1 @c PSPP - a program for statistical analysis.
2 @c Copyright (C) 2017 Free Software Foundation, Inc.
3 @c Permission is granted to copy, distribute and/or modify this document
4 @c under the terms of the GNU Free Documentation License, Version 1.3
5 @c or any later version published by the Free Software Foundation;
6 @c with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts.
7 @c A copy of the license is included in the section entitled "GNU
8 @c Free Documentation License".
10 @node Data Manipulation
11 @chapter Data transformations
12 @cindex transformations
14 The @pspp{} procedures examined in this chapter manipulate data and
15 prepare the active dataset for later analyses. They do not produce output,
19 * AGGREGATE:: Summarize multiple cases into a single case.
20 * AUTORECODE:: Automatic recoding of variables.
21 * COMPUTE:: Assigning a variable a calculated value.
22 * COUNT:: Counting variables with particular values.
23 * FLIP:: Exchange variables with cases.
24 * IF:: Conditionally assigning a calculated value.
25 * RECODE:: Mapping values from one set to another.
26 * SORT CASES:: Sort the active dataset.
35 OUTFILE=@{*,'@var{file_name}',@var{file_handle}@} [MODE=@{REPLACE, ADDVARIABLES@}]
40 /@var{dest_var}['@var{label}']@dots{}=@var{agr_func}(@var{src_vars}, @var{args}@dots{})@dots{}
43 @cmd{AGGREGATE} summarizes groups of cases into single cases.
44 Cases are divided into groups that have the same values for one or more
45 variables called @dfn{break variables}. Several functions are available
46 for summarizing case contents.
48 The @subcmd{OUTFILE} subcommand is required and must appear first. Specify a
49 system file or portable file by file name or file
50 handle (@pxref{File Handles}), or a dataset by its name
52 The aggregated cases are written to this file. If @samp{*} is
53 specified, then the aggregated cases replace the active dataset's data.
54 Use of @subcmd{OUTFILE} to write a portable file is a @pspp{} extension.
56 If @subcmd{OUTFILE=*} is given, then the subcommand @subcmd{MODE} may also be
58 The mode subcommand has two possible values: @subcmd{ADDVARIABLES} or @subcmd{REPLACE}.
59 In @subcmd{REPLACE} mode, the entire active dataset is replaced by a new dataset
60 which contains just the break variables and the destination varibles.
61 In this mode, the new file will contain as many cases as there are
62 unique combinations of the break variables.
63 In @subcmd{ADDVARIABLES} mode, the destination variables will be appended to
64 the existing active dataset.
65 Cases which have identical combinations of values in their break
66 variables, will receive identical values for the destination variables.
67 The number of cases in the active dataset will remain unchanged.
68 Note that if @subcmd{ADDVARIABLES} is specified, then the data @emph{must} be
69 sorted on the break variables.
71 By default, the active dataset will be sorted based on the break variables
72 before aggregation takes place. If the active dataset is already sorted
73 or otherwise grouped in terms of the break variables, specify
74 @subcmd{PRESORTED} to save time.
75 @subcmd{PRESORTED} is assumed if @subcmd{MODE=ADDVARIABLES} is used.
77 Specify @subcmd{DOCUMENT} to copy the documents from the active dataset into the
78 aggregate file (@pxref{DOCUMENT}). Otherwise, the aggregate file will
79 not contain any documents, even if the aggregate file replaces the
82 Normally, only a single case (for @subcmd{SD} and @subcmd{SD}., two cases) need be
83 non-missing in each group for the aggregate variable to be
84 non-missing. Specifying @subcmd{/MISSING=COLUMNWISE} inverts this behavior, so
85 that the aggregate variable becomes missing if any aggregated value is
88 If @subcmd{PRESORTED}, @subcmd{DOCUMENT}, or @subcmd{MISSING} are specified, they must appear
89 between @subcmd{OUTFILE} and @subcmd{BREAK}.
91 At least one break variable must be specified on @subcmd{BREAK}, a
92 required subcommand. The values of these variables are used to divide
93 the active dataset into groups to be summarized. In addition, at least
94 one @var{dest_var} must be specified.
96 One or more sets of aggregation variables must be specified. Each set
97 comprises a list of aggregation variables, an equals sign (@samp{=}),
98 the name of an aggregation function (see the list below), and a list
99 of source variables in parentheses. Some aggregation functions expect
100 additional arguments following the source variable names.
