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|
from __future__ import absolute_import
from __future__ import print_function
from functools import partial
import logging
import operator
import re
import six
import scss.config as config
from scss.cssdefs import COLOR_NAMES, is_builtin_css_function, _expr_glob_re, _interpolate_re
from scss.errors import SassError, SassEvaluationError, SassParseError
from scss.rule import Namespace
from scss.types import Boolean, Color, List, Map, Null, Number, String, Undefined, Value
from scss.util import dequote, normalize_var
################################################################################
# Load C acceleration modules
Scanner = None
try:
from scss._speedups import Scanner
except ImportError:
from scss._native import Scanner
log = logging.getLogger(__name__)
class Calculator(object):
"""Expression evaluator."""
ast_cache = {}
def __init__(self, namespace=None):
if namespace is None:
self.namespace = Namespace()
else:
self.namespace = namespace
def _pound_substitute(self, result):
expr = result.group(1)
value = self.evaluate_expression(expr)
if value is None:
return self.apply_vars(expr)
elif value.is_null:
return ""
else:
return dequote(value.render())
def do_glob_math(self, cont):
"""Performs #{}-interpolation. The result is always treated as a fixed
syntactic unit and will not be re-evaluated.
"""
# TODO that's a lie! this should be in the parser for most cases.
cont = str(cont)
if '#{' not in cont:
return cont
cont = _expr_glob_re.sub(self._pound_substitute, cont)
return cont
def apply_vars(self, cont):
# TODO this is very complicated. it should go away once everything
# valid is actually parseable.
if isinstance(cont, six.string_types) and '$' in cont:
try:
# Optimization: the full cont is a variable in the context,
cont = self.namespace.variable(cont)
except KeyError:
# Interpolate variables:
def _av(m):
v = None
n = m.group(2)
try:
v = self.namespace.variable(n)
except KeyError:
if config.FATAL_UNDEFINED:
raise SyntaxError("Undefined variable: '%s'." % n)
else:
if config.VERBOSITY > 1:
log.error("Undefined variable '%s'", n, extra={'stack': True})
return n
else:
if v:
if not isinstance(v, six.string_types):
v = v.render()
# TODO this used to test for _dequote
if m.group(1):
v = dequote(v)
else:
v = m.group(0)
return v
cont = _interpolate_re.sub(_av, cont)
# TODO this is surprising and shouldn't be here
cont = self.do_glob_math(cont)
return cont
def calculate(self, _base_str, divide=False):
better_expr_str = _base_str
better_expr_str = self.do_glob_math(better_expr_str)
better_expr_str = self.evaluate_expression(better_expr_str, divide=divide)
if better_expr_str is None:
better_expr_str = String.unquoted(self.apply_vars(_base_str))
return better_expr_str
# TODO only used by magic-import...?
def interpolate(self, var):
value = self.namespace.variable(var)
if var != value and isinstance(value, six.string_types):
_vi = self.evaluate_expression(value)
if _vi is not None:
value = _vi
return value
def evaluate_expression(self, expr, divide=False):
try:
ast = self.parse_expression(expr)
except SassError:
if config.DEBUG:
raise
else:
return None
try:
return ast.evaluate(self, divide=divide)
except Exception as e:
raise SassEvaluationError(e, expression=expr)
def parse_expression(self, expr, target='goal'):
if not isinstance(expr, six.string_types):
raise TypeError("Expected string, got %r" % (expr,))
key = (target, expr)
if key in self.ast_cache:
return self.ast_cache[key]
try:
parser = SassExpression(SassExpressionScanner(expr))
ast = getattr(parser, target)()
except SyntaxError as e:
raise SassParseError(e, expression=expr, expression_pos=parser._char_pos)
self.ast_cache[key] = ast
return ast
# ------------------------------------------------------------------------------
# Expression classes -- the AST resulting from a parse
class Expression(object):
def __repr__(self):
return '<%s()>' % (self.__class__.__name__)
def evaluate(self, calculator, divide=False):
"""Evaluate this AST node, and return a Sass value.
