模組:Parse utilities
外观
local export = {}
local m_string_utilities = require("Module:string utilities")
local parameters_module = "Module:parameters"
local rfind = mw.ustring.find
local rsplit = mw.text.split
local u = mw.ustring.char
local rsubn = mw.ustring.gsub
-- version of rsubn() that discards all but the first return value
local function rsub(term, foo, bar)
local retval = rsubn(term, foo, bar)
return retval
end
--[==[ intro:
In order to understand the following parsing code, you need to understand how inflected text specs work. They are
intended to work with inflected text where individual words to be inflected may be followed by inflection specs in
angle brackets. The format of the text inside of the angle brackets is up to the individual language and part-of-speech
specific implementation. A real-world example is as follows: `<nowiki>[[медичний|меди́чна]]<+> [[сестра́]]<*,*#.pr></nowiki>`.
This is the inflection of the Ukrainian multiword expression {{m|uk|меди́чна сестра́||nurse|lit=medical sister}},
consisting of two words: the adjective {{m|uk|меди́чна||medical|pos=feminine singular}} and the noun {{m|uk|сестра́||sister}}.
The specs in angle brackets follow each word to be inflected; for example, `<+>` means that the preceding word should be
declined as an adjective.
The code below works in terms of balanced expressions, which are bounded by delimiters such as `< >` or `[ ]`. The
intention is to allow separators such as spaces to be embedded inside of delimiters; such embedded separators will not
be parsed as separators. For example, Ukrainian noun specs allow footnotes in brackets to be inserted inside of angle
brackets; something like `меди́чна<+> сестра́<pr.[this is a footnote]>` is legal, as is
`<nowiki>[[медичний|меди́чна]]<+> [[сестра́]]<pr.[this is an <i>italicized footnote</i>]></nowiki>`, and the parsing code
should not be confused by the embedded brackets, spaces or angle brackets.
The parsing is done by two functions, which work in close concert: {parse_balanced_segment_run()} and
{split_alternating_runs()}. To illustrate, consider the following:
{parse_balanced_segment_run("foo<M.proper noun> bar<F>", "<", ">")} =<br />
{ {"foo", "<M.proper noun>", " bar", "<F>", ""}}
then
{split_alternating_runs({"foo", "<M.proper noun>", " bar", "<F>", ""}, " ")} =<br />
{ {{"foo", "<M.proper noun>", ""}, {"bar", "<F>", ""}}}
Here, we start out with a typical inflected text spec `foo<M.proper noun> bar<F>`, call {parse_balanced_segment_run()} on
it, and call {split_alternating_runs()} on the result. The output of {parse_balanced_segment_run()} is a list where
even-numbered segments are bounded by the bracket-like characters passed into the function, and odd-numbered segments
consist of the surrounding text. {split_alternating_runs()} is called on this, and splits '''only''' the odd-numbered
segments, grouping all segments between the specified character. Note that the inner lists output by
{split_alternating_runs()} are themselves in the same format as the output of {parse_balanced_segment_run()}, with
bracket-bounded text in the even-numbered segments. Hence, such lists can be passed again to {split_alternating_runs()}.
]==]
--[==[
Parse a string containing matched instances of parens, brackets or the like. Return a list of strings, alternating
between textual runs not containing the open/close characters and runs beginning and ending with the open/close
characters. For example,
{parse_balanced_segment_run("foo(x(1)), bar(2)", "(", ")") = {"foo", "(x(1))", ", bar", "(2)", ""}}
]==]
function export.parse_balanced_segment_run(segment_run, open, close)
return m_string_utilities.split(segment_run, "(%b" .. open .. close .. ")")
end
-- The following is an equivalent, older implementation that does not use %b (written before I was aware of %b).
--[=[
function export.parse_balanced_segment_run(segment_run, open, close)
local break_on_open_close = m_string_utilities.split(segment_run, "([%" .. open .. "%" .. close .. "])")
local text_and_specs = {}
local level = 0
local seg_group = {}
for i, seg in ipairs(break_on_open_close) do
if i % 2 == 0 then
if seg == open then
table.insert(seg_group, seg)
level = level + 1
else
assert(seg == close)
table.insert(seg_group, seg)
level = level - 1
if level < 0 then
error("Unmatched " .. close .. " sign: '" .. segment_run .. "'")
elseif level == 0 then
table.insert(text_and_specs, table.concat(seg_group))
seg_group = {}
end
end
elseif level > 0 then
table.insert(seg_group, seg)
else
table.insert(text_and_specs, seg)
end
end
if level > 0 then
error("Unmatched " .. open .. " sign: '" .. segment_run .. "'")
end
return text_and_specs
end
]=]
--[==[
Like parse_balanced_segment_run() but accepts multiple sets of delimiters. For example,
{parse_multi_delimiter_balanced_segment_run("foo[bar(baz[bat])], quux<glorp>", {{"[", "]"}, {"(", ")"}, {"<", ">"}}) =
{"foo", "[bar(baz[bat])]", ", quux", "<glorp>", ""}}.
Each element in the list of delimiter pairs is a string specifying an equivalence class of possible delimiter
characters. You can use this, for example, to allow either "[" or "&#91;" to be treated equivalently, with either
one closed by either "]" or "&#93;". To do this, first replace "&#91;" and "&#93;" with single Unicode
characters such as U+FFF0 and U+FFF1, and then specify a two-character string containing "[" and U+FFF0 as the opening
delimiter, and a two-character string containing "]" and U+FFF1 as the corresponding closing delimiter.
If `no_error_on_unmatched` is given and an error is found during parsing, a string is returned containing the error
message instead of throwing an error.
