# [147] DECIMAL ::= [0-9]* '.' [0-9]+
DECIMAL = Regex(r'[0-9]*\.[0-9]+') # (?![eE])
# DECIMAL.setResultsName('decimal')
DECIMAL.setParseAction(
lambda x: rdflib.Literal(x[0], datatype=rdflib.XSD.decimal))
# [148] DOUBLE ::= [0-9]+ '.' [0-9]* EXPONENT | '.' ([0-9])+ EXPONENT | ([0-9])+ EXPONENT
DOUBLE = Regex(r'[0-9]+\.[0-9]*%(e)s|\.([0-9])+%(e)s|[0-9]+%(e)s' %
{'e': EXPONENT_re})
# DOUBLE.setResultsName('double')
DOUBLE.setParseAction(
lambda x: rdflib.Literal(x[0], datatype=rdflib.XSD.double))
# [149] INTEGER_POSITIVE ::= '+' INTEGER
INTEGER_POSITIVE = Suppress('+') + INTEGER.copy().leaveWhitespace()
INTEGER_POSITIVE.setParseAction(
lambda x: rdflib.Literal("+" + x[0], datatype=rdflib.XSD.integer))
# [150] DECIMAL_POSITIVE ::= '+' DECIMAL
DECIMAL_POSITIVE = Suppress('+') + DECIMAL.copy().leaveWhitespace()
# [151] DOUBLE_POSITIVE ::= '+' DOUBLE
DOUBLE_POSITIVE = Suppress('+') + DOUBLE.copy().leaveWhitespace()
# [152] INTEGER_NEGATIVE ::= '-' INTEGER
INTEGER_NEGATIVE = Suppress('-') + INTEGER.copy().leaveWhitespace()
INTEGER_NEGATIVE.setParseAction(lambda x: neg(x[0]))
# [153] DECIMAL_NEGATIVE ::= '-' DECIMAL
DECIMAL_NEGATIVE = Suppress('-') + DECIMAL.copy().leaveWhitespace()
# [155] EXPONENT ::= [eE] [+-]? [0-9]+
EXPONENT_re = "[eE][+-]?[0-9]+"
# [147] DECIMAL ::= [0-9]* '.' [0-9]+
DECIMAL = Regex(r"[0-9]*\.[0-9]+") # (?![eE])
# DECIMAL.setResultsName('decimal')
DECIMAL.setParseAction(lambda x: rdflib.Literal(x[0], datatype=rdflib.XSD.decimal))
# [148] DOUBLE ::= [0-9]+ '.' [0-9]* EXPONENT | '.' ([0-9])+ EXPONENT | ([0-9])+ EXPONENT
DOUBLE = Regex(r"[0-9]+\.[0-9]*%(e)s|\.([0-9])+%(e)s|[0-9]+%(e)s" % {"e": EXPONENT_re})
# DOUBLE.setResultsName('double')
DOUBLE.setParseAction(lambda x: rdflib.Literal(x[0], datatype=rdflib.XSD.double))
# [149] INTEGER_POSITIVE ::= '+' INTEGER
INTEGER_POSITIVE = Suppress("+") + INTEGER.copy().leaveWhitespace()
# [150] DECIMAL_POSITIVE ::= '+' DECIMAL
DECIMAL_POSITIVE = Suppress("+") + DECIMAL.copy().leaveWhitespace()
# [151] DOUBLE_POSITIVE ::= '+' DOUBLE
DOUBLE_POSITIVE = Suppress("+") + DOUBLE.copy().leaveWhitespace()
# [152] INTEGER_NEGATIVE ::= '-' INTEGER
INTEGER_NEGATIVE = Suppress("-") + INTEGER.copy().leaveWhitespace()
INTEGER_NEGATIVE.setParseAction(lambda x: neg(x[0]))
# [153] DECIMAL_NEGATIVE ::= '-' DECIMAL
DECIMAL_NEGATIVE = Suppress("-") + DECIMAL.copy().leaveWhitespace()
DECIMAL_NEGATIVE.setParseAction(lambda x: neg(x[0]))
# Basis characters (by exclusion) for variable / field names. The following
# list of characters is from the btparse documentation
any_name = Regex("[^\\s\"#%'(),={}]+")
# btparse says, and the test bibs show by experiment, that macro and field names
# cannot start with a digit. In fact entry type names cannot start with a digit
# either (see tests/bibs). Cite keys can start with a digit
not_digname = Regex("[^\\d\\s\"#%'(),={}][^\\s\"#%'(),={}]*")
# Comment comments out to end of line
comment = AT + CaselessLiteral("comment") + Regex(
r"[\s{(].*").leaveWhitespace()
# The name types with their digiteyness
not_dig_lower = not_digname.copy().setParseAction(lambda t: t[0].lower())
macro_def = not_dig_lower.copy()
macro_ref = not_dig_lower.copy().setParseAction(lambda t: Macro(t[0].lower()))
field_name = not_dig_lower.copy()
# Spaces in names mean they cannot clash with field names
entry_type = not_dig_lower("entry_type")
cite_key = any_name("cite_key")
# Number has to be before macro name
string = number | macro_ref | quoted_string | curly_string
