScaleKernelInfo(kernel, 1.0/2.0*MagickSQ2, NoValue);
+ break;
+ case 14:
+ kernel=ParseKernelArray("3: 0,1,-2 -1,0,1 2,-1,0");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ kernel->values[2] = -MagickSQ2;
+ kernel->values[6] = +MagickSQ2;
+ CalcKernelMetaData(kernel);
+ ScaleKernelInfo(kernel, 1.0/2.0*MagickSQ2, NoValue);
+ break;
+ case 15:
+ kernel=ParseKernelArray("3: 0,-1,0 1,0,1 0,-1,0");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 1.0/2.0, NoValue);
+ break;
+ case 16:
+ kernel=ParseKernelArray("3: 1,0,-1 0,0,0 -1,0,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 1.0/2.0, NoValue);
+ break;
+ case 17:
+ kernel=ParseKernelArray("3: 1,-2,1 -2,4,-2 -1,-2,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 1.0/6.0, NoValue);
+ break;
+ case 18:
+ kernel=ParseKernelArray("3: -2,1,-2 1,4,1 -2,1,-2");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 1.0/6.0, NoValue);
+ break;
+ case 19:
+ kernel=ParseKernelArray("3: 1,1,1 1,1,1 1,1,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ScaleKernelInfo(kernel, 1.0/3.0, NoValue);
+ break;
+ }
+ if ( fabs(args->sigma) > MagickEpsilon )
+ /* Rotate by correctly supplied 'angle' */
+ RotateKernelInfo(kernel, args->sigma);
+ else if ( args->rho > 30.0 || args->rho < -30.0 )
+ /* Rotate by out of bounds 'type' */
+ RotateKernelInfo(kernel, args->rho);
+ break;
+ }
+
+ /* Boolean Kernels */
+ case DiamondKernel:
+ {
+ if (args->rho < 1.0)
+ kernel->width = kernel->height = 3; /* default radius = 1 */
+ else
+ kernel->width = kernel->height = ((size_t)args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
+
+ kernel->values=(double *) AcquireQuantumMemory(kernel->width,
+ kernel->height*sizeof(double));
+ if (kernel->values == (double *) NULL)
+ return(DestroyKernelInfo(kernel));
+
+ /* set all kernel values within diamond area to scale given */
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ if ( (labs((long) u)+labs((long) v)) <= (long) kernel->x)
+ kernel->positive_range += kernel->values[i] = args->sigma;
+ else
+ kernel->values[i] = nan;
+ kernel->minimum = kernel->maximum = args->sigma; /* a flat shape */
+ break;
+ }
+ case SquareKernel:
+ case RectangleKernel:
+ { double
+ scale;
+ if ( type == SquareKernel )
+ {
+ if (args->rho < 1.0)
kernel->width = kernel->height = 3; /* default radius = 1 */
else
- kernel->width = kernel->height = (unsigned long) (2*args->rho+1);
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = (size_t) (2*args->rho+1);
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
scale = args->sigma;
}
else {
/* NOTE: user defaults set in "AcquireKernelInfo()" */
if ( args->rho < 1.0 || args->sigma < 1.0 )
return(DestroyKernelInfo(kernel)); /* invalid args given */
- kernel->width = (unsigned long)args->rho;
- kernel->height = (unsigned long)args->sigma;
+ kernel->width = (size_t)args->rho;
+ kernel->height = (size_t)args->sigma;
if ( args->xi < 0.0 || args->xi > (double)kernel->width ||
args->psi < 0.0 || args->psi > (double)kernel->height )
return(DestroyKernelInfo(kernel)); /* invalid args given */
- kernel->x = (long) args->xi;
- kernel->y = (long) args->psi;
+ kernel->x = (ssize_t) args->xi;
+ kernel->y = (ssize_t) args->psi;
scale = 1.0;
}
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- /* set all kernel values to 1.0 */
- u=(long) kernel->width*kernel->height;
+ /* set all kernel values to scale given */
+ u=(ssize_t) (kernel->width*kernel->height);
for ( i=0; i < u; i++)
kernel->values[i] = scale;
kernel->minimum = kernel->maximum = scale; /* a flat shape */
kernel->positive_range = scale*u;
break;
}
- case DiamondKernel:
+ case DiskKernel:
{
- if (args->rho < 1.0)
- kernel->width = kernel->height = 3; /* default radius = 1 */
+ ssize_t
+ limit = (ssize_t)(args->rho*args->rho);
+
+ if (args->rho < 0.4) /* default radius approx 3.5 */
+ kernel->width = kernel->height = 7L, limit = 10L;
else
- kernel->width = kernel->height = ((unsigned long)args->rho)*2+1;
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = (size_t)fabs(args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- /* set all kernel values within diamond area to scale given */
- for ( i=0, v=-kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
- if ((labs(u)+labs(v)) <= (long)kernel->x)
+ /* set all kernel values within disk area to scale given */
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ if ((u*u+v*v) <= limit)
kernel->positive_range += kernel->values[i] = args->sigma;
else
kernel->values[i] = nan;
kernel->minimum = kernel->maximum = args->sigma; /* a flat shape */
break;
}
- case DiskKernel:
+ case PlusKernel:
{
- long
- limit;
-
- limit = (long)(args->rho*args->rho);
- if (args->rho < 0.1) /* default radius approx 3.5 */
- kernel->width = kernel->height = 7L, limit = 10L;
+ if (args->rho < 1.0)
+ kernel->width = kernel->height = 5; /* default radius 2 */
else
- kernel->width = kernel->height = ((unsigned long)args->rho)*2+1;
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = ((size_t)args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- /* set all kernel values within disk area to 1.0 */
- for ( i=0, v= -kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
- if ((u*u+v*v) <= limit)
- kernel->positive_range += kernel->values[i] = args->sigma;
- else
- kernel->values[i] = nan;
+ /* set all kernel values along axises to given scale */
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ kernel->values[i] = (u == 0 || v == 0) ? args->sigma : nan;
kernel->minimum = kernel->maximum = args->sigma; /* a flat shape */
+ kernel->positive_range = args->sigma*(kernel->width*2.0 - 1.0);
break;
}
- case PlusKernel:
+ case CrossKernel:
{
if (args->rho < 1.0)
kernel->width = kernel->height = 5; /* default radius 2 */
else
- kernel->width = kernel->height = ((unsigned long)args->rho)*2+1;
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = ((size_t)args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- /* set all kernel values along axises to 1.0 */
- for ( i=0, v=-kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
- kernel->values[i] = (u == 0 || v == 0) ? args->sigma : nan;
+ /* set all kernel values along axises to given scale */
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ kernel->values[i] = (u == v || u == -v) ? args->sigma : nan;
kernel->minimum = kernel->maximum = args->sigma; /* a flat shape */
kernel->positive_range = args->sigma*(kernel->width*2.0 - 1.0);
break;
}
- /* Distance Measuring Kernels */
- case ChebyshevKernel:
+ /* HitAndMiss Kernels */
+ case RingKernel:
+ case PeaksKernel:
{
- double
+ ssize_t
+ limit1,
+ limit2,
scale;
+ if (args->rho < args->sigma)
+ {
+ kernel->width = ((size_t)args->sigma)*2+1;
+ limit1 = (ssize_t)(args->rho*args->rho);
+ limit2 = (ssize_t)(args->sigma*args->sigma);
+ }
+ else
+ {
+ kernel->width = ((size_t)args->rho)*2+1;
+ limit1 = (ssize_t)(args->sigma*args->sigma);
+ limit2 = (ssize_t)(args->rho*args->rho);
+ }
+ if ( limit2 <= 0 )
+ kernel->width = 7L, limit1 = 7L, limit2 = 11L;
+
+ kernel->height = kernel->width;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
+ kernel->values=(double *) AcquireQuantumMemory(kernel->width,
+ kernel->height*sizeof(double));
+ if (kernel->values == (double *) NULL)
+ return(DestroyKernelInfo(kernel));
+
+ /* set a ring of points of 'scale' ( 0.0 for PeaksKernel ) */
+ scale = (ssize_t) (( type == PeaksKernel) ? 0.0 : args->xi);
+ for ( i=0, v= -kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
+ { ssize_t radius=u*u+v*v;
+ if (limit1 < radius && radius <= limit2)
+ kernel->positive_range += kernel->values[i] = (double) scale;
+ else
+ kernel->values[i] = nan;
+ }
+ kernel->minimum = kernel->minimum = (double) scale;
+ if ( type == PeaksKernel ) {
+ /* set the central point in the middle */
+ kernel->values[kernel->x+kernel->y*kernel->width] = 1.0;
+ kernel->positive_range = 1.0;
+ kernel->maximum = 1.0;
+ }
+ break;
+ }
+ case EdgesKernel:
+ {
+ kernel=ParseKernelArray("3: 0,0,0 -,1,- 1,1,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ExpandMirrorKernelInfo(kernel); /* mirror expansion of other kernels */
+ break;
+ }
+ case CornersKernel:
+ {
+ kernel=ParseKernelArray("3: 0,0,- 0,1,1 -,1,-");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ExpandRotateKernelInfo(kernel, 90.0); /* Expand 90 degree rotations */
+ break;
+ }
+ case LineEndsKernel:
+ { /* Kernels for finding the end of thin lines */
+ switch ( (int) args->rho ) {
+ case 0:
+ default:
+ /* set of kernels to find all end of lines */
+ kernel=AcquireKernelInfo("LineEnds:1>;LineEnds:2>");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ break;
+ case 1:
+ /* kernel for 4-connected line ends - no rotation */
+ kernel=ParseKernelArray("3: 0,0,0 0,1,0 -,1,-");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ case 2:
+ /* kernel to add for 8-connected lines - no rotation */
+ kernel=ParseKernelArray("3: 0,0,0 0,1,0 0,0,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ }
+ break;
+ }
+ case LineJunctionsKernel:
+ { /* kernels for finding the junctions of multiple lines */
+ switch ( (int) args->rho ) {
+ case 0:
+ default:
+ /* set of kernels to find all line junctions */
+ kernel=AcquireKernelInfo("LineJunctions:1@;LineJunctions:2>");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ break;
+ case 1:
+ /* Y Junction */
+ kernel=ParseKernelArray("3: 1,-,1 -,1,- -,1,-");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ case 2:
+ /* Diagonal T Junctions */
+ kernel=ParseKernelArray("3: 1,-,- -,1,- 1,-,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ case 3:
+ /* Orthogonal T Junctions */
+ kernel=ParseKernelArray("3: -,-,- 1,1,1 -,1,-");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ case 4:
+ /* Diagonal X Junctions */
+ kernel=ParseKernelArray("3: 1,-,1 -,1,- 1,-,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ case 5:
+ /* Orthogonal X Junctions - minimal diamond kernel */
+ kernel=ParseKernelArray("3: -,1,- 1,1,1 -,1,-");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ break;
+ }
+ break;
+ }
+ case RidgesKernel:
+ { /* Ridges - Ridge finding kernels */
+ KernelInfo
+ *new_kernel;
+ switch ( (int) args->rho ) {
+ case 1:
+ default:
+ kernel=ParseKernelArray("3x1:0,1,0");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ExpandRotateKernelInfo(kernel, 90.0); /* 2 rotated kernels (symmetrical) */
+ break;
+ case 2:
+ kernel=ParseKernelArray("4x1:0,1,1,0");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ExpandRotateKernelInfo(kernel, 90.0); /* 4 rotated kernels */
+
+ /* Kernels to find a stepped 'thick' line, 4 rotates + mirrors */
+ /* Unfortunatally we can not yet rotate a non-square kernel */
+ /* But then we can't flip a non-symetrical kernel either */
+ new_kernel=ParseKernelArray("4x3+1+1:0,1,1,- -,1,1,- -,1,1,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("4x3+2+1:0,1,1,- -,1,1,- -,1,1,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("4x3+1+1:-,1,1,0 -,1,1,- 0,1,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("4x3+2+1:-,1,1,0 -,1,1,- 0,1,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3x4+1+1:0,-,- 1,1,1 1,1,1 -,-,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3x4+1+2:0,-,- 1,1,1 1,1,1 -,-,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3x4+1+1:-,-,0 1,1,1 1,1,1 0,-,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3x4+1+2:-,-,0 1,1,1 1,1,1 0,-,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ break;
+ }
+ break;
+ }
+ case ConvexHullKernel:
+ {
+ KernelInfo
+ *new_kernel;
+ /* first set of 8 kernels */
+ kernel=ParseKernelArray("3: 1,1,- 1,0,- 1,-,0");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ExpandRotateKernelInfo(kernel, 90.0);
+ /* append the mirror versions too - no flip function yet */
+ new_kernel=ParseKernelArray("3: 1,1,1 1,0,- -,-,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ ExpandRotateKernelInfo(new_kernel, 90.0);
+ LastKernelInfo(kernel)->next = new_kernel;
+ break;
+ }
+ case SkeletonKernel:
+ {
+ KernelInfo
+ *new_kernel;
+ switch ( (int) args->rho ) {
+ case 1:
+ default:
+ /* Traditional Skeleton...
