OILS / osh / cmd_parse.py View on Github | oilshell.org

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1# Copyright 2016 Andy Chu. All rights reserved.
2# Licensed under the Apache License, Version 2.0 (the "License");
3# you may not use this file except in compliance with the License.
4# You may obtain a copy of the License at
5#
6# http://www.apache.org/licenses/LICENSE-2.0
7"""
8cmd_parse.py - Parse high level shell commands.
9"""
10from __future__ import print_function
11
12from _devbuild.gen import grammar_nt
13from _devbuild.gen.id_kind_asdl import Id, Id_t, Id_str, Kind, Kind_str
14from _devbuild.gen.types_asdl import lex_mode_e, cmd_mode_e, cmd_mode_t
15from _devbuild.gen.syntax_asdl import (
16 loc,
17 SourceLine,
18 source,
19 parse_result,
20 parse_result_t,
21 command,
22 command_t,
23 condition,
24 condition_t,
25 for_iter,
26 ArgList,
27 BraceGroup,
28 LiteralBlock,
29 CaseArm,
30 case_arg,
31 IfArm,
32 pat,
33 pat_t,
34 Redir,
35 redir_param,
36 redir_loc,
37 redir_loc_t,
38 word_e,
39 word_t,
40 CompoundWord,
41 Token,
42 word_part_e,
43 word_part_t,
44 rhs_word,
45 rhs_word_t,
46 sh_lhs,
47 sh_lhs_t,
48 AssignPair,
49 EnvPair,
50 ParsedAssignment,
51 assign_op_e,
52 NameType,
53 proc_sig,
54 proc_sig_e,
55 Proc,
56 Func,
57)
58from core import alloc
59from core import error
60from core.error import p_die
61from core import ui
62from frontend import consts
63from frontend import lexer
64from frontend import location
65from frontend import match
66from frontend import reader
67from mycpp.mylib import log
68from osh import braces
69from osh import bool_parse
70from osh import word_
71
72from typing import Optional, List, Dict, Any, Tuple, cast, TYPE_CHECKING
73if TYPE_CHECKING:
74 from core.alloc import Arena
75 from core import optview
76 from frontend.lexer import Lexer
77 from frontend.parse_lib import ParseContext, AliasesInFlight
78 from frontend.reader import _Reader
79 from osh.word_parse import WordParser
80
81_ = Kind_str # for debug prints
82
83TAB_CH = 9 # ord('\t')
84SPACE_CH = 32 # ord(' ')
85
86
87def _ReadHereLines(
88 line_reader, # type: _Reader
89 h, # type: Redir
90 delimiter, # type: str
91):
92 # type: (...) -> Tuple[List[Tuple[SourceLine, int]], Tuple[SourceLine, int]]
93 # NOTE: We read all lines at once, instead of parsing line-by-line,
94 # because of cases like this:
95 # cat <<EOF
96 # 1 $(echo 2
97 # echo 3) 4
98 # EOF
99 here_lines = [] # type: List[Tuple[SourceLine, int]]
100 last_line = None # type: Tuple[SourceLine, int]
101 strip_leading_tabs = (h.op.id == Id.Redir_DLessDash)
102
103 while True:
104 src_line, unused_offset = line_reader.GetLine()
105
106 if src_line is None: # EOF
107 # An unterminated here doc is just a warning in bash. We make it
108 # fatal because we want to be strict, and because it causes problems
109 # reporting other errors.
110 # Attribute it to the << in <<EOF for now.
111 p_die("Couldn't find terminator for here doc that starts here",
112 h.op)
113
114 assert len(src_line.content) != 0 # None should be the empty line
115
116 line = src_line.content
117
118 # If op is <<-, strip off ALL leading tabs -- not spaces, and not just
119 # the first tab.
120 start_offset = 0
121 if strip_leading_tabs:
122 n = len(line)
123 i = 0 # used after loop exit
124 while i < n:
125 if line[i] != '\t':
126 break
127 i += 1
128 start_offset = i
129
130 if line[start_offset:].rstrip() == delimiter:
131 last_line = (src_line, start_offset)
132 break
133
134 here_lines.append((src_line, start_offset))
135
136 return here_lines, last_line
137
138
139def _MakeLiteralHereLines(
140 here_lines, # type: List[Tuple[SourceLine, int]]
141 arena, # type: Arena
142 do_lossless, # type: bool
143):
144 # type: (...) -> List[word_part_t]
145 """Create a Token for each line.
146
147 For <<'EOF' and <<-'EOF' - single quoted rule
148
149 <<- has non-zero start_offset
150 """
151 # less precise type, because List[T] is an invariant type
152 tokens = [] # type: List[word_part_t]
153 for src_line, start_offset in here_lines:
154
155 # Maintain lossless invariant for STRIPPED tabs: add a Token to the
156 # arena invariant, but don't refer to it.
157 #
158 # Note: We could use Lit_CharsWithoutPrefix for 'single quoted' EOF
159 # here docs, but it's more complex with double quoted EOF docs.
160
161 if do_lossless: # avoid garbage, doesn't affect correctness
162 arena.NewToken(Id.Lit_CharsWithoutPrefix, start_offset, 0,
163 src_line)
164
165 t = arena.NewToken(Id.Lit_Chars, start_offset, len(src_line.content),
166 src_line)
167 tokens.append(t)
168 return tokens
169
170
171def _ParseHereDocBody(parse_ctx, r, line_reader, arena):
172 # type: (ParseContext, Redir, _Reader, Arena) -> None
173 """Fill in attributes of a pending here doc node."""
174 h = cast(redir_param.HereDoc, r.arg)
175 # "If any character in word is quoted, the delimiter shall be formed by
176 # performing quote removal on word, and the here-document lines shall not
177 # be expanded. Otherwise, the delimiter shall be the word itself."
178 # NOTE: \EOF counts, or even E\OF
179 ok, delimiter, delim_quoted = word_.StaticEval(h.here_begin)
180 if not ok:
181 p_die('Invalid here doc delimiter', loc.Word(h.here_begin))
182
183 here_lines, last_line = _ReadHereLines(line_reader, r, delimiter)
184
185 if delim_quoted:
186 # <<'EOF' and <<-'EOF' - Literal for each line.
187 h.stdin_parts = _MakeLiteralHereLines(here_lines, arena,
188 parse_ctx.do_lossless)
189 else:
190 # <<EOF and <<-EOF - Parse as word
191 line_reader = reader.VirtualLineReader(arena, here_lines,
192 parse_ctx.do_lossless)
193 w_parser = parse_ctx.MakeWordParserForHereDoc(line_reader)
194 w_parser.ReadHereDocBody(h.stdin_parts) # fills this in
195
196 end_line, start_offset = last_line
197
198 # Maintain lossless invariant for STRIPPED tabs: add a Token to the
199 # arena invariant, but don't refer to it.
200 if parse_ctx.do_lossless: # avoid garbage, doesn't affect correctness
201 arena.NewToken(Id.Lit_CharsWithoutPrefix, start_offset, 0, end_line)
202
203 # Create a Token with the end terminator. Maintains the invariant that the
204 # tokens "add up".
205 h.here_end_tok = arena.NewToken(Id.Undefined_Tok, start_offset,
206 len(end_line.content), end_line)
207
208
209def _MakeAssignPair(parse_ctx, preparsed, arena):
210 # type: (ParseContext, ParsedAssignment, Arena) -> AssignPair
211 """Create an AssignPair from a 4-tuples from DetectShAssignment."""
212
213 left_token = preparsed.left
214 close_token = preparsed.close
215
216 lhs = None # type: sh_lhs_t
217
218 if left_token.id == Id.Lit_VarLike: # s=1
219 if lexer.IsPlusEquals(left_token):
220 var_name = lexer.TokenSliceRight(left_token, -2)
221 op = assign_op_e.PlusEqual
222 else:
223 var_name = lexer.TokenSliceRight(left_token, -1)
224 op = assign_op_e.Equal
225
226 lhs = sh_lhs.Name(left_token, var_name)
227
228 elif left_token.id == Id.Lit_ArrayLhsOpen and parse_ctx.do_lossless:
229 var_name = lexer.TokenSliceRight(left_token, -1)
230 if lexer.IsPlusEquals(close_token):
231 op = assign_op_e.PlusEqual
232 else:
233 op = assign_op_e.Equal
234
235 assert left_token.line == close_token.line, \
236 '%s and %s not on same line' % (left_token, close_token)
237
238 left_pos = left_token.col + left_token.length
239 index_str = left_token.line.content[left_pos:close_token.col]
240 lhs = sh_lhs.UnparsedIndex(left_token, var_name, index_str)
241
242 elif left_token.id == Id.Lit_ArrayLhsOpen: # a[x++]=1
243 var_name = lexer.TokenSliceRight(left_token, -1)
244 if lexer.IsPlusEquals(close_token):
245 op = assign_op_e.PlusEqual
246 else:
247 op = assign_op_e.Equal
248
249 # Similar to SnipCodeString / SnipCodeBlock
250 if left_token.line == close_token.line:
251 # extract what's between brackets
252 s = left_token.col + left_token.length
253 code_str = left_token.line.content[s:close_token.col]
254 else:
255 raise NotImplementedError('%s != %s' %
256 (left_token.line, close_token.line))
257 a_parser = parse_ctx.MakeArithParser(code_str)
258
259 # a[i+1]= is a LHS
260 src = source.Reparsed('array LHS', left_token, close_token)
261 with alloc.ctx_SourceCode(arena, src):
262 index_node = a_parser.Parse() # may raise error.Parse
263
264 lhs = sh_lhs.IndexedName(left_token, var_name, index_node)
265
266 else:
267 raise AssertionError()
268
269 # TODO: Should we also create a rhs_expr.ArrayLiteral here?
270 parts = preparsed.w.parts
271 offset = preparsed.part_offset
272
273 n = len(parts)
274 if offset == n:
275 rhs = rhs_word.Empty # type: rhs_word_t
276 else:
277 w = CompoundWord(parts[offset:])
278 word_.TildeDetectAssign(w)
279 rhs = w
280
281 return AssignPair(left_token, lhs, op, rhs)
282
283
284def _AppendMoreEnv(preparsed_list, more_env):
285 # type: (List[ParsedAssignment], List[EnvPair]) -> None
286 """Helper to modify a SimpleCommand node.
287
288 Args:
289 preparsed: a list of 4-tuples from DetectShAssignment
290 more_env: a list to append env_pairs to
291 """
292 for preparsed in preparsed_list:
293 left_token = preparsed.left
294
295 if left_token.id != Id.Lit_VarLike: # can't be a[x]=1
296 p_die(
297 "Environment binding shouldn't look like an array assignment",
298 left_token)
299
300 if lexer.IsPlusEquals(left_token):
301 p_die('Expected = in environment binding, got +=', left_token)
302
303 var_name = lexer.TokenSliceRight(left_token, -1)
304
305 parts = preparsed.w.parts
306 n = len(parts)
307 offset = preparsed.part_offset
308 if offset == n:
309 rhs = rhs_word.Empty # type: rhs_word_t
310 else:
311 w = CompoundWord(parts[offset:])
312 word_.TildeDetectAssign(w)
313 rhs = w
314
315 more_env.append(EnvPair(left_token, var_name, rhs))
316
317
318def _SplitSimpleCommandPrefix(words):
319 # type: (List[CompoundWord]) -> Tuple[List[ParsedAssignment], List[CompoundWord]]
320 """Second pass of SimpleCommand parsing: look for assignment words."""
321 preparsed_list = [] # type: List[ParsedAssignment]
322 suffix_words = [] # type: List[CompoundWord]
323
324 done_prefix = False
325 for w in words:
326 if done_prefix:
327 suffix_words.append(w)
328 continue
329
330 left_token, close_token, part_offset = word_.DetectShAssignment(w)
331 if left_token:
332 preparsed_list.append(
333 ParsedAssignment(left_token, close_token, part_offset, w))
334 else:
335 done_prefix = True
336 suffix_words.append(w)
337
338 return preparsed_list, suffix_words
339
340
341def _MakeSimpleCommand(
342 preparsed_list, # type: List[ParsedAssignment]
343 suffix_words, # type: List[CompoundWord]
344 typed_args, # type: Optional[ArgList]
345 block, # type: Optional[LiteralBlock]
346):
347 # type: (...) -> command.Simple
348 """Create a command.Simple"""
349
350 # FOO=(1 2 3) ls is not allowed.
351 for preparsed in preparsed_list:
352 if word_.HasArrayPart(preparsed.w):
353 p_die("Environment bindings can't contain array literals",
354 loc.Word(preparsed.w))
355
356 # NOTE: It would be possible to add this check back. But it already happens
357 # at runtime in EvalWordSequence2.
358 # echo FOO=(1 2 3) is not allowed (but we should NOT fail on echo FOO[x]=1).
