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bazarr/libs/pyparsing/helpers.py

1070 lines
37 KiB

# helpers.py
import html.entities
import re
from . import __diag__
from .core import *
from .util import _bslash, _flatten, _escape_regex_range_chars
#
# global helpers
#
def delimited_list(
expr: Union[str, ParserElement],
delim: Union[str, ParserElement] = ",",
combine: bool = False,
min: OptionalType[int] = None,
max: OptionalType[int] = None,
*,
allow_trailing_delim: bool = False,
) -> ParserElement:
"""Helper to define a delimited list of expressions - the delimiter
defaults to ','. By default, the list elements and delimiters can
have intervening whitespace, and comments, but this can be
overridden by passing ``combine=True`` in the constructor. If
``combine`` is set to ``True``, the matching tokens are
returned as a single token string, with the delimiters included;
otherwise, the matching tokens are returned as a list of tokens,
with the delimiters suppressed.
If ``allow_trailing_delim`` is set to True, then the list may end with
a delimiter.
Example::
delimited_list(Word(alphas)).parse_string("aa,bb,cc") # -> ['aa', 'bb', 'cc']
delimited_list(Word(hexnums), delim=':', combine=True).parse_string("AA:BB:CC:DD:EE") # -> ['AA:BB:CC:DD:EE']
"""
if isinstance(expr, str_type):
expr = ParserElement._literalStringClass(expr)
dlName = "{expr} [{delim} {expr}]...{end}".format(
expr=str(expr.copy().streamline()),
delim=str(delim),
end=" [{}]".format(str(delim)) if allow_trailing_delim else "",
)
if not combine:
delim = Suppress(delim)
if min is not None:
if min < 1:
raise ValueError("min must be greater than 0")
min -= 1
if max is not None:
if min is not None and max <= min:
raise ValueError("max must be greater than, or equal to min")
max -= 1
delimited_list_expr = expr + (delim + expr)[min, max]
if allow_trailing_delim:
delimited_list_expr += Opt(delim)
if combine:
return Combine(delimited_list_expr).set_name(dlName)
else:
return delimited_list_expr.set_name(dlName)
def counted_array(
expr: ParserElement,
int_expr: OptionalType[ParserElement] = None,
*,
intExpr: OptionalType[ParserElement] = None,
) -> ParserElement:
"""Helper to define a counted list of expressions.
This helper defines a pattern of the form::
integer expr expr expr...
where the leading integer tells how many expr expressions follow.
The matched tokens returns the array of expr tokens as a list - the
leading count token is suppressed.
If ``int_expr`` is specified, it should be a pyparsing expression
that produces an integer value.
Example::
counted_array(Word(alphas)).parse_string('2 ab cd ef') # -> ['ab', 'cd']
# in this parser, the leading integer value is given in binary,
# '10' indicating that 2 values are in the array
binary_constant = Word('01').set_parse_action(lambda t: int(t[0], 2))
counted_array(Word(alphas), int_expr=binary_constant).parse_string('10 ab cd ef') # -> ['ab', 'cd']
# if other fields must be parsed after the count but before the
# list items, give the fields results names and they will
# be preserved in the returned ParseResults:
count_with_metadata = integer + Word(alphas)("type")
typed_array = counted_array(Word(alphanums), int_expr=count_with_metadata)("items")
result = typed_array.parse_string("3 bool True True False")
print(result.dump())
# prints
# ['True', 'True', 'False']
# - items: ['True', 'True', 'False']
# - type: 'bool'
"""
intExpr = intExpr or int_expr
array_expr = Forward()
def count_field_parse_action(s, l, t):
nonlocal array_expr
n = t[0]
array_expr <<= (expr * n) if n else Empty()
# clear list contents, but keep any named results
del t[:]
if intExpr is None:
intExpr = Word(nums).set_parse_action(lambda t: int(t[0]))
else:
intExpr = intExpr.copy()
intExpr.set_name("arrayLen")
intExpr.add_parse_action(count_field_parse_action, call_during_try=True)
return (intExpr + array_expr).set_name("(len) " + str(expr) + "...")
def match_previous_literal(expr: ParserElement) -> ParserElement:
"""Helper to define an expression that is indirectly defined from
the tokens matched in a previous expression, that is, it looks for
a 'repeat' of a previous expression. For example::
first = Word(nums)
second = match_previous_literal(first)
match_expr = first + ":" + second
will match ``"1:1"``, but not ``"1:2"``. Because this
matches a previous literal, will also match the leading
``"1:1"`` in ``"1:10"``. If this is not desired, use
:class:`match_previous_expr`. Do *not* use with packrat parsing
enabled.
