cv/mgflib/spec.txt

                MATERIALS AND GEOMETRY FORMAT
                SCCSid "$SunId$ LBL"

Introduction
============
The following file format is a simple ASCII representation of surface
geometry and materials for the purpose of visible-light simulation
and rendering.  The overall objective of this format is to provide
a very simple yet fairly complete modeling language that does not
place unreasonable demands on the applications programmer or the
object library creator.

Similar to Wavefront's .OBJ file format, our format utilizes a
number of object entities, one per line, some of which establish
a context for the entities that follow.  Specifically, there is
a context for the current vertex, the current color, and the
current material.  The current vertex is used only for setting
values related to that vertex.  The current color is used for
setting values related to that color, as well as by certain
material attributes which take an optional color setting.
The current material is used for setting material-related
parameters, and for establishing the material for the following
geometric entities.  In addition to these three named contexts,
there are two hierarchical (i.e. cumulative) contexts, the
current transform and the current object name.

Each entity is given by a short keyword, followed by space- or tab-
delimited arguments on a single line.  A single entity may be extended
over multiple lines using a backslash ('\') character right before the
end of line, though no extended line may exceed 512 characters in total
length.  (Given the current set of entities, even approaching 80
characters would be highly unusual.)

Entities and Contexts
=====================
There are three contexts in effect at all times, current vertex,
current color and current material.  Initially, these contexts are
unnamed, and have specific default values.  The unnamed vertex is the
origin.  The unnamed color is neutral gray.  The unnamed material is a
perfect absorber.  The unnamed contexts may be modified, but those
modifications will not be saved.  Thus, reestablishing an unnamed
context always gets its initial default value.  To save a new context
or modify an old one, it must first be named.  Entities associated with
named contexts (i.e. "v", "c" and "m") may be followed by an identifier
and an equals sign ('='), indicating a new context.  If there is no
equals, then the context must already be defined, and the appearance of
the entity merely reestablishes this context.  If the context id is
followed by an equals, then a new context is defined, destroying any
previous instance of that context name.  Redefining or changing values
of a context does not affect earlier uses of the same name, however.
Contexts are always associated with a name id, which is any non-blank
sequence of printing ASCII characters.  An optional template may be
given following the equals, which is a previously defined context to
use as a source of default values for this definition.  If no template
is given, then the unnamed context of that type is used to set initial
values.  Named contexts continue until the next context definition of
the same type.

Hierarchical Contexts
=====================
Two entities define a second type of context, which is hierarchical.
These are the transform ("xf") entity and the object ("o") entity.
The object entity is used simply for naming collections of surfaces.
An object entity with a name applies to the following surfaces up
until an object entity with no name, which signifies the end of this
object's scope.  Object entities may be nested to any level, and
can be thought of as parts and subparts of an enclosing global object.
Note that this is strictly for ease of identification, and has no
real meaning as far as the geometric description goes.  In contrast,
the transform entity is very significant as it determines how enclosing
objects are to be scaled and placed in the final description.

Without further ado, here are the proposed entities and their interpretations:

Keyword Arguments               Meaning
------- ---------               -------
#       anything                a comment
i       filename [xform]        include file (with transformation)
ies     filename [-m f][xform]  include IES luminaire (with transformation)
v       [id [= [template]]]     get/set vertex context
p       x y z                   set point position for current vertex
n       dx dy dz                set surface normal for current vertex
c       [id [= [template]]]     get/set color context
cxy     x y                     set CIE (x,y) chromaticity for current color
cspec   l_min l_max v1 v2 ..    set relative spectrum for current color
cmix    w1 c1 w2 c2 ..          mix named colors to make current color
m       [id [= [template]]]     get/set material context
rd      rho_d                   set diffuse reflectance for current material
td      tau_d                   set diffuse transmittance for current material
ed      epsilon_d               set diffuse emittance for current material
rs      rho_s alpha_r           set specular reflectance for current material
ts      tau_s alpha_t           set specular transmittance for current material
o       [name]                  begin/end object context
f       v1 v2 v3 ..             polygon using current material, spec. vertices
sph     vc radius               sphere
cyl     v1 radius v2            truncated right cylinder (open-ended)
cone    v1 rad1 v2 rad2         truncated right cone (open-ended)
prism   v1 v2 v3 .. length      right prism (closed solid)
ring    vc rmin rmax            circular ring with inner and outer radii
torus   vc rmin rmax            circular torus with inner and outer radii
xf      [xform]                 begin/end transformation context