+ ** A cyclically rotated single kernel
+ */
+ kernel=ParseKernelArray("3: 0,0,0 -,1,- 1,1,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ ExpandRotateKernelInfo(kernel, 45.0); /* 8 rotations */
+ break;
+ case 2:
+ /* HIPR Variation of the cyclic skeleton
+ ** Corners of the traditional method made more forgiving,
+ ** but the retain the same cyclic order.
+ */
+ kernel=ParseKernelArray("3: 0,0,0 -,1,- 1,1,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ new_kernel=ParseKernelArray("3: -,0,0 1,1,0 -,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ ExpandRotateKernelInfo(kernel, 90.0); /* 4 rotations of the 2 kernels */
+ break;
+ case 3:
+ /* Jittered Skeleton: do top, then bottom, then each sides */
+ /* Do top edge */
+ kernel=ParseKernelArray("3: 0,0,0 -,1,- 1,1,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ new_kernel=ParseKernelArray("3: 0,0,- 0,1,1 -,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3: -,0,0 1,1,0 -,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ /* Do Bottom edge */
+ new_kernel=ParseKernelArray("3: 1,1,1 -,1,- 0,0,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3: -,1,- 1,1,0 -,0,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3: -,1,- 0,1,1 0,0,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ /* Last the two sides */
+ new_kernel=ParseKernelArray("3: 0,-,1 0,1,1 0,-,1");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3: 1,-,0 1,1,0 1,-,0");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ break;
+ case 4:
+ /* Just a simple 'Edge' kernel, but with a extra two kernels
+ ** to finish off diagonal lines, top then bottom then sides.
+ ** Works well for test case but fails for general case.
+ */
+ kernel=ParseKernelArray("3: 0,0,0 -,1,- 1,1,1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = type;
+ new_kernel=ParseKernelArray("3: 0,0,0 0,1,1 1,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ new_kernel=ParseKernelArray("3: 0,0,0 1,1,0 -,1,1");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ LastKernelInfo(kernel)->next = new_kernel;
+ ExpandMirrorKernelInfo(kernel);
+ /* Append a set of corner kernels */
+ new_kernel=ParseKernelArray("3: 0,0,- 0,1,1 -,1,-");
+ if (new_kernel == (KernelInfo *) NULL)
+ return(DestroyKernelInfo(kernel));
+ new_kernel->type = type;
+ ExpandRotateKernelInfo(new_kernel, 90.0);
+ LastKernelInfo(kernel)->next = new_kernel;
+ break;
+ }
+ break;
+ }
+ /* Distance Measuring Kernels */
+ case ChebyshevKernel:
+ {
if (args->rho < 1.0)
kernel->width = kernel->height = 3; /* default radius = 1 */
else
- kernel->width = kernel->height = ((unsigned long)args->rho)*2+1;
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = ((size_t)args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- scale = (args->sigma < 1.0) ? 100.0 : args->sigma;
- for ( i=0, v=-kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
kernel->positive_range += ( kernel->values[i] =
- scale*((labs(u)>labs(v)) ? labs(u) : labs(v)) );
+ args->sigma*((labs((long) u)>labs((long) v)) ? labs((long) u) : labs((long) v)) );
kernel->maximum = kernel->values[0];
break;
}
- case ManhattenKernel:
+ case ManhattanKernel:
{
- double
- scale;
-
if (args->rho < 1.0)
kernel->width = kernel->height = 3; /* default radius = 1 */
else
- kernel->width = kernel->height = ((unsigned long)args->rho)*2+1;
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = ((size_t)args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- scale = (args->sigma < 1.0) ? 100.0 : args->sigma;
- for ( i=0, v=-kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
kernel->positive_range += ( kernel->values[i] =
- scale*(labs(u)+labs(v)) );
+ args->sigma*(labs((long) u)+labs((long) v)) );
kernel->maximum = kernel->values[0];
break;
}
case EuclideanKernel:
{
- double
- scale;
-
if (args->rho < 1.0)
kernel->width = kernel->height = 3; /* default radius = 1 */
else
- kernel->width = kernel->height = ((unsigned long)args->rho)*2+1;
- kernel->x = kernel->y = (long) (kernel->width-1)/2;
+ kernel->width = kernel->height = ((size_t)args->rho)*2+1;
+ kernel->x = kernel->y = (ssize_t) (kernel->width-1)/2;
kernel->values=(double *) AcquireQuantumMemory(kernel->width,
kernel->height*sizeof(double));
if (kernel->values == (double *) NULL)
return(DestroyKernelInfo(kernel));
- scale = (args->sigma < 1.0) ? 100.0 : args->sigma;
- for ( i=0, v=-kernel->y; v <= (long)kernel->y; v++)
- for ( u=-kernel->x; u <= (long)kernel->x; u++, i++)
+ for ( i=0, v=-kernel->y; v <= (ssize_t)kernel->y; v++)
+ for ( u=-kernel->x; u <= (ssize_t)kernel->x; u++, i++)
kernel->positive_range += ( kernel->values[i] =
- scale*sqrt((double)(u*u+v*v)) );
+ args->sigma*sqrt((double)(u*u+v*v)) );
kernel->maximum = kernel->values[0];
break;
}
- /* Undefined Kernels */
- case LaplacianKernel:
- case LOGKernel:
- case DOGKernel:
- perror("Kernel Type has not been defined yet");
- /* FALL THRU */
+ case UnityKernel:
default:
- /* Generate a No-Op minimal kernel - 1x1 pixel */
- kernel->values=(double *)AcquireQuantumMemory((size_t)1,sizeof(double));
- if (kernel->values == (double *) NULL)
- return(DestroyKernelInfo(kernel));
- kernel->width = kernel->height = 1;
- kernel->x = kernel->x = 0;
- kernel->type = UndefinedKernel;
- kernel->maximum =
- kernel->positive_range =
- kernel->values[0] = 1.0; /* a flat single-point no-op kernel! */
+ {
+ /* Unity or No-Op Kernel - Basically just a single pixel on its own */
+ kernel=ParseKernelArray("1:1");
+ if (kernel == (KernelInfo *) NULL)
+ return(kernel);
+ kernel->type = ( type == UnityKernel ) ? UnityKernel : UndefinedKernel;
+ break;
+ }
break;
}
% %
% %
% %
-+ C l o n e K e r n e l I n f o %
+% C l o n e K e r n e l I n f o %
% %
% %
% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
-% CloneKernelInfo() creates a new clone of the given Kernel so that its can
-% be modified without effecting the original. The cloned kernel should be
-% destroyed using DestoryKernelInfo() when no longer needed.
+% CloneKernelInfo() creates a new clone of the given Kernel List so that its
+% can be modified without effecting the original. The cloned kernel should
+% be destroyed using DestoryKernelInfo() when no ssize_ter needed.
%
-% The format of the DestroyKernelInfo method is:
+% The format of the CloneKernelInfo method is:
%
% KernelInfo *CloneKernelInfo(const KernelInfo *kernel)
%
% o kernel: the Morphology/Convolution kernel to be cloned
%
*/
-
-static KernelInfo *CloneKernelInfo(const KernelInfo *kernel)
+MagickExport KernelInfo *CloneKernelInfo(const KernelInfo *kernel)
{
- register long
+ register ssize_t
i;
- KernelInfo *
- new;
+ KernelInfo
+ *new_kernel;
assert(kernel != (KernelInfo *) NULL);
+ new_kernel=(KernelInfo *) AcquireMagickMemory(sizeof(*kernel));
+ if (new_kernel == (KernelInfo *) NULL)
+ return(new_kernel);
+ *new_kernel=(*kernel); /* copy values in structure */
+
+ /* replace the values with a copy of the values */
+ new_kernel->values=(double *) AcquireQuantumMemory(kernel->width,
+ kernel->height*sizeof(double));
+ if (new_kernel->values == (double *) NULL)
+ return(DestroyKernelInfo(new_kernel));
+ for (i=0; i < (ssize_t) (kernel->width*kernel->height); i++)
+ new_kernel->values[i]=kernel->values[i];
+
+ /* Also clone the next kernel in the kernel list */
+ if ( kernel->next != (KernelInfo *) NULL ) {
+ new_kernel->next = CloneKernelInfo(kernel->next);
+ if ( new_kernel->next == (KernelInfo *) NULL )
+ return(DestroyKernelInfo(new_kernel));
+ }
- new=(KernelInfo *) AcquireMagickMemory(sizeof(*kernel));
- if (new == (KernelInfo *) NULL)
- return(new);
- *new = *kernel; /* copy values in structure */
-
- new->values=(double *) AcquireQuantumMemory(kernel->width,
- kernel->height*sizeof(double));
- if (new->values == (double *) NULL)
- return(DestroyKernelInfo(new));
-
- for (i=0; i < (long) (kernel->width*kernel->height); i++)
- new->values[i] = kernel->values[i];
-
- return(new);
+ return(new_kernel);
}
\f
/*
% o kernel: the Morphology/Convolution kernel to be destroyed
%
*/
-
MagickExport KernelInfo *DestroyKernelInfo(KernelInfo *kernel)
{
assert(kernel != (KernelInfo *) NULL);
- kernel->values=(double *) AcquireQuantumMemory(kernel->width,
- kernel->height*sizeof(double));
- kernel->values=(double *)RelinquishMagickMemory(kernel->values);
- kernel=(KernelInfo *) RelinquishMagickMemory(kernel);
+ if ( kernel->next != (KernelInfo *) NULL )
+ kernel->next = DestroyKernelInfo(kernel->next);
+
+ kernel->values = (double *)RelinquishMagickMemory(kernel->values);
+ kernel = (KernelInfo *) RelinquishMagickMemory(kernel);
return(kernel);
}
\f
% %
% %
% %
-% M o r p h o l o g y I m a g e C h a n n e l %
+% E x p a n d M i r r o r K e r n e l I n f o %
% %
% %
% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
-% MorphologyImageChannel() applies a user supplied kernel to the image
-% according to the given mophology method.
+% ExpandMirrorKernelInfo() takes a single kernel, and expands it into a
+% sequence of 90-degree rotated kernels but providing a reflected 180
+% rotatation, before the -/+ 90-degree rotations.
%
-% The given kernel is assumed to have been pre-scaled appropriatally, usally
-% by the kernel generator.
+% This special rotation order produces a better, more symetrical thinning of
+% objects.
%
-% The format of the MorphologyImage method is:
+% The format of the ExpandMirrorKernelInfo method is:
%
-% Image *MorphologyImage(const Image *image, MorphologyMethod method,
-% const long iterations, KernelInfo *kernel, ExceptionInfo *exception)
-% Image *MorphologyImageChannel(const Image *image, const ChannelType
-% channel, MorphologyMethod method, const long iterations, KernelInfo
-% *kernel, ExceptionInfo *exception)
+% void ExpandMirrorKernelInfo(KernelInfo *kernel)
+%
+% A description of each parameter follows:
+%
+% o kernel: the Morphology/Convolution kernel
+%
+% This function is only internel to this module, as it is not finalized,
+% especially with regard to non-orthogonal angles, and rotation of larger
+% 2D kernels.
+*/
+
+#if 0
+static void FlopKernelInfo(KernelInfo *kernel)
+ { /* Do a Flop by reversing each row. */
+ size_t
+ y;
+ register ssize_t
+ x,r;
+ register double
+ *k,t;
+
+ for ( y=0, k=kernel->values; y < kernel->height; y++, k+=kernel->width)
+ for ( x=0, r=kernel->width-1; x<kernel->width/2; x++, r--)
+ t=k[x], k[x]=k[r], k[r]=t;
+
+ kernel->x = kernel->width - kernel->x - 1;
+ angle = fmod(angle+180.0, 360.0);
+ }
+#endif
+
+static void ExpandMirrorKernelInfo(KernelInfo *kernel)
+{
+ KernelInfo
+ *clone,
+ *last;
+
+ last = kernel;
+
+ clone = CloneKernelInfo(last);
+ RotateKernelInfo(clone, 180); /* flip */
+ LastKernelInfo(last)->next = clone;
+ last = clone;
+
+ clone = CloneKernelInfo(last);
+ RotateKernelInfo(clone, 90); /* transpose */
+ LastKernelInfo(last)->next = clone;
+ last = clone;
+
+ clone = CloneKernelInfo(last);
+ RotateKernelInfo(clone, 180); /* flop */
+ LastKernelInfo(last)->next = clone;
+
+ return;
+}
+\f
+/*
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% %
+% %
+% %
+% E x p a n d R o t a t e K e r n e l I n f o %
+% %
+% %
+% %
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%
+% ExpandRotateKernelInfo() takes a kernel list, and expands it by rotating
+% incrementally by the angle given, until the first kernel repeats.
