frontend/syntax.asdl

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1	# Data types for the Oils AST, aka "Lossless Syntax Tree".
2	#
3	# Invariant: the source text can be reconstructed byte-for-byte from this tree.
4	# The test/lossless.sh suite verifies this.
5
6	# We usually try to preserve the physical order of the source in the ASDL
7	# fields. One exception is the order of redirects:
8	#
9	# echo >out.txt hi
10	# # versus
11	# echo hi >out.txt
12
13	# Unrepresented:
14	# - let arithmetic (rarely used)
15	# - coprocesses # one with arg and one without
16	# - select block
17
18	# Possible refactorings:
19	#
20	# # %CompoundWord as first class variant:
21	# bool_expr = WordTest %CompoundWord \| ...
22	#
23	# # Can DoubleQuoted have a subset of parts compared with CompoundWord?
24	# string_part = ... # subset of word_part
25	#
26	# - Distinguish word_t with BracedTree vs. those without? seq_word_t?
27
28	module syntax
29	{
30	use core value {
31	value LiteralBlock
32	}
33
34	# More efficient than the List[bool] pattern we've been using
35	BoolParamBox = (bool b)
36	IntParamBox = (int i)
37
38	# core/main_loop.py
39	parse_result = EmptyLine \| Eof \| Node(command cmd)
40
41	# 'source' represents the location of a line / token.
42	source =
43	Interactive
44	\| Headless
45	\| Unused(str comment) # completion and history never show parse errors?
46	\| CFlag
47	\| Stdin(str comment)
48
49	# oshrc/ysh are considered a MainFile - loaded directly by the shell
50	\| MainFile(str path)
51	# TODO: if it's not the main script, it's sourced or a module/ and you
52	# could provide a chain of locations back to the sourced script!
53	\| OtherFile(str path, loc location)
54
55	# code parsed from a word
56	# used for 'eval', 'trap', 'printf', 'complete -W', parseCommand()
57	\| Dynamic(str what, loc location)
58
59	# code parsed from the value of a variable
60	# used for $PS1 $PROMPT_COMMAND
61	\| Variable(str var_name, loc location)
62
63	# Point to the original variable reference
64	\| VarRef(Token orig_tok)
65
66	# alias expansion (location of first word)
67	\| Alias(str argv0, loc argv0_loc)
68
69	# 2 kinds of reparsing: backticks, and x+1 in a[x+1]=y
70	# TODO: use this for eval_unsafe_arith instead of Variable
71	\| Reparsed(str what, Token left_token, Token right_token)
72
73	# For --location-str
74	\| Synthetic(str s)
75
76	SourceLine = (int line_num, str content, source src)
77
78	# Note that ASDL generates:
79	# typedef uint16_t Id_t;
80	# So Token is
81	# 8 bytes GC header + 2 + 2 + 4 + 8 + 8 = 32 bytes on 64-bit machines
82	#
83	# We transpose (id, col, length) -> (id, length, col) for C struct packing.
84	Token = (id id, uint16 length, int col, SourceLine? line, str? tval)
85
86	# I wanted to get rid of Token.tval with this separate WideToken type, but it
87	# is more efficient if word_part.Literal %Token literally is the same thing
88	# that comes out of the lexer. Otherwise we have extra garbage.
89
90	# WideToken = (id id, int length, int col, SourceLine? line, str? tval)
91
92	# Slight ASDL bug: CompoundWord has to be defined before using it as a shared
93	# variant. The _product_counter algorithm should be moved into a separate
94	# tag-assigning pass, and shared between gen_python.py and gen_cpp.py.
95	CompoundWord = (List[word_part] parts)
96
97	# Source location for errors
98	loc =
99	Missing # equivalent of runtime.NO_SPID
100	\| Token %Token
101	# Very common case: argv arrays need original location
102	\| ArgWord %CompoundWord
103	\| WordPart(word_part p)
104	\| Word(word w)
105	\| Arith(arith_expr a)
106	# e.g. for errexit blaming
107	\| Command(command c)
108	# the location of a token that's too long
109	\| TokenTooLong(SourceLine line, id id, int length, int col)
110
111	debug_frame =
112	Main(str dollar0)
113	# call_loc => BASH_LINENO
114	# call_loc may be None with new --source flag?
115	\| Source(Token? call_tok, str source_name)
116	# def_tok => BASH_SOURCE
117	# call_loc may be None if invoked via RunFuncForCompletion?