]==]
function export.parse_multi_delimiter_balanced_segment_run(segment_run, delimiter_pairs, no_error_on_unmatched)
local escaped_delimiter_pairs = {}
local open_to_close_map = {}
local open_close_items = {}
local open_items = {}
for _, open_close in ipairs(delimiter_pairs) do
local open, close = unpack(open_close)
open = rsub(open, "([%[%]%%%%-])", "%%%1")
close = rsub(close, "([%[%]%%%%-])", "%%%1")
table.insert(open_close_items, open)
table.insert(open_close_items, close)
table.insert(open_items, open)
open = "[" .. open .. "]"
close = "[" .. close .. "]"
open_to_close_map[open] = close
table.insert(escaped_delimiter_pairs, {open, close})
end
local open_close_pattern = "([" .. table.concat(open_close_items) .. "])"
local open_pattern = "([" .. table.concat(open_items) .. "])"
local break_on_open_close = m_string_utilities.split(segment_run, open_close_pattern)
local text_and_specs = {}
local level = 0
local seg_group = {}
local open_at_level_zero
for i, seg in ipairs(break_on_open_close) do
if i % 2 == 0 then
table.insert(seg_group, seg)
if level == 0 then
if not rfind(seg, open_pattern) then
local errmsg = "Unmatched close sign " .. seg .. ": '" .. segment_run .. "'"
if no_error_on_unmatched then
return errmsg
else
error(errmsg)
end
end
assert(open_at_level_zero == nil)
for _, open_close in ipairs(escaped_delimiter_pairs) do
local open, close = unpack(open_close)
if rfind(seg, open) then
open_at_level_zero = open
break
end
end
if open_at_level_zero == nil then
error(("Internal error: Segment %s didn't match any open regex"):format(seg))
end
level = level + 1
elseif rfind(seg, open_at_level_zero) then
level = level + 1
elseif rfind(seg, open_to_close_map[open_at_level_zero]) then
level = level - 1
assert(level >= 0)
if level == 0 then
table.insert(text_and_specs, table.concat(seg_group))
seg_group = {}
open_at_level_zero = nil
end
end
elseif level > 0 then
table.insert(seg_group, seg)
else
table.insert(text_and_specs, seg)
end
end
if level > 0 then
local errmsg = "Unmatched open sign " .. open_at_level_zero .. ": '" .. segment_run .. "'"
if no_error_on_unmatched then
return errmsg
else
error(errmsg)
end
end
return text_and_specs
end
--[==[
Check whether a term contains top-level HTML. We want to distinguish inline modifiers from HTML. We assume an inline
modifier is either a boolean modifier like `<bor>` or a prefix modifier like `<tr:Miryem>`. All other things inside of
angle brackets, e.g. `<nowiki><span class="foo"></nowiki>`, `<nowiki></span></nowiki>`, `<nowiki><br/></nowiki>`, etc.,
should be flagged as HTML (typically caused by wrapping an argument in {{tl|m|...}}, {{tl|af|...}} or similar, but
sometimes specified directly, e.g. `<nowiki><sup>6</sup></nowiki>`). By default, we assume the tag in an inline modifier
contains either letters, numbers, hyphens or underscore (but not spaces), and must either stand alone or be followed by
a colon, leading to a default HTML-checking pattern of {"<[%w_%-]*[^%w_%-:>]"}. But this can be modified; e.g.
[[Module:tl-pronunciation]] allows modifiers of the form `<<var>pos</var>^<var>defn</var>>` or
`<<var>pos</var>,<var>pos</var>,<var>pos</var>^<var>defn</var>>`, and would need to use its own HTML pattern. It's
important we restrict the check for HTML to top-level to allow for generated HTML inside of e.g. qualifier tags, such as
`<nowiki>foo<q:similar to {{m|fr|bar}}></nowiki>`.
]==]
function export.term_contains_top_level_html(term, html_pattern)
html_pattern = html_pattern or "<[%w_%-]*[^%w_%-:>]"
-- If no HTML anywhere, the answer is no.
if not term:find(html_pattern) then
return false
end
-- Otherwise, we have to call parse_balanced_segment_run() and check alternate runs at top level.
local runs = export.parse_balanced_segment_run(term, "<", ">")
for i = 2, #runs, 2 do
if runs[i]:find("^" .. html_pattern) then
return true
end
end
return false
end
--[==[
Split a list of alternating textual runs of the format returned by `parse_balanced_segment_run` on `splitchar`. This
only splits the odd-numbered textual runs (the portions between the balanced open/close characters). The return value
is a list of lists, where each list contains an odd number of elements, where the even-numbered elements of the sublists
are the original balanced textual run portions. For example, if we do
{parse_balanced_segment_run("foo<M.proper noun> bar<F>", "<", ">") =
{"foo", "<M.proper noun>", " bar", "<F>", ""}}
then
{split_alternating_runs({"foo", "<M.proper noun>", " bar", "<F>", ""}, " ") =
{{"foo", "<M.proper noun>", ""}, {"bar", "<F>", ""}}}
Note that we did not touch the text "<M.proper noun>" even though it contains a space in it, because it is an
even-numbered element of the input list. This is intentional and allows for embedded separators inside of
brackets/parens/etc. Note also that the inner lists in the return value are of the same form as the input list (i.e.
they consist of alternating textual runs where the even-numbered segments are balanced runs), and can in turn be passed
to split_alternating_runs().
If `preserve_splitchar` is passed in, the split character is included in the output, as follows:
{split_alternating_runs({"foo", "<M.proper noun>", " bar", "<F>", ""}, " ", true) =
{{"foo", "<M.proper noun>", ""}, {" "}, {"bar", "<F>", ""}}}
Consider what happens if the original string has multiple spaces between brackets, and multiple sets of brackets
without spaces between them.