+%
+% WARNING: 45 degree rotations only works for 3x3 kernels.
+% While 90 degree roatations only works for linear and square kernels
+%
+% The format of the ExpandRotateKernelInfo method is:
+%
+% void ExpandRotateKernelInfo(KernelInfo *kernel, double angle)
+%
+% A description of each parameter follows:
+%
+% o kernel: the Morphology/Convolution kernel
+%
+% o angle: angle to rotate in degrees
+%
+% This function is only internel to this module, as it is not finalized,
+% especially with regard to non-orthogonal angles, and rotation of larger
+% 2D kernels.
+*/
+
+/* Internal Routine - Return true if two kernels are the same */
+static MagickBooleanType SameKernelInfo(const KernelInfo *kernel1,
+ const KernelInfo *kernel2)
+{
+ register size_t
+ i;
+
+ /* check size and origin location */
+ if ( kernel1->width != kernel2->width
+ || kernel1->height != kernel2->height
+ || kernel1->x != kernel2->x
+ || kernel1->y != kernel2->y )
+ return MagickFalse;
+
+ /* check actual kernel values */
+ for (i=0; i < (kernel1->width*kernel1->height); i++) {
+ /* Test for Nan equivelence */
+ if ( IsNan(kernel1->values[i]) && !IsNan(kernel2->values[i]) )
+ return MagickFalse;
+ if ( IsNan(kernel2->values[i]) && !IsNan(kernel1->values[i]) )
+ return MagickFalse;
+ /* Test actual values are equivelent */
+ if ( fabs(kernel1->values[i] - kernel2->values[i]) > MagickEpsilon )
+ return MagickFalse;
+ }
+
+ return MagickTrue;
+}
+
+static void ExpandRotateKernelInfo(KernelInfo *kernel, const double angle)
+{
+ KernelInfo
+ *clone,
+ *last;
+
+ last = kernel;
+ while(1) {
+ clone = CloneKernelInfo(last);
+ RotateKernelInfo(clone, angle);
+ if ( SameKernelInfo(kernel, clone) == MagickTrue )
+ break;
+ LastKernelInfo(last)->next = clone;
+ last = clone;
+ }
+ clone = DestroyKernelInfo(clone); /* kernel has repeated - junk the clone */
+ return;
+}
+\f
+/*
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% %
+% %
+% %
++ C a l c M e t a K e r n a l I n f o %
+% %
+% %
+% %
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%
+% CalcKernelMetaData() recalculate the KernelInfo meta-data of this kernel only,
+% using the kernel values. This should only ne used if it is not posible to
+% calculate that meta-data in some easier way.
+%
+% It is important that the meta-data is correct before ScaleKernelInfo() is
+% used to perform kernel normalization.
+%
+% The format of the CalcKernelMetaData method is:
+%
+% void CalcKernelMetaData(KernelInfo *kernel, const double scale )
+%
+% A description of each parameter follows:
+%
+% o kernel: the Morphology/Convolution kernel to modify
+%
+% WARNING: Minimum and Maximum values are assumed to include zero, even if
+% zero is not part of the kernel (as in Gaussian Derived kernels). This
+% however is not true for flat-shaped morphological kernels.
+%
+% WARNING: Only the specific kernel pointed to is modified, not a list of
+% multiple kernels.
+%
+% This is an internal function and not expected to be useful outside this
+% module. This could change however.
+*/
+static void CalcKernelMetaData(KernelInfo *kernel)
+{
+ register size_t
+ i;
+
+ kernel->minimum = kernel->maximum = 0.0;
+ kernel->negative_range = kernel->positive_range = 0.0;
+ for (i=0; i < (kernel->width*kernel->height); i++)
+ {
+ if ( fabs(kernel->values[i]) < MagickEpsilon )
+ kernel->values[i] = 0.0;
+ ( kernel->values[i] < 0)
+ ? ( kernel->negative_range += kernel->values[i] )
+ : ( kernel->positive_range += kernel->values[i] );
+ Minimize(kernel->minimum, kernel->values[i]);
+ Maximize(kernel->maximum, kernel->values[i]);
+ }
+
+ return;
+}
+\f
+/*
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% %
+% %
+% %
+% M o r p h o l o g y A p p l y %
+% %
+% %
+% %
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%
+% MorphologyApply() applies a morphological method, multiple times using
+% a list of multiple kernels.
+%
+% It is basically equivelent to as MorphologyImageChannel() (see below) but
+% without any user controls. This allows internel programs to use this
+% function, to actually perform a specific task without posible interference
+% by any API user supplied settings.
+%
+% It is MorphologyImageChannel() task to extract any such user controls, and
+% pass them to this function for processing.
+%
+% More specifically kernels are not normalized/scaled/blended by the
+% 'convolve:scale' Image Artifact (setting), nor is the convolve bias
+% (-bias setting or image->bias) loooked at, but must be supplied from the
+% function arguments.
+%
+% The format of the MorphologyApply method is:
+%
+% Image *MorphologyApply(const Image *image,MorphologyMethod method,
+% const ssize_t iterations,const KernelInfo *kernel,
+% const CompositeMethod compose, const double bias,
+% ExceptionInfo *exception)
%
% A description of each parameter follows:
%
% o kernel: An array of double representing the morphology kernel.
% Warning: kernel may be normalized for the Convolve method.
%
-% o exception: return any errors or warnings in this structure.
+% o compose: How to handle or merge multi-kernel results.
+% If 'Undefined' use default of the Morphology method.
+% If 'No' force image to be re-iterated by each kernel.
+% Otherwise merge the results using the mathematical compose
+% method given.
%
+% o bias: Convolution Output Bias.
%
-% TODO: bias and auto-scale handling of the kernel for convolution
-% The given kernel is assumed to have been pre-scaled appropriatally, usally
-% by the kernel generator.
+% o exception: return any errors or warnings in this structure.
%
*/
-/* Internal function
- * Apply the Low-Level Morphology Method using the given Kernel
- * Returning the number of pixels that changed.
- * Two pre-created images must be provided, no image is created.
- */
-static unsigned long MorphologyApply(const Image *image, Image
+/* Apply a Morphology Primative to an image using the given kernel.
+** Two pre-created images must be provided, no image is created.
+** Returning the number of pixels that changed.
+*/
+static size_t MorphologyPrimitive(const Image *image, Image
*result_image, const MorphologyMethod method, const ChannelType channel,
- const KernelInfo *kernel, ExceptionInfo *exception)
+ const KernelInfo *kernel,const double bias,ExceptionInfo *exception)
{
#define MorphologyTag "Morphology/Image"
- long
- progress,
+ CacheView
+ *p_view,
+ *q_view;
+
+ ssize_t
y, offx, offy,
changed;
MagickBooleanType
status;
- MagickPixelPacket
- bias;
+ MagickOffsetType
+ progress;
- CacheView
- *p_view,
- *q_view;
-
- /* Only the most basic morphology is actually performed by this routine */
+ assert(image != (Image *) NULL);
+ assert(image->signature == MagickSignature);
+ assert(result_image != (Image *) NULL);
+ assert(result_image->signature == MagickSignature);
+ assert(kernel != (KernelInfo *) NULL);
+ assert(kernel->signature == MagickSignature);
+ assert(exception != (ExceptionInfo *) NULL);
+ assert(exception->signature == MagickSignature);
- /*
- Apply Basic Morphology to Image.
- */
status=MagickTrue;
changed=0;
progress=0;
- GetMagickPixelPacket(image,&bias);
- SetMagickPixelPacketBias(image,&bias);
- /* Future: handle auto-bias from user, based on kernel input */
-
p_view=AcquireCacheView(image);
q_view=AcquireCacheView(result_image);
/* Some methods (including convolve) needs use a reflected kernel.
- * Adjust 'origin' offsets for this reflected kernel.
+ * Adjust 'origin' offsets to loop though kernel as a reflection.
*/
offx = kernel->x;
offy = kernel->y;
switch(method) {
- case ErodeMorphology:
- case ErodeIntensityMorphology:
- /* kernel is user as is, without reflection */
- break;
case ConvolveMorphology:
case DilateMorphology:
case DilateIntensityMorphology:
case DistanceMorphology:
- /* kernel needs to used with reflection */
- offx = (long) kernel->width-offx-1;
- offy = (long) kernel->height-offy-1;
+ /* kernel needs to used with reflection about origin */
+ offx = (ssize_t) kernel->width-offx-1;
+ offy = (ssize_t) kernel->height-offy-1;
+ break;
+ case ErodeMorphology:
+ case ErodeIntensityMorphology:
+ case HitAndMissMorphology:
+ case ThinningMorphology:
+ case ThickenMorphology:
+ /* kernel is used as is, without reflection */
break;
default:
- perror("Not a low level Morpholgy Method");
+ assert("Not a Primitive Morphology Method" != (char *) NULL);
break;
}
#if defined(MAGICKCORE_OPENMP_SUPPORT)
#pragma omp parallel for schedule(dynamic,4) shared(progress,status)
#endif
- for (y=0; y < (long) image->rows; y++)
+ for (y=0; y < (ssize_t) image->rows; y++)
{
MagickBooleanType
sync;
register IndexPacket
*restrict q_indexes;
- register long
+ register ssize_t
x;
- unsigned long
+ size_t
r;
if (status == MagickFalse)
q_indexes=GetCacheViewAuthenticIndexQueue(q_view);
r = (image->columns+kernel->width)*offy+offx; /* constant */
- for (x=0; x < (long) image->columns; x++)
+ for (x=0; x < (ssize_t) image->columns; x++)
{
- long
+ ssize_t
v;
- register long
+ register ssize_t
u;
register const double
*restrict k_indexes;
MagickPixelPacket
- result;
+ result,
+ min,
+ max;
/* Copy input to ouput image for unused channels
* This removes need for 'cloning' a new image every iteration
if (image->colorspace == CMYKColorspace)
q_indexes[x] = p_indexes[r];
- result.green=(MagickRealType) 0;
- result.blue=(MagickRealType) 0;
- result.opacity=(MagickRealType) 0;
- result.index=(MagickRealType) 0;
+ /* Defaults */
+ min.red =
+ min.green =
+ min.blue =
+ min.opacity =
+ min.index = (MagickRealType) QuantumRange;
+ max.red =
+ max.green =
+ max.blue =
+ max.opacity =
+ max.index = (MagickRealType) 0;
+ /* default result is the original pixel value */
+ result.red = (MagickRealType) p[r].red;
+ result.green = (MagickRealType) p[r].green;
+ result.blue = (MagickRealType) p[r].blue;
+ result.opacity = QuantumRange - (MagickRealType) p[r].opacity;
+ result.index = 0.0;
+ if ( image->colorspace == CMYKColorspace)
+ result.index = (MagickRealType) p_indexes[r];
+
switch (method) {
case ConvolveMorphology:
- /* Set the user defined bias of the weighted average output
- **
- ** FUTURE: provide some way for internal functions to disable
- ** user defined bias and scaling effects.
- */
- result=bias;
- break;
- case DilateMorphology:
+ /* Set the user defined bias of the weighted average output */
result.red =
result.green =
result.blue =
result.opacity =
- result.index = -MagickHuge;
- break;
- case ErodeMorphology:
- result.red =
- result.green =
- result.blue =
- result.opacity =
- result.index = +MagickHuge;
+ result.index = bias;
break;
case DilateIntensityMorphology:
case ErodeIntensityMorphology:
- result.red = 0.0; /* flag indicating first match found */
+ /* use a boolean flag indicating when first match found */
+ result.red = 0.0; /* result is not used otherwise */
break;
default:
- /* Otherwise just start with the original pixel value */
- result.red = (MagickRealType) p[r].red;
- result.green = (MagickRealType) p[r].green;
- result.blue = (MagickRealType) p[r].blue;
- result.opacity = QuantumRange - (MagickRealType) p[r].opacity;
- if ( image->colorspace == CMYKColorspace)
- result.index = (MagickRealType) p_indexes[r];
break;
}
** the kernel, and thus 'lower-level' that Convolution. However
** as Convolution is the more common method used, and it does not
** really cost us much in terms of processing to use a reflected
- ** kernel it is Convolution that is implemented.