118	\| Call(Token? call_tok, Token def_tok, str func_name)
119
120	#
121	# Shell language
122	#
123
124	bracket_op =
125	WholeArray(id op_id) # * or @
126	\| ArrayIndex(arith_expr expr)
127
128	suffix_op =
129	Nullary %Token # ${x@Q} or ${!prefix@} (which also has prefix_op)
130	\| Unary(Token op, rhs_word arg_word) # e.g. ${v:-default}
131	# TODO: Implement YSH ${x\|html} and ${x %.3f}
132	\| Static(Token tok, str arg)
133	\| PatSub(CompoundWord pat, rhs_word replace, id replace_mode, Token slash_tok)
134	# optional begin is arith_expr.EmptyZero
135	# optional length is None, because it's handled in a special way
136	\| Slice(arith_expr begin, arith_expr? length)
137
138	BracedVarSub = (
139	Token left, # in dynamic ParseVarRef, same as name_tok
140	Token token, # location for the name
141	str var_name, # the name - TODO: remove this, use LazyStr() instead
142	Token? prefix_op, # prefix # or ! operators
143	bracket_op? bracket_op,
144	suffix_op? suffix_op,
145	Token right # in dynamic ParseVarRef, same as name_tok
146	)
147
148	# Variants:
149	# - Look at left token ID for $'' c'' vs r'' '' e.g. Id.Left_DollarSingleQuote
150	# - And """ and ''' e.g. Id.Left_TDoubleQuote
151	DoubleQuoted = (Token left, List[word_part] parts, Token right)
152
153	# Consider making str? sval LAZY, like lexer.LazyStr(tok)
154	SingleQuoted = (Token left, str sval, Token right)
155
156	# e.g. Id.VSub_QMark, Id.VSub_DollarName $foo with lexer.LazyStr()
157	SimpleVarSub = (Token tok)
158
159	CommandSub = (Token left_token, command child, Token right)
160
161	# - can contain word.BracedTree
162	# - no 'Token right' for now, doesn't appear to be used
163	ShArrayLiteral = (Token left, List[word] words, Token right)
164
165	# Unevaluated, typed arguments for func and proc.
166	# Note that ...arg is expr.Spread.
167	ArgList = (
168	Token left, List[expr] pos_args,
169	Token? semi_tok, List[NamedArg] named_args,
170	Token? semi_tok2, expr? block_expr,
171	Token right
172	)
173
174	AssocPair = (CompoundWord key, CompoundWord value)
175
176	word_part =
177	ShArrayLiteral %ShArrayLiteral
178	\| BashAssocLiteral(Token left, List[AssocPair] pairs, Token right)
179	\| Literal %Token
180	# escaped case is separate so the evaluator doesn't have to check token ID
181	\| EscapedLiteral(Token token, str ch)
182	\| SingleQuoted %SingleQuoted
183	\| DoubleQuoted %DoubleQuoted
184	# Could be SimpleVarSub %Token that's VSub_DollarName, but let's not
185	# confuse with the comon word_part.Literal is common for wno
186	\| SimpleVarSub %SimpleVarSub
187	\| BracedVarSub %BracedVarSub
188	\| ZshVarSub (Token left, CompoundWord ignored, Token right)
189	# For command sub and process sub: $(...) <(...) >(...)
190	\| CommandSub %CommandSub
191	# ~ or ~bob
192	\| TildeSub(Token left, # always the tilde
193	Token? name, str? user_name)
194	\| ArithSub(Token left, arith_expr anode, Token right)
195	# {a,b,c}
196	\| BracedTuple(List[CompoundWord] words)
197	# {1..10} or {-5..10..2} or {01..10} (leading zeros matter)
198	# {a..f} or {a..f..2} or {a..f..-2}
199	# the whole range is one Token,
200	\| BracedRange(Token blame_tok, id kind, str start, str end, int step)
201	# extended globs are parsed statically, unlike globs
202	\| ExtGlob(Token op, List[CompoundWord] arms, Token right)
203	# a regex group is similar to an extended glob part
204	\| BashRegexGroup(Token left, CompoundWord? child, Token right)
205
206	# YSH word_part extensions
207
208	# @myarray - Id.Lit_Splice (could be optimized to %Token)
209	\| Splice(Token blame_tok, str var_name)
210	# $[d.key], etc.
211	\| ExprSub(Token left, expr child, Token right)
212
213	# Use cases for Empty: RHS of 'x=', the argument in "${x:-}".
214	# The latter is semantically necessary. (See osh/word_parse.py).