These are the context dependencies of each entity:

Entities                                Contexts
--------                                --------
p, n                                    vertex
cxy, cspec, cmix                        color
rd, td, ed, rs, ts                      color, material
f, sph, cyl, cone, ring, torus, prism   material, object, transformation

Transformations
===============
A rigid body transformation is given with the transform entity, or as
part of an included file.  The following transformation flags and
arguments are defined:

        -t dx dy dz             translate objects along the given vector
        -rx degrees             rotate objects about the X-axis
        -ry degrees             rotate objects about the Y-axis
        -rz degrees             rotate objects about the Z-axis
        -s scalefactor          scale objects by the given factor
        -mx                     mirror objects about the Y-Z plane
        -my                     mirror objects about the X-Z plane
        -mz                     mirror objects about the X-Y plane
        -i N                    repeat the following arguments N times
        -a N                    make an array of N geometric instances

Transform arguments have a cumulative effect.  That is, a rotation
about X of 20 degrees followed by a rotation about X of -50 degrees
results in a total rotation of -30 degrees.  However, if the two
rotations are separated by some translation vector, the cumulative
effect is quite different.  It is best to think of each argument as
acting on the included geometric objects, and each subsequent transformation
argument affects the objects relative to their new position/orientation.

For example, rotating an object about its center requires translating
the object back to the origin, applying the desired rotation, and translating
it again back to its original position.

Rotations are given in degrees counter-clockwise about a principal axis.
That is, with the thumb of the right hand pointing in the direction
of the axis, rotation follows the curl of the fingers.

The transform command itself is also cumulative, and a transform
command with no arguments is used to return to the previous
condition.  It is best if transforms and their end statements
("xf" by itself) are balanced in a file, so that later or enclosing
files are not affected.

Transformations apply only to geometric types, e.g. polygons, spheres, etc.
Vertices and the components that go into geometry are not directly affected.
This is to avoid confusion and the inadvertent multiple application of a
given transformation.

Arrays
======
The -a N transform specification causes the following transform
arguments to be repeated along with the contents of the included
file N times.  (Note that this option is supported only for included
files.)  The first instance of the geometry will be in its initial
location; the second instance will be repositioned according to the
named transformation; the third instance will be repositioned by
applying this transformation twice, and so on up to N-1 applications.

Multi-dimensional arrays may be specified with a single include
entity by giving multiple array commands separated by their
corresponding transforms.  A final transformation may be given
by preceeding it with a -i 1 specification.  In other words, the
scope of an array command continues until the next -i or -a option.

Other Details
=============
End of line may be any one of the sequences:  linefeed ('\n'), carriage-
return ('\r'), or a carriage return followed by a linefeed.

Blank lines are ignored on the input, as are any blanks preceeding
a keyword on a line.  Indentation may improve readability, especially
in context definitions.

The comment character ('#') must be followed by at least one blank
character (space or tab) for easy parsing.  Like any other line,
a comment may be extended to multiple lines using a backslash ('\').

Include filename paths are relative to the current file.  Absolute
paths are expressly forbidden.  UNIX conventions should be used for the
path separator ('/') and disk names should not be used (i.e. no
"C:\file").  To further enhance portability across systems, directory
names should be 8 characters or fewer with no suffix, filenames should
fit within an 8.3 format, and all characters should be lower case.
(They will be automatically promoted to upper case by DOS systems.)
We suggest the standard suffix ".mgf" for "materials and geometry format".

The XYZ coordinate system is right-handed, and lengths are always in
SI meters.  This is not really a limitation as the first statement
in the file can always be a transform with the -s option to convert
to a more convenient set of units.  Included IES files will also start
out in meters, and it is important to specify a transform into the
local coordinate system.  The -m option (preceeding any transform)
may be used to specify an output multiplication factor.

