Much of this was extracted from %help.txt for %practice-split.red. Need to update some formatting for MD versus the help system @toomasv wrote.
Briefly, I worked with @giesse on the design of Rebol's split func, with the goal of making it dialected, covering many types of splitting. I started one for Red some time back, taking the idea further. @toomasv created a refinement-based version for comparison.
The repo also contains an experimental idea for design and learning (%practice-split.red). A question that's been nagging at me is how we can do evidence based language design.
First we need to clear up purpose for the design.
Then we need clear presentation of the alternatives of design.
And finally we should estimate how well do alternative design decisions serve the stated purpose.
Abstract-theoretically splitting should enable breaking any series into chunks according to any criteria appropriate for given series.
Practically it should, according to Red philosophy, make common cases of splitting easy and all cases possible.
Splitting should occur according to delimiter, which may determine value on which to split and/or position where to split. Value can be given literally, by pattern (type, alternatives or sequence or hierarchy of delimiter values) and dynamically with function. Position can be determined by size of chunks, number of chunks or dynamically with function returning next splitting position in series. By default splitting should break whole series by given delimiter permissively, i.e. allowing partial matches (reminder/rest) to be included. Further, partial (aka limited) splitting should be supported, so as to split limited number of times, still including reminder in result. Finally restricted splitting should be supported, returning only requested number of chunks and/or excluding empty chunks, and ignoring reminder.
Several specialized functions and dialected split making use of these. (Currently there are following specialized functions: partition (or group - IMO it should be separated from this split-bundle), split-into- N-parts, split-fixed-parts, split-var-parts, split-at-index, split-once, and split-ctx/split-delimited with refinements.)
Single split with refinements and dialect.
This will need more playing, and implementation of %practice-split- r.red.
Specialized functions can probably be implemented more efficiently, but to be pliable, they should include possibility of limited and restricted splitting. They also cause a little "explosion" of supportive functions with long multi-part names.
Single split with refinements avoids explosion of specialized functions, is more Red-like, but probably less efficient than specialized single- purpose functions.
Defining some terms will help us talk about the design.
Consider these drafts. Particularly in light of the design chat on at
vs skip and position vs index in general docs for series related
...positions.
Delimiter: See Separator.
Dialect: A domain specific sub-language in the context of a more general language.
Keyword: A word with special meaning in a language or dialect.
Part: A piece, chunk, segment, slice, or region of a Red series.
Position: An offset or index in a Red series. Indexes start at 1, offsets start at 0.
Rule: How to split, in general, may be considered a rule, or spec. But there are also parse rules.
Separator: A value specifying the boundary between separate, independent regions.
USAGE:
SPLIT series dlm
DESCRIPTION:
Split a series into parts, by delimiter, size, number, function, type,
or advanced rules.
SPLIT is a function! value.
ARGUMENTS:
series [series!] "The series to split."
dlm {Dialected rule (block), part size (integer), predicate (function),
or separator.}
USAGE:
SPLIT-R series delimiter
DESCRIPTION:
Split series according to specified delimiter.
SPLIT-R is a function! value.
ARGUMENTS:
series [series!] "Series to split."
delimiter [default!] "Delimiter on which to split."
REFINEMENTS:
/by => Dummy (default) refinement for compatibility with dialect.
/before => Split before the delimiter.
/after => Split after the delimiter.
/at => Split before and after the delimiter.
/first => Split on first delimiter / keep first chunk only.
/last => Split on last delimiter / keep last chunk only.
/tail => Split starting from tail.
/groups => Split series into delimiter-specified groups.
/each => Treat each element in block-delimiter individually.
/limit => Limit number of splittings / chunks to keep.
ct [integer!]
/quoted => Treat delimiter as quoted.
/only => Omit empty chunks and rest (i.e. not specified).
/with => Add options in block.
options [block!]
/case =>
(#Split By Delimiter)
<At an Offset/Index/Position>(#Split at a Position)
(#Split Into Equal Parts)
(#Split Into N Parts)
(#Split Into Uneven Parts)
(#Split Up To N Times)
<By Test Predicate(s)>(#Split By Test Predicates)
(#Split Using Advanced Rules)
Delimited data is a well known format, using a (https://en.wikipedia.org/wiki/Delimiter) to indicate where one thing stops and the next thing starts.
This is the most widely used form of splitting. And many languages have a split function. They also almost all follow a fixed pattern with regard to their spec: split [string delimiter opt limit] I have a hard time believing that the limit feature is /so/ widely useful that it's there on merit. Everybody just copied what came before. Or they say to use regexes. Some langs also added a refinement to omit empty results.