102 Aggregation variables typically are created with no variable label,
103 value labels, or missing values. Their default print and write
104 formats depend on the aggregation function used, with details given in
105 the table below. A variable label for an aggregation variable may be
106 specified just after the variable's name in the aggregation variable
109 Each set must have exactly as many source variables as aggregation
110 variables. Each aggregation variable receives the results of applying
111 the specified aggregation function to the corresponding source
112 variable. The @subcmd{MEAN}, @subcmd{MEDIAN}, @subcmd{SD}, and @subcmd{SUM}
113 aggregation functions may only be
114 applied to numeric variables. All the rest may be applied to numeric
115 and string variables.
117 The available aggregation functions are as follows:
120 @item @subcmd{FGT(@var{var_name}, @var{value})}
121 Fraction of values greater than the specified constant. The default
124 @item @subcmd{FIN(@var{var_name}, @var{low}, @var{high})}
125 Fraction of values within the specified inclusive range of constants.
126 The default format is F5.3.
128 @item @subcmd{FLT(@var{var_name}, @var{value})}
129 Fraction of values less than the specified constant. The default
132 @item @subcmd{FIRST(@var{var_name})}
133 First non-missing value in break group. The aggregation variable
134 receives the complete dictionary information from the source variable.
135 The sort performed by @cmd{AGGREGATE} (and by @cmd{SORT CASES}) is stable, so that
136 the first case with particular values for the break variables before
137 sorting will also be the first case in that break group after sorting.
139 @item @subcmd{FOUT(@var{var_name}, @var{low}, @var{high})}
140 Fraction of values strictly outside the specified range of constants.
141 The default format is F5.3.
143 @item @subcmd{LAST(@var{var_name})}
144 Last non-missing value in break group. The aggregation variable
145 receives the complete dictionary information from the source variable.
146 The sort performed by @cmd{AGGREGATE} (and by @cmd{SORT CASES}) is stable, so that
147 the last case with particular values for the break variables before
148 sorting will also be the last case in that break group after sorting.
150 @item @subcmd{MAX(@var{var_name})}
151 Maximum value. The aggregation variable receives the complete
152 dictionary information from the source variable.
154 @item @subcmd{MEAN(@var{var_name})}
155 Arithmetic mean. Limited to numeric values. The default format is
158 @item @subcmd{MEDIAN(@var{var_name})}
159 The median value. Limited to numeric values. The default format is F8.2.
161 @item @subcmd{MIN(@var{var_name})}
162 Minimum value. The aggregation variable receives the complete
163 dictionary information from the source variable.
165 @item @subcmd{N(@var{var_name})}
166 Number of non-missing values. The default format is F7.0 if weighting
167 is not enabled, F8.2 if it is (@pxref{WEIGHT}).
170 Number of cases aggregated to form this group. The default format is
171 F7.0 if weighting is not enabled, F8.2 if it is (@pxref{WEIGHT}).
173 @item @subcmd{NMISS(@var{var_name})}
174 Number of missing values. The default format is F7.0 if weighting is
175 not enabled, F8.2 if it is (@pxref{WEIGHT}).
177 @item @subcmd{NU(@var{var_name})}
178 Number of non-missing values. Each case is considered to have a weight
179 of 1, regardless of the current weighting variable (@pxref{WEIGHT}).
180 The default format is F7.0.
183 Number of cases aggregated to form this group. Each case is considered
184 to have a weight of 1, regardless of the current weighting variable.
185 The default format is F7.0.
187 @item @subcmd{NUMISS(@var{var_name})}
188 Number of missing values. Each case is considered to have a weight of
189 1, regardless of the current weighting variable. The default format is F7.0.
191 @item @subcmd{PGT(@var{var_name}, @var{value})}
192 Percentage between 0 and 100 of values greater than the specified
193 constant. The default format is F5.1.
195 @item @subcmd{PIN(@var{var_name}, @var{low}, @var{high})}
196 Percentage of values within the specified inclusive range of
197 constants. The default format is F5.1.
199 @item @subcmd{PLT(@var{var_name}, @var{value})}
200 Percentage of values less than the specified constant. The default
203 @item @subcmd{POUT(@var{var_name}, @var{low}, @var{high})}
204 Percentage of values strictly outside the specified range of
205 constants. The default format is F5.1.
207 @item @subcmd{SD(@var{var_name})}
208 Standard deviation of the mean. Limited to numeric values. The
209 default format is F8.2.
