3853 lines
127 KiB
Python
3853 lines
127 KiB
Python
# cython: auto_cpdef=True, infer_types=True, language_level=3, py2_import=True
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#
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# Parser
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#
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from __future__ import absolute_import
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# This should be done automatically
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import cython
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cython.declare(Nodes=object, ExprNodes=object, EncodedString=object,
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bytes_literal=object, StringEncoding=object,
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FileSourceDescriptor=object, lookup_unicodechar=object, unicode_category=object,
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Future=object, Options=object, error=object, warning=object,
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Builtin=object, ModuleNode=object, Utils=object, _unicode=object, _bytes=object,
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re=object, sys=object, _parse_escape_sequences=object, _parse_escape_sequences_raw=object,
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partial=object, reduce=object, _IS_PY3=cython.bint, _IS_2BYTE_UNICODE=cython.bint,
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_CDEF_MODIFIERS=tuple)
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from io import StringIO
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import re
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import sys
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from unicodedata import lookup as lookup_unicodechar, category as unicode_category
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from functools import partial, reduce
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from .Scanning import PyrexScanner, FileSourceDescriptor, StringSourceDescriptor
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from . import Nodes
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from . import ExprNodes
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from . import Builtin
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from . import StringEncoding
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from .StringEncoding import EncodedString, bytes_literal, _unicode, _bytes
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from .ModuleNode import ModuleNode
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from .Errors import error, warning
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from .. import Utils
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from . import Future
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from . import Options
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_IS_PY3 = sys.version_info[0] >= 3
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_IS_2BYTE_UNICODE = sys.maxunicode == 0xffff
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_CDEF_MODIFIERS = ('inline', 'nogil', 'api')
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class Ctx(object):
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# Parsing context
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level = 'other'
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visibility = 'private'
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cdef_flag = 0
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typedef_flag = 0
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api = 0
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overridable = 0
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nogil = 0
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namespace = None
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templates = None
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allow_struct_enum_decorator = False
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def __init__(self, **kwds):
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self.__dict__.update(kwds)
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def __call__(self, **kwds):
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ctx = Ctx()
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d = ctx.__dict__
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d.update(self.__dict__)
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d.update(kwds)
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return ctx
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def p_ident(s, message="Expected an identifier"):
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if s.sy == 'IDENT':
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name = s.systring
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s.next()
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return name
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else:
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s.error(message)
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def p_ident_list(s):
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names = []
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while s.sy == 'IDENT':
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names.append(s.systring)
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s.next()
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if s.sy != ',':
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break
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s.next()
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return names
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#------------------------------------------
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#
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# Expressions
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#
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#------------------------------------------
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def p_binop_operator(s):
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pos = s.position()
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op = s.sy
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s.next()
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return op, pos
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def p_binop_expr(s, ops, p_sub_expr):
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n1 = p_sub_expr(s)
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while s.sy in ops:
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op, pos = p_binop_operator(s)
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n2 = p_sub_expr(s)
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n1 = ExprNodes.binop_node(pos, op, n1, n2)
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if op == '/':
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if Future.division in s.context.future_directives:
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n1.truedivision = True
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else:
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n1.truedivision = None # unknown
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return n1
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#lambdef: 'lambda' [varargslist] ':' test
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def p_lambdef(s, allow_conditional=True):
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# s.sy == 'lambda'
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pos = s.position()
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s.next()
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if s.sy == ':':
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args = []
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star_arg = starstar_arg = None
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else:
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args, star_arg, starstar_arg = p_varargslist(
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s, terminator=':', annotated=False)
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s.expect(':')
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if allow_conditional:
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expr = p_test(s)
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else:
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expr = p_test_nocond(s)
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return ExprNodes.LambdaNode(
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pos, args = args,
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star_arg = star_arg, starstar_arg = starstar_arg,
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result_expr = expr)
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#lambdef_nocond: 'lambda' [varargslist] ':' test_nocond
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def p_lambdef_nocond(s):
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return p_lambdef(s, allow_conditional=False)
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#test: or_test ['if' or_test 'else' test] | lambdef
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def p_test(s):
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if s.sy == 'lambda':
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return p_lambdef(s)
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pos = s.position()
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expr = p_or_test(s)
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if s.sy == 'if':