Vertex normals need not be normalized, and a normal equal to (0,0,0) indicates
that the exact surface normal should be used.  (This is the default.)

Color in this system does not include intensity, only hue and
saturation.  Intensity, such as reflectance or emittance, is explicitly
included in the other material parameters.  All colors are absolute,
e.g. spectral reflectance or transmittance under uniform white light.

A CIE xy chromaticity pair is the most basic color specification.
A full spectrum is the most general specification, and the starting
(i.e. minimum) and ending (i.e. maximum) wavelengths are given along
with a set of evenly spaced values.  Wavelengths are given in nanometers,
and must be within the range of 380-780.  The spectral values themselves
are located starting at the first wavelength and proceeding at even
increments to the ending wavelength.  The values in between will be
interpolated as necessary, so there must be at least two specified points.
The color mixing entity is intended not only for the mixing of named
colors, but also for color specifications  using an arbitrary set
of basis functions.  The actual totals for spectral and mixing
coefficients is irrelevant, since the results will be normalized.

Diffuse emittance is always given in SI units of lumens/meter^2.  Note that
this is emittance, not exitance, and does not include light reflected or
transmitted by the surface.

The roughness associated with specular reflectance and transmittance
is the RMS surface facet slope.  A value of 0 indicates a perfectly
smooth surface, meaning that reflected or transmitted rays will not
be scattered.

The sum of the diffuse and specular reflectances and transmittances
must be strictly less than one (with no negative values, obviously).

The object entity establishes a hierarchical context, consisting of
this identifier and all those preceding.  It has no real meaning except
to group the following surfaces up until an empty object statement
under a descriptive name for improved file readability.

Surfaces are one-sided, and appear invisible when viewed from the
back side.  This means that a transmitting object will affect the
light coming in through the front surface and ignore the characteristics
of the back surface.  As long as the characteristics are the same,
the results should be correct.  If the rendering technique does not
allow for one-sided surfaces, an approximately correct result can
be obtained for transmitting surfaces by using the square root of
the given tau_s and half the given alpha_t.

The surface normal of a face is oriented by the right-hand rule.
Specifically, the surface normal faces towards the viewer when the
vertices circulate counter-clockwise.  Faces may be concave or convex,
but must be planar.  Holes may be represented as concave polygons with
coincident sides (i.e. seams).

A prism consists of a set of coplanar vertices specifying an end-face,
and a length value.  The prism will be extruded so that the end-face
points outward, unless the length value is negative, in which case the
object is extruded in the opposite direction, resulting in inward-
directed surface normals.

A sphere, cylinder or cone with negative radii is interpreted as having
an inward facing surface normal.  Otherwise, the normal is assumed
to face outwards.  (It is illegal for a cone to have one positive and
one negative radius.)

The central vertex for a ring or torus must have an associated normal,
which serves to orient the ring.  The inner radius must be given first,
and must be strictly less than the outer radius.  The inner radius may
be zero but not negative.  There is an exception for a torus with
inward-pointing normal, which is identified by a negative outer radius
and a non-positive inner radius.

Examples
========
The following is a complete example input file (don't ask me what it is):

        # Define some materials:
        m red_plastic =
                c red =
                        cxy .8 .1
                rd 0.5
                # reestablish unnamed (neutral) color context:
                c
                rs 0.04 0.02
        m green_plastic =
                c green =
                        cxy .2 .6
                rd 0.4
                c
                rs .05 0
        m bright_emitter =
                c
                ed 1000
        m dark =
                c
                rd .08
        # Define some vertices:
        v v1 =
                p 10 5 7
        v v2 =
                p 15 3 9
        v v3 =
                p 20 -7 6
        v v4 =
                p 20 10 6
        v v5 =
                p 10 10 6
        v v6 =
                p 10 -7 6
        v cv1 =
                p -5 3 8
                n 0 0 -1
        v cv2 =
                p -3 3 8
                n 0 0 1
        # make some faces:
        m green_plastic
        f v1 v3 v4
        m red_plastic
        f v3 v4 v5
        f v5 v6 v7
        m bright_emitter
        f v3 v4 v5 v6
        # make a cylindrical source with dark end caps:
        m bright_emitter
        cyl cv1 .15 cv2
        m dark
        ring cv1 0 .15
        ring cv2 0 .15

