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|
# HG changeset patch
# User Chris <cspiel@users.sourceforge.net>
# Date 1438958604 -7200
# Node ID 8387f0170f7b352baea887f77960e8066185a6cd
# Parent c1bcd2df4e3724f3bb0414d3a5e2e9302be78921
Get the Texinfo documentation to translate again with makeinfo-5.2.
This patch takes thus care of issue #1181678
https://bugs.launchpad.net/enblend/+bug/1181678
We do not strive for a nicely formatted documentation anymore in the
Stable Branch, because the Development Branch already has a flawless
new documentation *not* based on Texinfo.
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/Makefile.am
--- a/doc/Makefile.am Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/Makefile.am Fri Aug 07 16:43:24 2015 +0200
@@ -46,7 +46,7 @@
-I $(top_builddir) -I $(srcdir) \
--css-include=@srcdir@/default.css \
$(MAKEINFOHTMLFLAGS)
-export TEXINPUTS=$(top_builddir):$(srcdir)
+export TEXINPUTS = .:$(top_builddir):$(srcdir):
TEXI2DVI = texi2dvi $(TEXI2DVIFLAGS) $(EXTRATEXI2DVIFLAGS)
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/auxmac.tex
--- a/doc/auxmac.tex Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/auxmac.tex Fri Aug 07 16:43:24 2015 +0200
@@ -1,13 +1,6 @@
-\input thumbpdf.sty
-
-
% Auxilliary Macros.
%
% Include this file before texinfo.tex!
\def\mathit#1{\hbox{\it #1}}
\def\mathrm#1{\ifmmode{\rm #1}\else #1\fi}
-
-% These definitions are required for older versions of texinfo.tex.
-\def\geq{\ifmmode \ge\else $\ge$\fi}
-\def\leq{\ifmmode \le\else $\le$\fi}
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/auxmac.texi
--- a/doc/auxmac.texi Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/auxmac.texi Fri Aug 07 16:43:24 2015 +0200
@@ -2,16 +2,6 @@
@c Macro Definitions
@c
-@c redefined commands
-
-@c Get the spacing of dimensions right.
-@ifnottex
-@macro dmn{unit}
-@tie{}\unit\
-@end macro
-@end ifnottex
-
-
@c extended commands
@c Add a title to a DocBook element.
@@ -80,73 +70,6 @@
@c Operators
-@c Generate a nice representation of base^exponent.
-@macro power{base, exponent}
-@ifinfo
-\base\^\exponent\
-@end ifinfo
-@html
-\base\<sup>\exponent\</sup>
-@end html
-@tex
-$\base\^{\exponent\}$%
-@end tex
-@docbook
-\base\<superscript>\exponent\</superscript>
-@end docbook
-@end macro
-
-
-@macro classictimes
-@ifinfo
-x@c gobble following newline -- The Tricks of a Texinfo Wizard.
-@end ifinfo
-@html
-×
-@end html
-@tex
-\\ifmmode\\times\\else$\\times$\\fi% gobble following newline -- The Tricks of a TeX Wizard.
-@end tex
-@docbook
-×
-@end docbook
-@end macro
-
-
-@c Required for older versions of makeinfo. The definition of @geq
-@c for TeX lives in auxmac.tex.
-@ifnottex
-@macro geq
-@ifinfo
->=@c
-@end ifinfo
-@html
-≥
-@end html
-@docbook
-≥
-@end docbook
-@end macro
-@end ifnottex
-
-
-@c Required for older versions of makeinfo. The definition of @leq
-@c for TeX lives in auxmac.tex.