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s.next()
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test = p_or_test(s)
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s.expect('else')
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other = p_test(s)
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return ExprNodes.CondExprNode(pos, test=test, true_val=expr, false_val=other)
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else:
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return expr
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#test_nocond: or_test | lambdef_nocond
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def p_test_nocond(s):
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if s.sy == 'lambda':
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return p_lambdef_nocond(s)
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else:
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return p_or_test(s)
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#or_test: and_test ('or' and_test)*
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def p_or_test(s):
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return p_rassoc_binop_expr(s, ('or',), p_and_test)
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def p_rassoc_binop_expr(s, ops, p_subexpr):
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n1 = p_subexpr(s)
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if s.sy in ops:
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pos = s.position()
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op = s.sy
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s.next()
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n2 = p_rassoc_binop_expr(s, ops, p_subexpr)
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n1 = ExprNodes.binop_node(pos, op, n1, n2)
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return n1
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#and_test: not_test ('and' not_test)*
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def p_and_test(s):
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#return p_binop_expr(s, ('and',), p_not_test)
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return p_rassoc_binop_expr(s, ('and',), p_not_test)
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#not_test: 'not' not_test | comparison
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def p_not_test(s):
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if s.sy == 'not':
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pos = s.position()
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s.next()
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return ExprNodes.NotNode(pos, operand = p_not_test(s))
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else:
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return p_comparison(s)
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#comparison: expr (comp_op expr)*
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#comp_op: '<'|'>'|'=='|'>='|'<='|'<>'|'!='|'in'|'not' 'in'|'is'|'is' 'not'
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def p_comparison(s):
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n1 = p_starred_expr(s)
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if s.sy in comparison_ops:
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pos = s.position()
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op = p_cmp_op(s)
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n2 = p_starred_expr(s)
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n1 = ExprNodes.PrimaryCmpNode(pos,
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operator = op, operand1 = n1, operand2 = n2)
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if s.sy in comparison_ops:
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n1.cascade = p_cascaded_cmp(s)
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return n1
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def p_test_or_starred_expr(s):
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if s.sy == '*':
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return p_starred_expr(s)
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else:
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return p_test(s)
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def p_starred_expr(s):
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pos = s.position()
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if s.sy == '*':
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starred = True
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s.next()
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else:
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starred = False
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expr = p_bit_expr(s)
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if starred:
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expr = ExprNodes.StarredUnpackingNode(pos, expr)
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return expr
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def p_cascaded_cmp(s):
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pos = s.position()
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op = p_cmp_op(s)
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n2 = p_starred_expr(s)
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result = ExprNodes.CascadedCmpNode(pos,
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operator = op, operand2 = n2)
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if s.sy in comparison_ops:
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result.cascade = p_cascaded_cmp(s)
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return result
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def p_cmp_op(s):
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if s.sy == 'not':
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s.next()
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s.expect('in')
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op = 'not_in'
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elif s.sy == 'is':
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s.next()
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if s.sy == 'not':
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s.next()
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op = 'is_not'
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else:
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op = 'is'
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else:
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op = s.sy
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s.next()
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if op == '<>':
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op = '!='
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return op
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comparison_ops = cython.declare(set, set([
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'<', '>', '==', '>=', '<=', '<>', '!=',
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'in', 'is', 'not'
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]))
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#expr: xor_expr ('|' xor_expr)*
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def p_bit_expr(s):
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return p_binop_expr(s, ('|',), p_xor_expr)
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#xor_expr: and_expr ('^' and_expr)*
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def p_xor_expr(s):
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return p_binop_expr(s, ('^',), p_and_expr)
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#and_expr: shift_expr ('&' shift_expr)*
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def p_and_expr(s):
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return p_binop_expr(s, ('&',), p_shift_expr)
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#shift_expr: arith_expr (('<<'|'>>') arith_expr)*
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def p_shift_expr(s):
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return p_binop_expr(s, ('<<', '>>'), p_arith_expr)
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#arith_expr: term (('+'|'-') term)*
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def p_arith_expr(s):
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return p_binop_expr(s, ('+', '-'), p_term)
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#term: factor (('*'|'@'|'/'|'%'|'//') factor)*
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def p_term(s):
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return p_binop_expr(s, ('*', '@', '/', '%', '//'), p_factor)
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#factor: ('+'|'-'|'~'|'&'|typecast|sizeof) factor | power
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def p_factor(s):
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# little indirection for C-ification purposes
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return _p_factor(s)
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def _p_factor(s):
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sy = s.sy
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if sy in ('+', '-', '~'):
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op = s.sy
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pos = s.position()
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s.next()