211 @item @subcmd{SUM(@var{var_name})}
212 Sum. Limited to numeric values. The default format is F8.2.
215 Aggregation functions compare string values in terms of internal
217 On most modern computers, this is @acronym{ASCII} or a superset thereof.
219 The aggregation functions listed above exclude all user-missing values
220 from calculations. To include user-missing values, insert a period
221 (@samp{.}) at the end of the function name. (e.g.@: @samp{SUM.}).
222 (Be aware that specifying such a function as the last token on a line
223 will cause the period to be interpreted as the end of the command.)
225 @cmd{AGGREGATE} both ignores and cancels the current @cmd{SPLIT FILE}
226 settings (@pxref{SPLIT FILE}).
233 AUTORECODE VARIABLES=@var{src_vars} INTO @var{dest_vars}
237 [ /BLANK = @{VALID, MISSING@} ]
240 The @cmd{AUTORECODE} procedure considers the @var{n} values that a variable
241 takes on and maps them onto values 1@dots{}@var{n} on a new numeric
244 Subcommand @subcmd{VARIABLES} is the only required subcommand and must come
245 first. Specify @subcmd{VARIABLES}, an equals sign (@samp{=}), a list of source
246 variables, @subcmd{INTO}, and a list of target variables. There must the same
247 number of source and target variables. The target variables must not
250 By default, increasing values of a source variable (for a string, this
251 is based on character code comparisons) are recoded to increasing values
252 of its target variable. To cause increasing values of a source variable
253 to be recoded to decreasing values of its target variable (@var{n} down
254 to 1), specify @subcmd{DESCENDING}.
256 @subcmd{PRINT} is currently ignored.
258 The @subcmd{GROUP} subcommand is relevant only if more than one variable is to be
259 recoded. It causes a single mapping between source and target values to
260 be used, instead of one map per variable.
262 If @subcmd{/BLANK=MISSING} is given, then string variables which contain only
263 whitespace are recoded as SYSMIS. If @subcmd{/BLANK=VALID} is given then they
264 will be allocated a value like any other. @subcmd{/BLANK} is not relevant
265 to numeric values. @subcmd{/BLANK=VALID} is the default.
267 @cmd{AUTORECODE} is a procedure. It causes the data to be read.
274 COMPUTE @var{variable} = @var{expression}.
278 COMPUTE vector(@var{index}) = @var{expression}.
281 @cmd{COMPUTE} assigns the value of an expression to a target
282 variable. For each case, the expression is evaluated and its value
283 assigned to the target variable. Numeric and string
284 variables may be assigned. When a string expression's width differs
285 from the target variable's width, the string result of the expression
286 is truncated or padded with spaces on the right as necessary. The
287 expression and variable types must match.
289 For numeric variables only, the target variable need not already
290 exist. Numeric variables created by @cmd{COMPUTE} are assigned an
291 @code{F8.2} output format. String variables must be declared before
292 they can be used as targets for @cmd{COMPUTE}.
294 The target variable may be specified as an element of a vector
295 (@pxref{VECTOR}). In this case, an expression @var{index} must be
296 specified in parentheses following the vector name. The expression @var{index}
297 must evaluate to a numeric value that, after rounding down
298 to the nearest integer, is a valid index for the named vector.
300 Using @cmd{COMPUTE} to assign to a variable specified on @cmd{LEAVE}
301 (@pxref{LEAVE}) resets the variable's left state. Therefore,
302 @code{LEAVE} should be specified following @cmd{COMPUTE}, not before.
304 @cmd{COMPUTE} is a transformation. It does not cause the active dataset to be
307 When @cmd{COMPUTE} is specified following @cmd{TEMPORARY}
308 (@pxref{TEMPORARY}), the @cmd{LAG} function may not be used
316 COUNT @var{var_name} = @var{var}@dots{} (@var{value}@dots{}).
318 Each @var{value} takes one of the following forms:
321 @var{num1} THRU @var{num2}
324 where @var{num1} is a numeric expression or the words @subcmd{LO} or @subcmd{LOWEST}
325 and @var{num2} is a numeric expression or @subcmd{HI} or @subcmd{HIGHEST}.
328 @cmd{COUNT} creates or replaces a numeric @dfn{target} variable that
329 counts the occurrence of a @dfn{criterion} value or set of values over
330 one or more @dfn{test} variables for each case.
332 The target variable values are always nonnegative integers. They are
333 never missing. The target variable is assigned an F8.2 output format.
334 @xref{Input and Output Formats}. Any variables, including
335 string variables, may be test variables.
337 User-missing values of test variables are treated just like any other
338 values. They are @strong{not} treated as system-missing values.