"""
rep = Forward()
def copy_token_to_repeater(s, l, t):
if t:
if len(t) == 1:
rep << t[0]
else:
# flatten t tokens
tflat = _flatten(t.as_list())
rep << And(Literal(tt) for tt in tflat)
else:
rep << Empty()
expr.add_parse_action(copy_token_to_repeater, callDuringTry=True)
rep.set_name("(prev) " + str(expr))
return rep
def match_previous_expr(expr: ParserElement) -> ParserElement:
"""Helper to define an expression that is indirectly defined from
the tokens matched in a previous expression, that is, it looks for
a 'repeat' of a previous expression. For example::
first = Word(nums)
second = match_previous_expr(first)
match_expr = first + ":" + second
will match ``"1:1"``, but not ``"1:2"``. Because this
matches by expressions, will *not* match the leading ``"1:1"``
in ``"1:10"``; the expressions are evaluated first, and then
compared, so ``"1"`` is compared with ``"10"``. Do *not* use
with packrat parsing enabled.
"""
rep = Forward()
e2 = expr.copy()
rep <<= e2
def copy_token_to_repeater(s, l, t):
matchTokens = _flatten(t.as_list())
def must_match_these_tokens(s, l, t):
theseTokens = _flatten(t.as_list())
if theseTokens != matchTokens:
raise ParseException(s, l, "Expected {}, found{}".format(matchTokens, theseTokens))
rep.set_parse_action(must_match_these_tokens, callDuringTry=True)
expr.add_parse_action(copy_token_to_repeater, callDuringTry=True)
rep.set_name("(prev) " + str(expr))
return rep
def one_of(
strs: Union[IterableType[str], str],
caseless: bool = False,
use_regex: bool = True,
as_keyword: bool = False,
*,
useRegex: bool = True,
asKeyword: bool = False,
) -> ParserElement:
"""Helper to quickly define a set of alternative :class:`Literal` s,
and makes sure to do longest-first testing when there is a conflict,
regardless of the input order, but returns
a :class:`MatchFirst` for best performance.
Parameters:
- ``strs`` - a string of space-delimited literals, or a collection of
string literals
- ``caseless`` - treat all literals as caseless - (default= ``False``)
- ``use_regex`` - as an optimization, will
generate a :class:`Regex` object; otherwise, will generate
a :class:`MatchFirst` object (if ``caseless=True`` or ``asKeyword=True``, or if
creating a :class:`Regex` raises an exception) - (default= ``True``)
- ``as_keyword`` - enforce :class:`Keyword`-style matching on the
generated expressions - (default= ``False``)
- ``asKeyword`` and ``useRegex`` are retained for pre-PEP8 compatibility,
but will be removed in a future release
Example::
comp_oper = one_of("< = > <= >= !=")
var = Word(alphas)
number = Word(nums)
term = var | number
comparison_expr = term + comp_oper + term
print(comparison_expr.search_string("B = 12 AA=23 B<=AA AA>12"))
prints::
[['B', '=', '12'], ['AA', '=', '23'], ['B', '<=', 'AA'], ['AA', '>', '12']]
"""
asKeyword = asKeyword or as_keyword
useRegex = useRegex and use_regex
if (
isinstance(caseless, str_type)
and __diag__.warn_on_multiple_string_args_to_oneof
):
warnings.warn(
"More than one string argument passed to one_of, pass"
" choices as a list or space-delimited string",
stacklevel=2,
)
if caseless:
isequal = lambda a, b: a.upper() == b.upper()
masks = lambda a, b: b.upper().startswith(a.upper())
parseElementClass = CaselessKeyword if asKeyword else CaselessLiteral
else:
isequal = lambda a, b: a == b
masks = lambda a, b: b.startswith(a)
parseElementClass = Keyword if asKeyword else Literal
symbols: List[str] = []
if isinstance(strs, str_type):
symbols = strs.split()
elif isinstance(strs, Iterable):
symbols = list(strs)
else:
raise TypeError("Invalid argument to one_of, expected string or iterable")
if not symbols:
return NoMatch()
# reorder given symbols to take care to avoid masking longer choices with shorter ones
# (but only if the given symbols are not just single characters)
if any(len(sym) > 1 for sym in symbols):
i = 0
while i < len(symbols) - 1:
cur = symbols[i]
for j, other in enumerate(symbols[i + 1 :]):
if isequal(other, cur):
del symbols[i + j + 1]
break
elif masks(cur, other):
del symbols[i + j + 1]
symbols.insert(i, other)
break
else:
i += 1
if useRegex:
re_flags: int = re.IGNORECASE if caseless else 0
try:
if all(len(sym) == 1 for sym in symbols):
# symbols are just single characters, create range regex pattern
patt = "[{}]".format(