+ ** kernel, so it is Convolution that is implemented.
**
** Correlation will have its kernel reflected before calling
** this function to do a Convolve.
** For more details of Correlation vs Convolution see
** http://www.cs.umd.edu/~djacobs/CMSC426/Convolution.pdf
*/
- if (((channel & OpacityChannel) == 0) ||
- (image->matte == MagickFalse))
- {
- /* Convolution without transparency effects */
- k = &kernel->values[ kernel->width*kernel->height-1 ];
- k_pixels = p;
- k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k--) {
- if ( IsNan(*k) ) continue;
- result.red += (*k)*k_pixels[u].red;
- result.green += (*k)*k_pixels[u].green;
- result.blue += (*k)*k_pixels[u].blue;
- /* result.opacity += not involved here */
- if ( image->colorspace == CMYKColorspace)
- result.index += (*k)*k_indexes[u];
- }
- k_pixels += image->columns+kernel->width;
- k_indexes += image->columns+kernel->width;
- }
- }
- else
- { /* Kernel & Alpha weighted Convolution */
+ if (((channel & SyncChannels) != 0 ) &&
+ (image->matte == MagickTrue))
+ { /* Channel has a 'Sync' Flag, and Alpha Channel enabled.
+ ** Weight the color channels with Alpha Channel so that
+ ** transparent pixels are not part of the results.
+ */
MagickRealType
- alpha, /* alpha value * kernel weighting */
- gamma; /* weighting divisor */
+ alpha, /* color channel weighting : kernel*alpha */
+ gamma; /* divisor, sum of weighting values */
gamma=0.0;
k = &kernel->values[ kernel->width*kernel->height-1 ];
k_pixels = p;
k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k--) {
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k--) {
if ( IsNan(*k) ) continue;
alpha=(*k)*(QuantumScale*(QuantumRange-
k_pixels[u].opacity));
result.opacity *= gamma;
result.index *= gamma;
}
+ else
+ {
+ /* No 'Sync' flag, or no Alpha involved.
+ ** Convolution is simple individual channel weigthed sum.
+ */
+ k = &kernel->values[ kernel->width*kernel->height-1 ];
+ k_pixels = p;
+ k_indexes = p_indexes;
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k--) {
+ if ( IsNan(*k) ) continue;
+ result.red += (*k)*k_pixels[u].red;
+ result.green += (*k)*k_pixels[u].green;
+ result.blue += (*k)*k_pixels[u].blue;
+ result.opacity += (*k)*(QuantumRange-k_pixels[u].opacity);
+ if ( image->colorspace == CMYKColorspace)
+ result.index += (*k)*k_indexes[u];
+ }
+ k_pixels += image->columns+kernel->width;
+ k_indexes += image->columns+kernel->width;
+ }
+ }
break;
case ErodeMorphology:
- /* Minimize Value within kernel neighbourhood
+ /* Minimum Value within kernel neighbourhood
**
** NOTE that the kernel is not reflected for this operation!
**
k = kernel->values;
k_pixels = p;
k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k++) {
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k++) {
if ( IsNan(*k) || (*k) < 0.5 ) continue;
- Minimize(result.red, (double) k_pixels[u].red);
- Minimize(result.green, (double) k_pixels[u].green);
- Minimize(result.blue, (double) k_pixels[u].blue);
- Minimize(result.opacity, QuantumRange-(double) k_pixels[u].opacity);
+ Minimize(min.red, (double) k_pixels[u].red);
+ Minimize(min.green, (double) k_pixels[u].green);
+ Minimize(min.blue, (double) k_pixels[u].blue);
+ Minimize(min.opacity,
+ QuantumRange-(double) k_pixels[u].opacity);
if ( image->colorspace == CMYKColorspace)
- Minimize(result.index, (double) k_indexes[u]);
+ Minimize(min.index, (double) k_indexes[u]);
}
k_pixels += image->columns+kernel->width;
k_indexes += image->columns+kernel->width;
}
break;
+
case DilateMorphology:
- /* Maximize Value within kernel neighbourhood
+ /* Maximum Value within kernel neighbourhood
**
** NOTE for correct working of this operation for asymetrical
** kernels, the kernel needs to be applied in its reflected form.
k = &kernel->values[ kernel->width*kernel->height-1 ];
k_pixels = p;
k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k--) {
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k--) {
if ( IsNan(*k) || (*k) < 0.5 ) continue;
- Maximize(result.red, (double) k_pixels[u].red);
- Maximize(result.green, (double) k_pixels[u].green);
- Maximize(result.blue, (double) k_pixels[u].blue);
- Maximize(result.opacity, QuantumRange-(double) k_pixels[u].opacity);
+ Maximize(max.red, (double) k_pixels[u].red);
+ Maximize(max.green, (double) k_pixels[u].green);
+ Maximize(max.blue, (double) k_pixels[u].blue);
+ Maximize(max.opacity,
+ QuantumRange-(double) k_pixels[u].opacity);
if ( image->colorspace == CMYKColorspace)
- Maximize(result.index, (double) k_indexes[u]);
+ Maximize(max.index, (double) k_indexes[u]);
}
k_pixels += image->columns+kernel->width;
k_indexes += image->columns+kernel->width;
}
break;
+ case HitAndMissMorphology:
+ case ThinningMorphology:
+ case ThickenMorphology:
+ /* Minimum of Foreground Pixel minus Maxumum of Background Pixels
+ **
+ ** NOTE that the kernel is not reflected for this operation,
+ ** and consists of both foreground and background pixel
+ ** neighbourhoods, 0.0 for background, and 1.0 for foreground
+ ** with either Nan or 0.5 values for don't care.
+ **
+ ** Note that this will never produce a meaningless negative
+ ** result. Such results can cause Thinning/Thicken to not work
+ ** correctly when used against a greyscale image.
+ */
+ k = kernel->values;
+ k_pixels = p;
+ k_indexes = p_indexes;
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k++) {
+ if ( IsNan(*k) ) continue;
+ if ( (*k) > 0.7 )
+ { /* minimim of foreground pixels */
+ Minimize(min.red, (double) k_pixels[u].red);
+ Minimize(min.green, (double) k_pixels[u].green);
+ Minimize(min.blue, (double) k_pixels[u].blue);
+ Minimize(min.opacity,
+ QuantumRange-(double) k_pixels[u].opacity);
+ if ( image->colorspace == CMYKColorspace)
+ Minimize(min.index, (double) k_indexes[u]);
+ }
+ else if ( (*k) < 0.3 )
+ { /* maximum of background pixels */
+ Maximize(max.red, (double) k_pixels[u].red);
+ Maximize(max.green, (double) k_pixels[u].green);
+ Maximize(max.blue, (double) k_pixels[u].blue);
+ Maximize(max.opacity,
+ QuantumRange-(double) k_pixels[u].opacity);
+ if ( image->colorspace == CMYKColorspace)
+ Maximize(max.index, (double) k_indexes[u]);
+ }
+ }
+ k_pixels += image->columns+kernel->width;
+ k_indexes += image->columns+kernel->width;
+ }
+ /* Pattern Match if difference is positive */
+ min.red -= max.red; Maximize( min.red, 0.0 );
+ min.green -= max.green; Maximize( min.green, 0.0 );
+ min.blue -= max.blue; Maximize( min.blue, 0.0 );
+ min.opacity -= max.opacity; Maximize( min.opacity, 0.0 );
+ min.index -= max.index; Maximize( min.index, 0.0 );
+ break;
+
case ErodeIntensityMorphology:
/* Select Pixel with Minimum Intensity within kernel neighbourhood
**
k = kernel->values;
k_pixels = p;
k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k++) {
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k++) {
if ( IsNan(*k) || (*k) < 0.5 ) continue;
if ( result.red == 0.0 ||
PixelIntensity(&(k_pixels[u])) < PixelIntensity(q) ) {
/* Select Pixel with Maximum Intensity within kernel neighbourhood
**
** WARNING: the intensity test fails for CMYK and does not
- ** take into account the moderating effect of teh alpha channel
- ** on the intensity.
+ ** take into account the moderating effect of the alpha channel
+ ** on the intensity (yet).
**
** NOTE for correct working of this operation for asymetrical
** kernels, the kernel needs to be applied in its reflected form.
k = &kernel->values[ kernel->width*kernel->height-1 ];
k_pixels = p;
k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k--) {
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k--) {
if ( IsNan(*k) || (*k) < 0.5 ) continue; /* boolean kernel */
if ( result.red == 0.0 ||
PixelIntensity(&(k_pixels[u])) > PixelIntensity(q) ) {
}
break;
+
case DistanceMorphology:
/* Add kernel Value and select the minimum value found.
** The result is a iterative distance from edge of image shape.
** be the case. For example how about a distance from left edges?
** To work correctly with asymetrical kernels the reflected kernel
** needs to be applied.
+ **
+ ** Actually this is really a GreyErode with a negative kernel!
+ **
*/
-#if 0
- /* No need to do distance morphology if original value is zero
- ** Unfortunatally I have not been able to get this right
- ** when channel selection also becomes involved. -- Arrgghhh
- */
- if ( ((channel & RedChannel) == 0 && p[r].red == 0)
- || ((channel & GreenChannel) == 0 && p[r].green == 0)
- || ((channel & BlueChannel) == 0 && p[r].blue == 0)
- || ((channel & OpacityChannel) == 0 && p[r].opacity == 0)
- || (( (channel & IndexChannel) == 0
- || image->colorspace != CMYKColorspace
- ) && p_indexes[x] ==0 )
- )
- break;
-#endif
k = &kernel->values[ kernel->width*kernel->height-1 ];
k_pixels = p;
k_indexes = p_indexes;
- for (v=0; v < (long) kernel->height; v++) {
- for (u=0; u < (long) kernel->width; u++, k--) {
+ for (v=0; v < (ssize_t) kernel->height; v++) {
+ for (u=0; u < (ssize_t) kernel->width; u++, k--) {
if ( IsNan(*k) ) continue;
Minimize(result.red, (*k)+k_pixels[u].red);
Minimize(result.green, (*k)+k_pixels[u].green);
default:
break; /* Do nothing */
}
+ /* Final mathematics of results (combine with original image?)
+ **
+ ** NOTE: Difference Morphology operators Edge* and *Hat could also
+ ** be done here but works better with iteration as a image difference
+ ** in the controling function (below). Thicken and Thinning however
+ ** should be done here so thay can be iterated correctly.
+ */
+ switch ( method ) {
+ case HitAndMissMorphology:
+ case ErodeMorphology:
+ result = min; /* minimum of neighbourhood */
+ break;
+ case DilateMorphology:
+ result = max; /* maximum of neighbourhood */
+ break;
+ case ThinningMorphology:
+ /* subtract pattern match from original */
+ result.red -= min.red;
+ result.green -= min.green;
+ result.blue -= min.blue;
+ result.opacity -= min.opacity;
+ result.index -= min.index;
+ break;
+ case ThickenMorphology:
+ /* Add the pattern matchs to the original */
+ result.red += min.red;
+ result.green += min.green;
+ result.blue += min.blue;
+ result.opacity += min.opacity;
+ result.index += min.index;
+ break;
+ default:
+ /* result directly calculated or assigned */
+ break;
+ }
+ /* Assign the resulting pixel values - Clamping Result */
switch ( method ) {
case UndefinedMorphology:
case DilateIntensityMorphology:
case ErodeIntensityMorphology:
break; /* full pixel was directly assigned - not a channel method */
default:
- /* Assign the results */
if ((channel & RedChannel) != 0)
q->red = ClampToQuantum(result.red);
if ((channel & GreenChannel) != 0)
q_indexes[x] = ClampToQuantum(result.index);
break;
}
+ /* Count up changed pixels */
if ( ( p[r].red != q->red )
|| ( p[r].green != q->green )
|| ( p[r].blue != q->blue )
result_image->type=image->type;
q_view=DestroyCacheView(q_view);
p_view=DestroyCacheView(p_view);
- return(status ? (unsigned long) changed : 0);
+ return(status ? (size_t) changed : 0);
}
-MagickExport Image *MorphologyImage(const Image *image, const MorphologyMethod
- method, const long iterations,const KernelInfo *kernel, ExceptionInfo
- *exception)
+MagickExport Image *MorphologyApply(const Image *image, const ChannelType
+ channel,const MorphologyMethod method, const ssize_t iterations,
+ const KernelInfo *kernel, const CompositeOperator compose,
+ const double bias, ExceptionInfo *exception)
{
Image
- *morphology_image;
+ *curr_image, /* Image we are working with or iterating */
+ *work_image, /* secondary image for primative iteration */
+ *save_image, /* saved image - for 'edge' method only */
+ *rslt_image; /* resultant image - after multi-kernel handling */
+
+ KernelInfo
+ *reflected_kernel, /* A reflected copy of the kernel (if needed) */
+ *norm_kernel, /* the current normal un-reflected kernel */
+ *rflt_kernel, /* the current reflected kernel (if needed) */
+ *this_kernel; /* the kernel being applied */
+
+ MorphologyMethod
+ primative; /* the current morphology primative being applied */
+
+ CompositeOperator
+ rslt_compose; /* multi-kernel compose method for results to use */
+
+ MagickBooleanType
+ verbose; /* verbose output of results */
+
+ size_t
+ method_loop, /* Loop 1: number of compound method iterations */
+ method_limit, /* maximum number of compound method iterations */
+ kernel_number, /* Loop 2: the kernel number being applied */
+ stage_loop, /* Loop 3: primative loop for compound morphology */
+ stage_limit, /* how many primatives in this compound */
+ kernel_loop, /* Loop 4: iterate the kernel (basic morphology) */
+ kernel_limit, /* number of times to iterate kernel */
+ count, /* total count of primative steps applied */
+ changed, /* number pixels changed by last primative operation */
+ kernel_changed, /* total count of changed using iterated kernel */
+ method_changed; /* total count of changed over method iteration */
+
+ char
+ v_info[80];
+
+ assert(image != (Image *) NULL);
+ assert(image->signature == MagickSignature);
+ assert(kernel != (KernelInfo *) NULL);
+ assert(kernel->signature == MagickSignature);
+ assert(exception != (ExceptionInfo *) NULL);
+ assert(exception->signature == MagickSignature);
+
+ count = 0; /* number of low-level morphology primatives performed */
+ if ( iterations == 0 )
+ return((Image *)NULL); /* null operation - nothing to do! */
+
+ kernel_limit = (size_t) iterations;
+ if ( iterations < 0 ) /* negative interations = infinite (well alomst) */
+ kernel_limit = image->columns > image->rows ? image->columns : image->rows;
+
+ verbose = ( GetImageArtifact(image,"verbose") != (const char *) NULL ) ?