-@ifnottex
-@macro leq
-@ifinfo
-<=@c
-@end ifinfo
-@html
-≤
-@end html
-@docbook
-≤
-@end docbook
-@end macro
-@end ifnottex
-
-
@macro plusminus
@ifinfo
+/-@c
@@ -163,62 +86,6 @@
@end macro
-@c Special Characters
-
-@macro inlineomega
-@ifinfo
-@math{omega}@c
-@end ifinfo
-@html
-<mathinline xmlns="http://www.w3.org/1998/Math/MathML" display="inline">
- <mi>ω</mi>
-</mathinline>
-@end html
-@tex
-$\\omega$%
-@end tex
-@docbook
-ω
-@end docbook
-@end macro
-
-
-@macro inlinesigma
-@ifinfo
-@math{sigma}@c
-@end ifinfo
-@html
-<mathinline xmlns="http://www.w3.org/1998/Math/MathML" display="inline">
- <mi>σ</mi>
-</mathinline>
-@end html
-@tex
-$\\sigma$%
-@end tex
-@docbook
-σ
-@end docbook
-@end macro
-
-
-@macro inlinexi
-@ifinfo
-@math{xi}@c
-@end ifinfo
-@html
-<mathinline xmlns="http://www.w3.org/1998/Math/MathML" display="inline">
- <mi>ξ</mi>
-</mathinline>
-@end html
-@tex
-$\\xi$%
-@end tex
-@docbook
-ξ
-@end docbook
-@end macro
-
-
@c Text Fragments
@macro mainpurpose
@@ -236,26 +103,3 @@
@noindent
@strong{Summary of influential options}
@end macro
-
-
-@macro semilog{significant, exponent}
-@ifinfo
-\significant\*10^\exponent\@c
-@end ifinfo
-@html
-<math xmlns="http://www.w3.org/1998/Math/MathML" display="inline">
- <mn>\significant\</mn>
- <mo>×</mo>
- <msup>
- <mn>10</mn>
- <mn>\exponent\</mn>
- </msup>
-</math>
-@end html
-@tex
-\\ifmmode\significant\ \\times 10^{\exponent\}\\else$\significant\ \\times 10^{\exponent\}$\\fi%
-@end tex
-@docbook
-\significant\×10<superscript>\exponent\</superscript>
-@end docbook
-@end macro
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/bug-reports.texi
--- a/doc/bug-reports.texi Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/bug-reports.texi Fri Aug 07 16:43:24 2015 +0200
@@ -77,7 +77,7 @@
@item
A complete set of input images that will reproduce the bug. Strive
for a minimal set of @emph{small}@footnote{Images of a size less than
-1500@classictimes{}1000 pixels qualify as small.} images.
+1500x1000 pixels qualify as small.} images.
@item
The type of machine you are using, and the operating system name and
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/enblend.info
Binary file doc/enblend.info has changed
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/enblend.texi
--- a/doc/enblend.texi Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/enblend.texi Fri Aug 07 16:43:24 2015 +0200
@@ -508,9 +508,9 @@
twice as large as the previous one. So, the zeroth layer, the
original image, obviously defines the image at single-pixel scale, the
first level works at two-pixel scale, and generally, the @math{n}-th
-level contains image data at @power{2, n}-pixel scale. This is the
+level contains image data at 2^n-pixel scale. This is the
reason why an image of
-@math{width}@classictimes{}@/@math{height}@dmn{pixels} cannot be
+@math{width}x@/@math{height}@dmn{pixels} cannot be
deconstructed into a pyramid of more than
@ifinfo
@display
@@ -1194,11 +1194,11 @@
@itemize
@item
-Minimum normalized value: @semilog{1.2, -38}
+Minimum normalized value: 1.2e-38
@item
-Epsilon: @semilog{1.2, -7}
+Epsilon: 1.2e-7
@item
-Maximum finite value: @semilog{3.4, 38}
+Maximum finite value: 3.4e38
@end itemize
@c IEEE double: 64 bits, n = 53, k = 64 - n - 1 = 10
@@ -1210,11 +1210,11 @@
@itemize
@item
-Minimum normalized value: @semilog{2.2, -308}
+Minimum normalized value: 2.2e-308
@item
-Epsilon: @semilog{2.2, -16}
+Epsilon: 2.2e-16
@item
-Maximum finite value: @semilog{1.8, 308}
+Maximum finite value: 1.8e308
@end itemize
@end table
@@ -1236,11 +1236,11 @@
@itemize
@item
-Minimum normalized value: @semilog{9.3, -10}
+Minimum normalized value: 9.3e-10
@item
-Epsilon: @semilog{2.0, -3}
+Epsilon: 2.0e-3
@item
-Maximum finite value: @semilog{4.3, 9}
+Maximum finite value: 4.3e9
@end itemize
@item -f @var{WIDTH}x@var{HEIGHT}
@@ -1250,7 +1250,7 @@
@cindex canvas size
@cindex size, canvas
Ensure that the minimum ``canvas'' size of the output image is at
-least @var{WIDTH}@classictimes{}@/@var{HEIGHT}. Optionally specify
+least @var{WIDTH}x@/@var{HEIGHT}. Optionally specify
the @var{XOFFSET} and @var{YOFFSET}, too.