# There can be hash concatenation
field_value = string + ZeroOrMore(HASH + string)
field_def = Group(field_name + EQUALS + field_value)
entry_contents = Dict(ZeroOrMore(field_def + COMMA) + Optional(field_def))
# Entry is surrounded either by parentheses or curlies
# Basis characters (by exclusion) for variable / field names. The following
# list of characters is from the btparse documentation
any_name = Regex('[^\s"#%\'(),={}]+')
# btparse says, and the test bibs show by experiment, that macro and field names
# cannot start with a digit. In fact entry type names cannot start with a digit
# either (see tests/bibs). Cite keys can start with a digit
not_digname = Regex('[^\d\s"#%\'(),={}][^\s"#%\'(),={}]*')
# Comment comments out to end of line
comment = (AT + CaselessLiteral('comment') +
Regex("[\s{(].*").leaveWhitespace())
# The name types with their digiteyness
not_dig_lower = not_digname.copy().setParseAction(
lambda t: t[0].lower())
macro_def = not_dig_lower.copy()
macro_ref = not_dig_lower.copy().setParseAction(lambda t : Macro(t[0].lower()))
field_name = not_dig_lower.copy()
# Spaces in names mean they cannot clash with field names
entry_type = not_dig_lower.setResultsName('entry type')
cite_key = any_name.setResultsName('cite key')
# Number has to be before macro name
string = (number | macro_ref | quoted_string |
curly_string)
# There can be hash concatenation
field_value = string + ZeroOrMore(HASH + string)
field_def = Group(field_name + EQUALS + field_value)
entry_contents = Dict(ZeroOrMore(field_def + COMMA) + Optional(field_def))
valid_word = Regex(r'([a-zA-Z0-9*_+.-]|\\[!(){}\[\]^"~*?\\:])+').setName("word")
valid_word.setParseAction(
lambda t : t[0].replace('\\\\',chr(127)).replace('\\','').replace(chr(127),'\\')
)
string = QuotedString('"')
required_modifier = Literal("+")("required")
prohibit_modifier = Literal("-")("prohibit")
integer = Regex(r"\d+").setParseAction(lambda t:int(t[0]))
proximity_modifier = Group(TILDE + integer("proximity"))
number = Regex(r'\d+(\.\d+)?').setParseAction(lambda t:float(t[0]))
fuzzy_modifier = TILDE + Optional(number, default=0.5)("fuzzy")
term = Forward()
field_name = valid_word.copy().setName("fieldname")
incl_range_search = Group(LBRACK + term("lower") + to_ + term("upper") + RBRACK)
excl_range_search = Group(LBRACE + term("lower") + to_ + term("upper") + RBRACE)
range_search = incl_range_search("incl_range") | excl_range_search("excl_range")
boost = (CARAT + number("boost"))
string_expr = Group(string + proximity_modifier) | string
word_expr = Group(valid_word + fuzzy_modifier) | valid_word
term << (Optional(field_name("field") + COLON) +
(word_expr | string_expr | range_search | Group(LPAR + expression + RPAR)) +
Optional(boost))
term.setParseAction(lambda t:[t] if 'field' in t or 'boost' in t else None)
expression << operatorPrecedence(term,
[
(required_modifier | prohibit_modifier, 1, opAssoc.RIGHT),
valid_word = Regex(r'([a-zA-Z0-9*_+.-]|\\[!(){}\[\]^"~*?\\:])+').setName(
"word")
valid_word.setParseAction(lambda t: t[0].replace('\\\\', chr(127)).replace(
'\\', '').replace(chr(127), '\\'))
string = QuotedString('"')
required_modifier = Literal("+")("required")
prohibit_modifier = Literal("-")("prohibit")
integer = Regex(r"\d+").setParseAction(lambda t: int(t[0]))
proximity_modifier = Group(TILDE + integer("proximity"))
number = Regex(r'\d+(\.\d+)?').setParseAction(lambda t: float(t[0]))
fuzzy_modifier = TILDE + Optional(number, default=0.5)("fuzzy")
term = Forward()
field_name = valid_word.copy().setName("fieldname")