+ MagickTrue : MagickFalse;
+
+ /* initialise for cleanup */
+ curr_image = (Image *) image;
+ work_image = save_image = rslt_image = (Image *) NULL;
+ reflected_kernel = (KernelInfo *) NULL;
+
+ /* Initialize specific methods
+ * + which loop should use the given iteratations
+ * + how many primatives make up the compound morphology
+ * + multi-kernel compose method to use (by default)
+ */
+ method_limit = 1; /* just do method once, unless otherwise set */
+ stage_limit = 1; /* assume method is not a compount */
+ rslt_compose = compose; /* and we are composing multi-kernels as given */
+ switch( method ) {
+ case SmoothMorphology: /* 4 primative compound morphology */
+ stage_limit = 4;
+ break;
+ case OpenMorphology: /* 2 primative compound morphology */
+ case OpenIntensityMorphology:
+ case TopHatMorphology:
+ case CloseMorphology:
+ case CloseIntensityMorphology:
+ case BottomHatMorphology:
+ case EdgeMorphology:
+ stage_limit = 2;
+ break;
+ case HitAndMissMorphology:
+ rslt_compose = LightenCompositeOp; /* Union of multi-kernel results */
+ /* FALL THUR */
+ case ThinningMorphology:
+ case ThickenMorphology:
+ method_limit = kernel_limit; /* iterate the whole method */
+ kernel_limit = 1; /* do not do kernel iteration */
+ break;
+ default:
+ break;
+ }
+
+ /* Handle user (caller) specified multi-kernel composition method */
+ if ( compose != UndefinedCompositeOp )
+ rslt_compose = compose; /* override default composition for method */
+ if ( rslt_compose == UndefinedCompositeOp )
+ rslt_compose = NoCompositeOp; /* still not defined! Then re-iterate */
+
+ /* Some methods require a reflected kernel to use with primatives.
+ * Create the reflected kernel for those methods. */
+ switch ( method ) {
+ case CorrelateMorphology:
+ case CloseMorphology:
+ case CloseIntensityMorphology:
+ case BottomHatMorphology:
+ case SmoothMorphology:
+ reflected_kernel = CloneKernelInfo(kernel);
+ if (reflected_kernel == (KernelInfo *) NULL)
+ goto error_cleanup;
+ RotateKernelInfo(reflected_kernel,180);
+ break;
+ default:
+ break;
+ }
+
+ /* Loop 1: iterate the compound method */
+ method_loop = 0;
+ method_changed = 1;
+ while ( method_loop < method_limit && method_changed > 0 ) {
+ method_loop++;
+ method_changed = 0;
+
+ /* Loop 2: iterate over each kernel in a multi-kernel list */
+ norm_kernel = (KernelInfo *) kernel;
+ this_kernel = (KernelInfo *) kernel;
+ rflt_kernel = reflected_kernel;
+
+ kernel_number = 0;
+ while ( norm_kernel != NULL ) {
+
+ /* Loop 3: Compound Morphology Staging - Select Primative to apply */
+ stage_loop = 0; /* the compound morphology stage number */
+ while ( stage_loop < stage_limit ) {
+ stage_loop++; /* The stage of the compound morphology */
+
+ /* Select primative morphology for this stage of compound method */
+ this_kernel = norm_kernel; /* default use unreflected kernel */
+ primative = method; /* Assume method is a primative */
+ switch( method ) {
+ case ErodeMorphology: /* just erode */
+ case EdgeInMorphology: /* erode and image difference */
+ primative = ErodeMorphology;
+ break;
+ case DilateMorphology: /* just dilate */
+ case EdgeOutMorphology: /* dilate and image difference */
+ primative = DilateMorphology;
+ break;
+ case OpenMorphology: /* erode then dialate */
+ case TopHatMorphology: /* open and image difference */
+ primative = ErodeMorphology;
+ if ( stage_loop == 2 )
+ primative = DilateMorphology;
+ break;
+ case OpenIntensityMorphology:
+ primative = ErodeIntensityMorphology;
+ if ( stage_loop == 2 )
+ primative = DilateIntensityMorphology;
+ break;
+ case CloseMorphology: /* dilate, then erode */
+ case BottomHatMorphology: /* close and image difference */
+ this_kernel = rflt_kernel; /* use the reflected kernel */
+ primative = DilateMorphology;
+ if ( stage_loop == 2 )
+ primative = ErodeMorphology;
+ break;
+ case CloseIntensityMorphology:
+ this_kernel = rflt_kernel; /* use the reflected kernel */
+ primative = DilateIntensityMorphology;
+ if ( stage_loop == 2 )
+ primative = ErodeIntensityMorphology;
+ break;
+ case SmoothMorphology: /* open, close */
+ switch ( stage_loop ) {
+ case 1: /* start an open method, which starts with Erode */
+ primative = ErodeMorphology;
+ break;
+ case 2: /* now Dilate the Erode */
+ primative = DilateMorphology;
+ break;
+ case 3: /* Reflect kernel a close */
+ this_kernel = rflt_kernel; /* use the reflected kernel */
+ primative = DilateMorphology;
+ break;
+ case 4: /* Finish the Close */
+ this_kernel = rflt_kernel; /* use the reflected kernel */
+ primative = ErodeMorphology;
+ break;
+ }
+ break;
+ case EdgeMorphology: /* dilate and erode difference */
+ primative = DilateMorphology;
+ if ( stage_loop == 2 ) {
+ save_image = curr_image; /* save the image difference */
+ curr_image = (Image *) image;
+ primative = ErodeMorphology;
+ }
+ break;
+ case CorrelateMorphology:
+ /* A Correlation is a Convolution with a reflected kernel.
+ ** However a Convolution is a weighted sum using a reflected
+ ** kernel. It may seem stange to convert a Correlation into a
+ ** Convolution as the Correlation is the simplier method, but
+ ** Convolution is much more commonly used, and it makes sense to
+ ** implement it directly so as to avoid the need to duplicate the
+ ** kernel when it is not required (which is typically the
+ ** default).
+ */
+ this_kernel = rflt_kernel; /* use the reflected kernel */
+ primative = ConvolveMorphology;
+ break;
+ default:
+ break;
+ }
+ assert( this_kernel != (KernelInfo *) NULL );
+
+ /* Extra information for debugging compound operations */
+ if ( verbose == MagickTrue ) {
+ if ( stage_limit > 1 )
+ (void) FormatMagickString(v_info,MaxTextExtent,"%s:%.20g.%.20g -> ",
+ MagickOptionToMnemonic(MagickMorphologyOptions,method),(double)
+ method_loop,(double) stage_loop);
+ else if ( primative != method )
+ (void) FormatMagickString(v_info, MaxTextExtent, "%s:%.20g -> ",
+ MagickOptionToMnemonic(MagickMorphologyOptions, method),(double)
+ method_loop);
+ else
+ v_info[0] = '\0';
+ }
+
+ /* Loop 4: Iterate the kernel with primative */
+ kernel_loop = 0;
+ kernel_changed = 0;
+ changed = 1;
+ while ( kernel_loop < kernel_limit && changed > 0 ) {
+ kernel_loop++; /* the iteration of this kernel */
+
+ /* Create a destination image, if not yet defined */
+ if ( work_image == (Image *) NULL )
+ {
+ work_image=CloneImage(image,0,0,MagickTrue,exception);
+ if (work_image == (Image *) NULL)
+ goto error_cleanup;
+ if (SetImageStorageClass(work_image,DirectClass) == MagickFalse)
+ {
+ InheritException(exception,&work_image->exception);
+ goto error_cleanup;
+ }
+ }
+
+ /* APPLY THE MORPHOLOGICAL PRIMITIVE (curr -> work) */
+ count++;
+ changed = MorphologyPrimitive(curr_image, work_image, primative,
+ channel, this_kernel, bias, exception);
+ kernel_changed += changed;
+ method_changed += changed;
+
+ if ( verbose == MagickTrue ) {
+ if ( kernel_loop > 1 )
+ fprintf(stderr, "\n"); /* add end-of-line from previous */
+ (void) fprintf(stderr, "%s%s%s:%.20g.%.20g #%.20g => Changed %.20g",
+ v_info,MagickOptionToMnemonic(MagickMorphologyOptions,
+ primative),(this_kernel == rflt_kernel ) ? "*" : "",
+ (double) (method_loop+kernel_loop-1),(double) kernel_number,
+ (double) count,(double) changed);
+ }
+ /* prepare next loop */
+ { Image *tmp = work_image; /* swap images for iteration */
+ work_image = curr_image;
+ curr_image = tmp;
+ }
+ if ( work_image == image )
+ work_image = (Image *) NULL; /* replace input 'image' */
+
+ } /* End Loop 4: Iterate the kernel with primative */
- morphology_image=MorphologyImageChannel(image,DefaultChannels,method,
- iterations,kernel,exception);
- return(morphology_image);
-}
+ if ( verbose == MagickTrue && kernel_changed != changed )
+ fprintf(stderr, " Total %.20g",(double) kernel_changed);
+ if ( verbose == MagickTrue && stage_loop < stage_limit )
+ fprintf(stderr, "\n"); /* add end-of-line before looping */
+#if 0
+ fprintf(stderr, "--E-- image=0x%lx\n", (unsigned long)image);
+ fprintf(stderr, " curr =0x%lx\n", (unsigned long)curr_image);
+ fprintf(stderr, " work =0x%lx\n", (unsigned long)work_image);
+ fprintf(stderr, " save =0x%lx\n", (unsigned long)save_image);
+ fprintf(stderr, " union=0x%lx\n", (unsigned long)rslt_image);
+#endif
-MagickExport Image *MorphologyImageChannel(const Image *image, const
- ChannelType channel, const MorphologyMethod method, const long
- iterations, const KernelInfo *kernel, ExceptionInfo *exception)
-{
- long
- count;
+ } /* End Loop 3: Primative (staging) Loop for Coumpound Methods */
- Image
- *new_image,
- *old_image,
- *grad_image;
+ /* Final Post-processing for some Compound Methods
+ **
+ ** The removal of any 'Sync' channel flag in the Image Compositon
+ ** below ensures the methematical compose method is applied in a
+ ** purely mathematical way, and only to the selected channels.
+ ** Turn off SVG composition 'alpha blending'.
