man/man1/rmtxop.1

.\" RCSid "$Id: rmtxop.1,v 1.8 2015/02/20 18:26:09 greg Exp $"
.TH RMTXOP 1 7/8/97 RADIANCE
.SH NAME
rmtxop - concatenate, add, transpose, scale, and convert matrices
.SH SYNOPSIS
.B rmtxop
[
.B \-v
][
.B \-f[afdc]
][
.B \-t
][
.B "\-s sf .."
][
.B "\-c ce .."
]
.B m1
[
.B +
]
.B ".."
.SH DESCRIPTION
.I Rmtxop
loads and concatenates (multiplies) or adds together component matrix files
given on the command line.
Each file must have a header containing the following variables:
.sp
.nf
NROWS={number of rows}
NCOLS={number of columns}
NCOMP={number of components}
FORMAT={ascii|float|double|32-bit_rle_rgbe|32-bit_rle_xyze}
.sp
.fi
The number of components indicates that each matrix element is actually
composed of multiple elements, most commonly an RGB triple.
This is essentially dividing the matrix into planes, where each component
participates in a separate calculation.
If an appropriate header is not present, it may be added with a call to
.I rcollate(1).
A matrix may be read from the standard input using a hyphen by itself ('-')
in the appropriate place on the command line.
.PP
Any of the matrix inputs may be read from a command
instead of a file by
using quotes and a beginning exclamation point ('!').
.PP
Two special cases are handled for component matrices that are either
XML files containing BTDF data, or Radiance picture files.
In the first case, a BSDF library is used to load and interpret the
transmission matrix.
(XML files cannot be read from the standard input or from a command.)\0
In the second case, the RGBE or XYZE values are loaded in a 3-component
matrix where the number of columns match the X-dimension of the picture, and
the number of rows match the Y-dimension.
The picture must be in standard pixel ordering, and the first row
is at the top with the first column on the left.
.PP
Before each file, the
.I \-t
and
.I \-s
or
.I \-c
options may be used to modify the matrix.
The
.I \-t
option transposes the matrix, swapping rows and columns.
The
.I \-s
option applies the given scalar factor(s) to the elements of the matrix.
If only one factor is provided,
it will be used for all components.
If multiple factors are given, their number must match the number of matrix
components.
Alternatively, the
.I \-c
option may be used to "transform" the element values, possibly changing
the number of components in the matrix.
For example, a 3-component matrix can be transformed into a single-component
matrix by using
.I \-c
with three coefficients.
A four-component matrix can be turned into a two-component matrix using 8
coefficients, where the first four coefficients will be used to compute
the first new component, and the second four coefficients
yield the second new component.
Note that the number of coefficients must be an even multiple of the number
of original components.
The
.I \-s
and
.I \-c
options are mutually exclusive, insofar as they cannot be applied together
to the same input matrix.
.PP
If present, the second and subsequent matrices on the command
line are concatenated to the result unless separated by a plus ('+') symbol,
in which case the elements are added together.
The number of components in the new matrix after applying any
.I -c
transform must agree with the prior result.
For concatenation (matrix multiplication), the number of columns
in the prior result must equal the number of rows in the new matrix, and
the result will have the number of rows of the previous and the number
of columns of the new matrix.
In the case of addition, the number of rows and columns of the prior
result and the new matrix must match, and will not be changed by the
operation.
.PP
Results are sent to the standard output.
By default, the values will be written in the lowest resolution format
among the inputs, but the
.I \-f
option may be used to explicitly output components
as ASCII (-fa), binary doubles (-fd), floats (-ff), or RGBE colors (-fc).
In the latter case, the actual matrix dimensions are written in the resolution
string rather than the header.
Also, matrix results written as Radiance pictures must have either one
or three components.
In the one-component case, the output is written as grayscale.
.PP
The
.I \-v
option turns on verbose reporting, which announces each operation.
.SH EXAMPLES
To concatenate two matrix files with a BTDF between them and write
the result as binary double:
.IP "" .2i
rmtxop -fd view.vmx blinds.xml exterior.dmx > dcoef.dmx
.PP
To convert a BTDF matrix into a Radiance picture:
.IP "" .2i
rmtxop -fc blinds.xml > blinds.hdr
.PP
To scale a matrix by 4 and add it to the transpose of another matrix:
.IP "" .2i
rmtxop -s 4 left.mtx + -t right.mtx > result.mtx
.PP
To send the elements of a binary matrix to 
.I rcalc(1)
for further processing:
.IP "" .2i
rmtxop -fa orig.mtx | rcollate -ho -oc 1 | rcalc [operations]
.SH AUTHOR
Greg Ward
.SH "SEE ALSO"
cnt(1), getinfo(1), histo(1), neaten(1), rcalc(1), rcollate(1),
rcontrib(1), rfluxmtx(1), rlam(1), tabfunc(1), total(1), wrapBSDF(1)
Revision:	1.9
Committed:	Mon May 4 20:53:21 2015 UTC (10 years ago) by greg
Branch:	MAIN
CVS Tags:	rad5R0, rad5R1
Changes since 1.8:	+6 -2 lines
Log Message:	Added the ability to read matrix inputs from commands as well as files
#	User	Rev	Content
1	greg	1.9	.\" RCSid "$Id: rmtxop.1,v 1.8 2015/02/20 18:26:09 greg Exp $"
2	greg	1.1	.TH RMTXOP 1 7/8/97 RADIANCE
3			.SH NAME
4			rmtxop - concatenate, add, transpose, scale, and convert matrices
5			.SH SYNOPSIS
6			.B rmtxop
7			[
8			.B \-v
9			][
10	greg	1.3	.B \-f[afdc]
11	greg	1.1	][
12			.B \-t
13			][
14			.B "\-s sf .."
