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1/*
2 * Copyright (C) 2010 Google Inc.
3 *
4 * Licensed under the Apache License, Version 2.0 (the "License");
5 * you may not use this file except in compliance with the License.
6 * You may obtain a copy of the License at
7 *
8 * http://www.apache.org/licenses/LICENSE-2.0
9 *
10 * Unless required by applicable law or agreed to in writing, software
11 * distributed under the License is distributed on an "AS IS" BASIS,
12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13 * See the License for the specific language governing permissions and
14 * limitations under the License.
15 */
16
17 /* This is the JSilver grammar fed into SableCC to generate the parser. */
18
19// Java package of generated code.
20Package
21  com.google.clearsilver.jsilver.syntax;
22
23/***** Stage 1: The Lexer
24 *
25 * The lexer breaks the inbound text stream in to a sequence of tokens.
26 *
27 * SableCC will generate a wrapper class for each type of token.
28 *
29 * Anything outside of <?cs and ?> will be returned as a TData token.
30 * Anything in between (including) <?cs and ?> will be broken down
31 * into a finer grained set of tokens.
32 *
33 * For example: "Hello <?cs var:person.name ?>!"
34 * Results in:
35 *  TData        "Hello "
36 *  TCsOpen      "<?cs"
37 *  TWhiteSpace  " "
38 *  TVar         "var"
39 *  TColon       ":"
40 *  TWord        "person.name"
41 *  TWhitspace   " "
42 *  TCsClose     "?>"
43 *  TData        "!"
44 */
45
46/* Constants to be used elsewhere. */
47Helpers
48
49  // These aren't actually tokens, but can be used by tokens. Avoids the
50  // need for magic numbers in the token definitions.
51  alphanumeric = (['a' .. 'z'] | ['A' .. 'Z'] | ['0' .. '9']);
52  alpha        = (['a' .. 'z'] | ['A' .. 'Z']);
53  all = [0 .. 0xFFFF];
54  tab = 9;
55  cr = 13;
56  lf = 10;
57  whitespace = (tab | cr | lf | ' ');
58
59/* States of the lexer. */
60States
61
62  content,     // Anything outside of <?cs and ?>.
63  command,     // ClearSilver command: "<?cs var:".
64  args,        // Args to command: "some.variable=3 ?>"
65  comment;     // Inside a <?cs # comment ?>.
66
67/* Tokens and state transitions. */
68Tokens
69
70  // In the 'content' state, treat everything as a chunk of data,
71  // up to the sequence '<?cs '.
72  // Note, because the lexer has to read 5 characters '<?cs ' before
73  // knowing the definite state, it needs to be supplied a
74  // PushbackReader() with a buffer of at least 5.
75  {content} data = (        [all - '<']
76                   | '<'    [all - '?']
77                   | '<?'   [all - 'c']
78                   | '<?c'  [all - 's']
79                   | '<?cs' [[[[all - ' '] - cr] - lf] - tab])+;
80
81  {comment} comment = (        [all - '?']
82                      | '?'    [all - '>'] )+; // All up to ?>
83
84  // In the 'clearsilver' state, break each keyword, operator
85  // and symbol into it's own token.