`divide` indicates whether a descendant node representing a division
should be forcibly treated as a division. See the commentary in
`BinaryOp`.
"""
raise NotImplementedError
class Parentheses(Expression):
"""An expression of the form `(foo)`.
Only exists to force a slash to be interpreted as division when contained
within parentheses.
"""
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, repr(self.contents))
def __init__(self, contents):
self.contents = contents
def evaluate(self, calculator, divide=False):
return self.contents.evaluate(calculator, divide=True)
class UnaryOp(Expression):
def __repr__(self):
return '<%s(%s, %s)>' % (self.__class__.__name__, repr(self.op), repr(self.operand))
def __init__(self, op, operand):
self.op = op
self.operand = operand
def evaluate(self, calculator, divide=False):
return self.op(self.operand.evaluate(calculator, divide=True))
class BinaryOp(Expression):
def __repr__(self):
return '<%s(%s, %s, %s)>' % (self.__class__.__name__, repr(self.op), repr(self.left), repr(self.right))
def __init__(self, op, left, right):
self.op = op
self.left = left
self.right = right
def evaluate(self, calculator, divide=False):
left = self.left.evaluate(calculator, divide=True)
right = self.right.evaluate(calculator, divide=True)
# Special handling of division: treat it as a literal slash if both
# operands are literals, there are parentheses, or this is part of a
# bigger expression.
# The first condition is covered by the type check. The other two are
# covered by the `divide` argument: other nodes that perform arithmetic
# will pass in True, indicating that this should always be a division.
if (
self.op is operator.truediv
and not divide
and isinstance(self.left, Literal)
and isinstance(self.right, Literal)
):
return String(left.render() + ' / ' + right.render(), quotes=None)
return self.op(left, right)
class AnyOp(Expression):
def __repr__(self):
return '<%s(*%s)>' % (self.__class__.__name__, repr(self.op), repr(self.operands))
def __init__(self, *operands):
self.operands = operands
def evaluate(self, calculator, divide=False):
for operand in self.operands:
value = operand.evaluate(calculator, divide=True)
if value:
return value
return value
class AllOp(Expression):
def __repr__(self):
return '<%s(*%s)>' % (self.__class__.__name__, repr(self.operands))
def __init__(self, *operands):
self.operands = operands
def evaluate(self, calculator, divide=False):
for operand in self.operands:
value = operand.evaluate(calculator, divide=True)
if not value:
return value
return value
class NotOp(Expression):
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, repr(self.operand))
def __init__(self, operand):
self.operand = operand
def evaluate(self, calculator, divide=False):
operand = self.operand.evaluate(calculator, divide=True)
return Boolean(not(operand))
class CallOp(Expression):
def __repr__(self):
return '<%s(%s, %s)>' % (self.__class__.__name__, repr(self.func_name), repr(self.argspec))
def __init__(self, func_name, argspec):
self.func_name = func_name
self.argspec = argspec
def evaluate(self, calculator, divide=False):
# TODO bake this into the context and options "dicts", plus library
func_name = normalize_var(self.func_name)
argspec_node = self.argspec
# Turn the pairs of arg tuples into *args and **kwargs
# TODO unclear whether this is correct -- how does arg, kwarg, arg
# work?
args, kwargs = argspec_node.evaluate_call_args(calculator)
argspec_len = len(args) + len(kwargs)
# Translate variable names to Python identifiers
# TODO what about duplicate kw names? should this happen in argspec?
# how does that affect mixins?
kwargs = dict(
(key.lstrip('$').replace('-', '_'), value)
for key, value in kwargs.items())
# TODO merge this with the library
funct = None
try:
funct = calculator.namespace.function(func_name, argspec_len)
# @functions take a ns as first arg. TODO: Python functions possibly
# should too
if getattr(funct, '__name__', None) == '__call':
funct = partial(funct, calculator.namespace)
except KeyError:
try:
# DEVIATION: Fall back to single parameter
funct = calculator.namespace.function(func_name, 1)
args = [List(args, use_comma=True)]
except KeyError:
if not is_builtin_css_function(func_name):
log.error("Function not found: %s:%s", func_name, argspec_len, extra={'stack': True})
if funct:
ret = funct(*args, **kwargs)
if not isinstance(ret, Value):
raise TypeError("Expected Sass type as return value, got %r" % (ret,))