15			][
16			.B "\-c ce .."
17			]
18			.B m1
19			[
20			.B +
21			]
22			.B ".."
23			.SH DESCRIPTION
24			.I Rmtxop
25			loads and concatenates (multiplies) or adds together component matrix files
26			given on the command line.
27			Each file must have a header containing the following variables:
28			.sp
29			.nf
30			NROWS={number of rows}
31			NCOLS={number of columns}
32			NCOMP={number of components}
33			FORMAT={ascii\|float\|double\|32-bit_rle_rgbe\|32-bit_rle_xyze}
34			.sp
35			.fi
36			The number of components indicates that each matrix element is actually
37			composed of multiple elements, most commonly an RGB triple.
38			This is essentially dividing the matrix into planes, where each component
39			participates in a separate calculation.
40			If an appropriate header is not present, it may be added with a call to
41			.I rcollate(1).
42			A matrix may be read from the standard input using a hyphen by itself ('-')
43			in the appropriate place on the command line.
44			.PP
45	greg	1.9	Any of the matrix inputs may be read from a command
46			instead of a file by
47			using quotes and a beginning exclamation point ('!').
48			.PP
49	greg	1.1	Two special cases are handled for component matrices that are either
50			XML files containing BTDF data, or Radiance picture files.
51			In the first case, a BSDF library is used to load and interpret the
52			transmission matrix.
53	greg	1.9	(XML files cannot be read from the standard input or from a command.)\0
54	greg	1.1	In the second case, the RGBE or XYZE values are loaded in a 3-component
55			matrix where the number of columns match the X-dimension of the picture, and
56			the number of rows match the Y-dimension.
57			The picture must be in standard pixel ordering, and the first row
58	greg	1.7	is at the top with the first column on the left.
59	greg	1.1	.PP
60			Before each file, the
61			.I \-t
62			and
63			.I \-s
64			or
65			.I \-c
66			options may be used to modify the matrix.
67			The
68			.I \-t
69			option transposes the matrix, swapping rows and columns.
70			The
71			.I \-s
72			option applies the given scalar factor(s) to the elements of the matrix.
73			If only one factor is provided,
74			it will be used for all components.
75			If multiple factors are given, their number must match the number of matrix
76			components.
77			Alternatively, the
78			.I \-c
79			option may be used to "transform" the element values, possibly changing
80			the number of components in the matrix.
81			For example, a 3-component matrix can be transformed into a single-component
82			matrix by using
83			.I \-c
84			with three coefficients.
85			A four-component matrix can be turned into a two-component matrix using 8
86			coefficients, where the first four coefficients will be used to compute
87			the first new component, and the second four coefficients
88			yield the second new component.
89			Note that the number of coefficients must be an even multiple of the number
90			of original components.
91			The
92			.I \-s
93			and
94			.I \-c
95			options are mutually exclusive, insofar as they cannot be applied together
96			to the same input matrix.
97			.PP
98			If present, the second and subsequent matrices on the command
99			line are concatenated to the result unless separated by a plus ('+') symbol,
100			in which case the elements are added together.
101			The number of components in the new matrix after applying any
102			.I -c
103			transform must agree with the prior result.
104			For concatenation (matrix multiplication), the number of columns
105			in the prior result must equal the number of rows in the new matrix, and
106			the result will have the number of rows of the previous and the number
107			of columns of the new matrix.
108			In the case of addition, the number of rows and columns of the prior
109			result and the new matrix must match, and will not be changed by the
110			operation.
111			.PP
112			Results are sent to the standard output.
113	greg	1.4	By default, the values will be written in the lowest resolution format
114	greg	1.6	among the inputs, but the
115	greg	1.1	.I \-f
116	greg	1.4	option may be used to explicitly output components
117			as ASCII (-fa), binary doubles (-fd), floats (-ff), or RGBE colors (-fc).
118	greg	1.1	In the latter case, the actual matrix dimensions are written in the resolution
119			string rather than the header.
120			Also, matrix results written as Radiance pictures must have either one
121			or three components.
122			In the one-component case, the output is written as grayscale.
123			.PP
124			The
125			.I \-v
126			option turns on verbose reporting, which announces each operation.
127			.SH EXAMPLES
128			To concatenate two matrix files with a BTDF between them and write
129			the result as binary double:
130			.IP "" .2i
131			rmtxop -fd view.vmx blinds.xml exterior.dmx > dcoef.dmx
132			.PP
133			To convert a BTDF matrix into a Radiance picture:
134			.IP "" .2i
135			rmtxop -fc blinds.xml > blinds.hdr
136			.PP
137			To scale a matrix by 4 and add it to the transpose of another matrix:
138			.IP "" .2i
139			rmtxop -s 4 left.mtx + -t right.mtx > result.mtx
140			.PP
141			To send the elements of a binary matrix to
142			.I rcalc(1)
143			for further processing:
144			.IP "" .2i
145	greg	1.5	rmtxop -fa orig.mtx \| rcollate -ho -oc 1 \| rcalc [operations]
146	greg	1.1	.SH AUTHOR
147			Greg Ward
148			.SH "SEE ALSO"
149	greg	1.5	cnt(1), getinfo(1), histo(1), neaten(1), rcalc(1), rcollate(1),
150	greg	1.8	rcontrib(1), rfluxmtx(1), rlam(1), tabfunc(1), total(1), wrapBSDF(1)