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return ExprNodes.unop_node(pos, op, p_factor(s))
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elif not s.in_python_file:
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if sy == '&':
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pos = s.position()
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s.next()
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arg = p_factor(s)
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return ExprNodes.AmpersandNode(pos, operand = arg)
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elif sy == "<":
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return p_typecast(s)
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elif sy == 'IDENT' and s.systring == "sizeof":
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return p_sizeof(s)
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return p_power(s)
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def p_typecast(s):
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# s.sy == "<"
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pos = s.position()
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s.next()
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base_type = p_c_base_type(s)
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is_memslice = isinstance(base_type, Nodes.MemoryViewSliceTypeNode)
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is_template = isinstance(base_type, Nodes.TemplatedTypeNode)
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is_const = isinstance(base_type, Nodes.CConstTypeNode)
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if (not is_memslice and not is_template and not is_const
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and base_type.name is None):
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s.error("Unknown type")
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declarator = p_c_declarator(s, empty = 1)
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if s.sy == '?':
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s.next()
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typecheck = 1
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else:
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typecheck = 0
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s.expect(">")
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operand = p_factor(s)
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if is_memslice:
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return ExprNodes.CythonArrayNode(pos, base_type_node=base_type,
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operand=operand)
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return ExprNodes.TypecastNode(pos,
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base_type = base_type,
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declarator = declarator,
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operand = operand,
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typecheck = typecheck)
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def p_sizeof(s):
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# s.sy == ident "sizeof"
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pos = s.position()
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s.next()
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s.expect('(')
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# Here we decide if we are looking at an expression or type
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# If it is actually a type, but parsable as an expression,
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# we treat it as an expression here.
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if looking_at_expr(s):
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operand = p_test(s)
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node = ExprNodes.SizeofVarNode(pos, operand = operand)
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else:
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base_type = p_c_base_type(s)
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declarator = p_c_declarator(s, empty = 1)
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node = ExprNodes.SizeofTypeNode(pos,
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base_type = base_type, declarator = declarator)
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s.expect(')')
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return node
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def p_yield_expression(s):
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# s.sy == "yield"
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pos = s.position()
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s.next()
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is_yield_from = False
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if s.sy == 'from':
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is_yield_from = True
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s.next()
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if s.sy != ')' and s.sy not in statement_terminators:
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# "yield from" does not support implicit tuples, but "yield" does ("yield 1,2")
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arg = p_test(s) if is_yield_from else p_testlist(s)
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else:
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if is_yield_from:
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s.error("'yield from' requires a source argument",
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pos=pos, fatal=False)
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arg = None
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if is_yield_from:
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return ExprNodes.YieldFromExprNode(pos, arg=arg)
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else:
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return ExprNodes.YieldExprNode(pos, arg=arg)
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def p_yield_statement(s):
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# s.sy == "yield"
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yield_expr = p_yield_expression(s)
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return Nodes.ExprStatNode(yield_expr.pos, expr=yield_expr)
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def p_async_statement(s, ctx, decorators):
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# s.sy >> 'async' ...
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if s.sy == 'def':
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# 'async def' statements aren't allowed in pxd files
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if 'pxd' in ctx.level:
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s.error('def statement not allowed here')
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s.level = ctx.level
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return p_def_statement(s, decorators, is_async_def=True)
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elif decorators:
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s.error("Decorators can only be followed by functions or classes")
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elif s.sy == 'for':
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return p_for_statement(s, is_async=True)
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elif s.sy == 'with':
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s.next()
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return p_with_items(s, is_async=True)
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else:
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s.error("expected one of 'def', 'for', 'with' after 'async'")
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#power: atom_expr ('**' factor)*
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#atom_expr: ['await'] atom trailer*
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def p_power(s):
|
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if s.systring == 'new' and s.peek()[0] == 'IDENT':
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return p_new_expr(s)
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await_pos = None
|
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if s.sy == 'await':
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await_pos = s.position()
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s.next()
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n1 = p_atom(s)
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while s.sy in ('(', '[', '.'):
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n1 = p_trailer(s, n1)
|
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if await_pos:
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n1 = ExprNodes.AwaitExprNode(await_pos, arg=n1)
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if s.sy == '**':
|
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pos = s.position()
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s.next()
|
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n2 = p_factor(s)
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n1 = ExprNodes.binop_node(pos, '**', n1, n2)
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return n1
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|
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def p_new_expr(s):
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# s.systring == 'new'.
