The structure of a chart plus its data. Charts do not have a
``light'' format.
-@item @var{prefix}_model.xml
-@itemx @var{prefix}_pmml.xml
-@itemx @var{prefix}_stats.xml
+@item @var{prefix}_model.scf
+@itemx @var{prefix}_pmml.scf
Not yet investigated. The corpus contains only one example of each.
+
+@itemx @var{prefix}_stats.xml
+Not yet investigated. The corpus contains few examples.
@end table
The @file{@var{prefix}} in the names of the detail members is
(i0 | i-1) (00 | 01) 00 (00 | 01)
int
byte[decimal] byte[grouping]
- int[x5] string*[x5] /* @r{custom currency} */
- int[x6] byte*[x6]
+ int[n-ccs] string*[n-ccs] /* @r{custom currency} */
+ styles2
+
+x2 := 00 00 00 01 00 00 00 00 00 00 00 00 00 02 00 00 00 00 /* @r{18 bytes} */
+
+styles2 := i0 /* @r{version 1} */
+styles2 := count(count(x5) count(x6)) /* @r{version 3} */
+x5 := byte*33 int[n] int*n
+x6 := 01 00 (03 | 04) 00 00 00
+ string[command] string[subcommand]
+ string[language] string[charset] string[locale]
+ (00 | 01) 00 (00 | 01) (00 | 01)
+ int
+ byte[decimal] byte[grouping]
+ byte*8 01
+ (string[dataset] string[datafile] i0 int i0)?
+ int[n-ccs] string*[n-ccs]
+ 2e (00 | 01) (i2000000 i0)?
@end example
In every example in the corpus, @code{x1} is 240. The meaning of the
follow it are @code{00 00 00 01 00 00 00 00 00 00 00 00 00 02 00 00 00
00}. The meaning of these bytes is unknown.
-Observed values of @code{x3} vary from 16 to 150. The bytes that
-follow it vary somewhat.
+In every example in the corpus for version 1, @code{x3} is 16 and the
+bytes that follow it are @code{00 00 00 01 00 00 00 01 00 00 00 00 01
+01 01 01}. In version 3, observed @code{x3} varies from 117 to 150,
+and its bytes include a 1-byte count at offset 0x34. When the count
+is nonzero, a text string of that length at offset 0x35 is the name of
+a ``TableLook'', e.g. ``Default'' or ``Academic''.
Observed values of @code{x4} vary from 0 to 17. Out of 7060 examples
in the corpus, it is nonzero only 36 times.
@samp{,}, @samp{.}, @samp{'}, @samp{ }, and zero (presumably
indicating that digits should not be grouped).
-@code{x5} is observed as either 0 or 5. When it is 5, the following
-strings are CCA through CCE format strings. Most commonly these are
-all @code{-,,,} but other strings occur.
+@code{n-ccs} is observed as either 0 or 5. When it is 5, the
+following strings are CCA through CCE format strings. Most commonly
+these are all @code{-,,,} but other strings occur.
@example
font := byte[index] 31 string[typeface]
the case 98% of the time in the corpus.
@example
-category := value i1
- (00 | 01 (00 | 01 | 02) | 02) 00 00 00
+category := value[name] (terminal | group)
+terminal-category := 00 00 00 i2 int[index] i0
+@end example
+
+@code{name} is the name of the category (or group).
+
+@code{category} can represent a terminal category. In that case,
+@code{index} is a nonnegative integer less than @code{n-categories} in
+the @code{dimension} in which the @code{category} is nested (directly
+or indirectly).
+
+Alternatively, @code{category} can represent a @code{group} of nested
+categories:
+
+@example
+group := (00 | 01)[merge] 00 01 (i0 | i2)[data]
+ i-1 int[n-subcategories] category*[n-subcategories]
+@end example
+
+Ordinarily a group has some nested content, so that
+@code{n-subcategories} is positive, but a few instances of groups with
+@code{n-subcategories} 0 has been observed.
+
+If @code{merge} is 00, the most common value, then the group is really
+a distinct group that should be represented as such in the visual
+representation and user interface. If @code{merge} is 01, however,
+the categories in this group should be shown and treated as if they
+were direct children of the group's parent group (or if it has no
+parent group, then direct children of the dimension), and this group's
+name is irrelevant and should not be displayed. (Merged groups can be
+nested!)
+
+@code{data} appears to be i2 when all of the categories within a group
+are terminal categories that directly represent data values for a
+variable (e.g. in a frequency table or crosstabulation, a group of
+values in a variable being tabulated) and i0 otherwise, but this might
+be naive.
+
+@example
+data := int[layers] int[rows] int[columns] int*[n-dimensions]
+ int[n-data] datum*[n-data]
+@end example
+
+The values of @code{layers}, @code{rows}, and @code{columns} each
+specifies the number of dimensions represented in layers or rows or
+columns, respectively, and their values sum to the number of
+dimensions.
+
+The @code{n-dimensions} integers are a permutation of the 0-based
+dimension numbers. The first @code{layers} of them specify each of
+the dimensions represented by layers, the next @code{rows} of them
+specify the dimensions represented by rows, and the final
+@code{columns} of them specify the dimensions represented by columns.
+When there is more than one dimension of a given kind, the inner
+dimensions are given first.