215	# At runtime: RHS of 'declare x='.
216	rhs_word = Empty \| Compound %CompoundWord
217
218	word =
219	# Returns from WordParser, but not generally stored in LST
220	Operator %Token
221	# A Compound word can contain any word_part except the Braced*Part.
222	# We could model this with another variant type but it incurs runtime
223	# overhead and seems like overkill. Note that DoubleQuoted can't
224	# contain a SingleQuoted, etc. either.
225	\| Compound %CompoundWord
226	# For word sequences command.Simple, ShArrayLiteral, for_iter.Words
227	# Could be its own type
228	\| BracedTree(List[word_part] parts)
229	# For dynamic parsing of test aka [ - the string is already evaluated.
230	\| String(id id, str s, CompoundWord? blame_loc)
231
232	# Note: the name 'foo' is derived from token value 'foo=' or 'foo+='
233	sh_lhs =
234	Name(Token left, str name) # Lit_VarLike foo=
235	# TODO: Could be Name %Token
236	\| IndexedName(Token left, str name, arith_expr index)
237	\| UnparsedIndex(Token left, str name, str index) # for translation
238
239	arith_expr =
240	EmptyZero # these are valid: $(( )) (( )) ${a[@]: : }
241	\| EmptyOne # condition is 1 for infinite loop: for (( ; ; ))
242	\| VarSub %Token # e.g. $(( x )) Id.Arith_VarLike
243	\| Word %CompoundWord # e.g. $(( 123'456'$y ))
244
245	\| UnaryAssign(id op_id, arith_expr child)
246	\| BinaryAssign(id op_id, arith_expr left, arith_expr right)
247
248	\| Unary(id op_id, arith_expr child)
249	\| Binary(Token op, arith_expr left, arith_expr right)
250	\| TernaryOp(arith_expr cond, arith_expr true_expr, arith_expr false_expr)
251
252	bool_expr =
253	WordTest(word w) # e.g. [[ myword ]]
254	\| Binary(id op_id, word left, word right)
255	\| Unary(id op_id, word child)
256	\| LogicalNot(bool_expr child)
257	\| LogicalAnd(bool_expr left, bool_expr right)
258	\| LogicalOr(bool_expr left, bool_expr right)
259
260	redir_loc =
261	Fd(int fd) \| VarName(str name)
262
263	redir_param =
264	Word %CompoundWord
265	\| HereWord(CompoundWord w, bool is_multiline)
266	\| HereDoc(word here_begin, # e.g. EOF or 'EOF'
267	Token? here_end_tok, # Token consisting of the whole line
268	# It's always filled in AFTER creation, but
269	# temporarily so optional
270	List[word_part] stdin_parts # one for each line
271	)
272
273	Redir = (Token op, redir_loc loc, redir_param arg)
274
275	assign_op = Equal \| PlusEqual
276	AssignPair = (Token left, sh_lhs lhs, assign_op op, rhs_word rhs)
277	# TODO: could put Id.Lit_VarLike foo= into LazyStr() with -1 slice
278	EnvPair = (Token left, str name, rhs_word val)
279
280	condition =
281	Shell(List[command] commands) # if false; true; then echo hi; fi
282	\| YshExpr(expr e) # if (x > 0) { echo hi }
283	# TODO: add more specific blame location
284
285	# Each arm tests one word against multiple words
286	# shell: .cc\|.h) echo C++ ;;
287	# YSH: .cc\|.h { echo C++ }
288	#
289	# Three location tokens:
290	# 1. left - shell has ( or .cc ysh has .cc
291	# 2. middle - shell has ) ysh has {
292	# 3. right - shell has optional ;; ysh has required }
293	#
294	# For YSH typed case, left can be ( and /
295	# And case_pat may contain more details
296	CaseArm = (
297	Token left, pat pattern, Token middle, List[command] action,
298	Token? right
299	)
300
301	# The argument to match against in a case command
302	# In YSH-style case commands we match against an `expr`, but in sh-style case
303	# commands we match against a word.