"".join(_escape_regex_range_chars(sym) for sym in symbols)
)
else:
patt = "|".join(re.escape(sym) for sym in symbols)
# wrap with \b word break markers if defining as keywords
if asKeyword:
patt = r"\b(?:{})\b".format(patt)
ret = Regex(patt, flags=re_flags).set_name(" | ".join(symbols))
if caseless:
# add parse action to return symbols as specified, not in random
# casing as found in input string
symbol_map = {sym.lower(): sym for sym in symbols}
ret.add_parse_action(lambda s, l, t: symbol_map[t[0].lower()])
return ret
except sre_constants.error:
warnings.warn(
"Exception creating Regex for one_of, building MatchFirst", stacklevel=2
)
# last resort, just use MatchFirst
return MatchFirst(parseElementClass(sym) for sym in symbols).set_name(
" | ".join(symbols)
)
def dict_of(key: ParserElement, value: ParserElement) -> ParserElement:
"""Helper to easily and clearly define a dictionary by specifying
the respective patterns for the key and value. Takes care of
defining the :class:`Dict`, :class:`ZeroOrMore`, and
:class:`Group` tokens in the proper order. The key pattern
can include delimiting markers or punctuation, as long as they are
suppressed, thereby leaving the significant key text. The value
pattern can include named results, so that the :class:`Dict` results
can include named token fields.
Example::
text = "shape: SQUARE posn: upper left color: light blue texture: burlap"
attr_expr = (label + Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join))
print(OneOrMore(attr_expr).parse_string(text).dump())
attr_label = label
attr_value = Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join)
# similar to Dict, but simpler call format
result = dict_of(attr_label, attr_value).parse_string(text)
print(result.dump())
print(result['shape'])
print(result.shape) # object attribute access works too
print(result.as_dict())
prints::
[['shape', 'SQUARE'], ['posn', 'upper left'], ['color', 'light blue'], ['texture', 'burlap']]
- color: light blue
- posn: upper left
- shape: SQUARE
- texture: burlap
SQUARE
SQUARE
{'color': 'light blue', 'shape': 'SQUARE', 'posn': 'upper left', 'texture': 'burlap'}
"""
return Dict(OneOrMore(Group(key + value)))
def original_text_for(
expr: ParserElement, as_string: bool = True, *, asString: bool = True
) -> ParserElement:
"""Helper to return the original, untokenized text for a given
expression. Useful to restore the parsed fields of an HTML start
tag into the raw tag text itself, or to revert separate tokens with
intervening whitespace back to the original matching input text. By
default, returns astring containing the original parsed text.
If the optional ``as_string`` argument is passed as
``False``, then the return value is
a :class:`ParseResults` containing any results names that
were originally matched, and a single token containing the original
matched text from the input string. So if the expression passed to
:class:`original_text_for` contains expressions with defined
results names, you must set ``as_string`` to ``False`` if you
want to preserve those results name values.
The ``asString`` pre-PEP8 argument is retained for compatibility,
but will be removed in a future release.
Example::
src = "this is test <b> bold <i>text</i> </b> normal text "
for tag in ("b", "i"):
opener, closer = make_html_tags(tag)
patt = original_text_for(opener + SkipTo(closer) + closer)
print(patt.search_string(src)[0])
prints::
['<b> bold <i>text</i> </b>']
['<i>text</i>']
"""
asString = asString and as_string
locMarker = Empty().set_parse_action(lambda s, loc, t: loc)
endlocMarker = locMarker.copy()
endlocMarker.callPreparse = False
matchExpr = locMarker("_original_start") + expr + endlocMarker("_original_end")
if asString:
extractText = lambda s, l, t: s[t._original_start : t._original_end]
else:
def extractText(s, l, t):
t[:] = [s[t.pop("_original_start") : t.pop("_original_end")]]
matchExpr.set_parse_action(extractText)
matchExpr.ignoreExprs = expr.ignoreExprs
matchExpr.suppress_warning(Diagnostics.warn_ungrouped_named_tokens_in_collection)
return matchExpr
def ungroup(expr: ParserElement) -> ParserElement:
"""Helper to undo pyparsing's default grouping of And expressions,
even if all but one are non-empty.