339 User-missing values that are criterion values or inside ranges of
340 criterion values are counted as any other values. However (for numeric
341 variables), keyword @subcmd{MISSING} may be used to refer to all system-
342 and user-missing values.
344 @cmd{COUNT} target variables are assigned values in the order
345 specified. In the command @subcmd{COUNT @var{A}=@var{A} @var{B}(1) /@var{B}=@var{A} @var{B}(2).}, the
346 following actions occur:
350 The number of occurrences of 1 between @var{A} and @var{B} is counted.
353 @var{A} is assigned this value.
356 The number of occurrences of 1 between @var{B} and the @strong{new}
357 value of @var{A} is counted.
360 @var{B} is assigned this value.
363 Despite this ordering, all @cmd{COUNT} criterion variables must exist
364 before the procedure is executed---they may not be created as target
365 variables earlier in the command! Break such a command into two
368 The examples below may help to clarify.
372 Assuming @code{Q0}, @code{Q2}, @dots{}, @code{Q9} are numeric variables,
373 the following commands:
377 Count the number of times the value 1 occurs through these variables
378 for each case and assigns the count to variable @code{QCOUNT}.
381 Print out the total number of times the value 1 occurs throughout
382 @emph{all} cases using @cmd{DESCRIPTIVES}. @xref{DESCRIPTIVES}, for
387 COUNT QCOUNT=Q0 TO Q9(1).
388 DESCRIPTIVES QCOUNT /STATISTICS=SUM.
392 Given these same variables, the following commands:
396 Count the number of valid values of these variables for each case and
397 assigns the count to variable @code{QVALID}.
400 Multiplies each value of @code{QVALID} by 10 to obtain a percentage of
401 valid values, using @cmd{COMPUTE}. @xref{COMPUTE}, for details.
404 Print out the percentage of valid values across all cases, using
405 @cmd{DESCRIPTIVES}. @xref{DESCRIPTIVES}, for details.
409 COUNT QVALID=Q0 TO Q9 (LO THRU HI).
410 COMPUTE QVALID=QVALID*10.
411 DESCRIPTIVES QVALID /STATISTICS=MEAN.
420 FLIP /VARIABLES=@var{var_list} /NEWNAMES=@var{var_name}.
423 @cmd{FLIP} transposes rows and columns in the active dataset. It
424 causes cases to be swapped with variables, and vice versa.
426 All variables in the transposed active dataset are numeric. String
427 variables take on the system-missing value in the transposed file.
429 @subcmd{N} subcommands are required. If specified, the @subcmd{VARIABLES} subcommand
430 selects variables to be transformed into cases, and variables not
431 specified are discarded. If the @subcmd{VARIABLES} subcommand is omitted, all
432 variables are selected for transposition.
434 The variables specified by @subcmd{NEWNAMES}, which must be a
436 used to give names to the variables created by @cmd{FLIP}. Only the
437 first 8 characters of the variable are used. If
438 @subcmd{NEWNAMES} is not
439 specified then the default is a variable named CASE_LBL, if it exists.
440 If it does not then the variables created by @cmd{FLIP} are named VAR000
441 through VAR999, then VAR1000, VAR1001, and so on.
443 When a @subcmd{NEWNAMES} variable is available, the names must be canonicalized
444 before becoming variable names. Invalid characters are replaced by
445 letter @samp{V} in the first position, or by @samp{_} in subsequent
446 positions. If the name thus generated is not unique, then numeric
447 extensions are added, starting with 1, until a unique name is found or
448 there are no remaining possibilities. If the latter occurs then the
449 @cmd{FLIP} operation aborts.
451 The resultant dictionary contains a CASE_LBL variable, a string
452 variable of width 8, which stores the names of the variables in the
453 dictionary before the transposition. Variables names longer than 8
454 characters are truncated. If the active dataset is subsequently
455 transposed using @cmd{FLIP}, this variable can be used to recreate the
456 original variable names.
458 @cmd{FLIP} honors @cmd{N OF CASES} (@pxref{N OF CASES}). It ignores
459 @cmd{TEMPORARY} (@pxref{TEMPORARY}), so that ``temporary''
460 transformations become permanent.
467 IF @var{condition} @var{variable}=@var{expression}.
471 IF @var{condition} vector(@var{index})=@var{expression}.
474 The @cmd{IF} transformation conditionally assigns the value of a target
475 expression to a target variable, based on the truth of a test
478 Specify a boolean-valued expression (@pxref{Expressions}) to be tested
479 following the @cmd{IF} keyword. This expression is evaluated for each case.