+ */
+ switch( method ) {
+ case EdgeOutMorphology:
+ case EdgeInMorphology:
+ case TopHatMorphology:
+ case BottomHatMorphology:
+ if ( verbose == MagickTrue )
+ fprintf(stderr, "\n%s: Difference with original image",
+ MagickOptionToMnemonic(MagickMorphologyOptions, method) );
+ (void) CompositeImageChannel(curr_image,
+ (ChannelType) (channel & ~SyncChannels),
+ DifferenceCompositeOp, image, 0, 0);
+ break;
+ case EdgeMorphology:
+ if ( verbose == MagickTrue )
+ fprintf(stderr, "\n%s: Difference of Dilate and Erode",
+ MagickOptionToMnemonic(MagickMorphologyOptions, method) );
+ (void) CompositeImageChannel(curr_image,
+ (ChannelType) (channel & ~SyncChannels),
+ DifferenceCompositeOp, save_image, 0, 0);
+ save_image = DestroyImage(save_image); /* finished with save image */
+ break;
+ default:
+ break;
+ }
+
+ /* multi-kernel handling: re-iterate, or compose results */
+ if ( kernel->next == (KernelInfo *) NULL )
+ rslt_image = curr_image; /* just return the resulting image */
+ else if ( rslt_compose == NoCompositeOp )
+ { if ( verbose == MagickTrue ) {
+ if ( this_kernel->next != (KernelInfo *) NULL )
+ fprintf(stderr, " (re-iterate)");
+ else
+ fprintf(stderr, " (done)");
+ }
+ rslt_image = curr_image; /* return result, and re-iterate */
+ }
+ else if ( rslt_image == (Image *) NULL)
+ { if ( verbose == MagickTrue )
+ fprintf(stderr, " (save for compose)");
+ rslt_image = curr_image;
+ curr_image = (Image *) image; /* continue with original image */
+ }
+ else
+ { /* add the new 'current' result to the composition
+ **
+ ** The removal of any 'Sync' channel flag in the Image Compositon
+ ** below ensures the methematical compose method is applied in a
+ ** purely mathematical way, and only to the selected channels.
+ ** Turn off SVG composition 'alpha blending'.
+ **
+ ** The compose image order is specifically so that the new image can
+ ** be subtarcted 'Minus' from the collected result, to allow you to
+ ** convert a HitAndMiss methd into a Thinning method.
+ */
+ if ( verbose == MagickTrue )
+ fprintf(stderr, " (compose \"%s\")",
+ MagickOptionToMnemonic(MagickComposeOptions, rslt_compose) );
+ (void) CompositeImageChannel(curr_image,
+ (ChannelType) (channel & ~SyncChannels), rslt_compose,
+ rslt_image, 0, 0);
+ rslt_image = DestroyImage(rslt_image);
+ rslt_image = curr_image;
+ curr_image = (Image *) image; /* continue with original image */
+ }
+ if ( verbose == MagickTrue )
+ fprintf(stderr, "\n");
+
+ /* loop to the next kernel in a multi-kernel list */
+ norm_kernel = norm_kernel->next;
+ if ( rflt_kernel != (KernelInfo *) NULL )
+ rflt_kernel = rflt_kernel->next;
+ kernel_number++;
+ } /* End Loop 2: Loop over each kernel */
+
+ } /* End Loop 1: compound method interation */
+
+ goto exit_cleanup;
+
+ /* Yes goto's are bad, but it makes cleanup lot more efficient */
+error_cleanup:
+ if ( curr_image != (Image *) NULL &&
+ curr_image != rslt_image &&
+ curr_image != image )
+ curr_image = DestroyImage(curr_image);
+ if ( rslt_image != (Image *) NULL )
+ rslt_image = DestroyImage(rslt_image);
+exit_cleanup:
+ if ( curr_image != (Image *) NULL &&
+ curr_image != rslt_image &&
+ curr_image != image )
+ curr_image = DestroyImage(curr_image);
+ if ( work_image != (Image *) NULL )
+ work_image = DestroyImage(work_image);
+ if ( save_image != (Image *) NULL )
+ save_image = DestroyImage(save_image);
+ if ( reflected_kernel != (KernelInfo *) NULL )
+ reflected_kernel = DestroyKernelInfo(reflected_kernel);
+ return(rslt_image);
+}
+\f
+/*
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% %
+% %
+% %
+% M o r p h o l o g y I m a g e C h a n n e l %
+% %
+% %
+% %
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%
+% MorphologyImageChannel() applies a user supplied kernel to the image
+% according to the given mophology method.
+%
+% This function applies any and all user defined settings before calling
+% the above internal function MorphologyApply().
+%
+% User defined settings include...
+% * Output Bias for Convolution and correlation ("-bias")
+% * Kernel Scale/normalize settings ("-set 'option:convolve:scale'")
+% This can also includes the addition of a scaled unity kernel.
+% * Show Kernel being applied ("-set option:showkernel 1")
+%
+% The format of the MorphologyImage method is:
+%
+% Image *MorphologyImage(const Image *image,MorphologyMethod method,
+% const ssize_t iterations,KernelInfo *kernel,ExceptionInfo *exception)
+%
+% Image *MorphologyImageChannel(const Image *image, const ChannelType
+% channel,MorphologyMethod method,const ssize_t iterations,
+% KernelInfo *kernel,ExceptionInfo *exception)
+%
+% A description of each parameter follows:
+%
+% o image: the image.
+%
+% o method: the morphology method to be applied.
+%
+% o iterations: apply the operation this many times (or no change).
+% A value of -1 means loop until no change found.
+% How this is applied may depend on the morphology method.
+% Typically this is a value of 1.
+%
+% o channel: the channel type.
+%
+% o kernel: An array of double representing the morphology kernel.
+% Warning: kernel may be normalized for the Convolve method.
+%
+% o exception: return any errors or warnings in this structure.
+%
+*/
+MagickExport Image *MorphologyImageChannel(const Image *image,
+ const ChannelType channel,const MorphologyMethod method,
+ const ssize_t iterations,const KernelInfo *kernel,ExceptionInfo *exception)
+{
const char
*artifact;
- unsigned long
- changed,
- limit;
-
KernelInfo
*curr_kernel;
- MorphologyMethod
- curr_method;
+ CompositeOperator
+ compose;
- assert(image != (Image *) NULL);
- assert(image->signature == MagickSignature);
- assert(kernel != (KernelInfo *) NULL);
- assert(kernel->signature == MagickSignature);
- assert(exception != (ExceptionInfo *) NULL);
- assert(exception->signature == MagickSignature);
+ Image
+ *morphology_image;
- if ( iterations == 0 )
- return((Image *)NULL); /* null operation - nothing to do! */
- /* kernel must be valid at this point
- * (except maybe for posible future morphology methods like "Prune"
+ /* Apply Convolve/Correlate Normalization and Scaling Factors.
+ * This is done BEFORE the ShowKernelInfo() function is called so that
+ * users can see the results of the 'option:convolve:scale' option.
*/
- assert(kernel != (KernelInfo *)NULL);
-
- count = 0; /* interation count */
- changed = 1; /* if compound method assume image was changed */
- curr_kernel = (KernelInfo *)kernel; /* allow kernel and method */
- curr_method = method; /* to be changed as nessary */
-
- limit = (unsigned long) iterations;
- if ( iterations < 0 )
- limit = image->columns > image->rows ? image->columns : image->rows;
-
- /* Third-level morphology methods */
- grad_image=(Image *) NULL;
- switch( curr_method ) {
- case EdgeMorphology:
- grad_image = MorphologyImageChannel(image, channel,
- DilateMorphology, iterations, curr_kernel, exception);
- /* FALL-THRU */
- case EdgeInMorphology:
- curr_method = ErodeMorphology;
- break;
- case EdgeOutMorphology:
- curr_method = DilateMorphology;
- break;
- case TopHatMorphology:
- curr_method = OpenMorphology;
- break;
- case BottomHatMorphology:
- curr_method = CloseMorphology;
- break;
- default:
- break; /* not a third-level method */
- }
-
- /* Second-level morphology methods */
- switch( curr_method ) {
- case OpenMorphology:
- /* Open is a Erode then a Dilate without reflection */
- new_image = MorphologyImageChannel(image, channel,
- ErodeMorphology, iterations, curr_kernel, exception);
- if (new_image == (Image *) NULL)
- return((Image *) NULL);
- curr_method = DilateMorphology;
- break;
- case OpenIntensityMorphology:
- new_image = MorphologyImageChannel(image, channel,
- ErodeIntensityMorphology, iterations, curr_kernel, exception);
- if (new_image == (Image *) NULL)
- return((Image *) NULL);
- curr_method = DilateIntensityMorphology;
- break;
-
- case CloseMorphology:
- /* Close is a Dilate then Erode using reflected kernel */
- /* A reflected kernel is needed for a Close */
- if ( curr_kernel == kernel )
- curr_kernel = CloneKernelInfo(kernel);
- RotateKernelInfo(curr_kernel,180);
- new_image = MorphologyImageChannel(image, channel,
- DilateMorphology, iterations, curr_kernel, exception);
- if (new_image == (Image *) NULL)
- return((Image *) NULL);
- curr_method = ErodeMorphology;
- break;
- case CloseIntensityMorphology:
- /* A reflected kernel is needed for a Close */
- if ( curr_kernel == kernel )
- curr_kernel = CloneKernelInfo(kernel);
- RotateKernelInfo(curr_kernel,180);
- new_image = MorphologyImageChannel(image, channel,
- DilateIntensityMorphology, iterations, curr_kernel, exception);
- if (new_image == (Image *) NULL)
- return((Image *) NULL);
- curr_method = ErodeIntensityMorphology;
- break;
-
- case CorrelateMorphology:
- /* A Correlation is actually a Convolution with a reflected kernel.
- ** However a Convolution is a weighted sum with a reflected kernel.
- ** It may seem stange to convert a Correlation into a Convolution
- ** as the Correleation is the simplier method, but Convolution is
- ** much more commonly used, and it makes sense to implement it directly
- ** so as to avoid the need to duplicate the kernel when it is not
- ** required (which is typically the default).
- */
- if ( curr_kernel == kernel )
- curr_kernel = CloneKernelInfo(kernel);
- RotateKernelInfo(curr_kernel,180);
- curr_method = ConvolveMorphology;
- /* FALL-THRU into Correlate (weigthed sum without reflection) */
-
- case ConvolveMorphology:
- /* Scale or Normalize kernel, according to user wishes
- ** before using it for the Convolve/Correlate method.
- **
- ** FUTURE: provide some way for internal functions to disable
- ** user bias and scaling effects.
- */
+ curr_kernel = (KernelInfo *) kernel;
+ if ( method == ConvolveMorphology || method == CorrelateMorphology )
+ {
artifact = GetImageArtifact(image,"convolve:scale");
- if ( artifact != (char *)NULL ) {
- MagickStatusType
- flags;
- GeometryInfo
- args;
-
+ if ( artifact != (const char *)NULL ) {
if ( curr_kernel == kernel )
curr_kernel = CloneKernelInfo(kernel);
-
- args.rho = 1.0;
- flags = ParseGeometry(artifact, &args);
- ScaleKernelInfo(curr_kernel, args.rho, flags);
- }
- /* FALL-THRU to do the first, and typically the only iteration */
-
- default:
- /* Do a single iteration using the Low-Level Morphology method!
- ** This ensures a "new_image" has been generated, but allows us to skip
- ** the creation of 'old_image' if no more iterations are needed.
- **
- ** The "curr_method" should also be set to a low-level method that is
- ** understood by the MorphologyApply() internal function.
- */
- new_image=CloneImage(image,0,0,MagickTrue,exception);
- if (new_image == (Image *) NULL)
- return((Image *) NULL);
- if (SetImageStorageClass(new_image,DirectClass) == MagickFalse)
- {
- InheritException(exception,&new_image->exception);
- new_image=DestroyImage(new_image);
+ if (curr_kernel == (KernelInfo *) NULL) {
+ curr_kernel=DestroyKernelInfo(curr_kernel);
return((Image *) NULL);
}
- changed = MorphologyApply(image,new_image,curr_method,channel,curr_kernel,
- exception);
- count++;
- if ( GetImageArtifact(image,"verbose") != (const char *) NULL )
- fprintf(stderr, "Morphology %s:%ld => Changed %lu\n",
- MagickOptionToMnemonic(MagickMorphologyOptions, curr_method),
- count, changed);
- break;
- }
+ ScaleGeometryKernelInfo(curr_kernel, artifact);
+ }
+ }
- /* At this point the "curr_method" should not only be set to a low-level
- ** method that is understood by the MorphologyApply() internal function,
- ** but "new_image" should now be defined, as the image to apply the
- ** "curr_method" to.