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pos = s.position()
|
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s.next()
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cppclass = p_c_base_type(s)
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return p_call(s, ExprNodes.NewExprNode(pos, cppclass = cppclass))
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|
|
#trailer: '(' [arglist] ')' | '[' subscriptlist ']' | '.' NAME
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|
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def p_trailer(s, node1):
|
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pos = s.position()
|
|
if s.sy == '(':
|
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return p_call(s, node1)
|
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elif s.sy == '[':
|
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return p_index(s, node1)
|
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else: # s.sy == '.'
|
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s.next()
|
|
name = p_ident(s)
|
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return ExprNodes.AttributeNode(pos,
|
|
obj=node1, attribute=name)
|
|
|
|
|
|
# arglist: argument (',' argument)* [',']
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# argument: [test '='] test # Really [keyword '='] test
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|
|
|
# since PEP 448:
|
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# argument: ( test [comp_for] |
|
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# test '=' test |
|
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# '**' expr |
|
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# star_expr )
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|
|
|
def p_call_parse_args(s, allow_genexp=True):
|
|
# s.sy == '('
|
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pos = s.position()
|
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s.next()
|
|
positional_args = []
|
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keyword_args = []
|
|
starstar_seen = False
|
|
last_was_tuple_unpack = False
|
|
while s.sy != ')':
|
|
if s.sy == '*':
|
|
if starstar_seen:
|
|
s.error("Non-keyword arg following keyword arg", pos=s.position())
|
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s.next()
|
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positional_args.append(p_test(s))
|
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last_was_tuple_unpack = True
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elif s.sy == '**':
|
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s.next()
|
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keyword_args.append(p_test(s))
|
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starstar_seen = True
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else:
|
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arg = p_test(s)
|
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if s.sy == '=':
|
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s.next()
|
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if not arg.is_name:
|
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s.error("Expected an identifier before '='",
|
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pos=arg.pos)
|
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encoded_name = s.context.intern_ustring(arg.name)
|
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keyword = ExprNodes.IdentifierStringNode(
|
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arg.pos, value=encoded_name)
|
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arg = p_test(s)
|
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keyword_args.append((keyword, arg))
|
|
else:
|
|
if keyword_args:
|
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s.error("Non-keyword arg following keyword arg", pos=arg.pos)
|
|
if positional_args and not last_was_tuple_unpack:
|
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positional_args[-1].append(arg)
|
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else:
|
|
positional_args.append([arg])
|
|
last_was_tuple_unpack = False
|
|
if s.sy != ',':
|
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break