return ret
# No matching function found, so render the computed values as a CSS
# function call. Slurpy arguments are expanded and named arguments are
# unsupported.
if kwargs:
raise TypeError("The CSS function %s doesn't support keyword arguments." % (func_name,))
# TODO another candidate for a "function call" sass type
rendered_args = [arg.render() for arg in args]
return String(
u"%s(%s)" % (func_name, u", ".join(rendered_args)),
quotes=None)
class Literal(Expression):
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, repr(self.value))
def __init__(self, value):
if isinstance(value, Undefined) and config.FATAL_UNDEFINED:
raise SyntaxError("Undefined literal.")
else:
self.value = value
def evaluate(self, calculator, divide=False):
return self.value
class Variable(Expression):
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, repr(self.name))
def __init__(self, name):
self.name = name
def evaluate(self, calculator, divide=False):
try:
value = calculator.namespace.variable(self.name)
except KeyError:
if config.FATAL_UNDEFINED:
raise SyntaxError("Undefined variable: '%s'." % self.name)
else:
if config.VERBOSITY > 1:
log.error("Undefined variable '%s'", self.name, extra={'stack': True})
return Undefined()
else:
if isinstance(value, six.string_types):
evald = calculator.evaluate_expression(value)
if evald is not None:
return evald
return value
class ListLiteral(Expression):
def __repr__(self):
return '<%s(%s, comma=%s)>' % (self.__class__.__name__, repr(self.items), repr(self.comma))
def __init__(self, items, comma=True):
self.items = items
self.comma = comma
def evaluate(self, calculator, divide=False):
items = [item.evaluate(calculator, divide=divide) for item in self.items]
# Whether this is a "plain" literal matters for null removal: nulls are
# left alone if this is a completely vanilla CSS property
is_literal = True
if divide:
# TODO sort of overloading "divide" here... rename i think
is_literal = False
elif not all(isinstance(item, Literal) for item in self.items):
is_literal = False
return List(items, use_comma=self.comma, is_literal=is_literal)
class MapLiteral(Expression):
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, repr(self.pairs))
def __init__(self, pairs):
self.pairs = tuple((var, value) for var, value in pairs if value is not None)
def evaluate(self, calculator, divide=False):
scss_pairs = []
for key, value in self.pairs:
scss_pairs.append((
key.evaluate(calculator),
value.evaluate(calculator),
))
return Map(scss_pairs)
class ArgspecLiteral(Expression):
"""Contains pairs of argument names and values, as parsed from a function
definition or function call.
Note that the semantics are somewhat ambiguous. Consider parsing:
$foo, $bar: 3
If this appeared in a function call, $foo would refer to a value; if it
appeared in a function definition, $foo would refer to an existing
variable. This it's up to the caller to use the right iteration function.
"""
def __repr__(self):
return '<%s(%s)>' % (self.__class__.__name__, repr(self.argpairs))
def __init__(self, argpairs, slurp=None):
# argpairs is a list of 2-tuples, parsed as though this were a function
# call, so (variable name as string or None, default value as AST
# node).
# slurp is the name of a variable to receive slurpy arguments.
self.argpairs = tuple(argpairs)
if slurp is all:
# DEVIATION: special syntax to allow injecting arbitrary arguments
# from the caller to the callee
self.inject = True
self.slurp = None
elif slurp:
self.inject = False
self.slurp = Variable(slurp)
else:
self.inject = False
self.slurp = None
def iter_list_argspec(self):
yield None, ListLiteral(zip(*self.argpairs)[1])
def iter_def_argspec(self):
"""Interpreting this literal as a function definition, yields pairs of
(variable name as a string, default value as an AST node or None).