359 if 0:
360 for w in suffix_words:
361 if word_.HasArrayPart(w):
362 p_die("Commands can't contain array literals", loc.Word(w))
363
364 assert len(suffix_words) != 0
365 # {a,b,c} # Use { before brace detection
366 # ~/bin/ls # Use ~ before tilde detection
367 part0 = suffix_words[0].parts[0]
368 blame_tok = location.LeftTokenForWordPart(part0)
369
370 # NOTE: We only do brace DETECTION here, not brace EXPANSION. Therefore we
371 # can't implement bash's behavior of having say {~bob,~jane}/src work,
372 # because we only have a BracedTree.
373 # This is documented in spec/brace-expansion.
374 # NOTE: Technically we could do expansion outside of 'oshc translate', but it
375 # doesn't seem worth it.
376 words2 = braces.BraceDetectAll(suffix_words)
377 words3 = word_.TildeDetectAll(words2)
378
379 more_env = [] # type: List[EnvPair]
380 _AppendMoreEnv(preparsed_list, more_env)
381
382 # do_fork by default
383 return command.Simple(blame_tok, more_env, words3, typed_args, block, True)
384
385
386class VarChecker(object):
387 """Statically check for proc and variable usage errors."""
388
389 def __init__(self):
390 # type: () -> None
391 """
392 Args:
393 oil_proc: Whether to disallow nested proc/function declarations
394 """
395 # self.tokens for location info: 'proc' or another token
396 self.tokens = [] # type: List[Token]
397 self.names = [] # type: List[Dict[str, Id_t]]
398
399 def Push(self, blame_tok):
400 # type: (Token) -> None
401 """Called when we enter a shell function, proc, or func.
402
403 Bash allows this, but it's confusing because it's the same as two
404 functions at the top level.
405
406 f() {
407 g() {
408 echo 'top level function defined in another one'
409 }
410 }
411
412 YSH disallows nested procs and funcs.
413 """
414 if len(self.tokens) != 0:
415 if blame_tok.id == Id.KW_Proc:
416 p_die("procs must be defined at the top level", blame_tok)
417 if blame_tok.id == Id.KW_Func:
418 p_die("funcs must be defined at the top level", blame_tok)
419 if self.tokens[0].id in (Id.KW_Proc, Id.KW_Func):
420 p_die("shell functions can't be defined inside proc or func",
421 blame_tok)
422
423 self.tokens.append(blame_tok)
424 entry = {} # type: Dict[str, Id_t]
425 self.names.append(entry)
426
427 def Pop(self):
428 # type: () -> None
429 self.names.pop()
430 self.tokens.pop()
431
432 def Check(self, keyword_id, var_name, blame_tok):
433 # type: (Id_t, str, Token) -> None
434 """Check for declaration / mutation errors in proc and func.
435
436 var x
437 x already declared
438 setvar x:
439 x is not declared
440 setglobal x:
441 No errors are possible; we would need all these many conditions to
442 statically know the names:
443 - no 'source'
444 - shopt -u copy_env.
445 - AND use lib has to be static
446
447 What about bare assignment in Hay? I think these are dynamic checks --
448 there is no static check. Hay is for building up data imperatively,
449 and then LATER, right before main(), it can be type checked.
450
451 Package {
452 version = '3.11'
453 version = '3.12'
454 }
455 """
456 # No static checks are the global level! Because of 'source', var and
457 # setvar are essentially the same.
458 if len(self.names) == 0:
459 return
460
461 top = self.names[-1]
462 if keyword_id == Id.KW_Var:
463 if var_name in top:
464 p_die('%r was already declared' % var_name, blame_tok)
465 else:
466 top[var_name] = keyword_id
467
468 if keyword_id == Id.KW_SetVar:
469 if var_name not in top:
470 # Note: the solution could be setglobal, etc.
471 p_die(
472 "setvar couldn't find matching 'var %s' (OILS-ERR-10)" %
473 var_name, blame_tok)
474
475
476class ctx_VarChecker(object):
477
478 def __init__(self, var_checker, blame_tok):
479 # type: (VarChecker, Token) -> None
480 var_checker.Push(blame_tok)
481 self.var_checker = var_checker
482
483 def __enter__(self):
484 # type: () -> None
485 pass
486
487 def __exit__(self, type, value, traceback):
488 # type: (Any, Any, Any) -> None
489 self.var_checker.Pop()
490
491
492class ctx_CmdMode(object):
493
494 def __init__(self, cmd_parse, new_cmd_mode):
495 # type: (CommandParser, cmd_mode_t) -> None
496 self.cmd_parse = cmd_parse
497 self.prev_cmd_mode = cmd_parse.cmd_mode
498 cmd_parse.cmd_mode = new_cmd_mode
499
500 def __enter__(self):
501 # type: () -> None
502 pass
503
504 def __exit__(self, type, value, traceback):
505 # type: (Any, Any, Any) -> None
506 self.cmd_parse.cmd_mode = self.prev_cmd_mode
507
508
509SECONDARY_KEYWORDS = [
510 Id.KW_Do, Id.KW_Done, Id.KW_Then, Id.KW_Fi, Id.KW_Elif, Id.KW_Else,
511 Id.KW_Esac
512]
513
514
515class CommandParser(object):
516 """Recursive descent parser derived from POSIX shell grammar.
517
518 This is a BNF grammar:
519 https://pubs.opengroup.org/onlinepubs/9699919799/utilities/V3_chap02.html#tag_18_10
520
521 - Augmented with both bash/OSH and YSH constructs.
522
523 - We use regex-like iteration rather than recursive references
524 ? means optional (0 or 1)
525 * means 0 or more
526 + means 1 or more
527
528 - Keywords are spelled in Caps:
529 If Elif Case
530
531 - Operator tokens are quoted:
532 '(' '|'
533
534 or can be spelled directly if it matters:
535
536 Op_LParen Op_Pipe
537
538 - Non-terminals are snake_case:
539 brace_group subshell
540
541 Methods in this class should ROUGHLY CORRESPOND to grammar productions, and
542 the production should be in the method docstrings, e.g.
543
544 def ParseSubshell():
545 "
546 subshell : '(' compound_list ')'
547
548 Looking at Op_LParen # Comment to say how this method is called
549 "
550
551 The grammar may be factored to make parsing easier.
552 """
553
554 def __init__(self,
555 parse_ctx,
556 parse_opts,
557 w_parser,
558 lexer,
559 line_reader,
560 eof_id=Id.Eof_Real):
561 # type: (ParseContext, optview.Parse, WordParser, Lexer, _Reader, Id_t) -> None
562 self.parse_ctx = parse_ctx
563 self.aliases = parse_ctx.aliases # aliases to expand at parse time
564
565 self.parse_opts = parse_opts
566 self.w_parser = w_parser # type: WordParser # for normal parsing
567 self.lexer = lexer # for pushing hints, lookahead to (
568 self.line_reader = line_reader # for here docs
569 self.eof_id = eof_id
570
571 self.arena = line_reader.arena # for adding here doc and alias spans
572 self.aliases_in_flight = [] # type: AliasesInFlight
573
574 # A hacky boolean to remove 'if cd / {' ambiguity.
575 self.allow_block = True
576
577 # Stack of booleans for nested Attr and SHELL nodes.
578 # Attr nodes allow bare assignment x = 42, but not shell x=42.
579 # SHELL nodes are the inverse. 'var x = 42' is preferred in shell
580 # nodes, but x42 is still allowed.
581 #
582 # Note: this stack could be optimized by turning it into an integer and
583 # binary encoding.
584 self.hay_attrs_stack = [] # type: List[bool]
585
586 # Note: VarChecker is instantiated with each CommandParser, which means
587 # that two 'proc foo' -- inside a command sub and outside -- don't
588 # conflict, because they use different CommandParser instances. I think
589 # this OK but you can imagine different behaviors.
590 self.var_checker = VarChecker()
591
592 self.cmd_mode = cmd_mode_e.Shell # type: cmd_mode_t
593
594 self.Reset()
595
596 # Init_() function for "keyword arg"
597 def Init_AliasesInFlight(self, aliases_in_flight):
598 # type: (AliasesInFlight) -> None
599 self.aliases_in_flight = aliases_in_flight
600
601 def Reset(self):
602 # type: () -> None
603 """Reset our own internal state.
604
605 Called by the interactive loop.
606 """
607 # Cursor state set by _GetWord()
608 self.next_lex_mode = lex_mode_e.ShCommand
609 self.cur_word = None # type: word_t # current word
610 self.c_kind = Kind.Undefined
611 self.c_id = Id.Undefined_Tok
612
613 self.pending_here_docs = [] # type: List[Redir]
614
615 def ResetInputObjects(self):
616 # type: () -> None
617 """Reset the internal state of our inputs.
618
619 Called by the interactive loop.
620 """
621 self.w_parser.Reset()
622 self.lexer.ResetInputObjects()
623 self.line_reader.Reset()
624
625 def _SetNext(self):
626 # type: () -> None
627 """Call this when you no longer need the current token.
628
629 This method is lazy. A subsequent call to _GetWord() will
630 actually read the next Token.
631 """
632 self.next_lex_mode = lex_mode_e.ShCommand
633
634 def _SetNextBrack(self):
635 # type: () -> None
636 self.next_lex_mode = lex_mode_e.ShCommandFakeBrack
637
638 def _GetWord(self):
639 # type: () -> None
640 """Call this when you need to make a decision based on Id or Kind.
641
642 If there was an "unfulfilled" call to _SetNext(), it reads a word and sets
643 self.c_id and self.c_kind.
644
645 Otherwise it does nothing.
646 """
647 if self.next_lex_mode != lex_mode_e.Undefined:
648 w = self.w_parser.ReadWord(self.next_lex_mode)
649 #log("w %s", w)
650
651 # Here docs only happen in command mode, so other kinds of newlines don't
652 # count.
653 if w.tag() == word_e.Operator:
654 tok = cast(Token, w)
655 if tok.id == Id.Op_Newline:
656 for h in self.pending_here_docs:
657 _ParseHereDocBody(self.parse_ctx, h, self.line_reader,
658 self.arena)
659 del self.pending_here_docs[:] # No .clear() until Python 3.3.
660
661 self.cur_word = w
662
663 self.c_kind = word_.CommandKind(self.cur_word)
664 # Has special case for Id.Lit_{LBrace,RBrace,Equals}
665 self.c_id = word_.CommandId(self.cur_word)
666 self.next_lex_mode = lex_mode_e.Undefined
667
668 def _Eat(self, c_id, msg=None):
669 # type: (Id_t, Optional[str]) -> word_t
670 """Consume a word of a type, maybe showing a custom error message.
671
672 Args:
673 c_id: the Id we expected
674 msg: improved error message
675 """
676 self._GetWord()
677 if self.c_id != c_id:
678 if msg is None:
679 msg = 'Expected word type %s, got %s' % (
680 ui.PrettyId(c_id), ui.PrettyId(self.c_id))
681 p_die(msg, loc.Word(self.cur_word))
682
683 skipped = self.cur_word
684 self._SetNext()
685 return skipped
686
687 def _NewlineOk(self):
688 # type: () -> None
689 """Check for optional newline and consume it."""
690 self._GetWord()
691 if self.c_id == Id.Op_Newline:
692 self._SetNext()
693
694 def _AtSecondaryKeyword(self):
695 # type: () -> bool
696 self._GetWord()
697 if self.c_id in SECONDARY_KEYWORDS:
698 return True
699 return False
700
701 def ParseRedirect(self):
702 # type: () -> Redir
703 self._GetWord()
704 assert self.c_kind == Kind.Redir, self.cur_word
705 op_tok = cast(Token, self.cur_word) # for MyPy
706
707 # Note: the lexer could take distinguish between
708 # >out
709 # 3>out
710 # {fd}>out
711 #
712 # which would make the code below faster. But small string optimization
713 # would also speed it up, since redirects are small.
714
715 # One way to do this is with Kind.Redir and Kind.RedirNamed, and then
716 # possibly "unify" the IDs by subtracting a constant like 8 or 16?
717
718 op_val = lexer.TokenVal(op_tok)
719 if op_val[0] == '{':
720 pos = op_val.find('}')
721 assert pos != -1 # lexer ensures this
722 where = redir_loc.VarName(op_val[1:pos]) # type: redir_loc_t
723
724 elif op_val[0].isdigit():
725 pos = 1
726 if op_val[1].isdigit():
727 pos = 2
728 where = redir_loc.Fd(int(op_val[:pos]))
729
730 else:
731 where = redir_loc.Fd(consts.RedirDefaultFd(op_tok.id))
732
733 self._SetNext()
734
735 self._GetWord()
736 # Other redirect
737 if self.c_kind != Kind.Word:
738 p_die('Invalid token after redirect operator',
739 loc.Word(self.cur_word))
740
741 # Here doc
742 if op_tok.id in (Id.Redir_DLess, Id.Redir_DLessDash):
743 arg = redir_param.HereDoc.CreateNull()
744 arg.here_begin = self.cur_word
745 arg.stdin_parts = []
746
747 r = Redir(op_tok, where, arg)
748
749 self.pending_here_docs.append(r) # will be filled on next newline.