{parse_balanced_segment_run("foo[dated][low colloquial] baz-bat quux xyzzy[archaic]", "[", "]") =
{"foo", "[dated]", "", "[low colloquial]", " baz-bat quux xyzzy", "[archaic]", ""}}
then
{split_alternating_runs({"foo", "[dated]", "", "[low colloquial]", " baz-bat quux xyzzy", "[archaic]", ""}, "[ %-]") =
{{"foo", "[dated]", "", "[low colloquial]", ""}, {"baz"}, {"bat"}, {"quux"}, {"xyzzy", "[archaic]", ""}}}
If `preserve_splitchar` is passed in, the split character is included in the output,
as follows:
{split_alternating_runs({"foo", "[dated]", "", "[low colloquial]", " baz bat quux xyzzy", "[archaic]", ""}, "[ %-]", true) =
{{"foo", "[dated]", "", "[low colloquial]", ""}, {" "}, {"baz"}, {"-"}, {"bat"}, {" "}, {"quux"}, {" "}, {"xyzzy", "[archaic]", ""}}}
As can be seen, the even-numbered elements in the outer list are one-element lists consisting of the separator text.
]==]
function export.split_alternating_runs(segment_runs, splitchar, preserve_splitchar)
local grouped_runs = {}
local run = {}
for i, seg in ipairs(segment_runs) do
if i % 2 == 0 then
table.insert(run, seg)
else
local parts =
preserve_splitchar and m_string_utilities.split(seg, "(" .. splitchar .. ")") or
rsplit(seg, splitchar)
table.insert(run, parts[1])
for j=2,#parts do
table.insert(grouped_runs, run)
run = {parts[j]}
end
end
end
if #run > 0 then
table.insert(grouped_runs, run)
end
return grouped_runs
end
function export.strip_spaces(text)
return rsub(text, "^%s*(.-)%s*$", "%1")
end
--[==[
Apply an arbitrary function `frob` to the "raw-text" segments in a split run set (the output of
split_alternating_runs()). We leave alone stuff within balanced delimiters (footnotes, inflection specs and the
like), as well as splitchars themselves if present. `preserve_splitchar` indicates whether splitchars are present
in the split run set. `frob` is a function of one argument (the string to frob) and should return one argument (the
frobbed string). We operate by only frobbing odd-numbered segments, and only in odd-numbered runs if
preserve_splitchar is given.
]==]
function export.frob_raw_text_alternating_runs(split_run_set, frob, preserve_splitchar)
for i, run in ipairs(split_run_set) do
if not preserve_splitchar or i % 2 == 1 then
for j, segment in ipairs(run) do
if j % 2 == 1 then
run[j] = frob(segment)
end
end
end
end
end
--[==[
Like split_alternating_runs() but applies an arbitrary function `frob` to "raw-text" segments in the result (i.e.
not stuff within balanced delimiters such as footnotes and inflection specs, and not splitchars if present). `frob`
is a function of one argument (the string to frob) and should return one argument (the frobbed string).
]==]
function export.split_alternating_runs_and_frob_raw_text(run, splitchar, frob, preserve_splitchar)
local split_runs = export.split_alternating_runs(run, splitchar, preserve_splitchar)
export.frob_raw_text_alternating_runs(split_runs, frob, preserve_splitchar)
return split_runs
end
--[==[
Split the non-modifier parts of an alternating run (after parse_balanced_segment_run() is called) on a Lua pattern,
but not on certain sequences involving characters in that pattern (e.g. comma+whitespace). `splitchar` is the pattern
to split on; `preserve_splitchar` indicates whether to preserve the delimiter and is the same as in
split_alternating_runs(). `escape_fun` is called beforehand on each run of raw text and should return two values:
the escaped run and whether unescaping is needed. If any call to `escape_fun` indicates that unescaping is needed,
`unescape_fun` will be called on each run of raw text after splitting on `splitchar`. The return value of this
function is as in split_alternating_runs().
]==]
function export.split_alternating_runs_escaping(run, splitchar, preserve_splitchar, escape_fun, unescape_fun)
-- First replace comma with a temporary character in comma+whitespace sequences.
local need_unescape = false
for i, seg in ipairs(run) do
if i % 2 == 1 then
local this_need_unescape
run[i], this_need_unescape = escape_fun(run[i])
need_unescape = need_unescape or this_need_unescape
end
end
if need_unescape then
return export.split_alternating_runs_and_frob_raw_text(run, splitchar, unescape_fun, preserve_splitchar)
else
return export.split_alternating_runs(run, splitchar, preserve_splitchar)
end
end
--[==[
Replace comma with a temporary char in comma + whitespace.
]==]
function export.escape_comma_whitespace(run, tempcomma)
tempcomma = tempcomma or u(0xFFF0)
local escaped = false
if run:find("\\,") then
run = run:gsub("\\,", "\\" .. tempcomma) -- assign to temp to discard second return value
escaped = true
end
if run:find(",%s") then
run = run:gsub(",(%s)", tempcomma .. "%1") -- assign to temp to discard second return value
escaped = true
end
return run, escaped
end
--[==[
Undo the replacement of comma with a temporary char.
]==]
function export.unescape_comma_whitespace(run, tempcomma)
tempcomma = tempcomma or u(0xFFF0)
run = run:gsub(tempcomma, ",") -- assign to temp to discard second return value
return run
end
--[==[
Split the non-modifier parts of an alternating run (after parse_balanced_segment_run() is called) on comma, but not
on comma+whitespace. See `split_on_comma()` above for more information and the meaning of `tempcomma`.