The following is a more typical example, which relies on a material library:

        # Include our materials:
        i material.mgf
        # Modify red_plastic to have no specular component:
        m red_plastic
                rs 0 0
        # Make an alias for blue_plastic:
        m outer_material = blue_plastic
        # Make a new material based on brass, with greater roughness:
        m rough_brass = brass
                c brass_color
                rs 0.9 0.15
        # Load our vertices:
        i lum1vert.mgf
        # Modify appropriate vertices to make luminaire longer:
        v v10
                p 5 -2 -.1
        v v11
                p 5 2 -.1
        v v8
                p 5 2 0
        v v9
                p 5 -2 0
        # Load our surfaces, rotating them -90 degrees about Z:
        i lum1face.mgf -rz -90
        # Make a 2-D array of sequins covering the face of the fixture:
        m silver
        i sequin.mgf -a 5 -t .5 0 0 -a 4 -t 0 .75 0

Note that by using libraries and modifying values, it is possible to create
a variety of fixtures without requiring large files to describe each one.

Interpretation
==============
Interpretation of this language will be simplified by the creation
of a general parser that will be able to express the defined entities
in simpler forms and remove entities that would not be understood by
the caller.

For example, a caller may ask the standard parser to produce only
the entities for diffuse uncolored materials, vertices without normals,
and polygons.  The parser would then expand all include statements,
remove all color statements, convert spheres and cones to polygonal
approximations, and so forth.

This way, a single general parser can permit software to operate
at whatever level it is capable, with a minimal loss of generality.
Furthermore, distribution of a standard parser will improve
both forward and backward compatibility as new entities are added
to the specification.

Rationale
=========
Why create yet another file format for geometric data, when so many
others already exist?  The main answer to this question is that we
are not merely defining geometry, but materials as well.  Though the
number of committee and de facto standards for geometric data is large,
the number of standards for geometry + materials is small.  Of these,
almost all are non-physical in origin, i.e. they are based on common,
ad hoc computer graphics rendering practices and cannot be used to create
physical simulations.  Of the one or two formats that were intended
for or could be adapted to physical simulation, the syntax and semantics
are at the same time too complex and too limiting to serve as a suitable
standard.

Specifically, establishing the above, new standard has the following
advantages:

        o It is easy to parse.
        o It is easy to support, at least as a least common denominator.
        o It is ASCII and fairly easy for a person to read and understand.
        o It supports simple color, material and vertex libraries.
        o It includes a simple yet fairly complete material specification.
        o It is easy to skip unsupported entities (e.g. color, vertex normals)
        o It supports transformations and instances.
        o It is easy to add new entities, and as long as these entities can
                be approximated by the original set, backwards compatibility
                can be maintained through a standard parsing library.

Most of the disadvantages of this format relate to its simplicity, but
since simplicity was our most essential goal, this could not be helped.
Specifically:

        o There is no general representation of curved surfaces (though
                vertex normals make approximations straightforward).
        o There are no general surface scattering functions.
        o There are no textures or bump-maps.