750
751 self._SetNext()
752 return r
753
754 arg_word = self.cur_word
755 tilde = word_.TildeDetect(arg_word)
756 if tilde:
757 arg_word = tilde
758 self._SetNext()
759
760 # We should never get Empty, Token, etc.
761 assert arg_word.tag() == word_e.Compound, arg_word
762 return Redir(op_tok, where, cast(CompoundWord, arg_word))
763
764 def _ParseRedirectList(self):
765 # type: () -> List[Redir]
766 """Try parsing any redirects at the cursor.
767
768 This is used for blocks only, not commands.
769 """
770 redirects = [] # type: List[Redir]
771 while True:
772 # This prediction needs to ONLY accept redirect operators. Should we
773 # make them a separate Kind?
774 self._GetWord()
775 if self.c_kind != Kind.Redir:
776 break
777
778 node = self.ParseRedirect()
779 redirects.append(node)
780 self._SetNext()
781
782 return redirects
783
784 def _MaybeParseRedirectList(self, node):
785 # type: (command_t) -> command_t
786 """Try parsing redirects at the current position.
787
788 If there are any, then wrap the command_t argument with a
789 command.Redirect node. Otherwise, return argument unchanged.
790 """
791 self._GetWord()
792 if self.c_kind != Kind.Redir:
793 return node
794
795 redirects = [self.ParseRedirect()]
796
797 while True:
798 # This prediction needs to ONLY accept redirect operators. Should we
799 # make them a separate Kind?
800 self._GetWord()
801 if self.c_kind != Kind.Redir:
802 break
803
804 redirects.append(self.ParseRedirect())
805 self._SetNext()
806
807 return command.Redirect(node, redirects)
808
809 def _ScanSimpleCommand(self):
810 # type: () -> Tuple[List[Redir], List[CompoundWord], Optional[ArgList], Optional[LiteralBlock]]
811 """YSH extends simple commands with typed args and blocks.
812
813 Shell has a recursive grammar, which awkwardly expresses
814 non-grammatical rules:
815
816 simple_command : cmd_prefix cmd_word cmd_suffix
817 | cmd_prefix cmd_word
818 | cmd_prefix
819 | cmd_name cmd_suffix
820 | cmd_name
821 ;
822 cmd_name : WORD /* Apply rule 7a */
823 ;
824 cmd_word : WORD /* Apply rule 7b */
825 ;
826 cmd_prefix : io_redirect
827 | cmd_prefix io_redirect
828 | ASSIGNMENT_WORD
829 | cmd_prefix ASSIGNMENT_WORD
830 ;
831 cmd_suffix : io_redirect
832 | cmd_suffix io_redirect
833 | WORD
834 | cmd_suffix WORD
835
836 YSH grammar:
837
838 redirect = redir_op WORD
839 item = WORD | redirect
840
841 typed_args =
842 '(' arglist ')'
843 | '[' arglist ']'
844
845 simple_command =
846 cmd_prefix* item+ typed_args? BraceGroup? cmd_suffix*
847
848 Notably, redirects shouldn't appear after typed args, or after
849 BraceGroup.
850
851 Examples:
852
853 This is an assignment:
854 foo=1 >out
855
856 This is a command.Simple
857 >out
858
859 What about
860 >out (42)
861 """
862 redirects = [] # type: List[Redir]
863 words = [] # type: List[CompoundWord]
864 typed_args = None # type: Optional[ArgList]
865 block = None # type: Optional[LiteralBlock]
866
867 first_word_caps = False # does first word look like Caps, but not CAPS
868
869 i = 0
870 while True:
871 self._GetWord()
872
873 # If we got { }, change it to something that's not Kind.Word
874 kind2 = self.c_kind
875 if (kind2 == Kind.Word and self.parse_opts.parse_brace() and
876 self.c_id in (Id.Lit_LBrace, Id.Lit_RBrace)):
877 kind2 = Kind.Op
878
879 if kind2 == Kind.Redir:
880 node = self.ParseRedirect()
881 redirects.append(node)
882
883 elif kind2 == Kind.Word:
884 w = cast(CompoundWord, self.cur_word) # Kind.Word ensures this
885
886 if i == 0:
887 # Disallow leading =a because it's confusing
888 part0 = w.parts[0]
889 if part0.tag() == word_part_e.Literal:
890 tok = cast(Token, part0)
891 if tok.id == Id.Lit_Equals:
892 p_die(
893 "=word isn't allowed. Hint: add a space after =, or quote it",
894 tok)
895
896 # Is the first word a Hay Attr word?
897 #
898 # Can we remove this StaticEval() call, and just look
899 # inside Token? I think once we get rid of SHELL nodes,
900 # this will be simpler.
901
902 ok, word_str, quoted = word_.StaticEval(w)
903 # Foo { a = 1 } is OK, but not foo { a = 1 } or FOO { a = 1 }
904 if (ok and len(word_str) and word_str[0].isupper() and
905 not word_str.isupper()):
906 first_word_caps = True
907 #log('W %s', word_str)
908
909 words.append(w)
910
911 else:
912 break
913
914 self._SetNextBrack() # Allow bracket for SECOND word on
915 i += 1
916
917 # my-cmd (x) or my-cmd [x]
918 self._GetWord()
919 if self.c_id == Id.Op_LParen:
920 # 1. Check that there's a preceding space
921 prev_byte = self.lexer.ByteLookBack()
922 if prev_byte not in (SPACE_CH, TAB_CH):
923 if self.parse_opts.parse_at():
924 p_die('Space required before (', loc.Word(self.cur_word))
925 else:
926 # inline func call like @sorted(x) is invalid in OSH, but the
927 # solution isn't a space
928 p_die(
929 'Unexpected left paren (might need a space before it)',
930 loc.Word(self.cur_word))
931
932 # 2. Check that it's not (). We disallow this because it's a no-op and
933 # there could be confusion with shell func defs.
934 # For some reason we need to call lexer.LookPastSpace, not
935 # w_parser.LookPastSpace. I think this is because we're at (, which is
936 # an operator token. All the other cases are like 'x=', which is PART
937 # of a word, and we don't know if it will end.
938 next_id = self.lexer.LookPastSpace(lex_mode_e.ShCommand)
939 if next_id == Id.Op_RParen:
940 p_die('Empty arg list not allowed', loc.Word(self.cur_word))
941
942 typed_args = self.w_parser.ParseProcCallArgs(
943 grammar_nt.ysh_eager_arglist)
944
945 self._SetNext()
946
947 elif self.c_id == Id.Op_LBracket: # only when parse_bracket set
948 typed_args = self.w_parser.ParseProcCallArgs(
949 grammar_nt.ysh_lazy_arglist)
950
951 self._SetNext()
952
953 self._GetWord()
954
955 # Allow redirects after typed args, e.g.
956 # json write (x) > out.txt
957 if self.c_kind == Kind.Redir:
958 redirects.extend(self._ParseRedirectList())
959
960 # my-cmd { echo hi } my-cmd (x) { echo hi } ...
961 if (self.parse_opts.parse_brace() and self.c_id == Id.Lit_LBrace and
962 # Disabled for if/while condition, etc.
963 self.allow_block):
964
965 # allow x = 42
966 self.hay_attrs_stack.append(first_word_caps)
967 brace_group = self.ParseBraceGroup()
968
969 # So we can get the source code back later
970 lines = self.arena.SaveLinesAndDiscard(brace_group.left,
971 brace_group.right)
972 block = LiteralBlock(brace_group, lines)
973
974 self.hay_attrs_stack.pop()
975
976 self._GetWord()
977
978 # Allow redirects after block, e.g.
979 # cd /tmp { echo $PWD } > out.txt
980 if self.c_kind == Kind.Redir:
981 redirects.extend(self._ParseRedirectList())
982
983 return redirects, words, typed_args, block
984
985 def _MaybeExpandAliases(self, words):
986 # type: (List[CompoundWord]) -> Optional[command_t]
987 """Try to expand aliases.
988
989 Args:
990 words: A list of Compound
991
992 Returns:
993 A new LST node, or None.
994
995 Our implementation of alias has two design choices:
996 - Where to insert it in parsing. We do it at the end of ParseSimpleCommand.
997 - What grammar rule to parse the expanded alias buffer with. In our case
998 it's ParseCommand().
999
1000 This doesn't quite match what other shells do, but I can't figure out a
1001 better places.
1002
1003 Most test cases pass, except for ones like:
1004
1005 alias LBRACE='{'
1006 LBRACE echo one; echo two; }
1007
1008 alias MULTILINE='echo 1
1009 echo 2
1010 echo 3'
1011 MULTILINE
1012
1013 NOTE: dash handles aliases in a totally different way. It has a global
1014 variable checkkwd in parser.c. It assigns it all over the grammar, like
1015 this:
1016
1017 checkkwd = CHKNL | CHKKWD | CHKALIAS;
1018
1019 The readtoken() function checks (checkkwd & CHKALIAS) and then calls
1020 lookupalias(). This seems to provide a consistent behavior among shells,
1021 but it's less modular and testable.
1022
1023 Bash also uses a global 'parser_state & PST_ALEXPNEXT'.
1024
1025 Returns:
1026 A command node if any aliases were expanded, or None otherwise.
1027 """
1028 # Start a new list if there aren't any. This will be passed recursively
1029 # through CommandParser instances.
1030 aliases_in_flight = (self.aliases_in_flight
1031 if len(self.aliases_in_flight) else [])
1032
1033 # for error message
1034 first_word_str = None # type: Optional[str]
1035 argv0_loc = loc.Word(words[0])
1036
1037 expanded = [] # type: List[str]
1038 i = 0
1039 n = len(words)
1040
1041 while i < n:
1042 w = words[i]
1043
1044 ok, word_str, quoted = word_.StaticEval(w)
1045 if not ok or quoted:
1046 break
1047
1048 alias_exp = self.aliases.get(word_str)
1049 if alias_exp is None:
1050 break
1051
1052 # Prevent infinite loops. This is subtle: we want to prevent infinite
1053 # expansion of alias echo='echo x'. But we don't want to prevent
1054 # expansion of the second word in 'echo echo', so we add 'i' to
1055 # "aliases_in_flight".
1056 if (word_str, i) in aliases_in_flight:
1057 break
1058
1059 if i == 0:
1060 first_word_str = word_str # for error message
1061
1062 #log('%r -> %r', word_str, alias_exp)
1063 aliases_in_flight.append((word_str, i))
1064 expanded.append(alias_exp)
1065 i += 1
1066
1067 if not alias_exp.endswith(' '):
1068 # alias e='echo [ ' is the same expansion as
1069 # alias e='echo ['
1070 # The trailing space indicates whether we should continue to expand
1071 # aliases; it's not part of it.
1072 expanded.append(' ')
1073 break # No more expansions
1074
1075 if len(expanded) == 0: # No expansions; caller does parsing.
1076 return None
1077
1078 # We are expanding an alias, so copy the rest of the words and re-parse.
1079 if i < n:
1080 left_tok = location.LeftTokenForWord(words[i])
1081 right_tok = location.RightTokenForWord(words[-1])
1082
1083 # OLD CONSTRAINT
1084 #assert left_tok.line_id == right_tok.line_id
1085
1086 words_str = self.arena.SnipCodeString(left_tok, right_tok)
1087 expanded.append(words_str)
1088
1089 code_str = ''.join(expanded)
1090
1091 # TODO:
1092 # Aliases break static parsing (like backticks), so use our own Arena.
1093 # This matters for Hay, which calls SaveLinesAndDiscard().
1094 # arena = alloc.Arena()
1095 arena = self.arena
1096
1097 line_reader = reader.StringLineReader(code_str, arena)
1098 cp = self.parse_ctx.MakeOshParser(line_reader)
1099 cp.Init_AliasesInFlight(aliases_in_flight)
1100
1101 # break circular dep
1102 from frontend import parse_lib
1103
1104 # The interaction between COMPLETION and ALIASES requires special care.
1105 # See docstring of BeginAliasExpansion() in parse_lib.py.