86  {command} var           = 'var';
87  {command} lvar          = 'lvar';
88  {command} evar          = 'evar';
89  {command} uvar          = 'uvar';
90  {command} set           = 'set';
91  {command} if            = 'if';
92  {command} else_if       = ('elif' | 'elseif');
93  {command} else          = 'else';
94  {command} with          = 'with';
95  {command} escape        = 'escape';
96  {command} autoescape    = 'autoescape';
97  {command} loop          = 'loop';
98  {command} each          = 'each';
99  {command} alt           = 'alt';
100  {command} name          = 'name';
101  {command} def           = 'def';
102  {command} call          = 'call';
103  {command} include       = 'include';
104  {command} linclude      = 'linclude';
105  {command} content_type  = 'content-type';
106  {command} inline        = 'inline';
107
108  {args} comma         = ',';
109  {args} bang          = '!';
110  {args} assignment    = '=';
111  {args} eq            = '==';
112  {args} ne            = '!=';
113  {args} lt            = '<';
114  {args} gt            = '>';
115  {args} lte           = '<=';
116  {args} gte           = '>=';
117  {args} and           = '&&';
118  {args} or            = '||';
119  {args} string        = ('"' [all - '"']* '"' | ''' [all - ''']* ''');
120  {args} hash          = '#';
121  {args} plus          = '+';
122  {args} minus         = '-';
123  {args} star          = '*';
124  {args} percent       = '%';
125  {args} bracket_open  = '[';
126  {args} bracket_close = ']';
127  {args} paren_open    = '(';
128  {args} paren_close   = ')';
129  {args} dot           = '.';
130  {args} dollar        = '$';
131  {args} question      = '?';
132  {args} dec_number    = (['0' .. '9'])+;
133  {args} hex_number    = ('0x' | '0X') (['0' .. '9'] | ['a' .. 'f'] | ['A' .. 'F'])+;
134  {args} word          = (alphanumeric | '_')+;
135  {args} arg_whitespace = whitespace+;
136
137  // Tokens that are valid in multiple states
138  {command, args} slash         = '/'; // means divide or end command.
139
140  // State transitions.
141  {content->command}                                  cs_open        = '<?cs' whitespace+;
142  {command->comment}                                  comment_start  = '#';
143  {command->args}                                     command_delimiter = ':' | whitespace;
144  {command->args}                                     hard_delimiter = '!' | whitespace;
145  {command->content, args->content, comment->content} cs_close       = whitespace* '?>';
146
147/***** Stage 2: The Parser
148 *
149 * Below is a BNF-like grammar of how the tokens are assembled.
150 * The generate parser will read the token stream and build a
151 * tree of nodes representing the structure.
152 *
153 * This is the Concrete Syntax Tree (CST).
154 *
155 * Though this provides access to the underlying syntax tree, the
156 * resulting tree would be quite tricky to work with from code as
157 * it's heavily loaded with syntax specifics and parser tricks...
158 *
159 * So, the CST also contains transformation rules ({->x}) to
160 * convert it into a much simpler Abstract Syntax Tree (AST),
161 * which is defined in stage 3.
162 */
163
164/* Tokens from the lexer that the parser doesn't care about. */
165Ignored Tokens
166
167  arg_whitespace;
168
169/* Concrete syntax tree. */
170Productions
171
172  // Overall template structure...
173
174  grammar {->command}
175    = commands
176              {->commands.command}
177    ;
178
179  commands {->command}
180    = {none}
181              {->New command.noop()}
182    | {one}   command
183              {->command.command}
184    | {many}  command [more]:command+
185              {->New command.multiple([command.command, more.command])}
186    ;
187
188  command {->command}
189
190    = {data}  data
191              // Anything outside of <?cs ?> tag
192              {->New command.data(data)}
193
194    | {comment} cs_open comment_start comment? cs_close
195              // <?cs # comment ?>
196              {->New command.comment(New position.cs_open(cs_open),comment)}
197
198    | {var}   cs_open var command_delimiter expression_list cs_close
199              // <?cs var:x ?>
200              {->New command.var(
201                   New position.cs_open(cs_open),
202                   New expression.sequence([expression_list.expression]))}
203
204    | {lvar}  cs_open lvar command_delimiter expression_list cs_close
205              // <?cs lvar:x ?>
206              {->New command.lvar(
207                   New position.cs_open(cs_open),
208                   New expression.sequence([expression_list.expression]))}
209
210    | {evar}  cs_open evar command_delimiter expression_list cs_close
211              // <?cs evar:x ?>