@pindex nona @r{(Hugin)}
@@ -1572,7 +1572,7 @@
@value{src::default-coarseness-factor}, this means,
option@tie{}@option{--coarse-mask} shrinks the overlapping
@emph{areas} by a factor of
-@math{@value{src::default-coarseness-factor}@classictimes{}@/@value{src::default-coarseness-factor}}.
+@math{@value{src::default-coarseness-factor}x@/@value{src::default-coarseness-factor}}.
With @var{FACTOR}@tie{}=@tie{}8 the total memory allocated during a
run of Enblend shrinks approximately by 80% and the maximum amount of
memory in use at a time is decreased to 60% (Enblend compiled with
@@ -2494,7 +2494,7 @@
When using this option in conjunction with
option@tie{}@code{--coarse-mask}=@/@var{FACTOR}, keep in mind that the
smoothing occurs @emph{after} the overlap regions have been shrunken.
-Thus, blurring affects a @var{FACTOR}@classictimes{}@/@var{FACTOR}
+Thus, blurring affects a @var{FACTOR}x@/@var{FACTOR}
times larger area in the original images.
Valid range: @var{RADIUS} @geq{} @value{src::minimum-smooth-difference}.
@@ -2606,7 +2606,7 @@
@rimage{seam-line-visualization}
@caption{Seam-line visualization of a simple overlap. The
-853@classictimes{}238@dmn{pixel} image is shown at a magification of
+853x238@dmn{pixel} image is shown at a magification of
100%.}
@shortcaption{Seam-line visualization}
@@ -2618,7 +2618,7 @@
@rimage{seam-line-visualization, 15cm}
@caption{Seam-line visualization of a simple overlap. The
-853@classictimes{}238@dmn{pixel} image has been rescaled to a width of
+853x238@dmn{pixel} image has been rescaled to a width of
approximately 15@dmn{cm}.}
@shortcaption{Seam-line visualization}
@@ -2629,7 +2629,7 @@
@float Figure,Figure:seam-line-visualization
@rimage{seam-line-visualization, 15cm}
-@caption{Seam-line visualization of a simple overlap. The 853@classictimes{}238@dmn{pixel} image has been rescaled to a width of approximately 15@dmn{cm}.}
+@caption{Seam-line visualization of a simple overlap. The 853x238@dmn{pixel} image has been rescaled to a width of approximately 15@dmn{cm}.}
@shortcaption{Seam-line visualization}
@end float
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/enfuse.info
Binary file doc/enfuse.info has changed
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/enfuse.texi
--- a/doc/enfuse.texi Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/enfuse.texi Fri Aug 07 16:43:24 2015 +0200
@@ -621,9 +621,9 @@
twice as large as the previous one. So, the zeroth layer, the
original image, obviously defines the image at single-pixel scale, the
first level works at two-pixel scale, and generally, the @math{n}-th
-level contains image data at @power{2, n}-pixel scale. This is the
+level contains image data at 2^n-pixel scale. This is the
reason why an image of
-@math{width}@classictimes{}@/@math{height}@dmn{pixels} cannot be
+@math{width}x@/@math{height}@dmn{pixels} cannot be
deconstructed into a pyramid of more than
@ifinfo
@display
@@ -1255,11 +1255,11 @@
@itemize
@item
-Minimum normalized value: @semilog{1.2, -38}
+Minimum normalized value: 1.2e-38
@item
-Epsilon: @semilog{1.2, -7}
+Epsilon: 1.2e-7
@item
-Maximum finite value: @semilog{3.4, 38}
+Maximum finite value: 3.4e38
@end itemize
@c IEEE double: 64 bits, n = 53, k = 64 - n - 1 = 10
@@ -1271,11 +1271,11 @@
@itemize
@item
-Minimum normalized value: @semilog{2.2, -308}
+Minimum normalized value: 2.2e-308
@item
-Epsilon: @semilog{2.2, -16}
+Epsilon: 2.2e-16
@item
-Maximum finite value: @semilog{1.8, 308}
+Maximum finite value: 1.8e308
@end itemize
@end table
@@ -1297,11 +1297,11 @@
@itemize
@item
-Minimum normalized value: @semilog{9.3, -10}
+Minimum normalized value: 9.3e-10
@item
-Epsilon: @semilog{2.0, -3}
+Epsilon: 2.0e-3
@item
-Maximum finite value: @semilog{4.3, 9}
+Maximum finite value: 4.3e9
@end itemize
@item -f @var{WIDTH}x@var{HEIGHT}
@@ -1311,7 +1311,7 @@
@cindex canvas size
@cindex size, canvas
Ensure that the minimum ``canvas'' size of the output image is at
-least @var{WIDTH}@classictimes{}@/@var{HEIGHT}. Optionally specify
+least @var{WIDTH}x@/@var{HEIGHT}. Optionally specify
the @var{XOFFSET} and @var{YOFFSET}, too.