1106 src = source.Alias(first_word_str, argv0_loc)
1107 with alloc.ctx_SourceCode(arena, src):
1108 with parse_lib.ctx_Alias(self.parse_ctx.trail):
1109 try:
1110 # _ParseCommandTerm() handles multiline commands, compound
1111 # commands, etc. as opposed to ParseLogicalLine()
1112 node = cp._ParseCommandTerm()
1113 except error.Parse as e:
1114 # Failure to parse alias expansion is a fatal error
1115 # We don't need more handling here/
1116 raise
1117
1118 if 0:
1119 log('AFTER expansion:')
1120 node.PrettyPrint()
1121
1122 return node
1123
1124 def ParseSimpleCommand(self):
1125 # type: () -> command_t
1126 """Fixed transcription of the POSIX grammar
1127
1128 io_file : '<' filename
1129 | LESSAND filename
1130 ...
1131
1132 io_here : DLESS here_end
1133 | DLESSDASH here_end
1134
1135 redirect : IO_NUMBER (io_redirect | io_here)
1136
1137 prefix_part : ASSIGNMENT_WORD | redirect
1138 cmd_part : WORD | redirect
1139
1140 assign_kw : Declare | Export | Local | Readonly
1141
1142 # Without any words it is parsed as a command, not an assignment
1143 assign_listing : assign_kw
1144
1145 # Now we have something to do (might be changing assignment flags too)
1146 # NOTE: any prefixes should be a warning, but they are allowed in shell.
1147 assignment : prefix_part* assign_kw (WORD | ASSIGNMENT_WORD)+
1148
1149 # an external command, a function call, or a builtin -- a "word_command"
1150 word_command : prefix_part* cmd_part+
1151
1152 simple_command : assign_listing
1153 | assignment
1154 | proc_command
1155
1156 Simple imperative algorithm:
1157
1158 1) Read a list of words and redirects. Append them to separate lists.
1159 2) Look for the first non-assignment word. If it's declare, etc., then
1160 keep parsing words AND assign words. Otherwise, just parse words.
1161 3) If there are no non-assignment words, then it's a global assignment.
1162
1163 { redirects, global assignments } OR
1164 { redirects, prefix_bindings, words } OR
1165 { redirects, ERROR_prefix_bindings, keyword, assignments, words }
1166
1167 THEN CHECK that prefix bindings don't have any array literal parts!
1168 global assignment and keyword assignments can have the of course.
1169 well actually EXPORT shouldn't have them either -- WARNING
1170
1171 3 cases we want to warn: prefix_bindings for assignment, and array literal
1172 in prefix bindings, or export
1173
1174 A command can be an assignment word, word, or redirect on its own.
1175
1176 ls
1177 >out.txt
1178
1179 >out.txt FOO=bar # this touches the file
1180
1181 Or any sequence:
1182 ls foo bar
1183 <in.txt ls foo bar >out.txt
1184 <in.txt ls >out.txt foo bar
1185
1186 Or add one or more environment bindings:
1187 VAR=val env
1188 >out.txt VAR=val env
1189
1190 here_end vs filename is a matter of whether we test that it's quoted. e.g.
1191 <<EOF vs <<'EOF'.
1192 """
1193 redirects, words, typed_args, block = self._ScanSimpleCommand()
1194
1195 typed_loc = None # type: Optional[Token]
1196 if block:
1197 typed_loc = block.brace_group.left
1198 if typed_args:
1199 typed_loc = typed_args.left # preferred over block location
1200
1201 if len(words) == 0: # e.g. >out.txt # redirect without words
1202 assert len(redirects) != 0
1203 if typed_loc is not None:
1204 p_die("Unexpected typed args", typed_loc)
1205 return command.Redirect(command.NoOp, redirects)
1206
1207 preparsed_list, suffix_words = _SplitSimpleCommandPrefix(words)
1208 if len(preparsed_list):
1209 # Disallow X=Y inside proc and func
1210 # and inside Hay Attr blocks
1211 # But allow X=Y at the top level
1212 # for interactive use foo=bar
1213 # for global constants GLOBAL=~/src
1214 # because YSH assignment doesn't have tilde sub
1215 if len(suffix_words) == 0:
1216 if (self.cmd_mode != cmd_mode_e.Shell or
1217 (len(self.hay_attrs_stack) and self.hay_attrs_stack[-1])):
1218 p_die('Use var/setvar to assign in YSH',
1219 preparsed_list[0].left)
1220
1221 # Set a reference to words and redirects for completion. We want to
1222 # inspect this state after a failed parse.
1223 self.parse_ctx.trail.SetLatestWords(suffix_words, redirects)
1224
1225 if len(suffix_words) == 0:
1226 if typed_loc is not None:
1227 p_die("Unexpected typed args", typed_loc)
1228
1229 # ShAssignment: No suffix words like ONE=1 a[x]=1 TWO=2
1230 pairs = [] # type: List[AssignPair]
1231 for preparsed in preparsed_list:
1232 pairs.append(
1233 _MakeAssignPair(self.parse_ctx, preparsed, self.arena))
1234
1235 left_tok = location.LeftTokenForCompoundWord(words[0])
1236 assign_node = command.ShAssignment(left_tok, pairs)
1237 if len(redirects):
1238 return command.Redirect(assign_node, redirects)
1239 else:
1240 return assign_node
1241
1242 kind, kw_token = word_.IsControlFlow(suffix_words[0])
1243
1244 if kind == Kind.ControlFlow:
1245 if not self.parse_opts.parse_ignored() and len(redirects):
1246 p_die("Control flow shouldn't have redirects", kw_token)
1247 if len(preparsed_list): # FOO=bar local spam=eggs not allowed
1248 p_die("Control flow shouldn't have environment bindings",
1249 preparsed_list[0].left)
1250
1251 if kw_token.id == Id.ControlFlow_Return:
1252 # return x - inside procs and shell functions
1253 # return (x) - inside funcs
1254 if typed_args is None:
1255 if self.cmd_mode not in (cmd_mode_e.Shell,
1256 cmd_mode_e.Proc):
1257 p_die('Shell-style returns not allowed here', kw_token)
1258 else:
1259 if self.cmd_mode != cmd_mode_e.Func:
1260 p_die('Typed return is only allowed inside func',
1261 typed_loc)
1262 if len(typed_args.pos_args) != 1:
1263 p_die("Typed return expects one argument", typed_loc)
1264 if len(typed_args.named_args) != 0:
1265 p_die("Typed return doesn't take named arguments",
1266 typed_loc)
1267 return command.Retval(kw_token, typed_args.pos_args[0])
1268
1269 # Except for return (x), we shouldn't have typed args
1270 if typed_loc is not None:
1271 p_die("Unexpected typed args", typed_loc)
1272
1273 # Attach the token for errors. (ShAssignment may not need it.)
1274 if len(suffix_words) == 1:
1275 arg_word = None # type: Optional[word_t]
1276 elif len(suffix_words) == 2:
1277 arg_word = suffix_words[1]
1278 else:
1279 p_die('Unexpected argument to %r' % lexer.TokenVal(kw_token),
1280 loc.Word(suffix_words[2]))
1281
1282 return command.ControlFlow(kw_token, arg_word)
1283
1284 # Alias expansion only understands words, not typed args ( ) or block { }
1285 if not typed_args and not block and self.parse_opts.expand_aliases():
1286 # If any expansions were detected, then parse again.
1287 expanded_node = self._MaybeExpandAliases(suffix_words)
1288 if expanded_node:
1289 # Attach env bindings and redirects to the expanded node.
1290 more_env = [] # type: List[EnvPair]
1291 _AppendMoreEnv(preparsed_list, more_env)
1292 exp = command.ExpandedAlias(expanded_node, more_env)
1293 if len(redirects):
1294 return command.Redirect(exp, redirects)
1295 else:
1296 return exp
1297
1298 # TODO: check that we don't have env1=x x[1]=y env2=z here.
1299
1300 # FOO=bar printenv.py FOO
1301 node = _MakeSimpleCommand(preparsed_list, suffix_words, typed_args,
1302 block)
1303 if len(redirects):
1304 return command.Redirect(node, redirects)
1305 else:
1306 return node
1307
1308 def ParseBraceGroup(self):
1309 # type: () -> BraceGroup
1310 """
1311 Original:
1312 brace_group : LBrace command_list RBrace ;
1313
1314 YSH:
1315 brace_group : LBrace (Op_Newline IgnoredComment?)? command_list RBrace ;
1316
1317 The doc comment can only occur if there's a newline.
1318 """
1319 ate = self._Eat(Id.Lit_LBrace)
1320 left = word_.BraceToken(ate)
1321
1322 doc_word = None # type: word_t
1323 self._GetWord()
1324 if self.c_id == Id.Op_Newline:
1325 self._SetNext()
1326 # Set a flag so we don't skip over ###
1327 with word_.ctx_EmitDocToken(self.w_parser):
1328 self._GetWord()
1329
1330 if self.c_id == Id.Ignored_Comment:
1331 doc_word = self.cur_word
1332 self._SetNext()
1333
1334 # Id.Ignored_Comment means it's a Token, or None
1335 doc_token = cast(Token, doc_word)
1336
1337 c_list = self._ParseCommandList()
1338
1339 ate = self._Eat(Id.Lit_RBrace)
1340 right = word_.BraceToken(ate)
1341
1342 # Note(andychu): Related ASDL bug #1216. Choosing the Python [] behavior
1343 # would allow us to revert this back to None, which was changed in
1344 # https://github.com/oilshell/oil/pull/1211. Choosing the C++ nullptr
1345 # behavior saves allocations, but is less type safe.
1346 return BraceGroup(left, doc_token, c_list.children, right)
1347
1348 def ParseDoGroup(self):
1349 # type: () -> command.DoGroup
1350 """Used by ForEach, ForExpr, While, Until. Should this be a Do node?
1351
1352 do_group : Do command_list Done ; /* Apply rule 6 */
1353 """
1354 ate = self._Eat(Id.KW_Do)
1355 do_kw = word_.AsKeywordToken(ate)
1356
1357 c_list = self._ParseCommandList() # could be anything
1358
1359 ate = self._Eat(Id.KW_Done)
1360 done_kw = word_.AsKeywordToken(ate)
1361
1362 return command.DoGroup(do_kw, c_list.children, done_kw)
1363
1364 def ParseForWords(self):
1365 # type: () -> Tuple[List[CompoundWord], Optional[Token]]
1366 """
1367 for_words : WORD* for_sep
1368 ;
1369 for_sep : ';' newline_ok
1370 | NEWLINES
1371 ;
1372 """
1373 words = [] # type: List[CompoundWord]
1374 # The token of any semi-colon, so we can remove it.
1375 semi_tok = None # type: Optional[Token]
1376
1377 while True:
1378 self._GetWord()
1379 if self.c_id == Id.Op_Semi:
1380 tok = cast(Token, self.cur_word)
1381 semi_tok = tok
1382 self._SetNext()
1383 self._NewlineOk()
1384 break
1385 elif self.c_id == Id.Op_Newline:
1386 self._SetNext()
1387 break
1388 elif self.parse_opts.parse_brace() and self.c_id == Id.Lit_LBrace:
1389 break
1390
1391 if self.cur_word.tag() != word_e.Compound:
1392 # TODO: Can we also show a pointer to the 'for' keyword?
1393 p_die('Invalid word in for loop', loc.Word(self.cur_word))
1394
1395 w2 = cast(CompoundWord, self.cur_word)
1396 words.append(w2)
1397 self._SetNext()
1398 return words, semi_tok
1399
1400 def _ParseForExprLoop(self, for_kw):
1401 # type: (Token) -> command.ForExpr
1402 """
1403 Shell:
1404 for '((' init ';' cond ';' update '))' for_sep? do_group
1405
1406 YSH:
1407 for '((' init ';' cond ';' update '))' for_sep? brace_group
1408 """
1409 node = self.w_parser.ReadForExpression()
1410 node.keyword = for_kw
1411
1412 self._SetNext()
1413
1414 self._GetWord()
1415 if self.c_id == Id.Op_Semi:
1416 self._SetNext()
1417 self._NewlineOk()
1418 elif self.c_id == Id.Op_Newline:
1419 self._SetNext()
1420 elif self.c_id == Id.KW_Do: # missing semicolon/newline allowed
1421 pass
1422 elif self.c_id == Id.Lit_LBrace: # does NOT require parse_brace
1423 pass
1424 else:
1425 p_die('Invalid word after for expression', loc.Word(self.cur_word))
1426
1427 if self.c_id == Id.Lit_LBrace:
1428 node.body = self.ParseBraceGroup()
1429 else:
1430 node.body = self.ParseDoGroup()
1431 return node
1432
1433 def _ParseForEachLoop(self, for_kw):
1434 # type: (Token) -> command.ForEach
1435 node = command.ForEach.CreateNull(alloc_lists=True)
1436 node.keyword = for_kw
1437
1438 num_iter_names = 0
1439 while True:
1440 w = self.cur_word
1441
1442 # Hack that makes the language more familiar:
1443 # - 'x, y' is accepted, but not 'x,y' or 'x ,y'
1444 # - 'x y' is also accepted but not idiomatic.