480 If the value is true, then the value of the expression is computed and
481 assigned to the specified variable. If the value is false or missing,
482 nothing is done. Numeric and string variables may be
483 assigned. When a string expression's width differs from the target
484 variable's width, the string result of the expression is truncated or
485 padded with spaces on the right as necessary. The expression and
486 variable types must match.
488 The target variable may be specified as an element of a vector
489 (@pxref{VECTOR}). In this case, a vector index expression must be
490 specified in parentheses following the vector name. The index
491 expression must evaluate to a numeric value that, after rounding down
492 to the nearest integer, is a valid index for the named vector.
494 Using @cmd{IF} to assign to a variable specified on @cmd{LEAVE}
495 (@pxref{LEAVE}) resets the variable's left state. Therefore,
496 @code{LEAVE} should be specified following @cmd{IF}, not before.
498 When @cmd{IF} is specified following @cmd{TEMPORARY}
499 (@pxref{TEMPORARY}), the @cmd{LAG} function may not be used
506 The @cmd{RECODE} command is used to transform existing values into other,
507 user specified values.
511 RECODE @var{src_vars}
512 (@var{src_value} @var{src_value} @dots{} = @var{dest_value})
513 (@var{src_value} @var{src_value} @dots{} = @var{dest_value})
514 (@var{src_value} @var{src_value} @dots{} = @var{dest_value}) @dots{}
515 [INTO @var{dest_vars}].
518 Following the @cmd{RECODE} keyword itself comes @var{src_vars} which is a list
519 of variables whose values are to be transformed.
520 These variables may be string variables or they may be numeric.
521 However the list must be homogeneous; you may not mix string variables and
522 numeric variables in the same recoding.
524 After the list of source variables, there should be one or more @dfn{mappings}.
525 Each mapping is enclosed in parentheses, and contains the source values and
526 a destination value separated by a single @samp{=}.
527 The source values are used to specify the values in the dataset which
528 need to change, and the destination value specifies the new value
529 to which they should be changed.
530 Each @var{src_value} may take one of the following forms:
533 If the source variables are numeric then @var{src_value} may be a literal
536 If the source variables are string variables then @var{src_value} may be a
537 literal string (like all strings, enclosed in single or double quotes).
538 @item @var{num1} THRU @var{num2}
539 This form is valid only when the source variables are numeric.
540 It specifies all values in the range between @var{num1} and @var{num2},
541 including both endpoints of the range. By convention, @var{num1}
542 should be less than @var{num2}.
543 Open-ended ranges may be specified using @samp{LO} or @samp{LOWEST}
545 or @samp{HI} or @samp{HIGHEST} for @var{num2}.
547 The literal keyword @samp{MISSING} matches both system missing and user
549 It is valid for both numeric and string variables.
551 The literal keyword @samp{SYSMIS} matches system missing
553 It is valid for both numeric variables only.
555 The @samp{ELSE} keyword may be used to match any values which are
556 not matched by any other @var{src_value} appearing in the command.
557 If this keyword appears, it should be used in the last mapping of the
561 After the source variables comes an @samp{=} and then the @var{dest_value}.
562 The @var{dest_value} may take any of the following forms:
565 A literal numeric value to which the source values should be changed.
566 This implies the destination variable must be numeric.
568 A literal string value (enclosed in quotation marks) to which the source
569 values should be changed.
570 This implies the destination variable must be a string variable.
572 The keyword @samp{SYSMIS} changes the value to the system missing value.
573 This implies the destination variable must be numeric.
575 The special keyword @samp{COPY} means that the source value should not be
577 copied directly to the destination value.
578 This is meaningful only if @samp{INTO @var{dest_vars}} is specified.
581 Mappings are considered from left to right.
582 Therefore, if a value is matched by a @var{src_value} from more than
583 one mapping, the first (leftmost) mapping which matches will be considered.
584 Any subsequent matches will be ignored.
586 The clause @samp{INTO @var{dest_vars}} is optional.
587 The behaviour of the command is slightly different depending on whether it
590 If @samp{INTO @var{dest_vars}} does not appear, then values will be recoded
592 This means that the recoded values are written back to the
593 source variables from whence the original values came.
594 In this case, the @var{dest_value} for every mapping must imply a value which
595 has the same type as the @var{src_value}.
596 For example, if the source value is a string value, it is not permissible for
597 @var{dest_value} to be @samp{SYSMIS} or another forms which implies a numeric
599 It is also not permissible for @var{dest_value} to be longer than the width
600 of the source variable.