"""
started_kwargs = False
seen_vars = set()
for var, value in self.argpairs:
if var is None:
# value is actually the name
var = value
value = None
if started_kwargs:
raise SyntaxError(
"Required argument %r must precede optional arguments"
% (var.name,))
else:
started_kwargs = True
if not isinstance(var, Variable):
raise SyntaxError("Expected variable name, got %r" % (var,))
if var.name in seen_vars:
raise SyntaxError("Duplicate argument %r" % (var.name,))
seen_vars.add(var.name)
yield var.name, value
def evaluate_call_args(self, calculator):
"""Interpreting this literal as a function call, return a 2-tuple of
``(args, kwargs)``.
"""
args = []
kwargs = {}
for var_node, value_node in self.argpairs:
value = value_node.evaluate(calculator, divide=True)
if var_node is None:
# Positional
args.append(value)
else:
# Named
if not isinstance(var_node, Variable):
raise SyntaxError("Expected variable name, got %r" % (var_node,))
kwargs[var_node.name] = value
# Slurpy arguments go on the end of the args
if self.slurp:
args.extend(self.slurp.evaluate(calculator, divide=True))
return args, kwargs
def parse_bareword(word):
if word in COLOR_NAMES:
return Color.from_name(word)
elif word == 'null':
return Null()
elif word == 'undefined':
return Undefined()
elif word == 'true':
return Boolean(True)
elif word == 'false':
return Boolean(False)
else:
return String(word, quotes=None)
class Parser(object):
def __init__(self, scanner):
self._scanner = scanner
self._pos = 0
self._char_pos = 0
def reset(self, input):
self._scanner.reset(input)
self._pos = 0
self._char_pos = 0
def _peek(self, types):
"""
Returns the token type for lookahead; if there are any args
then the list of args is the set of token types to allow
"""
try:
tok = self._scanner.token(self._pos, types)
return tok[2]
except SyntaxError:
return None
def _scan(self, type):
"""
Returns the matched text, and moves to the next token
"""
tok = self._scanner.token(self._pos, set([type]))
self._char_pos = tok[0]
if tok[2] != type:
raise SyntaxError("SyntaxError[@ char %s: %s]" % (repr(tok[0]), "Trying to find " + type))
self._pos += 1
return tok[3]
################################################################################
## Grammar compiled using Yapps:
class SassExpressionScanner(Scanner):
patterns = None
_patterns = [
('":"', ':'),
('","', ','),
('[ \r\t\n]+', '[ \r\t\n]+'),
('LPAR', '\\(|\\['),
('RPAR', '\\)|\\]'),
('END', '$'),
('MUL', '[*]'),
('DIV', '/'),
('ADD', '[+]'),
('SUB', '-\\s'),
('SIGN', '-(?![a-zA-Z_])'),
('AND', '(?<![-\\w])and(?![-\\w])'),
('OR', '(?<![-\\w])or(?![-\\w])'),
('NOT', '(?<![-\\w])not(?![-\\w])'),
('NE', '!='),
('INV', '!'),
('EQ', '=='),
('LE', '<='),
('GE', '>='),
('LT', '<'),
('GT', '>'),
('DOTDOTDOT', '[.]{3}'),
('KWSTR', "'[^']*'(?=\\s*:)"),
('STR', "'[^']*'"),