incl_range_search = Group(LBRACK + term("lower") + to_ + term("upper") +
RBRACK)
excl_range_search = Group(LBRACE + term("lower") + to_ + term("upper") +
RBRACE)
range_search = incl_range_search("incl_range") | excl_range_search(
"excl_range")
boost = (CARAT + number("boost"))
string_expr = Group(string + proximity_modifier) | string
word_expr = Group(valid_word + fuzzy_modifier) | valid_word
term << (Optional(field_name("field") + COLON) +
(word_expr | string_expr | range_search
| Group(LPAR + expression + RPAR)) + Optional(boost))
term.setParseAction(lambda t: [t] if 'field' in t or 'boost' in t else None)
number = Regex("[0-9]+")
# Basis characters (by exclusion) for variable / field names. The following
# list of characters is from the btparse documentation
anyName = Regex("[^\s\"#%'(),={}]+")
# btparse says, and the test bibs show by experiment, that macro and field names
# cannot start with a digit. In fact entry type names cannot start with a digit
# either (see tests/bibs). Cite keys can start with a digit
notDigname = Regex("[^\d\s\"#%'(),={}][^\s\"#%'(),={}]*")
comment = AT + CaselessLiteral("comment") + LCURLY + charsNoCurly.setResultsName("comment") + RCURLY
comment.setParseAction(Comment.fromParseResult)
# The name types with their digiteyness
notDigLower = notDigname.copy().setParseAction(lambda t: t[0].lower())
macroDef = notDigLower.copy()
macroRef = notDigLower.copy().setParseAction(MacroReference.fromParseResult)
fieldName = notDigLower.copy()
entryType = notDigLower.setResultsName("entry type")
citeKey = anyName.setResultsName("cite key")
string = number | macroRef | quotedString | curlyString
# There can be hash concatenation
fieldValue = string + ZeroOrMore(HASH + string)
namePart = Regex(r"(?!\band\b)[^\s\.,{}]+\.?") | curlyString
nobility = Regex(r"[a-z]\w+\.?(\s[a-z]\w+\.?)*").setResultsName("nobility") # "van" etc.
spacedNames = originalTextFor(OneOrMore(namePart))
hs_row = _GenerateMatch(
lambda ver: Group(delimitedList(hs_cell[ver], delim=',') +
Suppress(hs_nl)
).setName('row'))
hs_rows = _GenerateMatch(
lambda ver: Group(hs_row[ver][...]).setName("rows"))
hs_metaPair = _GenerateMatch(
lambda ver: (
hs_id +
Suppress(':') +
hs_scalar[ver]
).setParseAction(lambda toks: [tuple(toks[:2])]).setName('metaPair'))
hs_metaMarker = hs_id.copy().setParseAction(
lambda toks: [(toks[0], MARKER)]).setName('metaMarker')
hs_metaItem = _GenerateMatch(
lambda ver: (
hs_metaMarker ^
hs_metaPair[ver]
).setName('metaItem'))
hs_meta = _GenerateMatch(
lambda ver: hs_metaItem[ver][1, ...].setParseAction(
lambda toks: [SortableDict(toks.asList())]
).setName('meta'))
hs_col = _GenerateMatch(
lambda ver: (
hs_id +
Optional(hs_meta[ver]).setName('colMeta')
).setParseAction(lambda toks: [
import six
from pysoa.test.compatibility import mock as unittest_mock
from pysoa.test.plan.errors import FixtureSyntaxError
from pysoa.test.plan.grammar.directive import (
ActionDirective,
Directive,
VarValueGrammar,
register_directive,
)
# __test_plan_prune_traceback = True # ensure code in this file is not included in failure stack traces
_mock_target_syntax = Regex(r'([a-z_]+[a-z0-9_]*)+(\.[a-z_]+[a-z0-9_]*)*')('mock_target')
_mock_path_syntax = _mock_target_syntax.copy()('mock_path')
_json_syntax = VarValueGrammar.copy()('json')
class _AttrDict(dict):
def __init__(self, *args, **kwargs):
super(_AttrDict, self).__init__(*args, **kwargs)
self.__dict__ = self
class _DeleteAttribute(object):
def __deepcopy__(self, *_, **__):
return self
_DELETE_ATTRIBUTE = _DeleteAttribute()