"""
return TokenConverter(expr).add_parse_action(lambda t: t[0])
def locatedExpr(expr: ParserElement) -> ParserElement:
"""
(DEPRECATED - future code should use the Located class)
Helper to decorate a returned token with its starting and ending
locations in the input string.
This helper adds the following results names:
- ``locn_start`` - location where matched expression begins
- ``locn_end`` - location where matched expression ends
- ``value`` - the actual parsed results
Be careful if the input text contains ``<TAB>`` characters, you
may want to call :class:`ParserElement.parseWithTabs`
Example::
wd = Word(alphas)
for match in locatedExpr(wd).searchString("ljsdf123lksdjjf123lkkjj1222"):
print(match)
prints::
[[0, 'ljsdf', 5]]
[[8, 'lksdjjf', 15]]
[[18, 'lkkjj', 23]]
"""
locator = Empty().set_parse_action(lambda ss, ll, tt: ll)
return Group(
locator("locn_start")
+ expr("value")
+ locator.copy().leaveWhitespace()("locn_end")
)
def nested_expr(
opener: Union[str, ParserElement] = "(",
closer: Union[str, ParserElement] = ")",
content: OptionalType[ParserElement] = None,
ignore_expr: ParserElement = quoted_string(),
*,
ignoreExpr: ParserElement = quoted_string(),
) -> ParserElement:
"""Helper method for defining nested lists enclosed in opening and
closing delimiters (``"("`` and ``")"`` are the default).
Parameters:
- ``opener`` - opening character for a nested list
(default= ``"("``); can also be a pyparsing expression
- ``closer`` - closing character for a nested list
(default= ``")"``); can also be a pyparsing expression
- ``content`` - expression for items within the nested lists
(default= ``None``)
- ``ignore_expr`` - expression for ignoring opening and closing delimiters
(default= :class:`quoted_string`)
- ``ignoreExpr`` - this pre-PEP8 argument is retained for compatibility
but will be removed in a future release
If an expression is not provided for the content argument, the
nested expression will capture all whitespace-delimited content
between delimiters as a list of separate values.
Use the ``ignore_expr`` argument to define expressions that may
contain opening or closing characters that should not be treated as
opening or closing characters for nesting, such as quoted_string or
a comment expression. Specify multiple expressions using an
:class:`Or` or :class:`MatchFirst`. The default is
:class:`quoted_string`, but if no expressions are to be ignored, then
pass ``None`` for this argument.
Example::
data_type = one_of("void int short long char float double")
decl_data_type = Combine(data_type + Opt(Word('*')))
ident = Word(alphas+'_', alphanums+'_')
number = pyparsing_common.number
arg = Group(decl_data_type + ident)
LPAR, RPAR = map(Suppress, "()")
code_body = nested_expr('{', '}', ignore_expr=(quoted_string | c_style_comment))
c_function = (decl_data_type("type")
+ ident("name")
+ LPAR + Opt(delimited_list(arg), [])("args") + RPAR
+ code_body("body"))
c_function.ignore(c_style_comment)
source_code = '''
int is_odd(int x) {
return (x%2);
}
int dec_to_hex(char hchar) {
if (hchar >= '0' && hchar <= '9') {
return (ord(hchar)-ord('0'));
} else {
return (10+ord(hchar)-ord('A'));
}
}
'''
for func in c_function.search_string(source_code):
print("%(name)s (%(type)s) args: %(args)s" % func)
prints::
is_odd (int) args: [['int', 'x']]
dec_to_hex (int) args: [['char', 'hchar']]
"""
if ignoreExpr != ignore_expr:
ignoreExpr = ignore_expr if ignoreExpr == quoted_string() else ignoreExpr
if opener == closer:
raise ValueError("opening and closing strings cannot be the same")
if content is None:
if isinstance(opener, str_type) and isinstance(closer, str_type):
if len(opener) == 1 and len(closer) == 1:
if ignoreExpr is not None:
content = Combine(
OneOrMore(