@pindex nona @r{(Hugin)}
@@ -1501,8 +1501,8 @@
@var{LCE-SCALE} is the radius of the Gaussian used in the enhancement
step, @var{LCE-FACTOR} is the weight factor (``strength'').
-@var{enhanced} = (1 + @var{LCE-FACTOR}) @classictimes{} @var{original}
-@minus{} @var{LCE-FACTOR} @classictimes{} Gaussian@/Smooth(@var{original},
+@var{enhanced} = (1 + @var{LCE-FACTOR}) x @var{original}
+@minus{} @var{LCE-FACTOR} x Gaussian@/Smooth(@var{original},
@var{LCE-SCALE}).
@var{LCE-SCALE} defaults to @value{src::default-lce-scale} pixels and
@@ -1531,7 +1531,7 @@
@opindex --contrast-window-size
Set the window @var{SIZE} for local contrast analysis. The window
-will be a square of @var{SIZE}@classictimes{}@/@var{SIZE} pixels. If
+will be a square of @var{SIZE}x@/@var{SIZE} pixels. If
given an even @var{SIZE}, Enfuse will automatically use the next odd
number.
@@ -1585,7 +1585,7 @@
@opindex --entropy-window-size
Window @var{SIZE} for local entropy analysis. The window will be a
-square of @var{SIZE}@classictimes{}@/@var{SIZE} pixels.
+square of @var{SIZE}x@/@var{SIZE} pixels.
In the entropy calculation @var{SIZE} values of 3 to 7 yield an
acceptable compromise of the locality of the information and the
@@ -2433,20 +2433,6 @@
from 1 to the common height, and @math{i} from 1 to the number of
input images@tie{}@math{n}.
-@macro equationW{}
-@ifnotdocbook
-@ifnottex
-(W)
-@end ifnottex
-@end ifnotdocbook
-@tex
-(W)%
-@end tex
-@docbook
-<xref linkend="equ:pixel-weighting-function"/>
-@end docbook
-@end macro
-
Enfuse allows for weighting the contribution of each @math{P(i, x, y)}
to the final @math{Q(x, y)}:
@ifinfo
@@ -2454,7 +2440,7 @@
@math{w(P(1, x, y)) * P(1, x, y) +
... +
w(P(n, x, y)) * P(n, x, y)
---> Q(x, y),}@w{ }@equationW{}
+--> Q(x, y),}
@end display
@end ifinfo
@html
@@ -2520,9 +2506,6 @@
<mi>y</mi>
</mfenced>
</mrow>
- <mtext>,</mtext>
- <mspace width="4em"/>
- <mtext>@equationW{}</mtext>
</mrow>
</math>
@end html
@@ -2530,7 +2513,7 @@
$$
w(P(1, x, y)) P(1, x, y) + \ldots + w(P(n, x, y)) P(n, x, y)
\rightarrow
- Q(x, y),\hskip4em\hbox{@equationW{}}
+ Q(x, y)
$$
@end tex
@docbook
@@ -2948,7 +2931,7 @@
be extreme, favoring only a few pixels or even only one pixel in the
input stack. Extremes are not typical, however.
-Equal weights are another extreme that turns @equationW{} into an
+Equal weights are another extreme that turns the equation into an
arithmetic average. This is why we sometimes speak of the ``averaging
property'' of this weighting algorithm, like smoothing out noise.
@@ -2969,7 +2952,7 @@
wins, this is, gets weight@tie{}one, and all other pixels get the
weight of zero
(@uref{http://@/en.wikipedia.org/@/wiki/@/The_@/Winner_@/Takes_@/It_@/All,,``The
-Winner Takes It All.''}). With @option{--hard-mask} Equation@tie{}@equationW{}
+Winner Takes It All.''}). With @option{--hard-mask} the equation
becomes
@ifinfo
@display
@@ -3114,8 +3097,8 @@
@noindent
Note that this ``averaging'' scheme lacks the nice noise-reduction
-property of the weighted average@tie{}@equationW{}, because only a
-single input pixel contributes to the output.
+property of the weighted average, because only a single input pixel
+contributes to the output.