]==]
function export.split_alternating_runs_on_comma(run, tempcomma)
tempcomma = tempcomma or u(0xFFF0)
-- Replace comma with a temporary char in comma + whitespace.
local function escape_comma_whitespace(seg)
return export.escape_comma_whitespace(seg, tempcomma)
end
-- Undo replacement of comma with a temporary char in comma + whitespace.
local function unescape_comma_whitespace(seg)
return export.unescape_comma_whitespace(seg, tempcomma)
end
return export.split_alternating_runs_escaping(run, ",", false, escape_comma_whitespace, unescape_comma_whitespace)
end
--[==[
Split text on a Lua pattern, but not on certain sequences involving characters in that pattern (e.g.
comma+whitespace). `splitchar` is the pattern to split on; `preserve_splitchar` indicates whether to preserve the
delimiter between split segments. `escape_fun` is called beforehand on the text and should return two values: the
escaped run and whether unescaping is needed. If the call to `escape_fun` indicates that unescaping is needed,
`unescape_fun` will be called on each run of text after splitting on `splitchar`. The return value of this a list
of runs, interspersed with delimiters if `preserve_splitchar` is specified.
]==]
function export.split_escaping(text, splitchar, preserve_splitchar, escape_fun, unescape_fun)
if not rfind(text, splitchar) then
return {text}
end
-- If there are square or angle brackets, we don't want to split on delimiters inside of them. To effect this, we
-- use parse_multi_delimiter_balanced_segment_run() to parse balanced brackets, then do delimiter splitting on the
-- non-bracketed portions of text using split_alternating_runs_escaping(), and concatenate back to a list of
-- strings. When calling parse_multi_delimiter_balanced_segment_run(), we make sure not to throw an error on
-- unbalanced brackets; in that case, we fall through to the code below that handles the case without brackets.
if text:find("[%[<]") then
local runs = export.parse_multi_delimiter_balanced_segment_run(text, {{"[", "]"}, {"<", ">"}},
"no error on unmatched")
if type(runs) ~= "string" then
local split_runs = export.split_alternating_runs_escaping(runs, splitchar, preserve_splitchar, escape_fun,
unescape_fun)
for i = 1, #split_runs, (preserve_splitchar and 2 or 1) do
split_runs[i] = table.concat(split_runs[i])
end
return split_runs
end
end
-- First escape sequences we don't want to count for splitting.
local need_unescape
text, need_unescape = escape_fun(text)
local parts =
preserve_splitchar and m_string_utilities.split(text, "(" .. splitchar .. ")") or
rsplit(text, splitchar)
if need_unescape then
for i = 1, #parts, (preserve_splitchar and 2 or 1) do
parts[i] = unescape_fun(parts[i])
end
end
return parts
end
--[==[
Split text on comma, but not on comma+whitespace. This is similar to `mw.text.split(text, ",")` but will not split
on commas directly followed by whitespace, to handle embedded commas in terms (which are almost always followed by
a space). `tempcomma` is the Unicode character to temporarily use when doing the splitting; normally U+FFF0, but
you can specify a different character if you use U+FFF0 for some internal purpose.
]==]
function export.split_on_comma(text, tempcomma)
-- Don't do anything if no comma. Note that split_escaping() has a similar check at the beginning, so if there's a
-- comma we effectively do this check twice, but this is worth it to optimize for the common no-comma case.
if not text:find(",") then
return {text}
end
tempcomma = tempcomma or u(0xFFF0)
-- Replace comma with a temporary char in comma + whitespace.
local function escape_comma_whitespace(run)
return export.escape_comma_whitespace(run, tempcomma)
end
-- Undo replacement of comma with a temporary char in comma + whitespace.
local function unescape_comma_whitespace(run)
return export.unescape_comma_whitespace(run, tempcomma)
end
return export.split_escaping(text, ",", false, escape_comma_whitespace, unescape_comma_whitespace)
end
--[==[
Ensure that Wikicode (template calls, bracketed links, HTML, bold/italics, etc.) displays literally in error messages
by inserting a Unicode word-joiner symbol after all characters that may trigger Wikicode interpretation. Replacing
with equivalent HTML escapes doesn't work because they are displayed literally. I could not get this to work using
<nowiki>...</nowiki> (those tags display literally), using using {{#tag:nowiki|...}} (same thing) or using
mw.getCurrentFrame():extensionTag("nowiki", ...) (everything gets converted to a strip marker
`UNIQ--nowiki-00000000-QINU` or similar). FIXME: This is a massive hack; there must be a better way.
]==]
function export.escape_wikicode(term)
term = term:gsub("([%[<'])", "%1" .. u(0x2060))
return term
end
function export.make_parse_err(arg_gloss)
return function(msg, stack_frames_to_ignore)
error(export.escape_wikicode(("%s: %s"):format(msg, arg_gloss)), stack_frames_to_ignore)
end
end
-- Parse a term that may include a link '[[LINK]]' or a two-part link '[[LINK|DISPLAY]]'. FIXME: Doesn't currently
-- handle embedded links like '[[FOO]] [[BAR]]' or [[FOO|BAR]] [[BAZ]]' or '[[FOO]]s'; if they are detected, it returns
-- the term unchanged and `nil` for the display form.
local function parse_bracketed_term(term, parse_err)
local inside = term:match("^%[%[(.*)%]%]$")
if inside then
if inside:find("%[%[") or inside:find("%]%]") then
-- embedded links, e.g. '[[FOO]] [[BAR]]'; FIXME: we should process them properly
return term, nil
end
local parts = rsplit(inside, "|")
if #parts > 2 then
parse_err("Saw more than two parts inside a bracketed link")
end
return unpack(parts)
end
return term, nil
end
--[==[
Parse a term that may have a language code (or possibly multiple comma-separated language codes, if `allow_multiple`
is given) preceding it (e.g. {la:minūtia} or {grc:[[σκῶρ|σκατός]]} or {nan-hbl,hak:[[毋]][[知]]}). Return four
arguments:
# the term minus the language code;
# the language object corresponding to the language code (possibly a family object if `allow_family` is given), or a
list of such objects if `allow_multiple` is given;
# the link if the term is of the form {[[<var>link</var>|<var>display</var>]]} (it may be generated into that form with
Wikipedia and Wikisource prefixes) or of the form {{[[<var>link</var>]]}, otherwise the full term;