If any of these seems particularly important, I will look into adding them,
though they will tend to complicate the specification and make it more
difficult to support.
Revision:	1.1
Committed:	Sat Jun 25 09:46:58 1994 UTC (29 years, 10 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Log Message:	Initial revision
#	Content
1	MATERIALS AND GEOMETRY FORMAT
2	SCCSid "$SunId$ LBL"
3
4	Introduction
5	============
6	The following file format is a simple ASCII representation of surface
7	geometry and materials for the purpose of visible-light simulation
8	and rendering. The overall objective of this format is to provide
9	a very simple yet fairly complete modeling language that does not
10	place unreasonable demands on the applications programmer or the
11	object library creator.
12
13	Similar to Wavefront's .OBJ file format, our format utilizes a
14	number of object entities, one per line, some of which establish
15	a context for the entities that follow. Specifically, there is
16	a context for the current vertex, the current color, and the
17	current material. The current vertex is used only for setting
18	values related to that vertex. The current color is used for
19	setting values related to that color, as well as by certain
20	material attributes which take an optional color setting.
21	The current material is used for setting material-related
22	parameters, and for establishing the material for the following
23	geometric entities. In addition to these three named contexts,
24	there are two hierarchical (i.e. cumulative) contexts, the
25	current transform and the current object name.
26
27	Each entity is given by a short keyword, followed by space- or tab-
28	delimited arguments on a single line. A single entity may be extended
29	over multiple lines using a backslash ('\') character right before the
30	end of line, though no extended line may exceed 512 characters in total
31	length. (Given the current set of entities, even approaching 80
32	characters would be highly unusual.)
33
34	Entities and Contexts
35	=====================
36	There are three contexts in effect at all times, current vertex,
37	current color and current material. Initially, these contexts are
38	unnamed, and have specific default values. The unnamed vertex is the
39	origin. The unnamed color is neutral gray. The unnamed material is a
40	perfect absorber. The unnamed contexts may be modified, but those
41	modifications will not be saved. Thus, reestablishing an unnamed
42	context always gets its initial default value. To save a new context
43	or modify an old one, it must first be named. Entities associated with
44	named contexts (i.e. "v", "c" and "m") may be followed by an identifier
45	and an equals sign ('='), indicating a new context. If there is no
46	equals, then the context must already be defined, and the appearance of
47	the entity merely reestablishes this context. If the context id is
48	followed by an equals, then a new context is defined, destroying any
49	previous instance of that context name. Redefining or changing values
50	of a context does not affect earlier uses of the same name, however.
51	Contexts are always associated with a name id, which is any non-blank
52	sequence of printing ASCII characters. An optional template may be
53	given following the equals, which is a previously defined context to
54	use as a source of default values for this definition. If no template
55	is given, then the unnamed context of that type is used to set initial
56	values. Named contexts continue until the next context definition of
57	the same type.
58
59	Hierarchical Contexts
60	=====================
61	Two entities define a second type of context, which is hierarchical.
62	These are the transform ("xf") entity and the object ("o") entity.
63	The object entity is used simply for naming collections of surfaces.
64	An object entity with a name applies to the following surfaces up
65	until an object entity with no name, which signifies the end of this
66	object's scope. Object entities may be nested to any level, and
67	can be thought of as parts and subparts of an enclosing global object.
68	Note that this is strictly for ease of identification, and has no
69	real meaning as far as the geometric description goes. In contrast,
70	the transform entity is very significant as it determines how enclosing
71	objects are to be scaled and placed in the final description.
72
73	Without further ado, here are the proposed entities and their interpretations:
74
75	Keyword Arguments Meaning
76	------- --------- -------
77	# anything a comment
78	i filename [xform] include file (with transformation)
79	ies filename [-m f][xform] include IES luminaire (with transformation)
80	v [id [= [template]]] get/set vertex context
81	p x y z set point position for current vertex
82	n dx dy dz set surface normal for current vertex
83	c [id [= [template]]] get/set color context
84	cxy x y set CIE (x,y) chromaticity for current color