304	case_arg =
305	Word(word w)
306	\| YshExpr(expr e)
307
308	EggexFlag = (bool negated, Token flag)
309
310	# canonical_flags can be compared for equality. This is needed to splice
311	# eggexes correctly, e.g. / 'abc' @pat ; i /
312	Eggex = (
313	Token left, re regex, List[EggexFlag] flags, Token? trans_pref,
314	str? canonical_flags)
315
316	pat =
317	Else
318	\| Words(List[word] words)
319	\| YshExprs(List[expr] exprs)
320	\| Eggex %Eggex
321
322	# Each if arm starts with either an "if" or "elif" keyword
323	# In YSH, the then keyword is not used (replaced by braces {})
324	IfArm = (
325	Token keyword, condition cond, Token? then_kw, List[command] action,
326	# then_tok used in ysh-ify
327	Token? then_tok)
328
329	for_iter =
330	Args # for x; do echo $x; done # implicit "$@"
331	\| Words(List[word] words) # for x in 'foo' *.py { echo $x }
332	# like ShArrayLiteral, but no location for %(
333	\| YshExpr(expr e, Token blame) # for x in (mylist) { echo $x }
334	#\| Files(Token left, List[word] words)
335	# for x in <> {
336	# for x in < @myfiles > {
337
338	BraceGroup = (
339	Token left, Token? doc_token, List[command] children, Token right
340	)
341
342	Param = (Token blame_tok, str name, TypeExpr? type, expr? default_val)
343	RestParam = (Token blame_tok, str name)
344
345	ParamGroup = (List[Param] params, RestParam? rest_of)
346
347	# 'open' is for proc p { }; closed is for proc p () { }
348	proc_sig =
349	Open
350	\| Closed(ParamGroup? word, ParamGroup? positional, ParamGroup? named,
351	Param? block_param)
352
353	Proc = (Token keyword, Token name, proc_sig sig, command body)
354
355	Func = (
356	Token keyword, Token name,
357	ParamGroup? positional, ParamGroup? named,
358	command body
359	)
360
361	# Represents all these case: s=1 s+=1 s[x]=1 ...
362	ParsedAssignment = (Token? left, Token? close, int part_offset, CompoundWord w)
363
364	command =
365	NoOp
366
367	# can wrap many children, e.g. { }, loops, functions
368	\| Redirect(command child, List[Redir] redirects)
369
370	\| Simple(Token? blame_tok, # TODO: make required (BracedTuple?)
371	List[EnvPair] more_env,
372	List[word] words,
373	ArgList? typed_args, LiteralBlock? block,
374	# is_last_cmd is used for fork() optimizations
375	bool is_last_cmd)
376
377	# This doesn't technically belong in the LST, but it's convenient for
378	# execution
379	\| ExpandedAlias(command child, List[EnvPair] more_env)
380	\| Sentence(command child, Token terminator)
381	# Represents "bare assignment"
382	# Token left is redundant with pairs[0].left
383	\| ShAssignment(Token left, List[AssignPair] pairs)
384
385	\| ControlFlow(Token keyword, word? arg_word)
386
387	# ops are \| \|&
388	\| Pipeline(Token? negated, List[command] children, List[Token] ops)
389	# ops are && \|\|
390	\| AndOr(List[command] children, List[Token] ops)
391
392	# Part of for, while, until (but not if, case, ShFunction). No redirects.
393	\| DoGroup(Token left, List[command] children, Token right)
394	# A brace group is a compound command, with redirects.
395	\| BraceGroup %BraceGroup
396	# Contains a single child, like CommandSub
397	\| Subshell(Token left, command child, Token right, bool is_last_cmd)
398	\| DParen(Token left, arith_expr child, Token right)
399	\| DBracket(Token left, bool_expr expr, Token right)
400
401	# up to 3 iterations variables
402	\| ForEach(Token keyword, List[str] iter_names, for_iter iterable,
403	Token? semi_tok, command body)
404	# C-style for loop. Any of the 3 expressions can be omitted.
405	# Note: body is required, but only optional here because of initialization
406	# order.
407	\| ForExpr(Token keyword, arith_expr? init, arith_expr? cond,
408	arith_expr? update, command? body)
409	\| WhileUntil(Token keyword, condition cond, command body)
410
411	\| If(Token if_kw, List[IfArm] arms, Token? else_kw, List[command] else_action,
412	Token? fi_kw)
413	\| Case(Token case_kw, case_arg to_match, Token arms_start, List[CaseArm] arms,
414	Token arms_end)
415
416	# The keyword is optional in the case of bash-style functions
417	# (ie. "foo() { ... }") which do not have one.
418	\| ShFunction(Token? keyword, Token name_tok, str name, command body)
419
420	\| TimeBlock(Token keyword, command pipeline)
421	# Some nodes optimize it out as List[command], but we use CommandList for
422	# 1. the top level
423	# 2. ls ; ls & ls (same line)
424	# 3. CommandSub # single child that's a CommandList
425	# 4. Subshell # single child that's a CommandList
426	\| CommandList(List[command] children)
427
428	# YSH command constructs
429
430	# var, const.