|
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s.next()
|
|
|
|
if s.sy in ('for', 'async'):
|
|
if not keyword_args and not last_was_tuple_unpack:
|
|
if len(positional_args) == 1 and len(positional_args[0]) == 1:
|
|
positional_args = [[p_genexp(s, positional_args[0][0])]]
|
|
s.expect(')')
|
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return positional_args or [[]], keyword_args
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|
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|
|
def p_call_build_packed_args(pos, positional_args, keyword_args):
|
|
keyword_dict = None
|
|
|
|
subtuples = [
|
|
ExprNodes.TupleNode(pos, args=arg) if isinstance(arg, list) else ExprNodes.AsTupleNode(pos, arg=arg)
|
|
for arg in positional_args
|
|
]
|
|
# TODO: implement a faster way to join tuples than creating each one and adding them
|
|
arg_tuple = reduce(partial(ExprNodes.binop_node, pos, '+'), subtuples)
|
|
|
|
if keyword_args:
|
|
kwargs = []
|
|
dict_items = []
|
|
for item in keyword_args:
|
|
if isinstance(item, tuple):
|
|
key, value = item
|
|
dict_items.append(ExprNodes.DictItemNode(pos=key.pos, key=key, value=value))
|
|
elif item.is_dict_literal:
|
|
# unpack "**{a:b}" directly
|
|
dict_items.extend(item.key_value_pairs)
|
|
else:
|
|
if dict_items:
|
|
kwargs.append(ExprNodes.DictNode(
|
|
dict_items[0].pos, key_value_pairs=dict_items, reject_duplicates=True))
|
|
dict_items = []
|
|
kwargs.append(item)
|
|
|
|
if dict_items:
|
|
kwargs.append(ExprNodes.DictNode(
|
|
dict_items[0].pos, key_value_pairs=dict_items, reject_duplicates=True))
|
|
|
|
if kwargs:
|
|
if len(kwargs) == 1 and kwargs[0].is_dict_literal:
|
|
# only simple keyword arguments found -> one dict
|
|
keyword_dict = kwargs[0]
|
|
else:
|
|
# at least one **kwargs
|
|
keyword_dict = ExprNodes.MergedDictNode(pos, keyword_args=kwargs)
|
|
|
|
return arg_tuple, keyword_dict
|
|
|
|
|
|
def p_call(s, function):
|
|
# s.sy == '('
|
|
pos = s.position()
|
|
positional_args, keyword_args = p_call_parse_args(s)
|
|
|
|
if not keyword_args and len(positional_args) == 1 and isinstance(positional_args[0], list):
|
|
return ExprNodes.SimpleCallNode(pos, function=function, args=positional_args[0])
|
|
else:
|
|
arg_tuple, keyword_dict = p_call_build_packed_args(pos, positional_args, keyword_args)
|
|
return ExprNodes.GeneralCallNode(
|
|
pos, function=function, positional_args=arg_tuple, keyword_args=keyword_dict)
|
|
|
|
|
|
#lambdef: 'lambda' [varargslist] ':' test
|
|
|
|
#subscriptlist: subscript (',' subscript)* [',']
|
|
|
|
def p_index(s, base):
|
|
# s.sy == '['
|
|
pos = s.position()
|
|
s.next()
|
|
subscripts, is_single_value = p_subscript_list(s)
|
|
if is_single_value and len(subscripts[0]) == 2:
|
|
start, stop = subscripts[0]
|
|
result = ExprNodes.SliceIndexNode(pos,
|
|
base = base, start = start, stop = stop)
|
|
else:
|
|
indexes = make_slice_nodes(pos, subscripts)
|
|
if is_single_value:
|
|
index = indexes[0]
|
|
else:
|
|
index = ExprNodes.TupleNode(pos, args = indexes)
|
|
result = ExprNodes.IndexNode(pos,
|
|
base = base, index = index)
|
|
s.expect(']')
|
|
return result
|
|
|
|
def p_subscript_list(s):
|
|
is_single_value = True
|
|
items = [p_subscript(s)]
|
|
while s.sy == ',':
|
|
is_single_value = False
|
|
s.next()
|
|
if s.sy == ']':
|
|
break
|
|
items.append(p_subscript(s))
|
|
return items, is_single_value
|
|
|
|
#subscript: '.' '.' '.' | test | [test] ':' [test] [':' [test]]
|
|
|
|
def p_subscript(s):
|
|
# Parse a subscript and return a list of
|
|
# 1, 2 or 3 ExprNodes, depending on how
|
|
# many slice elements were encountered.
|
|
pos = s.position()
|
|
start = p_slice_element(s, (':',))
|
|
if s.sy != ':':
|
|
return [start]
|
|
s.next()
|
|
stop = p_slice_element(s, (':', ',', ']'))
|
|
if s.sy != ':':
|
|
return [start, stop]
|
|
s.next()
|
|
step = p_slice_element(s, (':', ',', ']'))
|
|
return [start, stop, step]
|
|
|
|
def p_slice_element(s, follow_set):
|
|
# Simple expression which may be missing iff
|
|
# it is followed by something in follow_set.
|
|
if s.sy not in follow_set:
|
|
return p_test(s)
|
|
else:
|
|
return None
|
|
|
|
def expect_ellipsis(s):
|
|
s.expect('.')
|
|
s.expect('.')
|
|
s.expect('.')
|
|
|
|
def make_slice_nodes(pos, subscripts):