~ignoreExpr
+ CharsNotIn(
opener + closer + ParserElement.DEFAULT_WHITE_CHARS,
exact=1,
)
)
).set_parse_action(lambda t: t[0].strip())
else:
content = empty.copy() + CharsNotIn(
opener + closer + ParserElement.DEFAULT_WHITE_CHARS
).set_parse_action(lambda t: t[0].strip())
else:
if ignoreExpr is not None:
content = Combine(
OneOrMore(
~ignoreExpr
+ ~Literal(opener)
+ ~Literal(closer)
+ CharsNotIn(ParserElement.DEFAULT_WHITE_CHARS, exact=1)
)
).set_parse_action(lambda t: t[0].strip())
else:
content = Combine(
OneOrMore(
~Literal(opener)
+ ~Literal(closer)
+ CharsNotIn(ParserElement.DEFAULT_WHITE_CHARS, exact=1)
)
).set_parse_action(lambda t: t[0].strip())
else:
raise ValueError(
"opening and closing arguments must be strings if no content expression is given"
)
ret = Forward()
if ignoreExpr is not None:
ret <<= Group(
Suppress(opener) + ZeroOrMore(ignoreExpr | ret | content) + Suppress(closer)
)
else:
ret <<= Group(Suppress(opener) + ZeroOrMore(ret | content) + Suppress(closer))
ret.set_name("nested %s%s expression" % (opener, closer))
return ret
def _makeTags(tagStr, xml, suppress_LT=Suppress("<"), suppress_GT=Suppress(">")):
"""Internal helper to construct opening and closing tag expressions, given a tag name"""
if isinstance(tagStr, str_type):
resname = tagStr
tagStr = Keyword(tagStr, caseless=not xml)
else:
resname = tagStr.name
tagAttrName = Word(alphas, alphanums + "_-:")
if xml:
tagAttrValue = dbl_quoted_string.copy().set_parse_action(remove_quotes)
openTag = (
suppress_LT
+ tagStr("tag")
+ Dict(ZeroOrMore(Group(tagAttrName + Suppress("=") + tagAttrValue)))
+ Opt("/", default=[False])("empty").set_parse_action(
lambda s, l, t: t[0] == "/"
)
+ suppress_GT
)
else:
tagAttrValue = quoted_string.copy().set_parse_action(remove_quotes) | Word(
printables, exclude_chars=">"
)
openTag = (
suppress_LT
+ tagStr("tag")
+ Dict(
ZeroOrMore(
Group(
tagAttrName.set_parse_action(lambda t: t[0].lower())
+ Opt(Suppress("=") + tagAttrValue)
)
)
)
+ Opt("/", default=[False])("empty").set_parse_action(
lambda s, l, t: t[0] == "/"
)
+ suppress_GT
)
closeTag = Combine(Literal("</") + tagStr + ">", adjacent=False)
openTag.set_name("<%s>" % resname)
# add start<tagname> results name in parse action now that ungrouped names are not reported at two levels
openTag.add_parse_action(
lambda t: t.__setitem__(
"start" + "".join(resname.replace(":", " ").title().split()), t.copy()
)
)
closeTag = closeTag(
"end" + "".join(resname.replace(":", " ").title().split())
).set_name("</%s>" % resname)
openTag.tag = resname
closeTag.tag = resname
openTag.tag_body = SkipTo(closeTag())
return openTag, closeTag
def make_html_tags(
tag_str: Union[str, ParserElement]
) -> Tuple[ParserElement, ParserElement]:
"""Helper to construct opening and closing tag expressions for HTML,
given a tag name. Matches tags in either upper or lower case,
attributes with namespaces and with quoted or unquoted values.
Example::
text = '<td>More info at the <a href="https://github.com/pyparsing/pyparsing/wiki">pyparsing</a> wiki page</td>'
# make_html_tags returns pyparsing expressions for the opening and
# closing tags as a 2-tuple
a, a_end = make_html_tags("A")
link_expr = a + SkipTo(a_end)("link_text") + a_end
for link in link_expr.search_string(text):
# attributes in the <A> tag (like "href" shown here) are
# also accessible as named results
print(link.link_text, '->', link.href)
prints::
pyparsing -> https://github.com/pyparsing/pyparsing/wiki
"""
return _makeTags(tag_str, False)
def make_xml_tags(
tag_str: Union[str, ParserElement]
) -> Tuple[ParserElement, ParserElement]:
"""Helper to construct opening and closing tag expressions for XML,
given a tag name. Matches tags only in the given upper/lower case.