212              {->New command.evar(
213                   New position.cs_open(cs_open),
214                   New expression.sequence([expression_list.expression]))}
215
216    | {uvar}  cs_open uvar command_delimiter expression_list cs_close
217              // <?cs uvar:x ?>
218              {->New command.uvar(
219                   New position.cs_open(cs_open),
220                   New expression.sequence([expression_list.expression]))}
221
222    | {set}   cs_open set command_delimiter variable assignment expression cs_close
223              // <?cs set:x = y ?>
224              {->New command.set(
225                   New position.cs_open(cs_open),
226                   variable.variable,
227                   expression.expression)}
228
229    | {name}  cs_open name command_delimiter variable cs_close
230              // <?cs name:x ?>
231              {->New command.name(
232                   New position.cs_open(cs_open),
233                   variable.variable)}
234
235    | {escape} cs_open escape command_delimiter expression cs_close
236              commands
237              [i1]:cs_open slash [i3]:escape [i2]:cs_close
238              // <?cs escape:"html" ?>...<?cs /escape?>
239              {->New command.escape(
240                   New position.cs_open(cs_open),
241                   expression.expression,
242                   commands.command)}
243
244    | {autoescape} cs_open autoescape command_delimiter expression cs_close
245              commands
246              [i1]:cs_open slash [i3]:autoescape [i2]:cs_close
247              // <?cs autoescape:"html" ?>...<?cs /autoescape?>
248              {->New command.autoescape(
249                   New position.cs_open(cs_open),
250                   expression.expression,
251                   commands.command)}
252
253    | {with}  cs_open with command_delimiter variable assignment expression cs_close
254              commands
255              [i1]:cs_open slash [i3]:with [i2]:cs_close
256              // <?cs with:x=y ?>...<?cs /with?>
257              {->New command.with(
258                  New position.cs_open(cs_open),
259                  variable.variable,
260                  expression.expression,
261                  commands.command)}
262
263    | {loop_to}  cs_open loop command_delimiter variable assignment expression cs_close
264              commands
265              [i1]:cs_open slash [i3]:loop [i2]:cs_close
266              // <?cs loop:x=20 ?>...<?cs /loop ?>
267              {->New command.loop_to(
268                  New position.cs_open(cs_open),
269                  variable.variable,
270                  expression.expression,
271                  commands.command)}
272
273    | {loop}  cs_open loop command_delimiter variable assignment
274              [start]:expression comma [end]:expression cs_close
275              commands
276              [i1]:cs_open slash [i3]:loop [i2]:cs_close
277              // <?cs loop:x=1,20 ?>...<?cs /loop ?>
278              {->New command.loop(
279                  New position.cs_open(cs_open),
280                  variable.variable,
281                  start.expression,
282                  end.expression,
283                  commands.command)}
284
285    | {loop_inc} cs_open loop command_delimiter variable assignment
286              [start]:expression comma
287              [end]:expression [i3]:comma [increment]:expression cs_close
288              commands [i1]:cs_open slash [i4]:loop [i2]:cs_close
289              // <?cs loop:x=1,20,5 ?>...<?cs /loop ?>
290              {->New command.loop_inc(
291                  New position.cs_open(cs_open),
292                  variable.variable,
293                  start.expression,
294                  end.expression,
295                  increment.expression,
296                  commands.command)}
297
298    | {each}  cs_open each command_delimiter variable assignment expression cs_close
299              commands
300              [i1]:cs_open slash [i3]:each [i2]:cs_close
301              // <?cs each:x=some.thing ?>...<?cs /each ?>
302              {->New command.each(
303                  New position.cs_open(cs_open),
304                  variable.variable,
305                  expression.expression,
306                  commands.command)}
307
308    | {alt}   cs_open alt command_delimiter expression cs_close
309              commands
310              [i1]:cs_open slash [i3]:alt [i2]:cs_close
311              // <?cs alt:some.thing ?>...<?cs /alt ?>
312              {->New command.alt(
313                  New position.cs_open(cs_open),
314                  expression.expression,
315                  commands.command)}
316
317    | {def}   cs_open def command_delimiter multipart_word paren_open variable_list?