|
|
# Convert a list of subscripts as returned
|
|
# by p_subscript_list into a list of ExprNodes,
|
|
# creating SliceNodes for elements with 2 or
|
|
# more components.
|
|
result = []
|
|
for subscript in subscripts:
|
|
if len(subscript) == 1:
|
|
result.append(subscript[0])
|
|
else:
|
|
result.append(make_slice_node(pos, *subscript))
|
|
return result
|
|
|
|
def make_slice_node(pos, start, stop = None, step = None):
|
|
if not start:
|
|
start = ExprNodes.NoneNode(pos)
|
|
if not stop:
|
|
stop = ExprNodes.NoneNode(pos)
|
|
if not step:
|
|
step = ExprNodes.NoneNode(pos)
|
|
return ExprNodes.SliceNode(pos,
|
|
start = start, stop = stop, step = step)
|
|
|
|
#atom: '(' [yield_expr|testlist_comp] ')' | '[' [listmaker] ']' | '{' [dict_or_set_maker] '}' | '`' testlist '`' | NAME | NUMBER | STRING+
|
|
|
|
def p_atom(s):
|
|
pos = s.position()
|
|
sy = s.sy
|
|
if sy == '(':
|
|
s.next()
|
|
if s.sy == ')':
|
|
result = ExprNodes.TupleNode(pos, args = [])
|
|
elif s.sy == 'yield':
|
|
result = p_yield_expression(s)
|
|
else:
|
|
result = p_testlist_comp(s)
|
|
s.expect(')')
|
|
return result
|
|
elif sy == '[':
|
|
return p_list_maker(s)
|
|
elif sy == '{':
|
|
return p_dict_or_set_maker(s)
|
|
elif sy == '`':
|
|
return p_backquote_expr(s)
|
|
elif sy == '.':
|
|
expect_ellipsis(s)
|
|
return ExprNodes.EllipsisNode(pos)
|
|
elif sy == 'INT':
|
|
return p_int_literal(s)
|
|
elif sy == 'FLOAT':
|
|
value = s.systring
|
|
s.next()
|
|
return ExprNodes.FloatNode(pos, value = value)
|
|
elif sy == 'IMAG':
|
|
value = s.systring[:-1]
|
|
s.next()
|
|
return ExprNodes.ImagNode(pos, value = value)
|
|
elif sy == 'BEGIN_STRING':
|
|
kind, bytes_value, unicode_value = p_cat_string_literal(s)
|
|
if kind == 'c':
|
|
return ExprNodes.CharNode(pos, value = bytes_value)
|
|
elif kind == 'u':
|
|
return ExprNodes.UnicodeNode(pos, value = unicode_value, bytes_value = bytes_value)
|
|
elif kind == 'b':
|
|
return ExprNodes.BytesNode(pos, value = bytes_value)
|
|
elif kind == 'f':
|
|
return ExprNodes.JoinedStrNode(pos, values = unicode_value)
|
|
elif kind == '':
|
|
return ExprNodes.StringNode(pos, value = bytes_value, unicode_value = unicode_value)
|
|
else:
|
|
s.error("invalid string kind '%s'" % kind)
|
|
elif sy == 'IDENT':
|
|
name = s.systring
|
|
if name == "None":
|
|
result = ExprNodes.NoneNode(pos)
|
|
elif name == "True":
|
|
result = ExprNodes.BoolNode(pos, value=True)
|
|
elif name == "False":
|
|
result = ExprNodes.BoolNode(pos, value=False)
|
|
elif name == "NULL" and not s.in_python_file:
|
|
result = ExprNodes.NullNode(pos)
|
|
else:
|
|
result = p_name(s, name)
|
|
s.next()
|
|
return result
|
|
else:
|
|
s.error("Expected an identifier or literal")
|
|
|
|
def p_int_literal(s):
|
|
pos = s.position()
|
|
value = s.systring
|
|
s.next()
|
|
unsigned = ""
|
|
longness = ""
|
|
while value[-1] in u"UuLl":
|
|
if value[-1] in u"Ll":
|
|
longness += "L"
|
|
else:
|
|
unsigned += "U"
|
|
value = value[:-1]