1445 UP_w = w
1446 if w.tag() == word_e.Compound:
1447 w = cast(CompoundWord, UP_w)
1448 if word_.LiteralId(w.parts[-1]) == Id.Lit_Comma:
1449 w.parts.pop()
1450
1451 ok, iter_name, quoted = word_.StaticEval(w)
1452 if not ok or quoted: # error: for $x
1453 p_die('Expected loop variable (a constant word)', loc.Word(w))
1454
1455 if not match.IsValidVarName(iter_name): # error: for -
1456 # TODO: consider commas?
1457 if ',' in iter_name:
1458 p_die('Loop variables look like x, y (fix spaces)',
1459 loc.Word(w))
1460 p_die('Invalid loop variable name %r' % iter_name, loc.Word(w))
1461
1462 node.iter_names.append(iter_name)
1463 num_iter_names += 1
1464 self._SetNext()
1465
1466 self._GetWord()
1467 # 'in' or 'do' or ';' or Op_Newline marks the end of variable names
1468 # Subtlety: 'var' is KW_Var and is a valid loop name
1469 if self.c_id in (Id.KW_In, Id.KW_Do) or self.c_kind == Kind.Op:
1470 break
1471
1472 if num_iter_names == 3:
1473 p_die('Unexpected word after 3 loop variables',
1474 loc.Word(self.cur_word))
1475
1476 self._NewlineOk()
1477
1478 self._GetWord()
1479 if self.c_id == Id.KW_In:
1480 expr_blame = word_.AsKeywordToken(self.cur_word)
1481
1482 self._SetNext() # skip in
1483
1484 next_id = self.w_parser.LookPastSpace()
1485 #log('%s', Id_str(next_id))
1486
1487 if next_id == Id.Op_LParen: # for x in (expr) {
1488 enode = self.w_parser.ParseYshExprForCommand()
1489 node.iterable = for_iter.YshExpr(enode, expr_blame)
1490
1491 # We don't accept for x in (obj); do ...
1492 self._GetWord()
1493 if self.c_id != Id.Lit_LBrace:
1494 p_die('Expected { after iterable expression',
1495 loc.Word(self.cur_word))
1496
1497 elif next_id == Id.Redir_LessGreat: # for x in <> {
1498 # <> is Id.Redir_Great - reuse this for simplicity
1499
1500 w = self._Eat(Id.Redir_LessGreat)
1501 left = word_.AsOperatorToken(w)
1502
1503 node.iterable = for_iter.Files(left, [])
1504
1505 # Must be { not 'do'
1506 self._GetWord()
1507 if self.c_id != Id.Lit_LBrace:
1508 p_die('Expected { after files', loc.Word(self.cur_word))
1509
1510 elif next_id == Id.Redir_Less: # for x in < > {
1511 w = self._Eat(Id.Redir_Less)
1512 left = word_.AsOperatorToken(w)
1513
1514 # TODO: we could accept
1515 #
1516 # for x in < README.md *.py > {
1517 # for x in < @myfiles > {
1518 #
1519 # And set _filename _line_num, similar to awk
1520
1521 self._Eat(Id.Redir_Great)
1522
1523 node.iterable = for_iter.Files(left, [])
1524
1525 # Must be { not 'do'
1526 self._GetWord()
1527 if self.c_id != Id.Lit_LBrace:
1528 p_die('Expected { after files', loc.Word(self.cur_word))
1529
1530 else:
1531 semi_tok = None # type: Optional[Token]
1532 iter_words, semi_tok = self.ParseForWords()
1533 node.semi_tok = semi_tok
1534
1535 if not self.parse_opts.parse_bare_word() and len(
1536 iter_words) == 1:
1537 ok, s, quoted = word_.StaticEval(iter_words[0])
1538 if ok and match.IsValidVarName(s) and not quoted:
1539 p_die(
1540 'Surround this word with either parens or quotes (parse_bare_word)',
1541 loc.Word(iter_words[0]))
1542
1543 words2 = braces.BraceDetectAll(iter_words)
1544 words3 = word_.TildeDetectAll(words2)
1545 node.iterable = for_iter.Words(words3)
1546
1547 # Now that we know there are words, do an extra check
1548 if num_iter_names > 2:
1549 p_die('Expected at most 2 loop variables', for_kw)
1550
1551 elif self.c_id == Id.KW_Do:
1552 node.iterable = for_iter.Args # implicitly loop over "$@"
1553 # do not advance
1554
1555 elif self.c_id == Id.Op_Semi: # for x; do
1556 node.iterable = for_iter.Args # implicitly loop over "$@"
1557 self._SetNext()
1558
1559 else: # for foo BAD
1560 p_die('Unexpected word after for loop variable',
1561 loc.Word(self.cur_word))
1562
1563 self._GetWord()
1564 if self.c_id == Id.Lit_LBrace: # parse_opts.parse_brace() must be on
1565 node.body = self.ParseBraceGroup()
1566 else:
1567 node.body = self.ParseDoGroup()
1568
1569 return node
1570
1571 def ParseFor(self):
1572 # type: () -> command_t
1573 """
1574 TODO: Update the grammar
1575
1576 for_clause : For for_name newline_ok (in for_words? for_sep)? do_group ;
1577 | For '((' ... TODO
1578 """
1579 ate = self._Eat(Id.KW_For)
1580 for_kw = word_.AsKeywordToken(ate)
1581
1582 self._GetWord()
1583 if self.c_id == Id.Op_DLeftParen:
1584 if not self.parse_opts.parse_dparen():
1585 p_die("Bash for loops aren't allowed (parse_dparen)",
1586 loc.Word(self.cur_word))
1587
1588 # for (( i = 0; i < 10; i++)
1589 n1 = self._ParseForExprLoop(for_kw)
1590 return self._MaybeParseRedirectList(n1)
1591 else:
1592 # for x in a b; do echo hi; done
1593 n2 = self._ParseForEachLoop(for_kw)
1594 return self._MaybeParseRedirectList(n2)
1595
1596 def _ParseConditionList(self):
1597 # type: () -> condition_t
1598 """
1599 condition_list: command_list
1600
1601 This is a helper to parse a condition list for if commands and while/until
1602 loops. It will throw a parse error if there are no conditions in the list.
1603 """
1604 self.allow_block = False
1605 commands = self._ParseCommandList()
1606 self.allow_block = True
1607
1608 if len(commands.children) == 0:
1609 p_die("Expected a condition", loc.Word(self.cur_word))
1610
1611 return condition.Shell(commands.children)
1612
1613 def ParseWhileUntil(self, keyword):
1614 # type: (Token) -> command.WhileUntil
1615 """
1616 while_clause : While command_list do_group ;
1617 until_clause : Until command_list do_group ;
1618 """
1619 self._SetNext() # skip keyword
1620
1621 if (self.parse_opts.parse_paren() and
1622 self.w_parser.LookPastSpace() == Id.Op_LParen):
1623 enode = self.w_parser.ParseYshExprForCommand()
1624 cond = condition.YshExpr(enode) # type: condition_t
1625 else:
1626 cond = self._ParseConditionList()
1627
1628 # NOTE: The LSTs will be different for OSH and YSH, but the execution
1629 # should be unchanged. To be sure we should desugar.
1630 self._GetWord()
1631 if self.parse_opts.parse_brace() and self.c_id == Id.Lit_LBrace:
1632 # while test -f foo {
1633 body_node = self.ParseBraceGroup() # type: command_t
1634 else:
1635 body_node = self.ParseDoGroup()
1636
1637 return command.WhileUntil(keyword, cond, body_node)
1638
1639 def ParseCaseArm(self):
1640 # type: () -> CaseArm
1641 """
1642 case_item: '('? pattern ('|' pattern)* ')'
1643 newline_ok command_term? trailer? ;
1644
1645 Looking at '(' or pattern
1646 """
1647 self.lexer.PushHint(Id.Op_RParen, Id.Right_CasePat)
1648
1649 left_tok = location.LeftTokenForWord(self.cur_word) # ( or pat
1650
1651 if self.c_id == Id.Op_LParen: # Optional (
1652 self._SetNext()
1653
1654 pat_words = [] # type: List[word_t]
1655 while True:
1656 self._GetWord()
1657 if self.c_kind != Kind.Word:
1658 p_die('Expected case pattern', loc.Word(self.cur_word))
1659 pat_words.append(self.cur_word)
1660 self._SetNext()
1661
1662 self._GetWord()
1663 if self.c_id == Id.Op_Pipe:
1664 self._SetNext()
1665 else:
1666 break
1667
1668 ate = self._Eat(Id.Right_CasePat)
1669 middle_tok = word_.AsOperatorToken(ate)
1670
1671 self._NewlineOk()
1672
1673 self._GetWord()
1674 if self.c_id not in (Id.Op_DSemi, Id.Op_SemiAmp, Id.Op_DSemiAmp,
1675 Id.KW_Esac):
1676 c_list = self._ParseCommandTerm()
1677 action_children = c_list.children
1678 else:
1679 action_children = []
1680
1681 dsemi_tok = None # type: Token
1682 self._GetWord()
1683 if self.c_id == Id.KW_Esac: # missing last ;;
1684 pass
1685 elif self.c_id in (Id.Op_DSemi, Id.Op_SemiAmp, Id.Op_DSemiAmp):
1686 dsemi_tok = word_.AsOperatorToken(self.cur_word)
1687 self._SetNext()
1688 else:
1689 # Happens on EOF
1690 p_die('Expected ;; or esac', loc.Word(self.cur_word))
1691
1692 self._NewlineOk()
1693
1694 return CaseArm(left_tok, pat.Words(pat_words), middle_tok,
1695 action_children, dsemi_tok)
1696
1697 def ParseYshCaseArm(self, discriminant):
1698 # type: (Id_t) -> CaseArm
1699 """
1700 case_item : pattern newline_ok brace_group newline_ok
1701 pattern : pat_words
1702 | pat_exprs
1703 | pat_eggex
1704 | pat_else
1705 pat_words : pat_word (newline_ok '|' newline_ok pat_word)*
1706 pat_exprs : pat_expr (newline_ok '|' newline_ok pat_expr)*
1707 pat_word : WORD
1708 pat_eggex : '/' oil_eggex '/'
1709 pat_expr : '(' oil_expr ')'
1710 pat_else : '(' Id.KW_Else ')'
1711
1712 Looking at: 'pattern'
1713
1714 Note that the trailing `newline_ok` in `case_item` is handled by
1715 `ParseYshCase`. We do this because parsing that `newline_ok` returns
1716 the next "discriminant" for the next token, so it makes more sense to
1717 handle it there.
1718 """
1719 left_tok = None # type: Token
1720 pattern = None # type: pat_t
1721
1722 if discriminant in (Id.Op_LParen, Id.Arith_Slash):
1723 # pat_exprs, pat_else or pat_eggex
1724 pattern, left_tok = self.w_parser.ParseYshCasePattern()
1725 else:
1726 # pat_words
1727 pat_words = [] # type: List[word_t]
1728 while True:
1729 self._GetWord()
1730 if self.c_kind != Kind.Word:
1731 p_die('Expected case pattern', loc.Word(self.cur_word))
1732 pat_words.append(self.cur_word)
1733 self._SetNext()
1734
1735 if not left_tok:
1736 left_tok = location.LeftTokenForWord(self.cur_word)
1737
1738 self._NewlineOk()
1739
1740 self._GetWord()
1741 if self.c_id == Id.Op_Pipe:
1742 self._SetNext()
1743 self._NewlineOk()
1744 else:
1745 break
1746 pattern = pat.Words(pat_words)
1747
1748 self._NewlineOk()
1749 action = self.ParseBraceGroup()
1750
1751 # The left token of the action is our "middle" token
1752 return CaseArm(left_tok, pattern, action.left, action.children,
1753 action.right)
1754
1755 def ParseYshCase(self, case_kw):
1756 # type: (Token) -> command.Case
1757 """
1758 ysh_case : Case '(' expr ')' LBrace newline_ok ysh_case_arm* RBrace ;
1759
1760 Looking at: token after 'case'
1761 """
1762 enode = self.w_parser.ParseYshExprForCommand()
1763 to_match = case_arg.YshExpr(enode)
1764
1765 ate = self._Eat(Id.Lit_LBrace)
1766 arms_start = word_.BraceToken(ate)
1767
1768 discriminant = self.w_parser.NewlineOkForYshCase()
1769
1770 # Note: for now, zero arms are accepted, just like POSIX case $x in esac
1771 arms = [] # type: List[CaseArm]
1772 while discriminant != Id.Op_RBrace:
1773 arm = self.ParseYshCaseArm(discriminant)
1774 arms.append(arm)
1775
1776 discriminant = self.w_parser.NewlineOkForYshCase()
1777
1778 # NewlineOkForYshCase leaves the lexer in lex_mode_e.Expr. So the '}'
1779 # token is read as an Id.Op_RBrace, but we need to store this as a
1780 # Id.Lit_RBrace.