# the display part if the term is of the form {[[<var>link</var>|<var>display</var>]]}, otherwise nil.
Etymology-only languages are allowed. This function also correctly handles Wikipedia prefixes (e.g. {w:Abatemarco}
or {w:it:Colle Val d'Elsa} or {lw:ru:Филарет}) and Wikisource prefixes (e.g. {s:Twelve O'Clock} or
{s:[[Walden/Chapter XVIII|Walden]]} or {s:fr:Perceval ou le conte du Graal} or {s:ro:[[Domnul Vucea|Mr. Vucea]]} or
{ls:ko:이상적 부인} or {ls:ko:[[조선 독립의 서#一. 槪論|조선 독립의 서]]}) and converts them into two-part links,
with the display form not including the Wikipedia or Wikisource prefix unless it was explicitly specified using a
two-part link as in {lw:ru:[[Филарет (Дроздов)|Митрополи́т Филаре́т]]} or
{ls:ko:[[조선 독립의 서#一. 槪論|조선 독립의 서]]}. The difference between {w:} ("Wikipedia") and {lw:} ("Wikipedia
link") is that the latter requires a language code and returns the corresponding language object; same for the
difference between {s:} ("Wikisource") and {ls:} ("Wikisource link").
NOTE: Embedded links are not correctly handled currently. If an embedded link is detected, the whole term is returned
as the link part (third argument), and the display part is nil. If you construct your own link from the link and
display parts, you must check for this.
`parse_err_or_paramname` is an optional function of one or two arguments to display an error, or a string naming a
parameter to display in the error message. If omitted, a function is generated based off of `term`. (The second
argument to the function is the number of stack frames to ignore when calling error(); if you declare your error
function with only one argument, things will still work fine.)
]==]
function export.parse_term_with_lang(data_or_term, parse_err_or_paramname)
if type(data_or_term) == "string" then
data_or_term = {
term = data_or_term
}
if type(parse_err_or_paramname) == "function" then
data_or_term.parse_err = parse_err_or_paramname
else
data_or_term.paramname = parse_err_or_paramname
end
end
local term = data_or_term.term
local parse_err = data_or_term.parse_err or
data_or_term.paramname and export.make_parse_err(("%s=%s"):format(data_or_term.paramname, term)) or
export.make_parse_err(term)
-- Parse off an initial language code (e.g. 'la:minūtia' or 'grc:[[σκῶρ|σκατός]]'). First check for Wikipedia
-- prefixes ('w:Abatemarco' or 'w:it:Colle Val d'Elsa' or 'lw:zh:邹衡') and Wikisource prefixes
-- ('s:ro:[[Domnul Vucea|Mr. Vucea]]' or 'ls:ko:이상적 부인'). Wikipedia/Wikisource language codes follow a similar
-- format to Wiktionary language codes (see below). Here and below we don't parse if there's a space after the
-- colon (happens e.g. if the user uses {{desc|...}} inside of {{col}}, grrr ...).
local termlang, foreign_wiki, actual_term = term:match("^(l?[ws]):([a-z][a-z][a-z-]*):([^ ].*)$")
if not termlang then
termlang, actual_term = term:match("^([ws]):([^ ].*)$")
end
if termlang then
local wiki_links = termlang:find("^l")
local base_wiki_prefix = termlang:find("w$") and "w:" or "s:"
local wiki_prefix = base_wiki_prefix .. (foreign_wiki and foreign_wiki .. ":" or "")
local link, display = parse_bracketed_term(actual_term, parse_err)
if link:find("%[%[") or display and display:find("%[%[") then
-- FIXME, this should be handlable with the right parsing code
parse_err("Cannot have embedded brackets following a Wikipedia (w:... or lw:...) link; expand the term to a fully bracketed term w:[[LINK|DISPLAY]] or similar")
end
local lang = wiki_links and require("Module:languages").getByCode(foreign_wiki, parse_err, "allow etym") or nil
local prefixed_link = wiki_prefix .. link
return ("[[%s|%s]]"):format(prefixed_link, display or link), lang, prefixed_link, display
end
-- Wiktionary language codes are in one of the following formats, where 'x' is a lowercase letter and 'X' an
-- uppercase letter:
-- xx
-- xxx
-- xxx-xxx
-- xxx-xxx-xxx (esp. for protolanguages)
-- xx-xxx (for etymology-only languages)
-- xx-xxx-xxx (maybe? for etymology-only languages)
-- xx-XX (for etymology-only languages, where XX is a country code, e.g. en-US)
-- xxx-XX (for etymology-only languages, where XX is a country code)
-- xx-xxx-XX (for etymology-only languages, where XX is a country code)
-- xxx-xxx-XX (for etymology-only langauges, where XX is a country code, e.g. nan-hbl-PH)
-- Things like xxx-x+ (e.g. cmn-pinyin, cmn-tongyong)
-- VL., LL., etc.
--
-- We check the for nonstandard Latin etymology language codes separately, and otherwise make only the following
-- assumptions:
-- (1) There are one to three hyphen-separated components.
-- (2) The last component can consist of two uppercase ASCII letters; otherwise, all components contain only
-- lowercase ASCII letters.
-- (3) Each component must have at least two letters.