Example: similar to :class:`make_html_tags`
"""
return _makeTags(tag_str, True)
any_open_tag, any_close_tag = make_html_tags(
Word(alphas, alphanums + "_:").set_name("any tag")
)
_htmlEntityMap = {k.rstrip(";"): v for k, v in html.entities.html5.items()}
common_html_entity = Regex("&(?P<entity>" + "|".join(_htmlEntityMap) + ");").set_name(
"common HTML entity"
)
def replace_html_entity(t):
"""Helper parser action to replace common HTML entities with their special characters"""
return _htmlEntityMap.get(t.entity)
class OpAssoc(Enum):
LEFT = 1
RIGHT = 2
InfixNotationOperatorArgType = Union[
ParserElement, str, Tuple[Union[ParserElement, str], Union[ParserElement, str]]
]
InfixNotationOperatorSpec = Union[
Tuple[
InfixNotationOperatorArgType,
int,
OpAssoc,
OptionalType[ParseAction],
],
Tuple[
InfixNotationOperatorArgType,
int,
OpAssoc,
],
]
def infix_notation(
base_expr: ParserElement,
op_list: List[InfixNotationOperatorSpec],
lpar: Union[str, ParserElement] = Suppress("("),
rpar: Union[str, ParserElement] = Suppress(")"),
) -> ParserElement:
"""Helper method for constructing grammars of expressions made up of
operators working in a precedence hierarchy. Operators may be unary
or binary, left- or right-associative. Parse actions can also be
attached to operator expressions. The generated parser will also
recognize the use of parentheses to override operator precedences
(see example below).
Note: if you define a deep operator list, you may see performance
issues when using infix_notation. See
:class:`ParserElement.enable_packrat` for a mechanism to potentially
improve your parser performance.
Parameters:
- ``base_expr`` - expression representing the most basic operand to
be used in the expression
- ``op_list`` - list of tuples, one for each operator precedence level
in the expression grammar; each tuple is of the form ``(op_expr,
num_operands, right_left_assoc, (optional)parse_action)``, where:
- ``op_expr`` is the pyparsing expression for the operator; may also
be a string, which will be converted to a Literal; if ``num_operands``
is 3, ``op_expr`` is a tuple of two expressions, for the two
operators separating the 3 terms
- ``num_operands`` is the number of terms for this operator (must be 1,
2, or 3)
- ``right_left_assoc`` is the indicator whether the operator is right
or left associative, using the pyparsing-defined constants
``OpAssoc.RIGHT`` and ``OpAssoc.LEFT``.
- ``parse_action`` is the parse action to be associated with
expressions matching this operator expression (the parse action
tuple member may be omitted); if the parse action is passed
a tuple or list of functions, this is equivalent to calling
``set_parse_action(*fn)``
(:class:`ParserElement.set_parse_action`)
- ``lpar`` - expression for matching left-parentheses
(default= ``Suppress('(')``)
- ``rpar`` - expression for matching right-parentheses
(default= ``Suppress(')')``)
Example::
# simple example of four-function arithmetic with ints and
# variable names
integer = pyparsing_common.signed_integer
varname = pyparsing_common.identifier
arith_expr = infix_notation(integer | varname,
[
('-', 1, OpAssoc.RIGHT),
(one_of('* /'), 2, OpAssoc.LEFT),
(one_of('+ -'), 2, OpAssoc.LEFT),
])
arith_expr.run_tests('''
5+3*6
(5+3)*6
-2--11
''', full_dump=False)
prints::
5+3*6
[[5, '+', [3, '*', 6]]]
(5+3)*6
[[[5, '+', 3], '*', 6]]
-2--11
[[['-', 2], '-', ['-', 11]]]
"""
# captive version of FollowedBy that does not do parse actions or capture results names
class _FB(FollowedBy):
def parseImpl(self, instring, loc, doActions=True):
self.expr.try_parse(instring, loc)
return loc, []
_FB.__name__ = "FollowedBy>"
ret = Forward()
lpar = Suppress(lpar)
rpar = Suppress(rpar)
lastExpr = base_expr | (lpar + ret + rpar)
for i, operDef in enumerate(op_list):
opExpr, arity, rightLeftAssoc, pa = (operDef + (None,))[:4]
if isinstance(opExpr, str_type):
opExpr = ParserElement._literalStringClass(opExpr)
if arity == 3:
if not isinstance(opExpr, (tuple, list)) or len(opExpr) != 2:
raise ValueError(
"if numterms=3, opExpr must be a tuple or list of two expressions"
)
opExpr1, opExpr2 = opExpr
term_name = "{}{} term".format(opExpr1, opExpr2)
else:
term_name = "{} term".format(opExpr)
if not 1 <= arity <= 3:
raise ValueError("operator must be unary (1), binary (2), or ternary (3)")
if rightLeftAssoc not in (OpAssoc.LEFT, OpAssoc.RIGHT):
raise ValueError("operator must indicate right or left associativity")
thisExpr = Forward().set_name(term_name)
if rightLeftAssoc is OpAssoc.LEFT:
if arity == 1:
matchExpr = _FB(lastExpr + opExpr) + Group(lastExpr + opExpr[1, ...])