318              paren_close cs_close commands
319              [i1]:cs_open slash [i3]:def [i2]:cs_close
320              // <?cs def:some.macro(arg,arg) ?>...<?cs /def ?>
321              {->New command.def(
322                  New position.cs_open(cs_open),
323                  [multipart_word.word],
324                  [variable_list.variable],
325                  commands.command)}
326
327    | {call}  cs_open call command_delimiter multipart_word paren_open expression_list?
328              paren_close cs_close
329              // <?cs call:some.macro(arg,arg) ?>
330              {->New command.call(
331                  New position.cs_open(cs_open),
332                  [multipart_word.word],
333                  [expression_list.expression])}
334
335    | {if}    if_block
336              {->if_block.command}
337
338    | {include} cs_open include command_delimiter expression cs_close
339              // <?cs include:x ?>
340              {->New command.include(
341                  New position.cs_open(cs_open),
342                  expression.expression)}
343
344    | {hard_include} cs_open include hard_delimiter expression cs_close
345              // <?cs include!x ?>
346              {->New command.hard_include(
347                  New position.cs_open(cs_open),
348                  expression.expression)}
349
350    | {linclude} cs_open linclude command_delimiter expression cs_close
351              // <?cs linclude:x ?>
352              {->New command.linclude(
353                  New position.cs_open(cs_open),
354                  expression.expression)}
355
356    | {hard_linclude} cs_open linclude hard_delimiter expression cs_close
357              // <?cs linclude!x ?>
358              {->New command.hard_linclude(
359                  New position.cs_open(cs_open),
360                  expression.expression)}
361
362    | {content_type} cs_open content_type command_delimiter string cs_close
363              // <?cs content-type:"html" ?>
364              {->New command.content_type(
365                  New position.cs_open(cs_open),
366                  string)}
367
368    | {inline} cs_open inline cs_close
369              commands
370              [i1]:cs_open slash [i3]:inline [i2]:cs_close
371              // <?cs inline ?>...<?cs /inline?>
372              {->New command.inline(
373                   New position.cs_open(cs_open),
374                   commands.command)}
375
376    ;
377
378  multipart_word {->word*}
379    = {bit} word
380              {->[word]}
381    | {m} multipart_word dot word
382              {->[multipart_word.word, word]}
383    ;
384
385  variable_list {->variable*}
386    = {single} variable
387              {->[variable.variable]}
388    | {multiple} variable_list comma variable
389              {->[variable_list.variable, variable.variable]}
390    ;
391
392  expression_list {->expression*}
393    = {single} expression
394              {->[expression.expression]}
395    | {multiple} expression_list comma expression
396              {->[expression_list.expression, expression.expression]}
397    ;
398
399  // If/ElseIf/Else block...
400
401  if_block {->command}
402    =           cs_open if command_delimiter expression cs_close
403                commands
404                else_if_block
405                // <?cs if:x.y ?> (commands, then optional else_if_block)
406                {->New command.if(
407                    New position.cs_open(cs_open),
408                    expression.expression,
409                    commands.command,
410                    else_if_block.command)}
411    ;
412
413  // ElseIf statements get transformed into nested if/else blocks to simplify
414  // final AST.
415  else_if_block {->command}
416    = {present} cs_open else_if command_delimiter expression cs_close
417                commands
418                else_if_block
419                // <?cs elif:x.y ?> (recurses)
420                {->New command.if(
421                    New position.cs_open(cs_open),
422                    expression.expression,
423                    commands.command,
424                    else_if_block.command)}
425    | {missing} else_block
426                {->else_block.command}
427    ;
428
429  else_block {->command}
430    = {present} cs_open else cs_close
431                commands
432                end_if_block
433                // <?cs else ?> (followed by end_if_block)
434                {->commands.command}
435    | {skip}    end_if_block
436                {->New command.noop()}
437    ;
438
439  end_if_block
440    =           cs_open slash if cs_close
441                // <?cs /if ?>
442    ;
443
444  // Expression language...