('KWQSTR', '"[^"]*"(?=\\s*:)'),
('QSTR', '"[^"]*"'),
('UNITS', '(?<!\\s)(?:[a-zA-Z]+|%)(?![-\\w])'),
('KWNUM', '(?:\\d+(?:\\.\\d*)?|\\.\\d+)(?=\\s*:)'),
('NUM', '(?:\\d+(?:\\.\\d*)?|\\.\\d+)'),
('KWCOLOR', '#(?:[a-fA-F0-9]{6}|[a-fA-F0-9]{3})(?![a-fA-F0-9])(?=\\s*:)'),
('COLOR', '#(?:[a-fA-F0-9]{6}|[a-fA-F0-9]{3})(?![a-fA-F0-9])'),
('KWVAR', '\\$[-a-zA-Z0-9_]+(?=\\s*:)'),
('SLURPYVAR', '\\$[-a-zA-Z0-9_]+(?=[.][.][.])'),
('VAR', '\\$[-a-zA-Z0-9_]+'),
('FNCT', '[-a-zA-Z_][-a-zA-Z0-9_]*(?=\\()'),
('KWID', '[-a-zA-Z_][-a-zA-Z0-9_]*(?=\\s*:)'),
('ID', '[-a-zA-Z_][-a-zA-Z0-9_]*'),
('BANG_IMPORTANT', '!important'),
]
def __init__(self, input=None):
if hasattr(self, 'setup_patterns'):
self.setup_patterns(self._patterns)
elif self.patterns is None:
self.__class__.patterns = []
for t, p in self._patterns:
self.patterns.append((t, re.compile(p)))
super(SassExpressionScanner, self).__init__(None, ['[ \r\t\n]+'], input)
class SassExpression(Parser):
def goal(self):
expr_lst = self.expr_lst()
END = self._scan('END')
return expr_lst
def goal_argspec(self):
argspec = self.argspec()
END = self._scan('END')
return argspec
def argspec(self):
_token_ = self._peek(self.argspec_rsts)
if _token_ not in self.argspec_chks:
if self._peek(self.argspec_rsts_) not in self.argspec_chks_:
argspec_items = self.argspec_items()
args, slurpy = argspec_items
return ArgspecLiteral(args, slurp=slurpy)
return ArgspecLiteral([])
elif _token_ == 'SLURPYVAR':
SLURPYVAR = self._scan('SLURPYVAR')
DOTDOTDOT = self._scan('DOTDOTDOT')
return ArgspecLiteral([], slurp=SLURPYVAR)
else: # == 'DOTDOTDOT'
DOTDOTDOT = self._scan('DOTDOTDOT')
return ArgspecLiteral([], slurp=all)
def argspec_items(self):
slurpy = None
argspec_item = self.argspec_item()
args = [argspec_item]
if self._peek(self.argspec_items_rsts) == '","':
self._scan('","')
if self._peek(self.argspec_items_rsts_) not in self.argspec_chks_:
_token_ = self._peek(self.argspec_items_rsts__)
if _token_ == 'SLURPYVAR':
SLURPYVAR = self._scan('SLURPYVAR')
DOTDOTDOT = self._scan('DOTDOTDOT')
slurpy = SLURPYVAR
elif _token_ == 'DOTDOTDOT':
DOTDOTDOT = self._scan('DOTDOTDOT')
slurpy = all
else: # in self.argspec_items_chks
argspec_items = self.argspec_items()
more_args, slurpy = argspec_items
args.extend(more_args)
return args, slurpy
def argspec_item(self):
_token_ = self._peek(self.argspec_items_chks)
if _token_ == 'KWVAR':
KWVAR = self._scan('KWVAR')
self._scan('":"')
expr_slst = self.expr_slst()
return (Variable(KWVAR), expr_slst)
else: # in self.argspec_item_chks
expr_slst = self.expr_slst()
return (None, expr_slst)
def expr_map(self):
map_item = self.map_item()
pairs = [map_item]
while self._peek(self.expr_map_rsts) == '","':
self._scan('","')
map_item = (None, None)
if self._peek(self.expr_map_rsts_) not in self.expr_map_rsts:
map_item = self.map_item()
pairs.append(map_item)
return MapLiteral(pairs)
def map_item(self):
kwatom = self.kwatom()
self._scan('":"')
expr_slst = self.expr_slst()
return (kwatom, expr_slst)
def expr_lst(self):
expr_slst = self.expr_slst()
v = [expr_slst]
while self._peek(self.argspec_items_rsts) == '","':
self._scan('","')
expr_slst = self.expr_slst()
v.append(expr_slst)
return ListLiteral(v) if len(v) > 1 else v[0]
def expr_slst(self):
or_expr = self.or_expr()
v = [or_expr]
while self._peek(self.expr_slst_rsts) not in self.argspec_items_rsts:
or_expr = self.or_expr()
v.append(or_expr)
return ListLiteral(v, comma=False) if len(v) > 1 else v[0]
def or_expr(self):
and_expr = self.and_expr()
v = and_expr
while self._peek(self.or_expr_rsts) == 'OR':
OR = self._scan('OR')
and_expr = self.and_expr()
v = AnyOp(v, and_expr)
return v
def and_expr(self):
not_expr = self.not_expr()
v = not_expr
while self._peek(self.and_expr_rsts) == 'AND':
AND = self._scan('AND')
not_expr = self.not_expr()
v = AllOp(v, not_expr)
return v
def not_expr(self):
_token_ = self._peek(self.argspec_item_chks)
if _token_ != 'NOT':
comparison = self.comparison()
return comparison
else: # == 'NOT'
NOT = self._scan('NOT')
not_expr = self.not_expr()
return NotOp(not_expr)
def comparison(self):
a_expr = self.a_expr()
v = a_expr
while self._peek(self.comparison_rsts) in self.comparison_chks:
_token_ = self._peek(self.comparison_chks)
if _token_ == 'LT':
LT = self._scan('LT')
a_expr = self.a_expr()
v = BinaryOp(operator.lt, v, a_expr)
elif _token_ == 'GT':
GT = self._scan('GT')
a_expr = self.a_expr()
v = BinaryOp(operator.gt, v, a_expr)
elif _token_ == 'LE':
LE = self._scan('LE')
a_expr = self.a_expr()
v = BinaryOp(operator.le, v, a_expr)
elif _token_ == 'GE':
GE = self._scan('GE')
a_expr = self.a_expr()
v = BinaryOp(operator.ge, v, a_expr)
elif _token_ == 'EQ':
EQ = self._scan('EQ')
a_expr = self.a_expr()
v = BinaryOp(operator.eq, v, a_expr)
else: # == 'NE'
NE = self._scan('NE')
a_expr = self.a_expr()
v = BinaryOp(operator.ne, v, a_expr)
return v
def a_expr(self):
m_expr = self.m_expr()
v = m_expr
while self._peek(self.a_expr_rsts) in self.a_expr_chks:
_token_ = self._peek(self.a_expr_chks)
if _token_ == 'ADD':
ADD = self._scan('ADD')
m_expr = self.m_expr()
v = BinaryOp(operator.add, v, m_expr)
else: # == 'SUB'
SUB = self._scan('SUB')
m_expr = self.m_expr()
v = BinaryOp(operator.sub, v, m_expr)
return v
def m_expr(self):
u_expr = self.u_expr()
v = u_expr
while self._peek(self.m_expr_rsts) in self.m_expr_chks:
_token_ = self._peek(self.m_expr_chks)
if _token_ == 'MUL':
MUL = self._scan('MUL')
u_expr = self.u_expr()
v = BinaryOp(operator.mul, v, u_expr)
else: # == 'DIV'
DIV = self._scan('DIV')
u_expr = self.u_expr()
v = BinaryOp(operator.truediv, v, u_expr)
return v
def u_expr(self):