85	cspec l_min l_max v1 v2 .. set relative spectrum for current color
86	cmix w1 c1 w2 c2 .. mix named colors to make current color
87	m [id [= [template]]] get/set material context
88	rd rho_d set diffuse reflectance for current material
89	td tau_d set diffuse transmittance for current material
90	ed epsilon_d set diffuse emittance for current material
91	rs rho_s alpha_r set specular reflectance for current material
92	ts tau_s alpha_t set specular transmittance for current material
93	o [name] begin/end object context
94	f v1 v2 v3 .. polygon using current material, spec. vertices
95	sph vc radius sphere
96	cyl v1 radius v2 truncated right cylinder (open-ended)
97	cone v1 rad1 v2 rad2 truncated right cone (open-ended)
98	prism v1 v2 v3 .. length right prism (closed solid)
99	ring vc rmin rmax circular ring with inner and outer radii
100	torus vc rmin rmax circular torus with inner and outer radii
101	xf [xform] begin/end transformation context
102
103	These are the context dependencies of each entity:
104
105	Entities Contexts
106	-------- --------
107	p, n vertex
108	cxy, cspec, cmix color
109	rd, td, ed, rs, ts color, material
110	f, sph, cyl, cone, ring, torus, prism material, object, transformation
111
112	Transformations
113	===============
114	A rigid body transformation is given with the transform entity, or as
115	part of an included file. The following transformation flags and
116	arguments are defined:
117
118	-t dx dy dz translate objects along the given vector
119	-rx degrees rotate objects about the X-axis
120	-ry degrees rotate objects about the Y-axis
121	-rz degrees rotate objects about the Z-axis
122	-s scalefactor scale objects by the given factor
123	-mx mirror objects about the Y-Z plane
124	-my mirror objects about the X-Z plane
125	-mz mirror objects about the X-Y plane
126	-i N repeat the following arguments N times
127	-a N make an array of N geometric instances
128
129	Transform arguments have a cumulative effect. That is, a rotation
130	about X of 20 degrees followed by a rotation about X of -50 degrees
131	results in a total rotation of -30 degrees. However, if the two
132	rotations are separated by some translation vector, the cumulative
133	effect is quite different. It is best to think of each argument as
134	acting on the included geometric objects, and each subsequent transformation
135	argument affects the objects relative to their new position/orientation.
136
137	For example, rotating an object about its center requires translating
138	the object back to the origin, applying the desired rotation, and translating
139	it again back to its original position.
140
141	Rotations are given in degrees counter-clockwise about a principal axis.
142	That is, with the thumb of the right hand pointing in the direction
143	of the axis, rotation follows the curl of the fingers.
144
145	The transform command itself is also cumulative, and a transform
146	command with no arguments is used to return to the previous
147	condition. It is best if transforms and their end statements
148	("xf" by itself) are balanced in a file, so that later or enclosing
149	files are not affected.
150
151	Transformations apply only to geometric types, e.g. polygons, spheres, etc.
152	Vertices and the components that go into geometry are not directly affected.
153	This is to avoid confusion and the inadvertent multiple application of a
154	given transformation.
155
156	Arrays
157	======
158	The -a N transform specification causes the following transform
159	arguments to be repeated along with the contents of the included
160	file N times. (Note that this option is supported only for included
161	files.) The first instance of the geometry will be in its initial
162	location; the second instance will be repositioned according to the
163	named transformation; the third instance will be repositioned by
164	applying this transformation twice, and so on up to N-1 applications.
165
166	Multi-dimensional arrays may be specified with a single include
167	entity by giving multiple array commands separated by their
168	corresponding transforms. A final transformation may be given
169	by preceeding it with a -i 1 specification. In other words, the
170	scope of an array command continues until the next -i or -a option.
171
172	Other Details
173	=============
174	End of line may be any one of the sequences: linefeed ('\n'), carriage-
175	return ('\r'), or a carriage return followed by a linefeed.
176
177	Blank lines are ignored on the input, as are any blanks preceeding
178	a keyword on a line. Indentation may improve readability, especially
179	in context definitions.
180
181	The comment character ('#') must be followed by at least one blank
182	character (space or tab) for easy parsing. Like any other line,
183	a comment may be extended to multiple lines using a backslash ('\').
184
185	Include filename paths are relative to the current file. Absolute
186	paths are expressly forbidden. UNIX conventions should be used for the