+
+@example
+datum := int64[index] 00? value /* @r{version 1} */
+datum := int64[index] value /* @r{version 3} */
+@end example
+
+The format of a datum varies slightly from version 1 to version 3: in
+version 1 it allows for an extra optional 00 byte.
+
+A datum consists of an index and a value. Suppose there are @math{d}
+dimensions and dimension @math{i} for @math{0 \le i < d} has
+@math{n_i} categories. Consider the datum at coordinates @math{x_i}
+for @math{0 \le i < d}; note that @math{0 \le x_i < n_i}. Then the
+index is calculated by the following algorithm:
+
+@display
+let index = 0
+for each @math{i} from 0 to @math{d - 1}:
+ index = @math{n_i \times} index + @math{x_i}
+@end display
+
+For example, suppose there are 3 dimensions with 3, 4, and 5
+categories, respectively. The datum at coordinates (1, 2, 3) has
+index @math{5 \times (4 \times (3 \times 0 + 1) + 2) + 3 = 33}.
+
+@example
+value := 00? 00? 00? 00? raw-value
+raw-value :=
+ 01 value-mod int32[format] double[x]
+ | 02 value-mod int32[format] double[x]
+ string[varname] string[vallab] (01 | 02 | 03)
+ | 03 string[local] value-mod string[id] string[c] (00 | 01)[type]
+ | 04 value-mod int32[format] string[vallab] string[varname]
+ (01 | 02 | 03) string[s]
+ | 05 value-mod string[varname] string[varlabel] (01 | 02 | 03)
+ | value-mod string[format] int32[n-substs] substitution*[n-substs]
+substitution :=
+ i0 value
+ | int32[x] value*[x + 1] /* @r{x > 0} */
+value-mod :=
+ 31 i0 (i0 | i1 string[subscript]) value-mod-i0-v1 /* @r{version 1} */
+ | 31 i0 (i0 | i1 string[subscript]) value-mod-i0-v3 /* @r{version 3} */
+ | 31 i1 int32[footnote-number] template
+ | 31 i2 (00 | 01 | 02) 00 (i1 | i2 | i3) template
+ | 31 i3 00 00 01 00 i2 template
+ | 58
+value-mod-i0-v1 := 00 (i1 | i2) 00 00 int32 00 00
+value-mod-i0-v3 := count(template-string
+ (58 | 31 style)
+ (58
+ | 31 i0 i0 i0 i0 01 00 (01 | 02 | 08)
+ 00 08 00 0a 00))
+
+style := 01? 00? 00? 00? 01 string[fgcolor] string[bgcolor] string[font] byte
+template := 00 00 count(template-string (58 | 31 style) 58)
+template-string := count((i0 (58 | 31 string))?)
@end example
+
+A @code{value} boils down to a number or a string. There are several
+possibilities, which one can distinguish by the first nonzero byte in
+the encoding:
+
+@table @code
+@item 01
+The numeric value @code{x}, presented to the user formatted according
+to @code{format}, which is in the format described for system files.
+@xref{System File Output Formats}, for details. Most commonly
+@code{format} has width 40 (the maximum).
+
+An @code{x} with the maximum negative double @code{-DBL_MAX}
+represents the system-missing value SYSMIS. (HIGHEST and LOWEST have
+not been observed.) @xref{System File Format}, for more about these
+special values.
+
+@item 02
+Similar to @code{01}, with the additional information that @code{x} is
+a value of variable @code{varname} and has value label @code{vallab}.
+Both @code{varname} and @code{vallab} can be the empty string, the
+latter very commonly.
+
+The meaning of the final byte is unknown. Possibly it is connected to
+whether the value or the label should be displayed.
+
+@item 03
+A text string, in two forms: @code{c} is in English, and sometimes
+abbreviated or obscure, and @code{local} is localized to the user's
+locale. In an English-language locale, the two strings are often the
+same, and in the cases where they differ, @code{local} is more
+appropriate for a user interface, e.g.@: @code{c} of ``Not a PxP table
+for MCN...'' versus @code{local} of ``Computed only for a PxP table,
+where P must be greater than 1.''
+
+@code{c} and @code{local} are always either both empty or both
+nonempty.
+
+@code{id} is a brief identifying string whose form seems to resemble a
+programming language identifier, e.g.@: @code{cumulative_percent} or
+@code{factor_14}. It is not unique.
+
+@code{type} is 00 for text taken from user input, such as syntax
+fragment, expressions, file names, data set names, and 01 for fixed
+text strings such as names of procedures or statistics. In the former
+case, @code{id} is always the empty string; in the latter case,
+@code{id} is still sometimes empty.
+
+@item 04
+The string value @code{s}, presented to the user formatted according
+to @code{format}. The format for a string is not too interesting, and
+clearly invalid formats like A16.39 or A255.127 or A134.1 abound in
+the corpus, so readers should probably ignore the format entirely.
+
+@code{s} is a value of variable @code{varname} and has value label
+@code{vallab}. @code{varname} is never empty but @code{vallab} is
+commonly empty.
+
+The meaning of the final byte is unknown.
+
+@item 05
+Variable @code{varname}, which is rarely observed as empty in the
+corpus, with variable label @code{varlabel}, which is often empty.
+
+The meaning of the final byte is unknown.
+@end itemize