_token_ = self._peek(self.u_expr_rsts)
if _token_ == 'SIGN':
SIGN = self._scan('SIGN')
u_expr = self.u_expr()
return UnaryOp(operator.neg, u_expr)
elif _token_ == 'ADD':
ADD = self._scan('ADD')
u_expr = self.u_expr()
return UnaryOp(operator.pos, u_expr)
else: # in self.u_expr_chks
atom = self.atom()
return atom
def atom(self):
_token_ = self._peek(self.u_expr_chks)
if _token_ == 'LPAR':
LPAR = self._scan('LPAR')
_token_ = self._peek(self.atom_rsts)
if _token_ not in self.argspec_item_chks:
expr_map = self.expr_map()
v = expr_map
else: # in self.argspec_item_chks
expr_lst = self.expr_lst()
v = expr_lst
RPAR = self._scan('RPAR')
return Parentheses(v)
elif _token_ == 'FNCT':
FNCT = self._scan('FNCT')
LPAR = self._scan('LPAR')
argspec = self.argspec()
RPAR = self._scan('RPAR')
return CallOp(FNCT, argspec)
elif _token_ == 'BANG_IMPORTANT':
BANG_IMPORTANT = self._scan('BANG_IMPORTANT')
return Literal(String(BANG_IMPORTANT, quotes=None))
elif _token_ == 'ID':
ID = self._scan('ID')
return Literal(parse_bareword(ID))
elif _token_ == 'NUM':
NUM = self._scan('NUM')
UNITS = None
if self._peek(self.atom_rsts_) == 'UNITS':
UNITS = self._scan('UNITS')
return Literal(Number(float(NUM), unit=UNITS))
elif _token_ == 'STR':
STR = self._scan('STR')
return Literal(String(STR[1:-1], quotes="'"))
elif _token_ == 'QSTR':
QSTR = self._scan('QSTR')
return Literal(String(QSTR[1:-1], quotes='"'))
elif _token_ == 'COLOR':
COLOR = self._scan('COLOR')
return Literal(Color.from_hex(COLOR, literal=True))
else: # == 'VAR'
VAR = self._scan('VAR')
return Variable(VAR)
def kwatom(self):
_token_ = self._peek(self.kwatom_rsts)
if _token_ == '":"':
pass
elif _token_ == 'KWID':
KWID = self._scan('KWID')
return Literal(parse_bareword(KWID))
elif _token_ == 'KWNUM':
KWNUM = self._scan('KWNUM')
UNITS = None
if self._peek(self.kwatom_rsts_) == 'UNITS':
UNITS = self._scan('UNITS')
return Literal(Number(float(KWNUM), unit=UNITS))
elif _token_ == 'KWSTR':
KWSTR = self._scan('KWSTR')
return Literal(String(KWSTR[1:-1], quotes="'"))
elif _token_ == 'KWQSTR':
KWQSTR = self._scan('KWQSTR')
return Literal(String(KWQSTR[1:-1], quotes='"'))
elif _token_ == 'KWCOLOR':
KWCOLOR = self._scan('KWCOLOR')
return Literal(Color.from_hex(COLOR, literal=True))
else: # == 'KWVAR'
KWVAR = self._scan('KWVAR')
return Variable(KWVAR)
u_expr_chks = set(['LPAR', 'COLOR', 'QSTR', 'NUM', 'FNCT', 'STR', 'VAR', 'BANG_IMPORTANT', 'ID'])
m_expr_rsts = set(['LPAR', 'SUB', 'QSTR', 'RPAR', 'MUL', 'DIV', 'BANG_IMPORTANT', 'LE', 'COLOR', 'NE', 'LT', 'NUM', 'GT', 'END', 'SIGN', 'GE', 'FNCT', 'STR', 'VAR', 'EQ', 'ID', 'AND', 'ADD', 'NOT', 'OR', '","'])
argspec_items_rsts = set(['RPAR', 'END', '","'])
expr_map_rsts = set(['RPAR', '","'])
argspec_items_rsts__ = set(['KWVAR', 'LPAR', 'QSTR', 'SLURPYVAR', 'COLOR', 'DOTDOTDOT', 'SIGN', 'VAR', 'ADD', 'NUM', 'FNCT', 'STR', 'NOT', 'BANG_IMPORTANT', 'ID'])