1781 ate = self._Eat(Id.Op_RBrace)
1782 arms_end = word_.AsOperatorToken(ate)
1783 arms_end.id = Id.Lit_RBrace
1784
1785 return command.Case(case_kw, to_match, arms_start, arms, arms_end)
1786
1787 def ParseOldCase(self, case_kw):
1788 # type: (Token) -> command.Case
1789 """
1790 case_clause : Case WORD newline_ok In newline_ok case_arm* Esac ;
1791
1792 -> Looking at WORD
1793
1794 FYI original POSIX case list, which takes pains for DSEMI
1795
1796 case_list: case_item (DSEMI newline_ok case_item)* DSEMI? newline_ok;
1797 """
1798 self._GetWord()
1799 w = self.cur_word
1800 if not self.parse_opts.parse_bare_word():
1801 ok, s, quoted = word_.StaticEval(w)
1802 if ok and not quoted:
1803 p_die(
1804 "This is a constant string. You may want a variable like $x (parse_bare_word)",
1805 loc.Word(w))
1806
1807 if w.tag() != word_e.Compound:
1808 p_die("Expected a word to match against", loc.Word(w))
1809
1810 to_match = case_arg.Word(w)
1811 self._SetNext() # past WORD
1812
1813 self._NewlineOk()
1814
1815 ate = self._Eat(Id.KW_In)
1816 arms_start = word_.AsKeywordToken(ate)
1817
1818 self._NewlineOk()
1819
1820 arms = [] # type: List[CaseArm]
1821 while True:
1822 self._GetWord()
1823 if self.c_id == Id.KW_Esac:
1824 break
1825 # case arm should begin with a pattern word or (
1826 if self.c_kind != Kind.Word and self.c_id != Id.Op_LParen:
1827 break
1828
1829 arm = self.ParseCaseArm()
1830 arms.append(arm)
1831
1832 ate = self._Eat(Id.KW_Esac)
1833 arms_end = word_.AsKeywordToken(ate)
1834
1835 # no redirects yet
1836 return command.Case(case_kw, to_match, arms_start, arms, arms_end)
1837
1838 def ParseCase(self):
1839 # type: () -> command.Case
1840 """
1841 case_clause : old_case # from POSIX
1842 | ysh_case
1843 ;
1844
1845 Looking at 'Case'
1846 """
1847 case_kw = word_.AsKeywordToken(self.cur_word)
1848 self._SetNext() # past 'case'
1849
1850 if self.w_parser.LookPastSpace() == Id.Op_LParen:
1851 return self.ParseYshCase(case_kw)
1852 else:
1853 return self.ParseOldCase(case_kw)
1854
1855 def _ParseYshElifElse(self, if_node):
1856 # type: (command.If) -> None
1857 """If test -f foo { echo foo.
1858
1859 } elif test -f bar; test -f spam { ^ we parsed up to here echo
1860 bar } else { echo none }
1861 """
1862 arms = if_node.arms
1863
1864 while self.c_id == Id.KW_Elif:
1865 elif_kw = word_.AsKeywordToken(self.cur_word)
1866 self._SetNext() # skip elif
1867 if (self.parse_opts.parse_paren() and
1868 self.w_parser.LookPastSpace() == Id.Op_LParen):
1869 enode = self.w_parser.ParseYshExprForCommand()
1870 cond = condition.YshExpr(enode) # type: condition_t
1871 else:
1872 self.allow_block = False
1873 commands = self._ParseCommandList()
1874 self.allow_block = True
1875 cond = condition.Shell(commands.children)
1876
1877 body = self.ParseBraceGroup()
1878 self._GetWord()
1879
1880 arm = IfArm(elif_kw, cond, None, body.children, None)
1881 arms.append(arm)
1882
1883 self._GetWord()
1884 if self.c_id == Id.KW_Else:
1885 self._SetNext()
1886 body = self.ParseBraceGroup()
1887 if_node.else_action = body.children
1888
1889 def _ParseYshIf(self, if_kw, cond):
1890 # type: (Token, condition_t) -> command.If
1891 """
1892 if test -f foo {
1893 # ^ we parsed up to here
1894 echo foo
1895 } elif test -f bar; test -f spam {
1896 echo bar
1897 } else {
1898 echo none
1899 }
1900 NOTE: If you do something like if test -n foo{, the parser keeps going, and
1901 the error is confusing because it doesn't point to the right place.
1902
1903 I think we might need strict_brace so that foo{ is disallowed. It has to
1904 be foo\{ or foo{a,b}. Or just turn that on with parse_brace? After you
1905 form ANY CompoundWord, make sure it's balanced for Lit_LBrace and
1906 Lit_RBrace? Maybe this is pre-parsing step in the WordParser?
1907 """
1908 if_node = command.If.CreateNull(alloc_lists=True)
1909 if_node.if_kw = if_kw
1910
1911 body1 = self.ParseBraceGroup()
1912 # Every arm has 1 spid, unlike shell-style
1913 # TODO: We could get the spids from the brace group.
1914 arm = IfArm(if_kw, cond, None, body1.children, None)
1915
1916 if_node.arms.append(arm)
1917
1918 self._GetWord()
1919 if self.c_id in (Id.KW_Elif, Id.KW_Else):
1920 self._ParseYshElifElse(if_node)
1921 # the whole if node has the 'else' spid, unlike shell-style there's no 'fi'
1922 # spid because that's in the BraceGroup.
1923 return if_node
1924
1925 def _ParseElifElse(self, if_node):
1926 # type: (command.If) -> None
1927 """
1928 else_part: (Elif command_list Then command_list)* Else command_list ;
1929 """
1930 arms = if_node.arms
1931
1932 self._GetWord()
1933 while self.c_id == Id.KW_Elif:
1934 elif_kw = word_.AsKeywordToken(self.cur_word)
1935 self._SetNext() # past 'elif'
1936
1937 cond = self._ParseConditionList()
1938
1939 ate = self._Eat(Id.KW_Then)
1940 then_kw = word_.AsKeywordToken(ate)
1941
1942 body = self._ParseCommandList()
1943 arm = IfArm(elif_kw, cond, then_kw, body.children, then_kw)
1944
1945 arms.append(arm)
1946
1947 self._GetWord()
1948 if self.c_id == Id.KW_Else:
1949 else_kw = word_.AsKeywordToken(self.cur_word)
1950 self._SetNext() # past 'else'
1951 body = self._ParseCommandList()
1952 if_node.else_action = body.children
1953 else:
1954 else_kw = None
1955
1956 if_node.else_kw = else_kw
1957
1958 def ParseIf(self):
1959 # type: () -> command.If
1960 """
1961 if_clause : If command_list Then command_list else_part? Fi ;
1962
1963 open : '{' | Then
1964 close : '}' | Fi
1965
1966 ysh_if : If ( command_list | '(' expr ')' )
1967 open command_list else_part? close;
1968
1969 There are 2 conditionals here: parse_paren, then parse_brace
1970 """
1971 if_node = command.If.CreateNull(alloc_lists=True)
1972 if_kw = word_.AsKeywordToken(self.cur_word)
1973 if_node.if_kw = if_kw
1974 self._SetNext() # past 'if'
1975
1976 if (self.parse_opts.parse_paren() and
1977 self.w_parser.LookPastSpace() == Id.Op_LParen):
1978 # if (x + 1)
1979 enode = self.w_parser.ParseYshExprForCommand()
1980 cond = condition.YshExpr(enode) # type: condition_t
1981 else:
1982 # if echo 1; echo 2; then
1983 # Remove ambiguity with if cd / {
1984 cond = self._ParseConditionList()
1985
1986 self._GetWord()
1987 if self.parse_opts.parse_brace() and self.c_id == Id.Lit_LBrace:
1988 return self._ParseYshIf(if_kw, cond)
1989
1990 ate = self._Eat(Id.KW_Then)
1991 then_kw = word_.AsKeywordToken(ate)
1992
1993 body = self._ParseCommandList()
1994
1995 # First arm
1996 arm = IfArm(if_kw, cond, then_kw, body.children, then_kw)
1997 if_node.arms.append(arm)
1998
1999 # 2nd to Nth arm
2000 if self.c_id in (Id.KW_Elif, Id.KW_Else):
2001 self._ParseElifElse(if_node)
2002
2003 ate = self._Eat(Id.KW_Fi)
2004 if_node.fi_kw = word_.AsKeywordToken(ate)
2005
2006 return if_node
2007
2008 def ParseTime(self):
2009 # type: () -> command_t
2010 """Time [-p] pipeline.
2011
2012 According to bash help.
2013 """
2014 time_kw = word_.AsKeywordToken(self.cur_word)
2015 self._SetNext() # skip time
2016 pipeline = self.ParsePipeline()
2017 return command.TimeBlock(time_kw, pipeline)
2018
2019 def ParseCompoundCommand(self):
2020 # type: () -> command_t
2021 """
2022 Refactoring: we put io_redirect* here instead of in function_body and
2023 command.
2024
2025 compound_command : brace_group io_redirect*
2026 | subshell io_redirect*
2027 | for_clause io_redirect*
2028 | while_clause io_redirect*
2029 | until_clause io_redirect*
2030 | if_clause io_redirect*
2031 | case_clause io_redirect*
2032
2033 # bash extensions
2034 | time_clause
2035 | [[ BoolExpr ]]
2036 | (( ArithExpr ))
2037 """
2038 self._GetWord()
2039 if self.c_id == Id.Lit_LBrace:
2040 n1 = self.ParseBraceGroup()
2041 return self._MaybeParseRedirectList(n1)
2042 if self.c_id == Id.Op_LParen:
2043 n2 = self.ParseSubshell()
2044 return self._MaybeParseRedirectList(n2)
2045
2046 if self.c_id == Id.KW_For:
2047 # Note: Redirects parsed in this call. POSIX for and bash for ((
2048 # have different nodetypes.
2049 return self.ParseFor()
2050 if self.c_id in (Id.KW_While, Id.KW_Until):
2051 keyword = word_.AsKeywordToken(self.cur_word)
2052 n3 = self.ParseWhileUntil(keyword)
2053 return self._MaybeParseRedirectList(n3)
2054
2055 if self.c_id == Id.KW_If:
2056 n4 = self.ParseIf()
2057 return self._MaybeParseRedirectList(n4)
2058
2059 if self.c_id == Id.KW_Case:
2060 n5 = self.ParseCase()
2061 return self._MaybeParseRedirectList(n5)
2062
2063 if self.c_id == Id.KW_DLeftBracket:
2064 if not self.parse_opts.parse_dbracket():
2065 p_die('Bash [[ not allowed in YSH (parse_dbracket)',
2066 loc.Word(self.cur_word))
2067 n6 = self.ParseDBracket()
2068 return self._MaybeParseRedirectList(n6)
2069 if self.c_id == Id.Op_DLeftParen:
2070 if not self.parse_opts.parse_dparen():
2071 p_die(
2072 'Bash (( not allowed in YSH (parse_dparen, see OILS-ERR-14 for wart)',
2073 loc.Word(self.cur_word))
2074 n7 = self.ParseDParen()
2075 return self._MaybeParseRedirectList(n7)
2076
2077 # bash extensions: no redirects
2078 if self.c_id == Id.KW_Time:
2079 return self.ParseTime()
2080
2081 # Happens in function body, e.g. myfunc() oops
2082 p_die(
2083 'Unexpected word while parsing compound command (%s)' %
2084 Id_str(self.c_id), loc.Word(self.cur_word))
2085 assert False # for MyPy
2086
2087 def ParseFunctionDef(self):
2088 # type: () -> command.ShFunction
2089 """
2090 function_header : fname '(' ')'
2091 function_def : function_header newline_ok function_body ;
2092
2093 Precondition: Looking at the function name.
2094
2095 NOTE: There is an ambiguity with:
2096
2097 function foo ( echo hi ) and
2098 function foo () ( echo hi )
2099
2100 Bash only accepts the latter, though it doesn't really follow a grammar.
2101 """
2102 word0 = cast(CompoundWord, self.cur_word) # caller ensures validity
2103 name = word_.ShFunctionName(word0)
2104 if len(name) == 0: # example: foo$x is invalid
2105 p_die('Invalid function name', loc.Word(word0))
2106
2107 part0 = word0.parts[0]
2108 # If we got a non-empty string from ShFunctionName, this should be true.