elif arity == 2:
if opExpr is not None:
matchExpr = _FB(lastExpr + opExpr + lastExpr) + Group(
lastExpr + (opExpr + lastExpr)[1, ...]
)
else:
matchExpr = _FB(lastExpr + lastExpr) + Group(lastExpr[2, ...])
elif arity == 3:
matchExpr = _FB(
lastExpr + opExpr1 + lastExpr + opExpr2 + lastExpr
) + Group(lastExpr + OneOrMore(opExpr1 + lastExpr + opExpr2 + lastExpr))
elif rightLeftAssoc is OpAssoc.RIGHT:
if arity == 1:
# try to avoid LR with this extra test
if not isinstance(opExpr, Opt):
opExpr = Opt(opExpr)
matchExpr = _FB(opExpr.expr + thisExpr) + Group(opExpr + thisExpr)
elif arity == 2:
if opExpr is not None:
matchExpr = _FB(lastExpr + opExpr + thisExpr) + Group(
lastExpr + (opExpr + thisExpr)[1, ...]
)
else:
matchExpr = _FB(lastExpr + thisExpr) + Group(
lastExpr + thisExpr[1, ...]
)
elif arity == 3:
matchExpr = _FB(
lastExpr + opExpr1 + thisExpr + opExpr2 + thisExpr
) + Group(lastExpr + opExpr1 + thisExpr + opExpr2 + thisExpr)
if pa:
if isinstance(pa, (tuple, list)):
matchExpr.set_parse_action(*pa)
else:
matchExpr.set_parse_action(pa)
thisExpr <<= (matchExpr | lastExpr).setName(term_name)
lastExpr = thisExpr
ret <<= lastExpr
return ret
def indentedBlock(blockStatementExpr, indentStack, indent=True, backup_stacks=[]):
"""
(DEPRECATED - use IndentedBlock class instead)
Helper method for defining space-delimited indentation blocks,
such as those used to define block statements in Python source code.
Parameters:
- ``blockStatementExpr`` - expression defining syntax of statement that
is repeated within the indented block
- ``indentStack`` - list created by caller to manage indentation stack
(multiple ``statementWithIndentedBlock`` expressions within a single
grammar should share a common ``indentStack``)
- ``indent`` - boolean indicating whether block must be indented beyond
the current level; set to ``False`` for block of left-most statements
(default= ``True``)
A valid block must contain at least one ``blockStatement``.
(Note that indentedBlock uses internal parse actions which make it
incompatible with packrat parsing.)