431	# - Keyword is None for hay blocks
432	# - RHS is None, for use with value.Place
433	# - TODO: consider using BareDecl
434	\| VarDecl(Token? keyword, List[NameType] lhs, expr? rhs)
435
436	# this can behave like 'var', can be desugared
437	\| BareDecl(Token lhs, expr rhs)
438
439	# setvar, maybe 'auto' later
440	\| Mutation(Token keyword, List[y_lhs] lhs, Token op, expr rhs)
441	# = keyword
442	\| Expr(Token keyword, expr e)
443	\| Proc %Proc
444	\| Func %Func
445	\| Retval(Token keyword, expr val)
446
447	#
448	# Glob representation, for converting ${x//} to extended regexes.
449	#
450
451	# Example: *.[ch] is:
452	# GlobOp(<Glob_Star '*'>),
453	# GlobLit(Glob_OtherLiteral, '.'),
454	# CharClass(False, ['ch']) # from Glob_CleanLiterals token
455
456	glob_part =
457	Literal(id id, str s)
458	\| Operator(id op_id) # * or ?
459	\| CharClass(bool negated, List[str] strs)
460
461	# Char classes are opaque for now. If we ever need them:
462	# - Collating symbols are [. .]
463	# - Equivalence classes are [=
464
465	printf_part =
466	Literal %Token
467	# flags are 0 hyphen space + #
468	# type is 's' for %s, etc.
469	\| Percent(List[Token] flags, Token? width, Token? precision, Token type)
470
471	#
472	# YSH Language
473	#
474	# Copied and modified from Python-3.7/Parser/Python.asdl !
475
476	expr_context = Load \| Store \| Del \| AugLoad \| AugStore \| Param
477
478	# Type expressions: Int List[Int] Dict[Str, Any]
479	# Do we have Func[Int, Int => Int] ? I guess we can parse that into this
480	# system.
481	TypeExpr = (Token tok, str name, List[TypeExpr] params)
482
483	# LHS bindings in var/const, and eggex
484	NameType = (Token left, str name, TypeExpr? typ)
485
486	# TODO: Inline this into GenExp and ListComp? Just use a flag there?
487	Comprehension = (List[NameType] lhs, expr iter, expr? cond)
488
489	# Named arguments supplied to call. Token is null for f(; ...named).
490	NamedArg = (Token? name, expr value)
491
492	# Subscripts are lists of expressions
493	# a[:i, n] (we don't have matrices, but we have data frames)
494	Subscript = (Token left, expr obj, expr index)
495
496	# Attributes are obj.attr, d->key, name::scope,
497	Attribute = (expr obj, Token op, Token attr, str attr_name, expr_context ctx)
498
499	y_lhs =
500	Var %Token # Id.Expr_Name
501	\| Subscript %Subscript
502	\| Attribute %Attribute
503
504	place_op =
505	# &a[i+1]
506	Subscript(Token op, expr index)
507	# &d.mykey
508	\| Attribute(Token op, Token attr)
509
510	expr =
511	Var(Token left, str name) # a variable name to evaluate
512	# Constants are typically Null, Bool, Int, Float
513	# and also Str for key in {key: 42}
514	# But string literals are SingleQuoted or DoubleQuoted
515	# Python uses Num(object n), which doesn't respect our "LST" invariant.
516	\| Const(Token c, value val)
517
518	# read(&x) json read (&x[0])
519	\| Place(Token blame_tok, str var_name, place_op* ops)
520
521	# :\| one 'two' "$three" \|
522	\| ShArrayLiteral %ShArrayLiteral
523
524	# / d+ ; ignorecase; %python /
525	\| Eggex %Eggex
526
527	# $name is not an expr, but $? is, e.g. Id.VSub_QMark
528	\| SimpleVarSub %SimpleVarSub
529	\| BracedVarSub %BracedVarSub
530	\| CommandSub %CommandSub
531	\| SingleQuoted %SingleQuoted
532	\| DoubleQuoted %DoubleQuoted
533
534	\| Literal(expr inner)
535	\| Lambda(List[NameType] params, expr body)
536
537	\| Unary(Token op, expr child)
538	\| Binary(Token op, expr left, expr right)
539	# x < 4 < 3 and (x < 4) < 3
540	\| Compare(expr left, List[Token] ops, List[expr] comparators)
541	\| FuncCall(expr func, ArgList args)
542
543	# TODO: Need a representation for method call. We don't just want
544	# Attribute() and then Call()
545
546	\| IfExp(expr test, expr body, expr orelse)
547	\| Tuple(Token left, List[expr] elts, expr_context ctx)
548
549	\| List(Token left, List[expr] elts, expr_context ctx)
550	\| Dict(Token left, List[expr] keys, List[expr] values)
551	# For the values in {n1, n2}
552	\| Implicit
553
554	\| ListComp(Token left, expr elt, List[Comprehension] generators)
555	# not implemented
556	\| DictComp(Token left, expr key, expr value, List[Comprehension] generators)
557	\| GeneratorExp(expr elt, List[Comprehension] generators)
558
559	# Ranges are written 1:2, with first class expression syntax. There is no
560	# step as in Python. Use range(0, 10, step=2) for that.