445
446  // The multiple levels allow the parser to build a tree based on operator
447  // precedence. The higher the level in the tree, the lower the precedence.
448
449  expression {->expression}
450    = {or} [left]:expression or [right]:and_expression    // x.y || a.b
451              {->New expression.or(left.expression, right.expression)}
452    | {and_expression} [value]:and_expression             // x.y
453              {->value.expression}
454    ;
455
456  and_expression {->expression}
457    = {and}  [left]:and_expression and [right]:equality   // x.y && a.b
458              {->New expression.and(left.expression, right.expression)}
459    | {equality} [value]:equality                         // x.y
460              {->value.expression}
461    ;
462
463  equality {->expression}
464    = {eq}  [left]:equality eq [right]:comparison         // x.y == a.b
465              {->New expression.eq(left.expression, right.expression)}
466    | {ne}  [left]:equality ne [right]:comparison         // x.y != a.b
467              {->New expression.ne(left.expression, right.expression)}
468    | {comparison} [value]:comparison                  // x.y
469              {->value.expression}
470    ;
471
472  comparison {->expression}
473    = {lt}  [left]:comparison lt  [right]:add_subtract         // x.y < a.b
474              {->New expression.lt(left.expression, right.expression)}
475    | {gt}  [left]:comparison gt  [right]:add_subtract         // x.y > a.b
476              {->New expression.gt(left.expression, right.expression)}
477    | {lte} [left]:comparison lte [right]:add_subtract         // x.y <= a.b
478              {->New expression.lte(left.expression, right.expression)}
479    | {gte} [left]:comparison gte [right]:add_subtract         // x.y >= a.b
480              {->New expression.gte(left.expression, right.expression)}
481    | {add_subtract} [value]:add_subtract                      // x.y
482              {->value.expression}
483    ;
484
485  add_subtract {->expression}
486    = {add} [left]:add_subtract plus [right]:factor        // x.y + a.b
487              {->New expression.add(left.expression, right.expression)}
488    | {subtract} [left]:add_subtract minus [right]:factor  // x.y - a.b
489              {->New expression.subtract(left.expression, right.expression)}
490    | {factor} [value]:factor                              // x.y
491              {->value.expression}
492    ;
493
494  factor {->expression}
495    = {multiply} [left]:factor star [right]:value   // x.y * a.b
496              {->New expression.multiply(left.expression, right.expression)}
497    | {divide} [left]:factor slash [right]:value    // x.y / a.b
498              {->New expression.divide(left.expression, right.expression)}
499    | {modulo} [left]:factor percent [right]:value  // x.y % a.b
500              {->New expression.modulo(left.expression, right.expression)}
501    | {value} value                                 // x.y
502              {->value.expression}
503    ;
504
505  value {->expression}
506    = {variable} variable          // x.y
507              {->New expression.variable(variable.variable)}
508    | {string} string              // "hello"
509              {->New expression.string(string)}
510    | {number} number              // 123
511              {->number.expression}
512    | {forced_number} hash value   // #123 or #some.var
513              {->New expression.numeric(value.expression)}
514    | {not} bang value                              // !x.y
515              {->New expression.not(value.expression)}
516    | {exists} question value      // ?x.y
517              {->New expression.exists(value.expression)}
518    | {parens} paren_open expression_list paren_close        // (x.y, a.b, d.e)
519              {->New expression.sequence([expression_list.expression])}