-- (4) The first component must have two or three letters.
local function is_possible_lang_code(code)
-- Special hack for Latin variants, which can have nonstandard etym codes, e.g. VL., LL.
if code:find("^[A-Z]L%.$") then
return true
end
return code:find("^([a-z][a-z][a-z]?)$") or
code:find("^[a-z][a-z][a-z]?%-[A-Z][A-Z]$") or
code:find("^[a-z][a-z][a-z]?%-[a-z][a-z]+$") or
code:find("^[a-z][a-z][a-z]?%-[a-z][a-z]+%-[A-Z][A-Z]$") or
code:find("^[a-z][a-z][a-z]?%-[a-z][a-z]+%-[a-z][a-z]+$")
end
local function get_by_code(code, allow_bad)
local lang
if data_or_term.lang_cache then
lang = data_or_term.lang_cache[code]
end
if lang == nil then
lang = require("Module:languages").getByCode(code, not allow_bad and parse_err or nil, "allow etym",
data_or_term.allow_family)
if data_or_term.lang_cache then
data_or_term.lang_cache[code] = lang or false
end
end
return lang or nil
end
if data_or_term.allow_multiple then
local termlang_spec
termlang_spec, actual_term = term:match("^([a-zA-Z.,-]+):([^ ].*)$")
if termlang_spec then
termlang = rsplit(termlang_spec, ",")
local all_possible_code = true
for _, code in ipairs(termlang) do
if not is_possible_lang_code(code) then
all_possible_code = false
break
end
end
if all_possible_code then
local saw_nil = false
for i, code in ipairs(termlang) do
termlang[i] = get_by_code(code, data_or_term.allow_bad)
if not termlang[i] then
saw_nil = true
end
end
if saw_nil then
termlang = nil
else
term = actual_term
end
else
termlang = nil
end
end
else
termlang, actual_term = term:match("^([a-zA-Z.-]+):([^ ].*)$")
if termlang then
if is_possible_lang_code(termlang) then
termlang = get_by_code(termlang, data_or_term.allow_bad)
if termlang then
term = actual_term
end
else
termlang = nil
end
end
end
local link, display = parse_bracketed_term(term, parse_err)
return term, termlang, link, display
end
--[==[
Parse a term that may have inline modifiers attached (e.g. {rifiuti<q:plural-only>} or
{rinfusa<t:bulk cargo><lit:resupplying><qq:more common in the plural {{m|it|rinfuse}}>}).
* `arg` is the term to parse.
* `props` is an object holding further properties controlling how to parse the term (only `param_mods` and
`generate_obj` are required):
** `paramname` is the name of the parameter where `arg` comes from, or nil if this isn't available (it is used only in
error messages).
** `param_mods` is a table describing the allowed inline modifiers (see below).
** `generate_obj` is a function of one or two arguments that should parse the argument minus the inline modifiers and
return a corresponding parsed object (into which the inline modifiers will be rewritten). If declared with one
argument, that will be the raw value to parse; if declared with two arguments, the second argument will be the
`parse_err` function (see below).
** `parse_err` is an optional function of one argument (an error message) and should display the error message, along
with any desired contextual text (e.g. the argument name and value that triggered the error). If omitted, a default
function will be generated which displays the error along with the original value of `arg` (passed through
{escape_wikicode()} above to ensure that Wikicode (such as links) is displayed literally).
** `splitchar` is a Lua pattern. If specified, `arg` can consist of multiple delimiter-separated terms, each of which
may be followed by inline modifiers, and the return value will be a list of parsed objects instead of a single
object. Note that splitting on delimiters will not happen in certain protected sequences (by default
comma+whitespace; see below). The algorithm to split on delimiters is sensitive to inline modifier syntax and will
not be confused by delimiters inside of inline modifiers, which do not trigger splitting (whether or not contained
within protected sequences).
** `outer_container`, if specified, is used when multiple delimiter-separated terms are possible, and is the object
into which the list of per-term objects is stored (into the `terms` field) and into which any modifiers that are
given the `overall` property (see below) will be stored. If given, this value will be returned as the value of
{parse_inline_modifiers()}. If `outer_container` is not given, {parse_inline_modifiers()} will return the list of
per-term objects directly, and no modifier may have an `overall` property.
** `preserve_splitchar`, if specified, causes the actual delimiter matched by `splitchar` to be returned in the
parsed object describing the element that comes after the delimiter. The delimiter is stored in a key whose
name is controlled by `separator_key`, which defaults to "separator".
** `separator_key` controls the key into which the actual delimiter is written when `preserve_splitchar` is used.
See above.
** `escape_fun` and `unescape_fun` are as in split_escaping() and split_alternating_runs_escaping() above and
control the protected sequences that won't be split. By default, `escape_comma_whitespace` and
`unescape_comma_whitespace` are used, so that comma+whitespace sequences won't be split.
** `pre_normalize_modifiers`, if specified, is a function of one argument, which can be used to "normalize" modifiers
prior to further parsing. This is used, for example, in [[Module:tl-pronunciation]] to convert modifiers of the
form `<noun^expectation; hope>` to `<t:noun^expectation; hope>`, so they can be processed as standard modifiers. It
is also used in [[Module:ar-verb]] to convert footnotes of the form `[rare]` to `<footnote:[rare]>`, to allow for
mixing bracketed footnotes and inline modifiers when overriding verbal nouns and such. It could similarly be used to
handle boolean modifiers like `<slb>` in {{tl|desc}} and convert them to a standard form `<slb:1>`. It runs just
before parsing out the modifier prefix and value, and is passed an object containing fields `modtext` (the
un-normalized modifier text, including surrounding angle brackets, or in some cases, text surrounded by other
delimiters such as square brackets, if `parse_inline_modifiers_from_segments()` is being called and the caller did
their own parsing of balanced segment runs) and `parse_err` (the passed-in or autogenerated function to signal an
error during parsing; a function of one argument, a message, which throws an error displaying that message). It
should return a single value, the normalized value of `modtext`, including surrounding angle brackets.