@node Single Criterion Fusing
@@ -3562,7 +3545,7 @@
@noindent
It associates a probability@tie{}@math{p} with each of the @math{n}
-different possible outcomes@tie{}@inlineomega{} of the random
+different possible outcomes@tie{}@math{omega} of the random
variable@tie{}@math{X}.
@cindex expectation value
Based on @math{w}, we define the @dfn{expectation value} or ``First
@@ -4189,7 +4172,7 @@
@end docbook
@noindent
-The parameter@tie{}@inlinesigma{}, the argument of
+The parameter@tie{}@math{sigma}, the argument of
option@tie{}@option{--contrast-edge-scale}, is the length scale on which edges
are detected by @math{g(x, y)}. We apply the Laplacian operator in
Cartesian coordinates
@@ -4401,7 +4384,7 @@
</informalequation>
@end docbook
-where we have used the dimensionless distance@tie{}@inlinexi{} from
+where we have used the dimensionless distance@tie{}@math{xi} from
the origin
@ifinfo
@display
@@ -4556,7 +4539,7 @@
@float Figure,Figure:laplacian-of-gaussian
@vimage{laplacian-of-gaussian}
-@caption{Laplacian-of-Gaussian function for @inlinesigma{} = 0.5.}
+@caption{Laplacian-of-Gaussian function for @math{sigma} = 0.5.}
@shortcaption{Laplacian-of-Gaussian}
@end float
@@ -4656,10 +4639,10 @@
@var{CURVATURE} nor the mode of operation (@acronym{SDev}-only,
@acronym{LoG}-only, or a blend of both) scales to different image
sizes. In practice, this means that if you start with a set of
-reduced size images, say 2808@classictimes{}1872 pixels, carefully
+reduced size images, say 2808x1872 pixels, carefully
optimize @var{EDGESCALE}, @var{CURVATURE} and so on, and find
@acronym{LoG}-only the best mode, and then switch to the original
-resolution of 5616@classictimes{}3744 pixels, multiplying (or
+resolution of 5616x3744 pixels, multiplying (or
dividing) the parameters by four and sticking to @acronym{LoG}-only
might @emph{not} result in the best fused image. For best quality,
perform the parameter optimization and the search for the most
@@ -5080,9 +5063,9 @@
Images should align well to be suitable for fusion. However, there is
no hard mathematical rule what ``well'' means. The alignment
requirements for 16@dmn{MPixel} images to yield a sharp
-4"@classictimes{}6" print at 300@dmn{dpi} (``dpi'' means dots per
+4"x6" print at 300@dmn{dpi} (``dpi'' means dots per
inch) or even for web presentation are relatively low, whereas the
-alignment of 8@dmn{MPixel} images for a 12"@classictimes{}18" print
+alignment of 8@dmn{MPixel} images for a 12"x18" print
ought to be tight.
@pindex hugin
@@ -5548,7 +5531,7 @@
Let us use an example to illustrate the problem of relating the
sharpness with the local contrast variations. Say we use a
-5@classictimes{}5 contrast window. Moreover, let @code{sharp_edge}
+5x5 contrast window. Moreover, let @code{sharp_edge}
and @code{smooth_edge} be two specific configurations:
@example
@@ -5727,7 +5710,7 @@
Apply the default grayscale projector: @code{average} and throw away
all edges with a curvature of less than 0.5% and replace the
@acronym{LoG} data between 0% and 0.5% with @acronym{SDev} data. Use
-a window of 7@classictimes{}7@dmn{pixel} window to compute the
+a window of 7x7@dmn{pixel} window to compute the
@acronym{SDev}.
@end table
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/versenblend.texi
--- a/doc/versenblend.texi Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/versenblend.texi Fri Aug 07 16:43:24 2015 +0200
@@ -1,4 +1,4 @@
-@set UPDATED 10 March 2014
-@set UPDATED-MONTH March 2014
+@set UPDATED 15 June 2015
+@set UPDATED-MONTH June 2015
@set EDITION 4.1.3
@set VERSION 4.1.3
diff -r c1bcd2df4e37 -r 8387f0170f7b doc/versenfuse.texi
--- a/doc/versenfuse.texi Fri Aug 07 16:43:18 2015 +0200
+++ b/doc/versenfuse.texi Fri Aug 07 16:43:24 2015 +0200
@@ -1,4 +1,4 @@
-@set UPDATED 10 March 2014
-@set UPDATED-MONTH March 2014
+@set UPDATED 15 June 2015
+@set UPDATED-MONTH June 2015
@set EDITION 4.1.3
@set VERSION 4.1.3
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