520    | {function} [name]:variable paren_open
521                  expression_list? paren_close // a.b(x, y)
522              {->New expression.function(
523                  name.variable,[expression_list.expression])}
524    ;
525
526  variable {->variable}
527    = {name}   dollar? word
528              {->New variable.name(word)}
529    | {dec_number} dollar dec_number
530              {->New variable.dec_number(dec_number)}
531    | {hex_number} dollar hex_number
532              {->New variable.hex_number(hex_number)}
533    | {descend_name} variable dot word
534              {->New variable.descend(
535                  variable.variable, New variable.name(word))}
536    | {descend_dec_number} variable dot dec_number
537              {->New variable.descend(
538                  variable.variable, New variable.dec_number(dec_number))}
539    | {descend_hex_number} variable dot hex_number
540              {->New variable.descend(
541                  variable.variable, New variable.hex_number(hex_number))}
542    | {expand} variable bracket_open expression bracket_close
543              {->New variable.expand(
544                  variable.variable, expression.expression)}
545    ;
546
547  number {->expression}
548    = {unsigned} digits
549              {->digits.expression}
550    | {positive} plus digits
551              {->digits.expression}
552    | {negative} minus digits
553              {->New expression.negative(digits.expression)}
554    ;
555
556  digits {->expression}
557    = {decimal} dec_number
558              {->New expression.decimal(dec_number)}
559    | {hex}     hex_number
560              {->New expression.hex(hex_number)}
561    ;
562
563
564/***** Stage 3: The Abstract Syntax Tree
565 *
566 * This is the resulting model that will be generated by the parser.
567 *
568 * It is represented in Java by a strongly typed node tree (the
569 * classes are code generated by SableCC). These can be interrogated
570 * using getter methods, or processed by passing a visitor to the
571 * tree.
572 *
573 * The Abstract Syntax Tree definition below is the only thing
574 * the Java application need to worry about. All previous definitions
575 * in this file are taken care of by the generated parser.
576 *
577 * Example input:
578 *   Hello <?cs var:user.name ?>!
579 *   <?cs if:user.age >= 90 ?>
580 *   You're way old.
581 *   <?cs elif:user.age >= 21 ?>
582 *   You're about the right age.
583 *   <?cs else ?>
584 *   You're too young.
585 *   <?cs /if ?>
586 *   Seeya!
587 *
588 * Results in the tree:
589 *   AMultipleCommand (start)
590 *     ADataCommand (command)
591 *       TData (data) "Hello "
592 *     AVarCommand (command)
593 *       AVariableExpression (expression)
594 *         TWord "user.name" (name)
595 *     ADataCommand (command)
596 *       TData "!\n" (data)
597 *     AIfCommand (command)
598 *       AGteExpression (expression)
599 *         AVariableExpression (left)
600 *           TWord "user.age" (name)
601 *         ADecimalExpresion (right)
602 *           TDecNumber "90" (value)
603 *       ADataCommand (block)
604 *         TData (data) "\nYou're way old.\n"
605 *       AGteCommand (otherwise)
606 *         AEqExpression (expression)
607 *           AVariableExpression (left)
608 *             TWord "user.age" (name)
609 *           ADecimalExpresion (right)
610 *             TDecNumber "21" (value)
611 *         ADataCommand (block)
612 *           TData (data) "\nYou're about the right age.\n"
613 *         ADataCommand (otherwise)
614 *           TData (data) "\nYou're too young.\n"
615 *     ADataCommand (command)
616 *       TData (data) "\nSeeya!\n"
617 *
618 * Although not strictly necessary, tokens are prefixed with 'T.' in
619 * the grammar so they stand out from the rest of the other rules.