187	path separator ('/') and disk names should not be used (i.e. no
188	"C:\file"). To further enhance portability across systems, directory
189	names should be 8 characters or fewer with no suffix, filenames should
190	fit within an 8.3 format, and all characters should be lower case.
191	(They will be automatically promoted to upper case by DOS systems.)
192	We suggest the standard suffix ".mgf" for "materials and geometry format".
193
194	The XYZ coordinate system is right-handed, and lengths are always in
195	SI meters. This is not really a limitation as the first statement
196	in the file can always be a transform with the -s option to convert
197	to a more convenient set of units. Included IES files will also start
198	out in meters, and it is important to specify a transform into the
199	local coordinate system. The -m option (preceeding any transform)
200	may be used to specify an output multiplication factor.
201
202	Vertex normals need not be normalized, and a normal equal to (0,0,0) indicates
203	that the exact surface normal should be used. (This is the default.)
204
205	Color in this system does not include intensity, only hue and
206	saturation. Intensity, such as reflectance or emittance, is explicitly
207	included in the other material parameters. All colors are absolute,
208	e.g. spectral reflectance or transmittance under uniform white light.
209
210	A CIE xy chromaticity pair is the most basic color specification.
211	A full spectrum is the most general specification, and the starting
212	(i.e. minimum) and ending (i.e. maximum) wavelengths are given along
213	with a set of evenly spaced values. Wavelengths are given in nanometers,
214	and must be within the range of 380-780. The spectral values themselves
215	are located starting at the first wavelength and proceeding at even
216	increments to the ending wavelength. The values in between will be
217	interpolated as necessary, so there must be at least two specified points.
218	The color mixing entity is intended not only for the mixing of named
219	colors, but also for color specifications using an arbitrary set
220	of basis functions. The actual totals for spectral and mixing
221	coefficients is irrelevant, since the results will be normalized.
222
223	Diffuse emittance is always given in SI units of lumens/meter^2. Note that
224	this is emittance, not exitance, and does not include light reflected or
225	transmitted by the surface.
226
227	The roughness associated with specular reflectance and transmittance
228	is the RMS surface facet slope. A value of 0 indicates a perfectly
229	smooth surface, meaning that reflected or transmitted rays will not
230	be scattered.
231
232	The sum of the diffuse and specular reflectances and transmittances
233	must be strictly less than one (with no negative values, obviously).
234
235	The object entity establishes a hierarchical context, consisting of
236	this identifier and all those preceding. It has no real meaning except
237	to group the following surfaces up until an empty object statement
238	under a descriptive name for improved file readability.
239
240	Surfaces are one-sided, and appear invisible when viewed from the
241	back side. This means that a transmitting object will affect the
242	light coming in through the front surface and ignore the characteristics
243	of the back surface. As long as the characteristics are the same,
244	the results should be correct. If the rendering technique does not
245	allow for one-sided surfaces, an approximately correct result can
246	be obtained for transmitting surfaces by using the square root of
247	the given tau_s and half the given alpha_t.
248
249	The surface normal of a face is oriented by the right-hand rule.
250	Specifically, the surface normal faces towards the viewer when the
251	vertices circulate counter-clockwise. Faces may be concave or convex,
252	but must be planar. Holes may be represented as concave polygons with
253	coincident sides (i.e. seams).
254
255	A prism consists of a set of coplanar vertices specifying an end-face,
256	and a length value. The prism will be extruded so that the end-face
257	points outward, unless the length value is negative, in which case the
258	object is extruded in the opposite direction, resulting in inward-
259	directed surface normals.
260
261	A sphere, cylinder or cone with negative radii is interpreted as having
262	an inward facing surface normal. Otherwise, the normal is assumed
263	to face outwards. (It is illegal for a cone to have one positive and
264	one negative radius.)
265
266	The central vertex for a ring or torus must have an associated normal,
267	which serves to orient the ring. The inner radius must be given first,
268	and must be strictly less than the outer radius. The inner radius may
269	be zero but not negative. There is an exception for a torus with
270	inward-pointing normal, which is identified by a negative outer radius