602 The following example two numeric variables @var{x} and @var{y} are recoded
604 Zero is recoded to 99, the values 1 to 10 inclusive are unchanged,
605 values 1000 and higher are recoded to the system-missing value and all other
606 values are changed to 999:
608 recode @var{x} @var{y}
611 (1000 THRU HIGHEST = SYSMIS)
615 If @samp{INTO @var{dest_vars}} is given, then recoded values are written
616 into the variables specified in @var{dest_vars}, which must therefore
617 contain a list of valid variable names.
618 The number of variables in @var{dest_vars} must be the same as the number
619 of variables in @var{src_vars}
620 and the respective order of the variables in @var{dest_vars} corresponds to
621 the order of @var{src_vars}.
622 That is to say, recoded values whose
623 original value came from the @var{n}th variable in @var{src_vars} will be
624 placed into the @var{n}th variable in @var{dest_vars}.
625 The source variables will be unchanged.
626 If any mapping implies a string as its destination value, then the respective
627 destination variable must already exist, or
628 have been declared using @cmd{STRING} or another transformation.
629 Numeric variables however will be automatically created if they don't already
631 The following example deals with two source variables, @var{a} and @var{b}
632 which contain string values. Hence there are two destination variables
633 @var{v1} and @var{v2}.
634 Any cases where @var{a} or @var{b} contain the values @samp{apple},
635 @samp{pear} or @samp{pomegranate} will result in @var{v1} or @var{v2} being
636 filled with the string @samp{fruit} whilst cases with
637 @samp{tomato}, @samp{lettuce} or @samp{carrot} will result in @samp{vegetable}.
638 Any other values will produce the result @samp{unknown}:
640 string @var{v1} (a20).
641 string @var{v2} (a20).
643 recode @var{a} @var{b}
644 ("apple" "pear" "pomegranate" = "fruit")
645 ("tomato" "lettuce" "carrot" = "vegetable")
647 into @var{v1} @var{v2}.
650 There is one very special mapping, not mentioned above.
651 If the source variable is a string variable
652 then a mapping may be specified as @samp{(CONVERT)}.
653 This mapping, if it appears must be the last mapping given and
654 the @samp{INTO @var{dest_vars}} clause must also be given and
655 must not refer to a string variable.
656 @samp{CONVERT} causes a number specified as a string to
657 be converted to a numeric value.
658 For example it will convert the string @samp{"3"} into the numeric
659 value 3 (note that it will not convert @samp{three} into 3).
660 If the string cannot be parsed as a number, then the system-missing value
662 In the following example, cases where the value of @var{x} (a string variable)
663 is the empty string, are recoded to 999 and all others are converted to the
664 numeric equivalent of the input value. The results are placed into the
665 numeric variable @var{y}:
673 It is possible to specify multiple recodings on a single command.
674 Introduce additional recodings with a slash (@samp{/}) to
675 separate them from the previous recodings:
678 @var{a} (2 = 22) (else = 99)
679 /@var{b} (1 = 3) into @var{z}
682 @noindent Here we have two recodings. The first affects the source variable
683 @var{a} and recodes in-place the value 2 into 22 and all other values to 99.
684 The second recoding copies the values of @var{b} into the variable @var{z},
685 changing any instances of 1 into 3.
692 SORT CASES BY @var{var_list}[(@{D|A@}] [ @var{var_list}[(@{D|A@}] ] ...
695 @cmd{SORT CASES} sorts the active dataset by the values of one or more
698 Specify @subcmd{BY} and a list of variables to sort by. By default, variables
699 are sorted in ascending order. To override sort order, specify @subcmd{(D)} or
700 @subcmd{(DOWN)} after a list of variables to get descending order, or @subcmd{(A)} or @subcmd{(UP)}
701 for ascending order. These apply to all the listed variables
702 up until the preceding @subcmd{(A)}, @subcmd{(D)}, @subcmd{(UP)} or @subcmd{(DOWN)}.
704 The sort algorithms used by @cmd{SORT CASES} are stable. That is,
705 records that have equal values of the sort variables will have the
706 same relative order before and after sorting. As a special case,
707 re-sorting an already sorted file will not affect the ordering of
710 @cmd{SORT CASES} is a procedure. It causes the data to be read.
712 @cmd{SORT CASES} attempts to sort the entire active dataset in main memory.
713 If workspace is exhausted, it falls back to a merge sort algorithm that
714 involves creates numerous temporary files.
716 @cmd{SORT CASES} may not be specified following @cmd{TEMPORARY}.