kwatom_rsts = set(['KWVAR', 'KWID', 'KWSTR', 'KWQSTR', 'KWCOLOR', '":"', 'KWNUM'])
argspec_item_chks = set(['LPAR', 'COLOR', 'QSTR', 'SIGN', 'VAR', 'ADD', 'NUM', 'FNCT', 'STR', 'NOT', 'BANG_IMPORTANT', 'ID'])
a_expr_chks = set(['ADD', 'SUB'])
expr_slst_rsts = set(['LPAR', 'END', 'COLOR', 'QSTR', 'SIGN', 'VAR', 'ADD', 'NUM', 'RPAR', 'FNCT', 'STR', 'NOT', 'BANG_IMPORTANT', 'ID', '","'])
or_expr_rsts = set(['LPAR', 'END', 'COLOR', 'QSTR', 'SIGN', 'VAR', 'ADD', 'NUM', 'RPAR', 'FNCT', 'STR', 'NOT', 'ID', 'BANG_IMPORTANT', 'OR', '","'])
and_expr_rsts = set(['AND', 'LPAR', 'END', 'COLOR', 'QSTR', 'SIGN', 'VAR', 'ADD', 'NUM', 'RPAR', 'FNCT', 'STR', 'NOT', 'ID', 'BANG_IMPORTANT', 'OR', '","'])
comparison_rsts = set(['LPAR', 'QSTR', 'RPAR', 'BANG_IMPORTANT', 'LE', 'COLOR', 'NE', 'LT', 'NUM', 'GT', 'END', 'SIGN', 'ADD', 'FNCT', 'STR', 'VAR', 'EQ', 'ID', 'AND', 'GE', 'NOT', 'OR', '","'])
argspec_chks = set(['DOTDOTDOT', 'SLURPYVAR'])
atom_rsts_ = set(['LPAR', 'SUB', 'QSTR', 'RPAR', 'VAR', 'MUL', 'DIV', 'BANG_IMPORTANT', 'LE', 'COLOR', 'NE', 'LT', 'NUM', 'GT', 'END', 'SIGN', 'GE', 'FNCT', 'STR', 'UNITS', 'EQ', 'ID', 'AND', 'ADD', 'NOT', 'OR', '","'])
expr_map_rsts_ = set(['KWVAR', 'KWID', 'KWSTR', 'KWQSTR', 'RPAR', 'KWCOLOR', '":"', 'KWNUM', '","'])
u_expr_rsts = set(['LPAR', 'COLOR', 'QSTR', 'SIGN', 'ADD', 'NUM', 'FNCT', 'STR', 'VAR', 'BANG_IMPORTANT', 'ID'])
comparison_chks = set(['GT', 'GE', 'NE', 'LT', 'LE', 'EQ'])
argspec_items_rsts_ = set(['KWVAR', 'LPAR', 'QSTR', 'END', 'SLURPYVAR', 'COLOR', 'DOTDOTDOT', 'SIGN', 'VAR', 'ADD', 'NUM', 'RPAR', 'FNCT', 'STR', 'NOT', 'BANG_IMPORTANT', 'ID'])
a_expr_rsts = set(['LPAR', 'SUB', 'QSTR', 'RPAR', 'BANG_IMPORTANT', 'LE', 'COLOR', 'NE', 'LT', 'NUM', 'GT', 'END', 'SIGN', 'GE', 'FNCT', 'STR', 'VAR', 'EQ', 'ID', 'AND', 'ADD', 'NOT', 'OR', '","'])
m_expr_chks = set(['MUL', 'DIV'])
kwatom_rsts_ = set(['UNITS', '":"'])
argspec_items_chks = set(['KWVAR', 'LPAR', 'COLOR', 'QSTR', 'SIGN', 'VAR', 'ADD', 'NUM', 'FNCT', 'STR', 'NOT', 'BANG_IMPORTANT', 'ID'])
argspec_rsts = set(['KWVAR', 'LPAR', 'BANG_IMPORTANT', 'END', 'SLURPYVAR', 'COLOR', 'DOTDOTDOT', 'RPAR', 'VAR', 'ADD', 'NUM', 'FNCT', 'STR', 'NOT', 'QSTR', 'SIGN', 'ID'])
atom_rsts = set(['KWVAR', 'KWID', 'KWSTR', 'BANG_IMPORTANT', 'LPAR', 'COLOR', 'KWQSTR', 'SIGN', 'KWCOLOR', 'VAR', 'ADD', 'NUM', '":"', 'STR', 'NOT', 'QSTR', 'KWNUM', 'ID', 'FNCT'])
argspec_chks_ = set(['END', 'RPAR'])
argspec_rsts_ = set(['KWVAR', 'LPAR', 'BANG_IMPORTANT', 'END', 'COLOR', 'QSTR', 'SIGN', 'VAR', 'ADD', 'NUM', 'FNCT', 'STR', 'NOT', 'RPAR', 'ID'])
### Grammar ends.
################################################################################
__all__ = ('Calculator',)
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