`param_mods` is a table describing allowed modifiers. The keys of the table are modifier prefixes and the values are
tables describing how to parse and store the associated modifier values. Here is a typical example, for an item that
takes the standard modifiers associated with `full_link()` in [[Module:links]], as well as left and right qualifiers
and labels:
{
local param_mods = {
alt = {},
t = {
-- [[Module:links]] expects the gloss in "gloss".
item_dest = "gloss",
},
gloss = {},
tr = {},
ts = {},
g = {
-- [[Module:links]] expects the genders in "g". `sublist = true` automatically splits on comma (optionally
-- with surrounding whitespace).
item_dest = "genders",
sublist = true,
},
pos = {},
lit = {},
id = {},
sc = {
-- Automatically parse as a script code and convert to a script object.
type = "script",
},
-- Qualifiers and labels
q = {
type = "qualifier",
},
qq = {
type = "qualifier",
},
l = {
type = "labels",
},
ll = {
type = "labels",
},
}
}
In the table values:
* `item_dest` specifies the destination key to store the object into (if not the same as the modifier key itself).
* `type`, `set`, `sublist` and `convert` have the same meaning as in [[Module:parameters]] and are used for converting
the object from the string form given by the user into the form needed for further processing. Note that `type` makes
use of additional properties that may be specified. Specifically, if {type = "language"}, the properties `family` and
`method` are also examined, and if {type = "family"} or {type = "script"}, the property `method` is examined.
* `store` describes how to store the converted modifier value into the parsed object. If omitted, the converted value
is simply written into the parsed object under the appropriate key; but an error is generated if the key already has
a value. (This means that multiple occurrences of a given modifier are allowed if `store` is given, but not
otherwise.) `store` can be one of the following:
** {"insert"}: the converted value is appended to the key's value using {table.insert()}; if the key has no value, it
is first converted to an empty list;
** {"insertIfNot"}: is similar but appends the value using {insertIfNot()} in [[Module:table]];
** {"insert-flattened"}, the converted value is assumed to be a list and the objects are appended one-by-one into the
key's existing value using {table.insert()};
** {"insertIfNot-flattened"} is similar but appends using {insertIfNot()} in [[Module:table]]; (WARNING: When using
{"insert-flattened"} and {"insertIfNot-flattened"}, if there is no existing value for the key, the converted value is
just stored directly. This means that future appends will side-effect that value, so make sure that the return value
of the conversion function for this key generates a fresh list each time.)
** a function of one argument, an object with the following properties:
*** `dest`: the object to write the value into;
*** `key`: the field where the value should be written;
*** `converted`: the (converted) value to write;
*** `raw_val`: the raw, user-specified value (a string);
*** `parse_err`: a function of one argument (an error string), which signals an error, and includes extra context in
the message about the modifier in question, the angle-bracket spec that includes the modifier in it, the overall
value, and (if `paramname` was given) the parameter holding the overall value.
* `overall` only applies if `splitchar` is given. In this case, the modifier applies to the entire argument rather than
to an individual term in the argument, and must occur after the last item separated by `splitchar`, instead of being
allowed to occur after any of them. The modifier will be stored into the outer container object, which must exist
(i.e. `outer_container` must have been given).
The return value of {parse_inline_modifiers()} depends on whether `splitchar` and `outer_container` have been given. If
neither is given, the return value is the object returned by `generate_obj`. If `splitchar` but not `outer_container` is
given, the return value is a list of per-term objects, each of which is generated by `generate_obj`. If both `splitchar`
and `outer_container` are given, the return value is the value of `outer_container` and the per-term objects are stored
into the `terms` field of this object.
]==]
function export.parse_inline_modifiers(arg, props)
local segments = export.parse_balanced_segment_run(arg, "<", ">")
local function verify_no_overall()
for mod, mod_props in pairs(props.param_mods) do
if mod_props.overall then
error("Internal caller error: Can't specify `overall` for a modifier in `param_mods` unless `outer_container` property is given")
end
end
end
if not props.splitchar then
if props.outer_container then
error("Internal caller error: Can't specify `outer_container` property unless `splitchar` is given")
end
verify_no_overall()
return export.parse_inline_modifiers_from_segments {
group = segments,
group_index = nil,
separated_groups = nil,
arg = arg,
props = props
}
else
local terms = {}
if props.outer_container then
props.outer_container.terms = terms
else
verify_no_overall()
end
local separated_groups = export.split_alternating_runs_escaping(segments, props.splitchar,
props.preserve_splitchar, props.escape_fun or export.escape_comma_whitespace,
props.unescape_fun or export.unescape_comma_whitespace)
for j = 1, #separated_groups, (props.preserve_splitchar and 2 or 1) do
local parsed = export.parse_inline_modifiers_from_segments {
group = separated_groups[j],
group_index = j,
separated_groups = separated_groups,
arg = arg,
props = props
}
if props.preserve_splitchar and j > 1 then
parsed[props.separator_key or "separator"] = separated_groups[j - 1][1]
end
table.insert(terms, parsed)
end
if props.outer_container then
return props.outer_container
else
return terms
end
end
end
--[==[
Parse a single term that may have inline modifiers attached. This is a helper function of {parse_inline_modifiers()} but
is exported separately in case the caller needs to make their own call to {parse_balanced_segment_run()} (as in
[[Module:quote]], which splits on several matched delimiters simultaneously). It takes only a single argument, `data`,
which is an object with the following fields:
* `group`: A list of segments as output by {parse_balanced_segment_run()} (see the overall comment at the top of
[[Module:parse utilities]]), or one of the lists returned by calling {split_alternating_runs()}.
* `separated_groups`: The list of groups (each of which is of the form of `group`) describing all the terms in the
argument parsed by {parse_inline_modifiers()}, or {nil} if this isn't applicable (i.e. multiple terms aren't allowed
in the argument).
* `group_index`: The index into `separated_groups` where `group` can be found, or {nil} if not applicable (see below).