561	\| Range(expr lower, Token op, expr upper)
562
563	# Slices occur within [] only. Unlike ranges, the start/end can be #
564	# implicit. Like ranges, denote a step with slice(0, 10, step=2).
565	# a[3:] a[:i]
566	\| Slice(expr? lower, Token op, expr? upper)
567
568	\| Subscript %Subscript
569	\| Attribute %Attribute
570
571	# Ellipsis is like 'Starred' within Python, which are valid on the LHS in
572	# Python for unpacking, and # within list literals for splicing.
573	# (Starred is NOT used for {k:v, **a}. That used a blank "keys"
574	# attribute.)
575
576	# I think we can use { **pairs } like Python
577	\| Spread(Token left, expr child)
578
579	#
580	# Regex Language (Eggex)
581	#
582
583	# e.g. alnum digit
584	PosixClass = (Token? negated, str name)
585	# e.g. d w s
586	PerlClass = (Token? negated, str name)
587
588	# Char Sets and Ranges both use Char Codes
589	# with u_braced == true : \u{ff}
590	# with u_braced == false: \xff \\ 'a' a '0' 0
591	# ERE doesn't make a distinction, but compiling to Python/PCRE can use it
592	CharCode = (Token blame_tok, int i, bool u_braced)
593	CharRange = (CharCode start, CharCode end)
594
595	# Note: .NET has && in character classes, making it a recursive language
596
597	class_literal_term =
598	PosixClass %PosixClass
599	\| PerlClass %PerlClass
600	\| CharRange %CharRange
601	\| CharCode %CharCode
602
603	\| SingleQuoted %SingleQuoted
604	# @chars
605	\| Splice(Token name, str var_name) # coudl be Splice %Token
606
607	# evaluated version of class_literal_term (could be in runtime.asdl)
608	char_class_term =
609	PosixClass %PosixClass
610	\| PerlClass %PerlClass
611
612	\| CharRange %CharRange
613	# For [ \x00 \\ ]
614	\| CharCode %CharCode
615
616	# NOTE: modifier is unused now, can represent L or P
617	re_repeat =
618	Op %Token # + * ? or Expr_DecInt for x{3}
619	\| Range(Token? left, str lower, str upper, Token? right) # dot{1,2}
620	# Haven't implemented the modifier, e.g. x{+ P}
621	# \| Num(Token times, id modifier)
622	# \| Range(Token? lower, Token? upper, id modifier)
623
624	re =
625	Primitive(Token blame_tok, id id) # . ^ $ dot %start %end
626	\| PosixClass %PosixClass
627	\| PerlClass %PerlClass
628	# syntax [ $x \n ]
629	\| CharClassLiteral(bool negated, List[class_literal_term] terms)
630	# evaluated [ 'abc' \n ]
631	\| CharClass(bool negated, List[char_class_term] terms)
632
633	# @D
634	\| Splice(Token name, str var_name) # TODO: Splice %Token ?
635
636	\| SingleQuoted %SingleQuoted
637
638	# Compound:
639	\| Repeat(re child, re_repeat op)
640	\| Seq(List[re] children)
641	\| Alt(List[re] children)
642
643	\| Group(re child)
644	# convert_func is filled in on evaluation
645	# TODO: name and func_name can be expanded to strings
646	\| Capture(re child, Token? name, Token? func_name)
647	\| Backtracking(bool negated, Token name, re child)
648
649	# \u{ff} is parsed as this, but SingleQuoted also evaluates to it
650	\| LiteralChars(Token blame_tok, str s)
651	}