2109 assert part0.tag() == word_part_e.Literal
2110 blame_tok = cast(Token, part0) # for ctx_VarChecker
2111
2112 self._SetNext() # move past function name
2113
2114 # Must be true because of lookahead
2115 self._GetWord()
2116 assert self.c_id == Id.Op_LParen, self.cur_word
2117
2118 self.lexer.PushHint(Id.Op_RParen, Id.Right_ShFunction)
2119 self._SetNext()
2120
2121 self._GetWord()
2122 if self.c_id == Id.Right_ShFunction:
2123 # 'f ()' implies a function definition, since invoking it with no args
2124 # would just be 'f'
2125 self._SetNext()
2126
2127 self._NewlineOk()
2128
2129 func = command.ShFunction.CreateNull()
2130 func.name = name
2131 with ctx_VarChecker(self.var_checker, blame_tok):
2132 func.body = self.ParseCompoundCommand()
2133
2134 func.name_tok = location.LeftTokenForCompoundWord(word0)
2135 return func
2136 else:
2137 p_die('Expected ) in function definition', loc.Word(self.cur_word))
2138 return None
2139
2140 def ParseKshFunctionDef(self):
2141 # type: () -> command.ShFunction
2142 """
2143 ksh_function_def : 'function' fname ( '(' ')' )? newline_ok function_body
2144 """
2145 keyword_tok = word_.AsKeywordToken(self.cur_word)
2146
2147 self._SetNext() # skip past 'function'
2148 self._GetWord()
2149
2150 cur_word = cast(CompoundWord, self.cur_word) # caller ensures validity
2151 name = word_.ShFunctionName(cur_word)
2152 if len(name) == 0: # example: foo$x is invalid
2153 p_die('Invalid KSH-style function name', loc.Word(cur_word))
2154
2155 name_word = self.cur_word
2156 self._SetNext() # skip past 'function name
2157
2158 self._GetWord()
2159 if self.c_id == Id.Op_LParen:
2160 self.lexer.PushHint(Id.Op_RParen, Id.Right_ShFunction)
2161 self._SetNext()
2162 self._Eat(Id.Right_ShFunction)
2163
2164 self._NewlineOk()
2165
2166 func = command.ShFunction.CreateNull()
2167 func.name = name
2168 with ctx_VarChecker(self.var_checker, keyword_tok):
2169 func.body = self.ParseCompoundCommand()
2170
2171 func.keyword = keyword_tok
2172 func.name_tok = location.LeftTokenForWord(name_word)
2173 return func
2174
2175 def ParseYshProc(self):
2176 # type: () -> Proc
2177 node = Proc.CreateNull(alloc_lists=True)
2178
2179 keyword_tok = word_.AsKeywordToken(self.cur_word)
2180 node.keyword = keyword_tok
2181
2182 with ctx_VarChecker(self.var_checker, keyword_tok):
2183 with ctx_CmdMode(self, cmd_mode_e.Proc):
2184 self.w_parser.ParseProc(node)
2185 if node.sig.tag() == proc_sig_e.Closed: # Register params
2186 sig = cast(proc_sig.Closed, node.sig)
2187
2188 # Treat 3 kinds of params as variables.
2189 wp = sig.word
2190 if wp:
2191 for param in wp.params:
2192 self.var_checker.Check(Id.KW_Var, param.name,
2193 param.blame_tok)
2194 if wp.rest_of:
2195 r = wp.rest_of
2196 self.var_checker.Check(Id.KW_Var, r.name,
2197 r.blame_tok)
2198 # We COULD register __out here but it would require a different API.
2199 #if param.prefix and param.prefix.id == Id.Arith_Colon:
2200 # self.var_checker.Check(Id.KW_Var, '__' + param.name)
2201
2202 posit = sig.positional
2203 if posit:
2204 for param in posit.params:
2205 self.var_checker.Check(Id.KW_Var, param.name,
2206 param.blame_tok)
2207 if posit.rest_of:
2208 r = posit.rest_of
2209 self.var_checker.Check(Id.KW_Var, r.name,
2210 r.blame_tok)
2211
2212 named = sig.named
2213 if named:
2214 for param in named.params:
2215 self.var_checker.Check(Id.KW_Var, param.name,
2216 param.blame_tok)
2217 if named.rest_of:
2218 r = named.rest_of
2219 self.var_checker.Check(Id.KW_Var, r.name,
2220 r.blame_tok)
2221
2222 if sig.block_param:
2223 b = sig.block_param
2224 self.var_checker.Check(Id.KW_Var, b.name, b.blame_tok)
2225
2226 self._SetNext()
2227 node.body = self.ParseBraceGroup()
2228 # No redirects for YSH procs (only at call site)
2229
2230 return node
2231
2232 def ParseYshFunc(self):
2233 # type: () -> Func
2234 """
2235 ysh_func: (
2236 Expr_Name '(' [func_params] [';' func_params] ')' ['=>' type_expr] '{'
2237 )
2238 Looking at KW_Func
2239 """
2240 node = Func.CreateNull(alloc_lists=True)
2241
2242 keyword_tok = word_.AsKeywordToken(self.cur_word)
2243 node.keyword = keyword_tok
2244
2245 with ctx_VarChecker(self.var_checker, keyword_tok):
2246 self.w_parser.ParseFunc(node)
2247
2248 posit = node.positional
2249 if posit:
2250 for param in posit.params:
2251 self.var_checker.Check(Id.KW_Var, param.name,
2252 param.blame_tok)
2253 if posit.rest_of:
2254 r = posit.rest_of
2255 self.var_checker.Check(Id.KW_Var, r.name, r.blame_tok)
2256
2257 named = node.named
2258 if named:
2259 for param in named.params:
2260 self.var_checker.Check(Id.KW_Var, param.name,
2261 param.blame_tok)
2262 if named.rest_of:
2263 r = named.rest_of
2264 self.var_checker.Check(Id.KW_Var, r.name, r.blame_tok)
2265
2266 self._SetNext()
2267 with ctx_CmdMode(self, cmd_mode_e.Func):
2268 node.body = self.ParseBraceGroup()
2269
2270 return node
2271
2272 def ParseCoproc(self):
2273 # type: () -> command_t
2274 """
2275 TODO: command.Coproc?
2276 """
2277 raise NotImplementedError()
2278
2279 def ParseSubshell(self):
2280 # type: () -> command.Subshell
2281 """
2282 subshell : '(' compound_list ')'
2283
2284 Looking at Op_LParen
2285 """
2286 left = word_.AsOperatorToken(self.cur_word)
2287 self._SetNext() # skip past (
2288
2289 # Ensure that something $( (cd / && pwd) ) works. If ) is already on the
2290 # translation stack, we want to delay it.
2291
2292 self.lexer.PushHint(Id.Op_RParen, Id.Right_Subshell)
2293
2294 c_list = self._ParseCommandList()
2295 if len(c_list.children) == 1:
2296 child = c_list.children[0]
2297 else:
2298 child = c_list
2299
2300 ate = self._Eat(Id.Right_Subshell)
2301 right = word_.AsOperatorToken(ate)
2302
2303 return command.Subshell(left, child, right)
2304
2305 def ParseDBracket(self):
2306 # type: () -> command.DBracket
2307 """Pass the underlying word parser off to the boolean expression
2308 parser."""
2309 left = word_.AsKeywordToken(self.cur_word)
2310 # TODO: Test interactive. Without closing ]], you should get > prompt
2311 # (PS2)
2312
2313 self._SetNext() # skip [[
2314 b_parser = bool_parse.BoolParser(self.w_parser)
2315 bnode, right = b_parser.Parse() # May raise
2316 return command.DBracket(left, bnode, right)
2317
2318 def ParseDParen(self):
2319 # type: () -> command.DParen
2320 left = word_.AsOperatorToken(self.cur_word)
2321
2322 self._SetNext() # skip ((
2323 anode, right = self.w_parser.ReadDParen()
2324 assert anode is not None
2325
2326 return command.DParen(left, anode, right)
2327
2328 def ParseCommand(self):
2329 # type: () -> command_t
2330 """
2331 command : simple_command
2332 | compound_command # OSH edit: io_redirect* folded in
2333 | function_def
2334 | ksh_function_def
2335
2336 # YSH extensions
2337 | proc NAME ...
2338 | typed proc NAME ...
2339 | func NAME ...
2340 | const ...
2341 | var ...
2342 | setglobal ...
2343 | setref ...
2344 | setvar ...
2345 | call EXPR
2346 | = EXPR
2347 ;
2348
2349 Note: the reason const / var are not part of compound_command is because
2350 they can't be alone in a shell function body.
2351
2352 Example:
2353 This is valid shell f() if true; then echo hi; fi
2354 This is invalid f() var x = 1
2355 """
2356 if self._AtSecondaryKeyword():
2357 p_die('Unexpected word when parsing command',
2358 loc.Word(self.cur_word))
2359
2360 # YSH Extensions
2361
2362 if self.c_id == Id.KW_Proc: # proc p { ... }
2363 # proc is hidden because of the 'local reasoning' principle. Code
2364 # inside procs should be YSH, full stop. That means ysh:upgrade is
2365 # on.
2366 if self.parse_opts.parse_proc():
2367 return self.ParseYshProc()
2368 else:
2369 # 2024-02: This avoids bad syntax errors if you type YSH code
2370 # into OSH
2371 # proc p (x) { echo hi } would actually be parsed as a
2372 # command.Simple! Shell compatibility: quote 'proc'
2373 p_die("proc is a YSH keyword, but this is OSH.",
2374 loc.Word(self.cur_word))
2375
2376 if self.c_id == Id.KW_Typed: # typed proc p () { ... }
2377 self._SetNext()
2378 self._GetWord()
2379 if self.c_id != Id.KW_Proc:
2380 p_die("Expected 'proc' after 'typed'", loc.Word(self.cur_word))
2381
2382 if self.parse_opts.parse_proc():
2383 return self.ParseYshProc()
2384 else:
2385 p_die("typed is a YSH keyword, but this is OSH.",
2386 loc.Word(self.cur_word))
2387
2388 if self.c_id == Id.KW_Func: # func f(x) { ... }
2389 if self.parse_opts.parse_func():
2390 return self.ParseYshFunc()
2391 else:
2392 # Same reasoning as above, for 'proc'
2393 p_die("func is a YSH keyword, but this is OSH.",
2394 loc.Word(self.cur_word))
2395
2396 if self.c_id == Id.KW_Const and self.cmd_mode != cmd_mode_e.Shell:
2397 p_die("const can't be inside proc or func. Use var instead.",
2398 loc.Word(self.cur_word))
2399
2400 if self.c_id in (Id.KW_Var, Id.KW_Const): # var x = 1
2401 keyword_id = self.c_id
2402 kw_token = word_.LiteralToken(self.cur_word)
2403 self._SetNext()
2404 n8 = self.w_parser.ParseVarDecl(kw_token)
2405 for lhs in n8.lhs:
2406 self.var_checker.Check(keyword_id, lhs.name, lhs.left)
2407 return n8
2408
2409 if self.c_id in (Id.KW_SetVar, Id.KW_SetGlobal):
2410 kw_token = word_.LiteralToken(self.cur_word)
2411 self._SetNext()
2412 n9 = self.w_parser.ParseMutation(kw_token, self.var_checker)
2413 return n9
2414
2415 if self.c_id in (Id.KW_Call, Id.Lit_Equals):
2416 # = 42 + a[i]
2417 # call mylist->append('x')
2418
2419 keyword = word_.LiteralToken(self.cur_word)
2420 assert keyword is not None
2421 self._SetNext()
2422 enode = self.w_parser.ParseCommandExpr()
2423 return command.Expr(keyword, enode)
2424
2425 if self.c_id == Id.KW_Function:
2426 return self.ParseKshFunctionDef()
2427
2428 if self.c_id in (Id.KW_DLeftBracket, Id.Op_DLeftParen, Id.Op_LParen,
2429 Id.Lit_LBrace, Id.KW_For, Id.KW_While, Id.KW_Until,
2430 Id.KW_If, Id.KW_Case, Id.KW_Time):
2431 return self.ParseCompoundCommand()
2432
2433 # Syntax error for '}' starting a line, which all shells disallow.
2434 if self.c_id == Id.Lit_RBrace:
2435 p_die('Unexpected right brace', loc.Word(self.cur_word))
2436
2437 if self.c_kind == Kind.Redir: # Leading redirect
2438 return self.ParseSimpleCommand()
2439
2440 if self.c_kind == Kind.Word:
2441 # ensured by Kind.Word
2442 cur_word = cast(CompoundWord, self.cur_word)
2443
2444 # NOTE: At the top level, only Token and Compound are possible.
2445 # Can this be modelled better in the type system, removing asserts?