What this model lacks is /any other/ useful feature, like splitting at only the first or last occurrence of the separator. Or /including/ the separator in the result. For example, you want to split /after/ :, keeping it with the left part; or split /before/ uppercase characters, keeping them with the right part. Rust adds some variants, with the result of having 13 different split* functions.
Most telling, for Red, is that other langs only consider strings as the input and characters (sometimes strings), as the separator. This makes sense, but is (#FutureThought) for Red.
Split just once, giving two parts. The data may be marked by a delimiting value, or by the size of the either the first or last part.
Use cases:
Splitting a large file: Each part should be no more than N bytes or may be a dataset where each record is a fixed size. Of course this use case has limits, and a stream based approach, reading and writing each part in sequence should be used for very large files.
Breaking work up: When data has the potential to cause processing errors, it can be helpful to work on smaller parts of the data, both for error handling and user interactions. This is especially true when cumulative errors or resource constraints come into play.
Design questions:
If the input can't be split evenly, should only the last item be shorter, or should the last two items be "leveled" so they are as close in size as possible? If the part of the data is odd in length, they still won't be exactly even.
Only last shorter: [gregg] leveled: []
Use cases:
Distributing work: You have N workers and want to give each a part of the data to work on.
Secure Fragments: Each part is useless, and can't be decrypted, without all the others.
Design questions:
https://gitter.im/red/split?at=618909abd78911028a27db26
If the input can't be split evenly, should only the last item be longer, or should entire result be "leveled" so the parts are as close in size as possible?
Only last longer: [] leveled: [gregg]
Small Fixed Values: YYYYMMDD into [YYYY MM DD], or Mon, 24 Nov 1997 into ["Mon" "24" "Nov" "1997"].
Tabular Data: The much-maligned, but still useful, flat file.
Schema Based Data: A schema/header tells you the size of each part in a payload.
Historical Data: Legacy formats are often based on fixed size fields.
Design questions:
Should the rule be applied only once, or repeatedly across the entire series?
once: [] repeat: [toomas gregg boris jose galen]
When you want to split more than once, but less than every time. This can be useful if you want to check individual parts, and not split any more than necessary once you find what you want. Or when there's more than one "header" part but a trailing payload that may contain separators.
This is a refinement to other splitting options, for how many times to apply them. It is not a standalone algorithm.
Partition data into groups based on one or more tests.
Data Analysis: How many of a particular type of data occur, relative to others? What are the min/max or average values for all the numeric items (first you have to find them)?
Specialize Processing: Break data up into groups of small and large values, or by type, so you can send each to a specific handler.
Design questions:
NAME: [ partition [] group [] filter [] ]
part of split: [gregg] separate: []
group: [gregg] delim: [toomas]
split [1 a 2 b 3 c] :number?
;== [[1 2 3] [a b c]]
split [1 a 2 b 3 c] [:even? :odd?]
;== [[2] [1 3] [a b c]]
Or
split [1 a 2 b 3 c] :number?
;== [[] [a] [b] [c]]]
split [1 a 2 3 b 4 c] [:even? :odd?]
;== [[1 a] [b 4 c]]
split/group [1 a 2 3 b 4 c] [:even? :odd?]
;== [[] [[a] []] [[b] [c]]]
split/group "a,b.c,d." [comma dot]
;== [["a" "b"] ["c" "d"] []]
This same question applies to the map HOF, which Gregg has done
experimentally with multiple args.
one: [] two: []
Think parse+collect.
Literal values (TBD)
Full parse support, or just a subset (TBD, e.g. actions set/get-words)
https://gitter.im/red/split?at=6186752fa41fd206992955bb (chat about how much power user have, the risk of things blowing up on them, and how much flexibility is needed.)
https://gitter.im/red/split?at=618832c5cd4972068b93b1c4
Collect items into groups based on the change in values in the series or matching of a predicate function per Toomas' idea of binary (arity 2) funcs that know the series position and can compare to that, rather than strictly an independent value.
Use Cases:
Run length encoding.
Gregg said: On char-change splitting, I consider this a special case, outside split (group-runs). I think it was @GalenIvanov I chatted to about it recently, noting that it can be used for RLE (Run Length Encoding). In Red we can do that at the value level, not just byte level.
Each function is given confidence ratings, based on its design and implementation. Overall confidence is their average.
A baseline confidence of 8/10 means a function is good enough to be included in a release. Notes about other reasons to exclude functions may also be made. For example, a function may be good enough technically but its purpose doesn't justify inclusion. Inclusion also doesn't mean the function is design or code complete, just that it's good enough for comment, even if changes are pending based on existing discussion.