271	and a non-positive inner radius.
272
273	Examples
274	========
275	The following is a complete example input file (don't ask me what it is):
276
277	# Define some materials:
278	m red_plastic =
279	c red =
280	cxy .8 .1
281	rd 0.5
282	# reestablish unnamed (neutral) color context:
283	c
284	rs 0.04 0.02
285	m green_plastic =
286	c green =
287	cxy .2 .6
288	rd 0.4
289	c
290	rs .05 0
291	m bright_emitter =
292	c
293	ed 1000
294	m dark =
295	c
296	rd .08
297	# Define some vertices:
298	v v1 =
299	p 10 5 7
300	v v2 =
301	p 15 3 9
302	v v3 =
303	p 20 -7 6
304	v v4 =
305	p 20 10 6
306	v v5 =
307	p 10 10 6
308	v v6 =
309	p 10 -7 6
310	v cv1 =
311	p -5 3 8
312	n 0 0 -1
313	v cv2 =
314	p -3 3 8
315	n 0 0 1
316	# make some faces:
317	m green_plastic
318	f v1 v3 v4
319	m red_plastic
320	f v3 v4 v5
321	f v5 v6 v7
322	m bright_emitter
323	f v3 v4 v5 v6
324	# make a cylindrical source with dark end caps:
325	m bright_emitter
326	cyl cv1 .15 cv2
327	m dark
328	ring cv1 0 .15
329	ring cv2 0 .15
330
331	The following is a more typical example, which relies on a material library:
332
333	# Include our materials:
334	i material.mgf
335	# Modify red_plastic to have no specular component:
336	m red_plastic
337	rs 0 0
338	# Make an alias for blue_plastic:
339	m outer_material = blue_plastic
340	# Make a new material based on brass, with greater roughness:
341	m rough_brass = brass
342	c brass_color
343	rs 0.9 0.15
344	# Load our vertices:
345	i lum1vert.mgf
346	# Modify appropriate vertices to make luminaire longer:
347	v v10
348	p 5 -2 -.1
349	v v11
350	p 5 2 -.1
351	v v8
352	p 5 2 0
353	v v9
354	p 5 -2 0
355	# Load our surfaces, rotating them -90 degrees about Z:
356	i lum1face.mgf -rz -90
357	# Make a 2-D array of sequins covering the face of the fixture:
358	m silver
359	i sequin.mgf -a 5 -t .5 0 0 -a 4 -t 0 .75 0
360
361	Note that by using libraries and modifying values, it is possible to create
362	a variety of fixtures without requiring large files to describe each one.
363
364	Interpretation
365	==============
366	Interpretation of this language will be simplified by the creation
367	of a general parser that will be able to express the defined entities
368	in simpler forms and remove entities that would not be understood by
369	the caller.
370
371	For example, a caller may ask the standard parser to produce only
372	the entities for diffuse uncolored materials, vertices without normals,
373	and polygons. The parser would then expand all include statements,
374	remove all color statements, convert spheres and cones to polygonal
375	approximations, and so forth.
376
377	This way, a single general parser can permit software to operate
378	at whatever level it is capable, with a minimal loss of generality.
379	Furthermore, distribution of a standard parser will improve
380	both forward and backward compatibility as new entities are added
381	to the specification.
382
383	Rationale
384	=========
385	Why create yet another file format for geometric data, when so many
386	others already exist? The main answer to this question is that we
387	are not merely defining geometry, but materials as well. Though the
388	number of committee and de facto standards for geometric data is large,
389	the number of standards for geometry + materials is small. Of these,
390	almost all are non-physical in origin, i.e. they are based on common,
391	ad hoc computer graphics rendering practices and cannot be used to create
392	physical simulations. Of the one or two formats that were intended
393	for or could be adapted to physical simulation, the syntax and semantics
394	are at the same time too complex and too limiting to serve as a suitable
395	standard.
396
397	Specifically, establishing the above, new standard has the following
398	advantages:
399
400	o It is easy to parse.
401	o It is easy to support, at least as a least common denominator.
402	o It is ASCII and fairly easy for a person to read and understand.
403	o It supports simple color, material and vertex libraries.
404	o It includes a simple yet fairly complete material specification.
405	o It is easy to skip unsupported entities (e.g. color, vertex normals)
406	o It supports transformations and instances.
407	o It is easy to add new entities, and as long as these entities can
408	be approximated by the original set, backwards compatibility
409	can be maintained through a standard parsing library.
410
411	Most of the disadvantages of this format relate to its simplicity, but
412	since simplicity was our most essential goal, this could not be helped.
413	Specifically:
414
415	o There is no general representation of curved surfaces (though
416	vertex normals make approximations straightforward).
417	o There are no general surface scattering functions.
418	o There are no textures or bump-maps.
419
420	If any of these seems particularly important, I will look into adding them,
421	though they will tend to complicate the specification and make it more
422	difficult to support.