2446 #
2447 # TODO: This can be a proc INVOCATION! (Doesn't even need parse_paren)
2448 # Problem: We have to distinguish f( ) { echo ; } and myproc (x, y)
2449 # That requires 2 tokens of lookahead, which we don't have
2450 #
2451 # Or maybe we don't just have ParseSimpleCommand -- we will have
2452 # ParseYshCommand or something
2453
2454 if (self.w_parser.LookAheadFuncParens() and
2455 not word_.IsVarLike(cur_word)):
2456 return self.ParseFunctionDef() # f() { echo; } # function
2457
2458 # Parse x = 1+2*3 when inside HayNode { } blocks
2459 parts = cur_word.parts
2460 if self.parse_opts.parse_equals() and len(parts) == 1:
2461 part0 = parts[0]
2462 if part0.tag() == word_part_e.Literal:
2463 tok = cast(Token, part0)
2464 if (tok.id == Id.Lit_Chars and
2465 self.w_parser.LookPastSpace() == Id.Lit_Equals and
2466 match.IsValidVarName(lexer.LazyStr(tok))):
2467
2468 if (len(self.hay_attrs_stack) and
2469 self.hay_attrs_stack[-1]):
2470 # Note: no static var_checker.Check() for bare assignment
2471 enode = self.w_parser.ParseBareDecl()
2472 self._SetNext() # Somehow this is necessary
2473 # TODO: Use BareDecl here. Well, do that when we
2474 # treat it as const or lazy.
2475 return command.VarDecl(
2476 None,
2477 [NameType(tok, lexer.TokenVal(tok), None)],
2478 enode)
2479 else:
2480 self._SetNext()
2481 self._GetWord()
2482 p_die(
2483 'Unexpected = (Hint: use var/setvar, or quote it)',
2484 loc.Word(self.cur_word))
2485
2486 # echo foo
2487 # f=(a b c) # array
2488 # array[1+2]+=1
2489 return self.ParseSimpleCommand()
2490
2491 if self.c_kind == Kind.Eof:
2492 p_die("Unexpected EOF while parsing command",
2493 loc.Word(self.cur_word))
2494
2495 # NOTE: This only happens in batch mode in the second turn of the loop!
2496 # e.g. )
2497 p_die("Invalid word while parsing command", loc.Word(self.cur_word))
2498
2499 assert False # for MyPy
2500
2501 def ParsePipeline(self):
2502 # type: () -> command_t
2503 """
2504 pipeline : Bang? command ( '|' newline_ok command )* ;
2505 """
2506 negated = None # type: Optional[Token]
2507
2508 self._GetWord()
2509 if self.c_id == Id.KW_Bang:
2510 negated = word_.AsKeywordToken(self.cur_word)
2511 self._SetNext()
2512
2513 child = self.ParseCommand()
2514 assert child is not None
2515
2516 children = [child]
2517
2518 self._GetWord()
2519 if self.c_id not in (Id.Op_Pipe, Id.Op_PipeAmp):
2520 if negated is not None:
2521 node = command.Pipeline(negated, children, [])
2522 return node
2523 else:
2524 return child # no pipeline
2525
2526 # | or |&
2527 ops = [] # type: List[Token]
2528 while True:
2529 op = word_.AsOperatorToken(self.cur_word)
2530 ops.append(op)
2531
2532 self._SetNext() # skip past Id.Op_Pipe or Id.Op_PipeAmp
2533 self._NewlineOk()
2534
2535 child = self.ParseCommand()
2536 children.append(child)
2537
2538 self._GetWord()
2539 if self.c_id not in (Id.Op_Pipe, Id.Op_PipeAmp):
2540 break
2541
2542 return command.Pipeline(negated, children, ops)
2543
2544 def ParseAndOr(self):
2545 # type: () -> command_t
2546 self._GetWord()
2547 if self.c_id == Id.Lit_TDot:
2548 # We got '...', so parse in multiline mode
2549 self._SetNext()
2550 with word_.ctx_Multiline(self.w_parser):
2551 return self._ParseAndOr()
2552
2553 # Parse in normal mode, not multiline
2554 return self._ParseAndOr()
2555
2556 def _ParseAndOr(self):
2557 # type: () -> command_t
2558 """
2559 and_or : and_or ( AND_IF | OR_IF ) newline_ok pipeline
2560 | pipeline
2561
2562 Note that it is left recursive and left associative. We parse it
2563 iteratively with a token of lookahead.
2564 """
2565 child = self.ParsePipeline()
2566 assert child is not None
2567
2568 self._GetWord()
2569 if self.c_id not in (Id.Op_DPipe, Id.Op_DAmp):
2570 return child
2571
2572 ops = [] # type: List[Token]
2573 children = [child]
2574
2575 while True:
2576 ops.append(word_.AsOperatorToken(self.cur_word))
2577
2578 self._SetNext() # skip past || &&
2579 self._NewlineOk()
2580
2581 child = self.ParsePipeline()
2582 children.append(child)
2583
2584 self._GetWord()
2585 if self.c_id not in (Id.Op_DPipe, Id.Op_DAmp):
2586 break
2587
2588 return command.AndOr(children, ops)
2589
2590 # NOTE: _ParseCommandLine and _ParseCommandTerm are similar, but different.
2591
2592 # At the top level, we execute after every line, e.g. to
2593 # - process alias (a form of dynamic parsing)
2594 # - process 'exit', because invalid syntax might appear after it
2595
2596 # On the other hand, for a while loop body, we parse the whole thing at once,
2597 # and then execute it. We don't want to parse it over and over again!
2598
2599 # COMPARE
2600 # command_line : and_or (sync_op and_or)* trailer? ; # TOP LEVEL
2601 # command_term : and_or (trailer and_or)* ; # CHILDREN
2602
2603 def _ParseCommandLine(self):
2604 # type: () -> command_t
2605 """
2606 command_line : and_or (sync_op and_or)* trailer? ;
2607 trailer : sync_op newline_ok
2608 | NEWLINES;
2609 sync_op : '&' | ';';
2610
2611 NOTE: This rule causes LL(k > 1) behavior. We would have to peek to see if
2612 there is another command word after the sync op.
2613
2614 But it's easier to express imperatively. Do the following in a loop:
2615 1. ParseAndOr
2616 2. Peek.
2617 a. If there's a newline, then return. (We're only parsing a single
2618 line.)
2619 b. If there's a sync_op, process it. Then look for a newline and
2620 return. Otherwise, parse another AndOr.
2621 """
2622 # This END_LIST is slightly different than END_LIST in _ParseCommandTerm.
2623 # I don't think we should add anything else here; otherwise it will be
2624 # ignored at the end of ParseInteractiveLine(), e.g. leading to bug #301.
2625 END_LIST = [Id.Op_Newline, Id.Eof_Real]
2626
2627 children = [] # type: List[command_t]
2628 done = False
2629 while not done:
2630 child = self.ParseAndOr()
2631
2632 self._GetWord()
2633 if self.c_id in (Id.Op_Semi, Id.Op_Amp):
2634 tok = cast(Token, self.cur_word) # for MyPy
2635 child = command.Sentence(child, tok)
2636 self._SetNext()
2637
2638 self._GetWord()
2639 if self.c_id in END_LIST:
2640 done = True
2641
2642 elif self.c_id in END_LIST:
2643 done = True
2644
2645 else:
2646 # e.g. echo a(b)
2647 p_die(
2648 'Invalid word while parsing command line (%s)' %
2649 Id_str(self.c_id), loc.Word(self.cur_word))
2650
2651 children.append(child)
2652
2653 # Simplify the AST.
2654 if len(children) > 1:
2655 return command.CommandList(children)
2656 else:
2657 return children[0]
2658
2659 def _ParseCommandTerm(self):
2660 # type: () -> command.CommandList
2661 """"
2662 command_term : and_or (trailer and_or)* ;
2663 trailer : sync_op newline_ok
2664 | NEWLINES;
2665 sync_op : '&' | ';';
2666
2667 This is handled in imperative style, like _ParseCommandLine.
2668 Called by _ParseCommandList for all blocks, and also for ParseCaseArm,
2669 which is slightly different. (HOW? Is it the DSEMI?)
2670
2671 Returns:
2672 syntax_asdl.command
2673 """
2674 # Token types that will end the command term.
2675 END_LIST = [
2676 self.eof_id, Id.Right_Subshell, Id.Lit_RBrace, Id.Op_DSemi,
2677 Id.Op_SemiAmp, Id.Op_DSemiAmp
2678 ]
2679
2680 # NOTE: This is similar to _ParseCommandLine.
2681 #
2682 # - Why aren't we doing END_LIST in _ParseCommandLine?
2683 # - Because you will never be inside $() at the top level.
2684 # - We also know it will end in a newline. It can't end in "fi"!
2685 # - example: if true; then { echo hi; } fi
2686
2687 children = [] # type: List[command_t]
2688 done = False
2689 while not done:
2690 # Most keywords are valid "first words". But do/done/then do not BEGIN
2691 # commands, so they are not valid.
2692 if self._AtSecondaryKeyword():
2693 break
2694
2695 child = self.ParseAndOr()
2696
2697 self._GetWord()
2698 if self.c_id == Id.Op_Newline:
2699 self._SetNext()
2700
2701 self._GetWord()
2702 if self.c_id in END_LIST:
2703 done = True
2704
2705 elif self.c_id in (Id.Op_Semi, Id.Op_Amp):
2706 tok = cast(Token, self.cur_word) # for MyPy
2707 child = command.Sentence(child, tok)
2708 self._SetNext()
2709
2710 self._GetWord()
2711 if self.c_id == Id.Op_Newline:
2712 self._SetNext() # skip over newline
2713
2714 # Test if we should keep going. There might be another command after
2715 # the semi and newline.
2716 self._GetWord()
2717 if self.c_id in END_LIST: # \n EOF
2718 done = True
2719
2720 elif self.c_id in END_LIST: # ; EOF
2721 done = True
2722
2723 elif self.c_id in END_LIST: # EOF
2724 done = True
2725
2726 # For if test -f foo; test -f bar {
2727 elif self.parse_opts.parse_brace() and self.c_id == Id.Lit_LBrace:
2728 done = True
2729
2730 elif self.c_kind != Kind.Word:
2731 # e.g. f() { echo (( x )) ; }
2732 # but can't fail on 'fi fi', see osh/cmd_parse_test.py
2733
2734 #log("Invalid %s", self.cur_word)
2735 p_die("Invalid word while parsing command list",
2736 loc.Word(self.cur_word))
2737
2738 children.append(child)
2739
2740 return command.CommandList(children)
2741
2742 def _ParseCommandList(self):
2743 # type: () -> command.CommandList
2744 """
2745 command_list : newline_ok command_term trailer? ;
2746
2747 This one is called by all the compound commands. It's basically a command
2748 block.
2749
2750 NOTE: Rather than translating the CFG directly, the code follows a style
2751 more like this: more like this: (and_or trailer)+. It makes capture
2752 easier.
2753 """
2754 self._NewlineOk()
2755 return self._ParseCommandTerm()
2756
2757 def ParseLogicalLine(self):
2758 # type: () -> command_t
2759 """Parse a single line for main_loop.
2760
2761 A wrapper around _ParseCommandLine(). Similar but not identical to
2762 _ParseCommandList() and ParseCommandSub().
2763
2764 Raises:
2765 ParseError
2766 """
2767 self._NewlineOk()
2768 self._GetWord()
2769 if self.c_id == Id.Eof_Real:
2770 return None # main loop checks for here docs
2771 node = self._ParseCommandLine()
2772 return node
2773
2774 def ParseInteractiveLine(self):
2775 # type: () -> parse_result_t
2776 """Parse a single line for Interactive main_loop.
2777
2778 Different from ParseLogicalLine because newlines are handled differently.
2779
2780 Raises:
2781 ParseError
2782 """
2783 self._GetWord()
2784 if self.c_id == Id.Op_Newline:
2785 return parse_result.EmptyLine
2786 if self.c_id == Id.Eof_Real:
2787 return parse_result.Eof
2788
2789 node = self._ParseCommandLine()
2790 return parse_result.Node(node)
2791
2792 def ParseCommandSub(self):
2793 # type: () -> command_t
2794 """Parse $(echo hi) and `echo hi` for word_parse.py.
2795
2796 They can have multiple lines, like this: echo $( echo one echo
2797 two )
2798 """
2799 self._NewlineOk()
2800
2801 self._GetWord()
2802 if self.c_kind == Kind.Eof: # e.g. $()
2803 return command.NoOp
2804
2805 c_list = self._ParseCommandTerm()
2806 if len(c_list.children) == 1:
2807 return c_list.children[0]
2808 else:
2809 return c_list
2810
2811 def CheckForPendingHereDocs(self):
2812 # type: () -> None
2813 # NOTE: This happens when there is no newline at the end of a file, like
2814 # osh -c 'cat <<EOF'
2815 if len(self.pending_here_docs):
2816 node = self.pending_here_docs[0] # Just show the first one?
2817 h = cast(redir_param.HereDoc, node.arg)
2818 p_die('Unterminated here doc began here', loc.Word(h.here_begin))
2819
2820
2821# vim: sw=4