- */
+ /* display the (normalized) kernel via stderr */
+ artifact = GetImageArtifact(image,"showkernel");
+ if ( artifact == (const char *) NULL)
+ artifact = GetImageArtifact(image,"convolve:showkernel");
+ if ( artifact == (const char *) NULL)
+ artifact = GetImageArtifact(image,"morphology:showkernel");
+ if ( artifact != (const char *) NULL)
+ ShowKernelInfo(curr_kernel);
+
+ /* Override the default handling of multi-kernel morphology results
+ * If 'Undefined' use the default method
+ * If 'None' (default for 'Convolve') re-iterate previous result
+ * Otherwise merge resulting images using compose method given.
+ * Default for 'HitAndMiss' is 'Lighten'.
+ */
+ compose = UndefinedCompositeOp; /* use default for method */
+ artifact = GetImageArtifact(image,"morphology:compose");
+ if ( artifact != (const char *) NULL)
+ compose = (CompositeOperator) ParseMagickOption(
+ MagickComposeOptions,MagickFalse,artifact);
- /* Repeat the low-level morphology until count or no change reached */
- if ( count < (long) limit && changed > 0 ) {
- old_image = CloneImage(new_image,0,0,MagickTrue,exception);
- if (old_image == (Image *) NULL)
- return(DestroyImage(new_image));
- if (SetImageStorageClass(old_image,DirectClass) == MagickFalse)
- {
- InheritException(exception,&old_image->exception);
- old_image=DestroyImage(old_image);
- return(DestroyImage(new_image));
- }
- while( count < (long) limit && changed != 0 )
- {
- Image *tmp = old_image;
- old_image = new_image;
- new_image = tmp;
- changed = MorphologyApply(old_image,new_image,curr_method,channel,
- curr_kernel, exception);
- count++;
- if ( GetImageArtifact(image,"verbose") != (const char *) NULL )
- fprintf(stderr, "Morphology %s:%ld => Changed %lu\n",
- MagickOptionToMnemonic(MagickMorphologyOptions, curr_method),
- count, changed);
- }
- old_image=DestroyImage(old_image);
- }
+ /* Apply the Morphology */
+ morphology_image = MorphologyApply(image, channel, method, iterations,
+ curr_kernel, compose, image->bias, exception);
- /* We are finished with kernel - destroy it if we made a clone */
+ /* Cleanup and Exit */
if ( curr_kernel != kernel )
curr_kernel=DestroyKernelInfo(curr_kernel);
+ return(morphology_image);
+}
- /* Third-level Subtractive methods post-processing */
- switch( method ) {
- case EdgeOutMorphology:
- case EdgeInMorphology:
- case TopHatMorphology:
- case BottomHatMorphology:
- /* Get Difference relative to the original image */
- (void) CompositeImageChannel(new_image, channel, DifferenceCompositeOp,
- image, 0, 0);
- break;
- case EdgeMorphology: /* subtract the Erode from a Dilate */
- (void) CompositeImageChannel(new_image, channel, DifferenceCompositeOp,
- grad_image, 0, 0);
- grad_image=DestroyImage(grad_image);
- break;
- default:
- break;
- }
+MagickExport Image *MorphologyImage(const Image *image, const MorphologyMethod
+ method, const ssize_t iterations,const KernelInfo *kernel, ExceptionInfo
+ *exception)
+{
+ Image
+ *morphology_image;
- return(new_image);
+ morphology_image=MorphologyImageChannel(image,DefaultChannels,method,
+ iterations,kernel,exception);
+ return(morphology_image);
}
\f
/*
% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
-% RotateKernelInfo() rotates the kernel by the angle given. Currently it is
-% restricted to 90 degree angles, but this may be improved in the future.
+% RotateKernelInfo() rotates the kernel by the angle given.
+%
+% Currently it is restricted to 90 degree angles, of either 1D kernels
+% or square kernels. And 'circular' rotations of 45 degrees for 3x3 kernels.
+% It will ignore usless rotations for specific 'named' built-in kernels.
%
% The format of the RotateKernelInfo method is:
%
%
% o angle: angle to rotate in degrees
%
-% This function is only internel to this module, as it is not finalized,
-% especially with regard to non-orthogonal angles, and rotation of larger
-% 2D kernels.
+% This function is currently internal to this module only, but can be exported
+% to other modules if needed.
*/
static void RotateKernelInfo(KernelInfo *kernel, double angle)
{
+ /* angle the lower kernels first */
+ if ( kernel->next != (KernelInfo *) NULL)
+ RotateKernelInfo(kernel->next, angle);
+
/* WARNING: Currently assumes the kernel (rightly) is horizontally symetrical
**
** TODO: expand beyond simple 90 degree rotates, flips and flops
if ( angle < 0 )
angle += 360.0;
- if ( 315.0 < angle || angle <= 45.0 )
- return; /* no change! - At least at this time */
+ if ( 337.5 < angle || angle <= 22.5 )
+ return; /* Near zero angle - no change! - At least not at this time */
+ /* Handle special cases */
switch (kernel->type) {
/* These built-in kernels are cylindrical kernels, rotating is useless */
case GaussianKernel:
- case LaplacianKernel:
- case LOGKernel:
- case DOGKernel:
+ case DoGKernel:
+ case LoGKernel:
case DiskKernel:
+ case PeaksKernel:
+ case LaplacianKernel:
case ChebyshevKernel:
- case ManhattenKernel:
+ case ManhattanKernel:
case EuclideanKernel:
return;
case SquareKernel:
case DiamondKernel:
case PlusKernel:
+ case CrossKernel:
return;
/* These only allows a +/-90 degree rotation (by transpose) */
angle -= 180;
break;
- /* these are freely rotatable in 90 degree units */
- case CometKernel:
- case UndefinedKernel:
- case UserDefinedKernel:
+ default:
break;
}
+ /* Attempt rotations by 45 degrees */
+ if ( 22.5 < fmod(angle,90.0) && fmod(angle,90.0) <= 67.5 )
+ {
+ if ( kernel->width == 3 && kernel->height == 3 )
+ { /* Rotate a 3x3 square by 45 degree angle */
+ MagickRealType t = kernel->values[0];
+ kernel->values[0] = kernel->values[3];
+ kernel->values[3] = kernel->values[6];
+ kernel->values[6] = kernel->values[7];
+ kernel->values[7] = kernel->values[8];
+ kernel->values[8] = kernel->values[5];
+ kernel->values[5] = kernel->values[2];
+ kernel->values[2] = kernel->values[1];
+ kernel->values[1] = t;
+ /* rotate non-centered origin */
+ if ( kernel->x != 1 || kernel->y != 1 ) {
+ ssize_t x,y;
+ x = (ssize_t) kernel->x-1;
+ y = (ssize_t) kernel->y-1;
+ if ( x == y ) x = 0;
+ else if ( x == 0 ) x = -y;
+ else if ( x == -y ) y = 0;
+ else if ( y == 0 ) y = x;
+ kernel->x = (ssize_t) x+1;
+ kernel->y = (ssize_t) y+1;
+ }
+ angle = fmod(angle+315.0, 360.0); /* angle reduced 45 degrees */
+ kernel->angle = fmod(kernel->angle+45.0, 360.0);
+ }
+ else
+ perror("Unable to rotate non-3x3 kernel by 45 degrees");
+ }
+ if ( 45.0 < fmod(angle, 180.0) && fmod(angle,180.0) <= 135.0 )
+ {
+ if ( kernel->width == 1 || kernel->height == 1 )
+ { /* Do a transpose of a 1 dimentional kernel,
+ ** which results in a fast 90 degree rotation of some type.
+ */
+ ssize_t
+ t;
+ t = (ssize_t) kernel->width;
+ kernel->width = kernel->height;
+ kernel->height = (size_t) t;
+ t = kernel->x;
+ kernel->x = kernel->y;
+ kernel->y = t;
+ if ( kernel->width == 1 ) {
+ angle = fmod(angle+270.0, 360.0); /* angle reduced 90 degrees */
+ kernel->angle = fmod(kernel->angle+90.0, 360.0);
+ } else {
+ angle = fmod(angle+90.0, 360.0); /* angle increased 90 degrees */
+ kernel->angle = fmod(kernel->angle+270.0, 360.0);
+ }
+ }
+ else if ( kernel->width == kernel->height )
+ { /* Rotate a square array of values by 90 degrees */
+ { register size_t
+ i,j,x,y;
+ register MagickRealType
+ *k,t;
+ k=kernel->values;
+ for( i=0, x=kernel->width-1; i<=x; i++, x--)
+ for( j=0, y=kernel->height-1; j<y; j++, y--)
+ { t = k[i+j*kernel->width];
+ k[i+j*kernel->width] = k[j+x*kernel->width];
+ k[j+x*kernel->width] = k[x+y*kernel->width];
+ k[x+y*kernel->width] = k[y+i*kernel->width];
+ k[y+i*kernel->width] = t;
+ }
+ }
+ /* rotate the origin - relative to center of array */
+ { register ssize_t x,y;
+ x = (ssize_t) (kernel->x*2-kernel->width+1);
+ y = (ssize_t) (kernel->y*2-kernel->height+1);
+ kernel->x = (ssize_t) ( -y +(ssize_t) kernel->width-1)/2;
+ kernel->y = (ssize_t) ( +x +(ssize_t) kernel->height-1)/2;
+ }
+ angle = fmod(angle+270.0, 360.0); /* angle reduced 90 degrees */
+ kernel->angle = fmod(kernel->angle+90.0, 360.0);
+ }
+ else
+ perror("Unable to rotate a non-square, non-linear kernel 90 degrees");
+ }
if ( 135.0 < angle && angle <= 225.0 )
{
- /* For a 180 degree rotation - also know as a reflection */
- /* This is actually a very very common operation! */
- /* Basically all that is needed is a reversal of the kernel data! */
- unsigned long
+ /* For a 180 degree rotation - also know as a reflection
+ * This is actually a very very common operation!
+ * Basically all that is needed is a reversal of the kernel data!
+ * And a reflection of the origon
+ */
+ size_t
i,j;
register double
*k,t;
for ( i=0, j=kernel->width*kernel->height-1; i<j; i++, j--)
t=k[i], k[i]=k[j], k[j]=t;
- kernel->x = (long) kernel->width - kernel->x - 1;
- kernel->y = (long) kernel->height - kernel->y - 1;
- angle = fmod(angle+180.0, 360.0);
- }
- if ( 45.0 < angle && angle <= 135.0 )
- { /* Do a transpose and a flop, of the image, which results in a 90
- * degree rotation using two mirror operations.
- *
- * WARNING: this assumes the original image was a 1 dimentional image
- * but currently that is the only built-ins it is applied to.
- */
- long
- t;
- t = (long) kernel->width;
- kernel->width = kernel->height;
- kernel->height = (unsigned long) t;
- t = kernel->x;
- kernel->x = kernel->y;
- kernel->y = t;
- angle = fmod(450.0 - angle, 360.0);
+ kernel->x = (ssize_t) kernel->width - kernel->x - 1;
+ kernel->y = (ssize_t) kernel->height - kernel->y - 1;
+ angle = fmod(angle-180.0, 360.0); /* angle+180 degrees */
+ kernel->angle = fmod(kernel->angle+180.0, 360.0);
}
- /* At this point angle should be between -45 (315) and +45 degrees
+ /* At this point angle should at least between -45 (315) and +45 degrees
* In the future some form of non-orthogonal angled rotates could be
* performed here, posibily with a linear kernel restriction.
*/
-#if 0
- Not currently in use!
- { /* Do a flop, this assumes kernel is horizontally symetrical.
- * Each row of the kernel needs to be reversed!
- */
- unsigned long
- y;
- register long
- x,r;
- register double
- *k,t;
+ return;
+}
+\f
+/*
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% %
+% %
+% %
+% S c a l e G e o m e t r y K e r n e l I n f o %
+% %
+% %
+% %
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%
+% ScaleGeometryKernelInfo() takes a geometry argument string, typically
+% provided as a "-set option:convolve:scale {geometry}" user setting,
+% and modifies the kernel according to the parsed arguments of that setting.
+%
+% The first argument (and any normalization flags) are passed to
+% ScaleKernelInfo() to scale/normalize the kernel. The second argument
+% is then passed to UnityAddKernelInfo() to add a scled unity kernel
+% into the scaled/normalized kernel.
+%
+% The format of the ScaleKernelInfo method is:
+%
+% void ScaleKernelInfo(KernelInfo *kernel, const double scaling_factor,
+% const MagickStatusType normalize_flags )
+%
+% A description of each parameter follows:
+%
+% o kernel: the Morphology/Convolution kernel to modify
+%
+% o geometry:
+% The geometry string to parse, typically from the user provided
+% "-set option:convolve:scale {geometry}" setting.