* `arg`: The original user-specified argument being parsed; used only for error messages and only when `props.parse_err`
is not specified.
* `props`: The `props` argument to {parse_inline_modifiers()}.
The return value is the object created by `generate_obj`, with properties filled in describing the modifiers of the
term in question. Note that `props.outer_container` and the `overall` setting of the `props.param_mods` structure are
respected, but `props.splitchar` is ignored because the splitting happens in the caller. Specifically, if there are any
modifiers with the `overall` setting, `props.separated_groups` and `props.group_index` must be given so that the
function is able to determine if the modifier is indeed attached to the last term, and `props.outer_container` must be
given because that is where such modifiers are stored. Otherwise, none of these settings need be given.
]==]
function export.parse_inline_modifiers_from_segments(data)
local props = data.props
local group = data.group
local function get_valid_prefixes()
local valid_prefixes = {}
for param_mod, _ in pairs(props.param_mods) do
table.insert(valid_prefixes, param_mod)
end
table.sort(valid_prefixes)
return valid_prefixes
end
local function get_arg_gloss()
if props.paramname then
return ("%s=%s"):format(props.paramname, data.arg)
else
return data.arg
end
end
local parse_err = props.parse_err or export.make_parse_err(get_arg_gloss())
local term_obj = props.generate_obj(group[1], parse_err)
for k = 2, #group - 1, 2 do
if group[k + 1] ~= "" then
parse_err("Extraneous text '" .. group[k + 1] .. "' after modifier")
end
local group_k = group[k]
if props.pre_normalize_modifiers then
-- FIXME: For some use cases, we might have to pass more information.
group_k = props.pre_normalize_modifiers {
modtext = group_k,
parse_err = parse_err
}
end
local modtext = group_k:match("^<(.*)>$")
if not modtext then
parse_err("Internal error: Modifier '" .. group_k .. "' isn't surrounded by angle brackets")
end
local prefix, val = modtext:match("^([a-zA-Z0-9+_-]+):(.*)$")
if not prefix then
local valid_prefixes = get_valid_prefixes()
for i, valid_prefix in ipairs(valid_prefixes) do
valid_prefixes[i] = "'" .. valid_prefix .. ":'"
end
parse_err(("Modifier %s%s lacks a prefix, should begin with one of %s"):format(
group_k, group_k ~= group[k] and (" (normalized from %s)"):format(group[k]) or "",
require("Module:table").serialCommaJoin(valid_prefixes, {dontTag = true})))
end
local prefix_parse_err
if props.parse_err then
prefix_parse_err = function(msg, stack_frames_to_ignore)
props.parse_err(("%s: modifier prefix '%s' in %s"):format(msg, prefix, group[k]),
stack_frames_to_ignore)
end
else
prefix_parse_err = export.make_parse_err(("modifier prefix '%s' in %s in %s"):format(
prefix, group[k], get_arg_gloss()))
end
if props.param_mods[prefix] then
local mod_props = props.param_mods[prefix]
local key = mod_props.item_dest or prefix
local dest
if mod_props.overall then
if not data.separated_groups then
prefix_parse_err("Internal error: `data.separated_groups` not given when `overall` is seen")
end
if not props.outer_container then
-- This should have been caught earlier during validation in parse_inline_modifiers().
prefix_parse_err("Internal error: `props.outer_container` not given when `overall` is seen")
end
if data.group_index ~= #data.separated_groups then
prefix_parse_err("Prefix should occur after the last comma-separated term")
end
dest = props.outer_container
else
dest = term_obj
end
local converted = val
if mod_props.type or mod_props.set or mod_props.sublist or mod_props.convert then
-- WARNING: Here as an optimization we embed some knowledge of convert_val() in [[Module:parameters]],
-- specifically that if none of `type`, `set`, `sublist` and `convert` are set, the conversion is an
-- identity operation and can be skipped. (convert_val() also makes use of the fields `method` and
-- `family`, but only if `type` is set to certain values such as "language", "family" or "script", and
-- makes use of the field `required`, but only if `set` is set.) If this becomes problematic, consider
-- removing the optimization.
converted = require(parameters_module).convert_val(converted, prefix_parse_err, mod_props)
end
local store = props.param_mods[prefix].store
if not store then
if dest[key] then
prefix_parse_err("Prefix occurs twice")
end
dest[key] = converted
elseif store == "insert" then
if not dest[key] then
dest[key] = {converted}
else
table.insert(dest[key], converted)
end
elseif store == "insertIfNot" then
if not dest[key] then
dest[key] = {converted}
else
require("Module:table").insertIfNot(dest[key], converted)
end
elseif store == "insert-flattened" then
if not dest[key] then
dest[key] = converted
else
for _, obj in ipairs(converted) do
table.insert(dest[key], obj)
end
end
elseif store == "insertIfNot-flattened" then
if not dest[key] then
dest[key] = converted
else
for _, obj in ipairs(converted) do
require("Module:table").insertIfNot(dest[key], obj)
end
end
elseif type(store) == "string" then
prefix_parse_err(("Internal caller error: Unrecognized value '%s' for `store` property"):format(store))
elseif type(store) ~= "function" then
prefix_parse_err(("Internal caller error: Unrecognized type for `store` property %s"):format(
mw.dumpObject(store)))
else
store {
dest = dest,
key = key,
converted = converted,
raw = val,
parse_err = prefix_parse_err
}
end
else
local valid_prefixes = get_valid_prefixes()
for i, valid_prefix in ipairs(valid_prefixes) do
valid_prefixes[i] = "'" .. valid_prefix .. "'"
end
prefix_parse_err("Unrecognized prefix, should be one of " ..
require("Module:table").serialCommaJoin(valid_prefixes, {dontTag = true}))
end
end
return term_obj
end
return export