620 */
621Abstract Syntax Tree
622
623  command    = {multiple} command*             // Sequence of commands
624             | {comment}  position T.comment?  // Contents of <?cs # comment ?>
625             | {data}     T.data               // Any data outside of <?cs ?>
626             | {var}      position expression           // var:x statement
627             | {lvar}     position expression           // lvar:x statement
628             | {evar}     position expression           // evar:x statement
629             | {uvar}     position expression           // uvar:x statement
630             | {set}      position variable expression  // set:x=y statement
631             | {name}     position variable             // name:x statement
632             | {escape}   position expression  // escape:x statement
633                          command              // ... commands in context
634             | {autoescape}   position expression  // autoescape:x statement
635                          command              // ... commands in context
636             | {with}     position variable expression  // with:x=y statement
637                          command              // ... commands in context
638             | {loop_to}  position variable    // loop:x=10 statement
639                          expression           // ... value to end at
640                          command              // ... commands in loop
641             | {loop}     position variable    // loop:x=1,10 statement
642                          [start]:expression   // ... value to start at
643                          [end]:expression     // ... value to end at
644                          command              // ... commands in loop
645             | {loop_inc} position variable    // loop:x=1,10,2 statement
646                          [start]:expression   // ... value to start at
647                          [end]:expression     // ... value to end at
648                          [increment]:expression // . value to increment by
649                          command              // ... commands in loop
650             | {each}     position variable expression  // each:x=y statement
651                          command              // ... commands in loop
652             | {def}      position [macro]:T.word* // def:some_macro statement
653                          [arguments]:variable* // ... arguments
654                          command              // ... commands to execute
655             | {call}     position [macro]:T.word*  // call:some_macro statement
656                          [arguments]:expression* // ... arguments
657             | {if}       position expression  // if:x statement
658                          [block]:command      // ... commands if true
659                          [otherwise]:command  // ... commands if false
660             | {alt}      position expression command   // alt:x statement
661             | {include}  position expression           // include:x statement
662             | {hard_include} position expression       // include!x statement
663             | {linclude} position expression           // linclude:x statement
664             | {hard_linclude} position expression      // linclude!x statement
665             | {content_type}  position string          // content-type:x statement
666             | {inline}   position command              // inline commands
667             | {noop}                                   // No operation
668             ;
669
670  position   = {cs_open}  T.cs_open   // We retain the <?cs token in the AST
671             ;                        // as a convenient way to get the position
672                                      // of the start of the command.
673
674  expression = {string}      [value]:T.string                     // "hello"
675             | {numeric}     expression                           // #something
676             | {decimal}     [value]:T.dec_number                 // 123
677             | {hex}         [value]:T.hex_number                 // 0x1BF
678             | {variable}    variable                             // some.thing[1]
679             | {function}    [name]:variable [args]:expression*   // a.b(x, y)
680             | {sequence}    [args]:expression*                   // x, y, z
681             | {negative}    expression                           // -x
682             | {not}         expression                           // !x
683             | {exists}      expression                           // ?x
684             | {comma}       [left]:expression [right]:expression // x, y
685             | {eq}          [left]:expression [right]:expression // x == y
686             | {numeric_eq}  [left]:expression [right]:expression // x == y (numeric)
687             | {ne}          [left]:expression [right]:expression // x != y
688             | {numeric_ne}  [left]:expression [right]:expression // x != y (numeric)
689             | {lt}          [left]:expression [right]:expression // x < y
690             | {gt}          [left]:expression [right]:expression // x > y
691             | {lte}         [left]:expression [right]:expression // x <= y
692             | {gte}         [left]:expression [right]:expression // x >= y
693             | {and}         [left]:expression [right]:expression // x && y
694             | {or}          [left]:expression [right]:expression // x || y
695             | {add}         [left]:expression [right]:expression // x + y
696             | {numeric_add} [left]:expression [right]:expression // x + y (numeric)
697             | {subtract}    [left]:expression [right]:expression // x - y
698             | {multiply}    [left]:expression [right]:expression // x * y
699             | {divide}      [left]:expression [right]:expression // x / y
700             | {modulo}      [left]:expression [right]:expression // x % y
701             | {noop}                                             // No operation
702             ;
703
704  variable   = {name}       T.word                             // something
705             | {dec_number} T.dec_number                       // 2
706             | {hex_number} T.hex_number                       // 0xA1
707             | {descend}  [parent]:variable [child]:variable   // foo.bar
708             | {expand}   [parent]:variable [child]:expression // foo["bar"]
709             ;
710