Example::
data = '''
def A(z):
A1
B = 100
G = A2
A2
A3
B
def BB(a,b,c):
BB1
def BBA():
bba1
bba2
bba3
C
D
def spam(x,y):
def eggs(z):
pass
'''
indentStack = [1]
stmt = Forward()
identifier = Word(alphas, alphanums)
funcDecl = ("def" + identifier + Group("(" + Opt(delimitedList(identifier)) + ")") + ":")
func_body = indentedBlock(stmt, indentStack)
funcDef = Group(funcDecl + func_body)
rvalue = Forward()
funcCall = Group(identifier + "(" + Opt(delimitedList(rvalue)) + ")")
rvalue << (funcCall | identifier | Word(nums))
assignment = Group(identifier + "=" + rvalue)
stmt << (funcDef | assignment | identifier)
module_body = OneOrMore(stmt)
parseTree = module_body.parseString(data)
parseTree.pprint()
prints::
[['def',
'A',
['(', 'z', ')'],
':',
[['A1'], [['B', '=', '100']], [['G', '=', 'A2']], ['A2'], ['A3']]],
'B',
['def',
'BB',
['(', 'a', 'b', 'c', ')'],
':',
[['BB1'], [['def', 'BBA', ['(', ')'], ':', [['bba1'], ['bba2'], ['bba3']]]]]],
'C',
'D',
['def',
'spam',
['(', 'x', 'y', ')'],
':',
[[['def', 'eggs', ['(', 'z', ')'], ':', [['pass']]]]]]]
"""
backup_stacks.append(indentStack[:])
def reset_stack():
indentStack[:] = backup_stacks[-1]
def checkPeerIndent(s, l, t):
if l >= len(s):
return
curCol = col(l, s)
if curCol != indentStack[-1]:
if curCol > indentStack[-1]:
raise ParseException(s, l, "illegal nesting")
raise ParseException(s, l, "not a peer entry")
def checkSubIndent(s, l, t):
curCol = col(l, s)
if curCol > indentStack[-1]:
indentStack.append(curCol)
else:
raise ParseException(s, l, "not a subentry")
def checkUnindent(s, l, t):
if l >= len(s):
return
curCol = col(l, s)
if not (indentStack and curCol in indentStack):
raise ParseException(s, l, "not an unindent")
if curCol < indentStack[-1]:
indentStack.pop()
NL = OneOrMore(LineEnd().set_whitespace_chars("\t ").suppress())
INDENT = (Empty() + Empty().set_parse_action(checkSubIndent)).set_name("INDENT")
PEER = Empty().set_parse_action(checkPeerIndent).set_name("")
UNDENT = Empty().set_parse_action(checkUnindent).set_name("UNINDENT")
if indent:
smExpr = Group(
Opt(NL)
+ INDENT
+ OneOrMore(PEER + Group(blockStatementExpr) + Opt(NL))
+ UNDENT
)
else:
smExpr = Group(
Opt(NL)
+ OneOrMore(PEER + Group(blockStatementExpr) + Opt(NL))
+ Opt(UNDENT)
)
# add a parse action to remove backup_stack from list of backups
smExpr.add_parse_action(
lambda: backup_stacks.pop(-1) and None if backup_stacks else None
)
smExpr.set_fail_action(lambda a, b, c, d: reset_stack())
blockStatementExpr.ignore(_bslash + LineEnd())
return smExpr.set_name("indented block")
# it's easy to get these comment structures wrong - they're very common, so may as well make them available
c_style_comment = Combine(Regex(r"/\*(?:[^*]|\*(?!/))*") + "*/").set_name(
"C style comment"
)
"Comment of the form ``/* ... */``"
html_comment = Regex(r"<!--[\s\S]*?-->").set_name("HTML comment")
"Comment of the form ``<!-- ... -->``"
rest_of_line = Regex(r".*").leave_whitespace().set_name("rest of line")
dbl_slash_comment = Regex(r"//(?:\\\n|[^\n])*").set_name("// comment")
"Comment of the form ``// ... (to end of line)``"
cpp_style_comment = Combine(
Regex(r"/\*(?:[^*]|\*(?!/))*") + "*/" | dbl_slash_comment
).set_name("C++ style comment")
"Comment of either form :class:`c_style_comment` or :class:`dbl_slash_comment`"
java_style_comment = cpp_style_comment
"Same as :class:`cpp_style_comment`"
python_style_comment = Regex(r"#.*").set_name("Python style comment")
"Comment of the form ``# ... (to end of line)``"
# build list of built-in expressions, for future reference if a global default value
# gets updated
_builtin_exprs = [v for v in vars().values() if isinstance(v, ParserElement)]
# pre-PEP8 compatible names
delimitedList = delimited_list
countedArray = counted_array
matchPreviousLiteral = match_previous_literal
matchPreviousExpr = match_previous_expr
oneOf = one_of
dictOf = dict_of
originalTextFor = original_text_for
nestedExpr = nested_expr
makeHTMLTags = make_html_tags
makeXMLTags = make_xml_tags
anyOpenTag, anyCloseTag = any_open_tag, any_close_tag
commonHTMLEntity = common_html_entity
replaceHTMLEntity = replace_html_entity
opAssoc = OpAssoc
infixNotation = infix_notation
cStyleComment = c_style_comment
htmlComment = html_comment
restOfLine = rest_of_line
dblSlashComment = dbl_slash_comment
cppStyleComment = cpp_style_comment
javaStyleComment = java_style_comment
pythonStyleComment = python_style_comment