+%
+*/
+MagickExport void ScaleGeometryKernelInfo (KernelInfo *kernel,
+ const char *geometry)
+{
+ GeometryFlags
+ flags;
+ GeometryInfo
+ args;
- for ( y=0, k=kernel->values; y < kernel->height; y++, k+=kernel->width)
- for ( x=0, r=kernel->width-1; x<kernel->width/2; x++, r--)
- t=k[x], k[x]=k[r], k[r]=t;
+ SetGeometryInfo(&args);
+ flags = (GeometryFlags) ParseGeometry(geometry, &args);
- kernel->x = kernel->width - kernel->x - 1;
- angle = fmod(angle+180.0, 360.0);
- }
+#if 0
+ /* For Debugging Geometry Input */
+ fprintf(stderr, "Geometry = 0x%04X : %lg x %lg %+lg %+lg\n",
+ flags, args.rho, args.sigma, args.xi, args.psi );
#endif
+
+ if ( (flags & PercentValue) != 0 ) /* Handle Percentage flag*/
+ args.rho *= 0.01, args.sigma *= 0.01;
+
+ if ( (flags & RhoValue) == 0 ) /* Set Defaults for missing args */
+ args.rho = 1.0;
+ if ( (flags & SigmaValue) == 0 )
+ args.sigma = 0.0;
+
+ /* Scale/Normalize the input kernel */
+ ScaleKernelInfo(kernel, args.rho, flags);
+
+ /* Add Unity Kernel, for blending with original */
+ if ( (flags & SigmaValue) != 0 )
+ UnityAddKernelInfo(kernel, args.sigma);
+
return;
}
-\f
/*
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
% %
% %
% %
-+ S c a l e K e r n e l I n f o %
+% S c a l e K e r n e l I n f o %
% %
% %
% %
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%
-% ScaleKernelInfo() scales the kernel by the given amount, with or without
-% normalization of the sum of the kernel values.
+% ScaleKernelInfo() scales the given kernel list by the given amount, with or
+% without normalization of the sum of the kernel values (as per given flags).
%
% By default (no flags given) the values within the kernel is scaled
-% according the given scaling factor.
+% directly using given scaling factor without change.
%
-% If any 'normalize_flags' are given the kernel will be normalized and then
-% further scaled by the scaleing factor value given. A 'PercentValue' flag
-% will cause the given scaling factor to be divided by one hundred percent.
+% If either of the two 'normalize_flags' are given the kernel will first be
+% normalized and then further scaled by the scaling factor value given.
%
% Kernel normalization ('normalize_flags' given) is designed to ensure that
% any use of the kernel scaling factor with 'Convolve' or 'Correlate'
-% morphology methods will fall into -1.0 to +1.0 range. Note however that
-% for non-HDRI versions of IM this may cause images to have any negative
-% results clipped, unless some 'clip' any negative output from 'Convolve'
-% with the use of some kernels.
+% morphology methods will fall into -1.0 to +1.0 range. Note that for
+% non-HDRI versions of IM this may cause images to have any negative results
+% clipped, unless some 'bias' is used.
%
% More specifically. Kernels which only contain positive values (such as a
% 'Gaussian' kernel) will be scaled so that those values sum to +1.0,
-% ensuring a 0.0 to +1.0 convolution output range for non-HDRI images.
+% ensuring a 0.0 to +1.0 output range for non-HDRI images.
%
% For Kernels that contain some negative values, (such as 'Sharpen' kernels)
% the kernel will be scaled by the absolute of the sum of kernel values, so
% values seperatally to those of the negative values, so the kernel will be
% forced to become a zero-sum kernel better suited to such searches.
%
-% WARNING: Correct normalization of the kernal assumes that the '*_range'
+% WARNING: Correct normalization of the kernel assumes that the '*_range'
% attributes within the kernel structure have been correctly set during the
% kernels creation.
%
% NOTE: The values used for 'normalize_flags' have been selected specifically
% to match the use of geometry options, so that '!' means NormalizeValue, '^'
-% means CorrelateNormalizeValue, and '%' means PercentValue. All other
-% GeometryFlags values are ignored.
+% means CorrelateNormalizeValue. All other GeometryFlags values are ignored.
%
% The format of the ScaleKernelInfo method is:
%
% specifically: NormalizeValue, CorrelateNormalizeValue,
% and/or PercentValue
%
-% This function is internal to this module only at this time, but can be
-% exported to other modules if needed.
*/
-static void ScaleKernelInfo(KernelInfo *kernel, const double scaling_factor,
- const GeometryFlags normalize_flags)
+MagickExport void ScaleKernelInfo(KernelInfo *kernel,
+ const double scaling_factor,const GeometryFlags normalize_flags)
{
- register long
+ register ssize_t
i;
register double
pos_scale,
neg_scale;
+ /* do the other kernels in a multi-kernel list first */
+ if ( kernel->next != (KernelInfo *) NULL)
+ ScaleKernelInfo(kernel->next, scaling_factor, normalize_flags);
+
+ /* Normalization of Kernel */
pos_scale = 1.0;
if ( (normalize_flags&NormalizeValue) != 0 ) {
- /* normalize kernel appropriately */
if ( fabs(kernel->positive_range + kernel->negative_range) > MagickEpsilon )
+ /* non-zero-summing kernel (generally positive) */
pos_scale = fabs(kernel->positive_range + kernel->negative_range);
else
- pos_scale = kernel->positive_range; /* special zero-summing kernel */
+ /* zero-summing kernel */
+ pos_scale = kernel->positive_range;
}
- /* force kernel into being a normalized zero-summing kernel */
+ /* Force kernel into a normalized zero-summing kernel */
if ( (normalize_flags&CorrelateNormalizeValue) != 0 ) {
pos_scale = ( fabs(kernel->positive_range) > MagickEpsilon )
? kernel->positive_range : 1.0;
/* finialize scaling_factor for positive and negative components */
pos_scale = scaling_factor/pos_scale;
neg_scale = scaling_factor/neg_scale;
- if ( (normalize_flags&PercentValue) != 0 ) {
- pos_scale /= 100.0;
- neg_scale /= 100.0;
- }
- for (i=0; i < (long) (kernel->width*kernel->height); i++)
+ for (i=0; i < (ssize_t) (kernel->width*kernel->height); i++)
if ( ! IsNan(kernel->values[i]) )
kernel->values[i] *= (kernel->values[i] >= 0) ? pos_scale : neg_scale;
kernel->maximum *= (kernel->maximum >= 0.0) ? pos_scale : neg_scale;
kernel->minimum *= (kernel->minimum >= 0.0) ? pos_scale : neg_scale;
- /* swap kernel settings if user scaling factor is negative */
+ /* swap kernel settings if user's scaling factor is negative */
if ( scaling_factor < MagickEpsilon ) {
double t;
t = kernel->positive_range;
% %
% %
% %
-+ S h o w K e r n e l I n f o %
+% S h o w K e r n e l I n f o %
% %
% %
% %
%
% o kernel: the Morphology/Convolution kernel
%
-% This function is internal to this module only at this time. That may change
-% in the future.
*/
MagickExport void ShowKernelInfo(KernelInfo *kernel)
{
- long
- i, u, v;
-
- fprintf(stderr,
- "Kernel \"%s\" of size %lux%lu%+ld%+ld with values from %.*lg to %.*lg\n",
- MagickOptionToMnemonic(MagickKernelOptions, kernel->type),
- kernel->width, kernel->height,
- kernel->x, kernel->y,
- GetMagickPrecision(), kernel->minimum,
- GetMagickPrecision(), kernel->maximum);
- fprintf(stderr, "Forming convolution output range from %.*lg to %.*lg%s\n",
- GetMagickPrecision(), kernel->negative_range,
- GetMagickPrecision(), kernel->positive_range,
- /*kernel->normalized == MagickTrue ? " (normalized)" : */ "" );
- for (i=v=0; v < (long) kernel->height; v++) {
- fprintf(stderr,"%2ld:",v);
- for (u=0; u < (long) kernel->width; u++, i++)
- if ( IsNan(kernel->values[i]) )
- fprintf(stderr," %*s", GetMagickPrecision()+2, "nan");
- else
- fprintf(stderr," %*.*lg", GetMagickPrecision()+2,
- GetMagickPrecision(), kernel->values[i]);
- fprintf(stderr,"\n");
+ KernelInfo
+ *k;
+
+ size_t
+ c, i, u, v;
+
+ for (c=0, k=kernel; k != (KernelInfo *) NULL; c++, k=k->next ) {
+
+ fprintf(stderr, "Kernel");
+ if ( kernel->next != (KernelInfo *) NULL )
+ fprintf(stderr, " #%lu", (unsigned long) c );
+ fprintf(stderr, " \"%s",
+ MagickOptionToMnemonic(MagickKernelOptions, k->type) );
+ if ( fabs(k->angle) > MagickEpsilon )
+ fprintf(stderr, "@%lg", k->angle);
+ fprintf(stderr, "\" of size %lux%lu%+ld%+ld",(unsigned long) k->width,
+ (unsigned long) k->height,(long) k->x,(long) k->y);
+ fprintf(stderr,
+ " with values from %.*lg to %.*lg\n",
+ GetMagickPrecision(), k->minimum,
+ GetMagickPrecision(), k->maximum);
+ fprintf(stderr, "Forming a output range from %.*lg to %.*lg",
+ GetMagickPrecision(), k->negative_range,
+ GetMagickPrecision(), k->positive_range);
+ if ( fabs(k->positive_range+k->negative_range) < MagickEpsilon )
+ fprintf(stderr, " (Zero-Summing)\n");
+ else if ( fabs(k->positive_range+k->negative_range-1.0) < MagickEpsilon )
+ fprintf(stderr, " (Normalized)\n");
+ else
+ fprintf(stderr, " (Sum %.*lg)\n",
+ GetMagickPrecision(), k->positive_range+k->negative_range);
+ for (i=v=0; v < k->height; v++) {
+ fprintf(stderr, "%2lu:", (unsigned long) v );
+ for (u=0; u < k->width; u++, i++)
+ if ( IsNan(k->values[i]) )
+ fprintf(stderr," %*s", GetMagickPrecision()+3, "nan");
+ else
+ fprintf(stderr," %*.*lg", GetMagickPrecision()+3,
+ GetMagickPrecision(), k->values[i]);
+ fprintf(stderr,"\n");
+ }
}
}
\f
% %
% %
% %
-+ Z e r o K e r n e l N a n s %
+% U n i t y A d d K e r n a l I n f o %
+% %
+% %
+% %
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+%
+% UnityAddKernelInfo() Adds a given amount of the 'Unity' Convolution Kernel
+% to the given pre-scaled and normalized Kernel. This in effect adds that
+% amount of the original image into the resulting convolution kernel. This
+% value is usually provided by the user as a percentage value in the
+% 'convolve:scale' setting.
+%
+% The resulting effect is to convert the defined kernels into blended
+% soft-blurs, unsharp kernels or into sharpening kernels.
+%
+% The format of the UnityAdditionKernelInfo method is:
+%
+% void UnityAdditionKernelInfo(KernelInfo *kernel, const double scale )
+%
+% A description of each parameter follows:
+%
+% o kernel: the Morphology/Convolution kernel
+%
+% o scale:
+% scaling factor for the unity kernel to be added to
+% the given kernel.
+%
+*/
+MagickExport void UnityAddKernelInfo(KernelInfo *kernel,
+ const double scale)
+{
+ /* do the other kernels in a multi-kernel list first */
+ if ( kernel->next != (KernelInfo *) NULL)
+ UnityAddKernelInfo(kernel->next, scale);
+
+ /* Add the scaled unity kernel to the existing kernel */
+ kernel->values[kernel->x+kernel->y*kernel->width] += scale;
+ CalcKernelMetaData(kernel); /* recalculate the meta-data */
+
+ return;
+}
+\f
+/*
+%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
+% %
+% %
+% %
+% Z e r o K e r n e l N a n s %
% %
% %
% %
%
% The format of the ZeroKernelNans method is:
%
-% voidZeroKernelNans (KernelInfo *kernel)
+% void ZeroKernelNans (KernelInfo *kernel)
%
% A description of each parameter follows:
%
% o kernel: the Morphology/Convolution kernel
%
-% FUTURE: return the information in a string for API usage.
*/
MagickExport void ZeroKernelNans(KernelInfo *kernel)
{
- register long
+ register size_t
i;
- for (i=0; i < (long) (kernel->width*kernel->height); i++)
+ /* do the other kernels in a multi-kernel list first */
+ if ( kernel->next != (KernelInfo *) NULL)
+ ZeroKernelNans(kernel->next);
+
+ for (i=0; i < (kernel->width*kernel->height); i++)
if ( IsNan(kernel->values[i]) )
kernel->values[i] = 0.0;