The goal here is to help prioritize work and do an initial release of some functionality for user feedback and testing.
| Function | Design | Code | Purpose | Overall | Notes |
|---|---|---|---|---|---|
| Split (dialected) | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-r | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-r-v2 | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-r-v3 | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-into-N-parts | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-fixed-parts | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-var-parts | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-at-index | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-once | ?/10 | ?/10 | ?/10 | ?/10 | |
| split-deliimited | ?/10 | ?/10 | ?/10 | ?/10 | |
| partition/group | ?/10 | ?/10 | ?/10 | ?/10 | HOF filter |
| split-image | ?/10 | ?/10 | ?/10 | ?/10 | |
| 2D data split | ?/10 | ?/10 | ?/10 | ?/10 | |
Prior. = Priority for inclusion
Uses = Use cases (should list if using a number of examples)
Purpose and Overall may be removed here
Not all options apply to all splitting types. For example, case and
around make no sense for size-based/offset-based splitting. Reverse
with last is just a confusing way to express a sensible default of
splitting at the first.
Once is technically a special case of N Times but may
| Option | Prior. | Uses | Purpose | Overall | Notes |
|---|---|---|---|---|---|
| Delimited | [tv 1] | ||||
| N Parts | [tv 3] | ||||
| Fixed Parts | [tv 2] | ||||
| Variable Sized Parts | [tv 2] | ||||
| At Index | [tv: /limit .. 1] | ||||
| Once | [tv: /trim/limit .. 1] | ||||
| N Times (Limit) | [tv 2] | ||||
| Parse Rule | [tv 3] | ||||
| Partition/Group | [tv: should be different func] | ||||
| split-image | |||||
| 2D data split | |||||
| case sensitive | [tv 3] | ||||
| before | [tv 2] | ||||
| after | [tv 2] | ||||
| keep delim (around) | [tv 3] | ||||
| first | Default, with last overriding [tv: /limit .. 1] |
||||
| last | [tv: /limit .. -1] | ||||
| Nth | [tv: last split/limit .. n] | ||||
| reverse/tail | [tv 4] | ||||
| only | [tv: in what meaning - treat arg as block?] | ||||
| quoted/as-delim | [tv: /quoted is meaningful only for parse-based; /as-is is alias for /case; /case, /before, /after, /around imply as-is for nums] | ||||
| each | [tv 2] | [tv: if meant as - interpret block as alternatives] | |||
| keep empty values | [tv 3] | ||||
| Nested (2 levels) | [tv 2] | ||||
| Nested (> 2 levels) | [tv 4] | ||||
Isn't filtering always a part of splitting
No. Breaking data at markers, losslessly is an important use case. The simple example in strings is a PascalCaseName broken at uppercase letters, or dialects like draw where you could break at keywords.
(ToomasV) Something like this to split code into expressions:
expression: [s: [
set-word! expression
| [word! | path!] if (all [i: info-ctx/get-info :s/1 a: i/arity]) a expression
| skip
] opt [o: word! if (op? attempt [get/any o/1]) expression]
]
expressions: function [element series][parse series [expression e:] :e]
exs: split-r/after body-of :split :expressions
>> exs/1
== [
=num: =once: =mod: =ord: =pos: =dlm: =ct: =char-word: none
]
>> exs/2
== [
=sub-rule: none
]
>> exs/3
== [
split-rule: [
(=num: =once: =mod: =ord: =pos: =dlm: =ct: =char-word: =sub-rule: no...
General consensus is YES, with splitting into groups and regrouping being
outside split's scope. Split is the opposite of join.
Gregg said:
I think order should be preserved, both for reconstructive purposes (e.g. split on one dlm and rejoin with another), but also for reasoning. That is, a completely random result order would be hard to compare to sources, to see if your splitting rules are being applied as expected. Grouping can preserve relative order within a group, but can't do more than that.
@GalenIvanov raises an interesting point about preserving delimiters in cases where they would normally be removed. Splitting and rejoining makes the second step like merge (sometimes called zip) of two series. But what are the use cases, and are they common enough to be a feature (split is already heavily loaded). Or is a general callback approach worth supporting. So far I've thought about fixed inputs, and of limited size. But large inputs and streams should be considered, and aligns with HOFs, aggregates, and FRP models.
Preserving delimiters also only works in cases where the delimiter is, itself, a value. That narrows the use cases. And if we account for before/after already retaining the delimiter, it narrows further.
or rules.
Quoting in general.
https://gitter.im/red/split?at=6186b8ab9d20982e4f04b5f7
Gregg's thoughts on dialect vs refinements. https://gitter.im/red/split?at=6186c5167db1e3753e863ba6
More from Gregg: https://gitter.im/red/split?at=61969e2263c1e83c9516fa70