|
|
# '3L' is ambiguous in Py2 but not in Py3. '3U' and '3LL' are
|
|
# illegal in Py2 Python files. All suffixes are illegal in Py3
|
|
# Python files.
|
|
is_c_literal = None
|
|
if unsigned:
|
|
is_c_literal = True
|
|
elif longness:
|
|
if longness == 'LL' or s.context.language_level >= 3:
|
|
is_c_literal = True
|
|
if s.in_python_file:
|
|
if is_c_literal:
|
|
error(pos, "illegal integer literal syntax in Python source file")
|
|
is_c_literal = False
|
|
return ExprNodes.IntNode(pos,
|
|
is_c_literal = is_c_literal,
|
|
value = value,
|
|
unsigned = unsigned,
|
|
longness = longness)
|
|
|
|
|
|
def p_name(s, name):
|
|
pos = s.position()
|
|
if not s.compile_time_expr and name in s.compile_time_env:
|
|
value = s.compile_time_env.lookup_here(name)
|
|
node = wrap_compile_time_constant(pos, value)
|
|
if node is not None:
|
|
return node
|
|
return ExprNodes.NameNode(pos, name=name)
|
|
|
|
|
|
def wrap_compile_time_constant(pos, value):
|
|
rep = repr(value)
|
|
if value is None:
|
|
return ExprNodes.NoneNode(pos)
|
|
elif value is Ellipsis:
|
|
return ExprNodes.EllipsisNode(pos)
|
|
elif isinstance(value, bool):
|
|
return ExprNodes.BoolNode(pos, value=value)
|
|
elif isinstance(value, int):
|
|
return ExprNodes.IntNode(pos, value=rep, constant_result=value)
|
|
elif isinstance(value, float):
|
|
return ExprNodes.FloatNode(pos, value=rep, constant_result=value)
|
|
elif isinstance(value, complex):
|
|
node = ExprNodes.ImagNode(pos, value=repr(value.imag), constant_result=complex(0.0, value.imag))
|
|
if value.real:
|
|
# FIXME: should we care about -0.0 ?
|
|
# probably not worth using the '-' operator for negative imag values
|
|
node = ExprNodes.binop_node(
|
|
pos, '+', ExprNodes.FloatNode(pos, value=repr(value.real), constant_result=value.real), node,
|
|
constant_result=value)
|
|
return node
|
|
elif isinstance(value, _unicode):
|
|
return ExprNodes.UnicodeNode(pos, value=EncodedString(value))
|
|
elif isinstance(value, _bytes):
|
|
bvalue = bytes_literal(value, 'ascii') # actually: unknown encoding, but BytesLiteral requires one
|
|
return ExprNodes.BytesNode(pos, value=bvalue, constant_result=value)
|
|
elif isinstance(value, tuple):
|
|
args = [wrap_compile_time_constant(pos, arg)
|
|
for arg in value]
|
|
if None not in args:
|
|
return ExprNodes.TupleNode(pos, args=args)
|
|
else:
|
|
# error already reported
|
|
return None
|
|
elif not _IS_PY3 and isinstance(value, long):
|
|
return ExprNodes.IntNode(pos, value=rep.rstrip('L'), constant_result=value)
|
|
error(pos, "Invalid type for compile-time constant: %r (type %s)"
|
|
% (value, value.__class__.__name__))
|
|
return None
|
|
|
|
|
|
def p_cat_string_literal(s):
|
|
# A sequence of one or more adjacent string literals.
|
|
# Returns (kind, bytes_value, unicode_value)
|
|
# where kind in ('b', 'c', 'u', 'f', '')
|
|
pos = s.position()
|
|
kind, bytes_value, unicode_value = p_string_literal(s)
|
|
if kind == 'c' or s.sy != 'BEGIN_STRING':
|
|
return kind, bytes_value, unicode_value
|
|
bstrings, ustrings, positions = [bytes_value], [unicode_value], [pos]
|
|
bytes_value = unicode_value = None
|
|
while s.sy == 'BEGIN_STRING':
|
|
pos = s.position()
|
|
next_kind, next_bytes_value, next_unicode_value = p_string_literal(s)
|
|
if next_kind == 'c':
|
|
error(pos, "Cannot concatenate char literal with another string or char literal")
|
|
continue
|
|
elif next_kind != kind:
|
|
# concatenating f strings and normal strings is allowed and leads to an f string
|
|
if set([kind, next_kind]) in (set(['f', 'u']), set(['f', ''])):
|
|
kind = 'f'
|
|
else:
|
|
error(pos, "Cannot mix string literals of different types, expected %s'', got %s''" % (
|
|
kind, next_kind))
|
|
continue
|
|
bstrings.append(next_bytes_value)
|
|
ustrings.append(next_unicode_value)
|
|
positions.append(pos)
|
|
# join and rewrap the partial literals
|
|
if kind in ('b', 'c', '') or kind == 'u' and None not in bstrings:
|
|
# Py3 enforced unicode literals are parsed as bytes/unicode combination
|
|
bytes_value = bytes_literal(StringEncoding.join_bytes(bstrings), s.source_encoding)
|
|
if kind in ('u', ''):
|
|
unicode_value = EncodedString(u''.join([u for u in ustrings if u is not None]))
|
|
if kind == 'f':
|
|
unicode_value = []
|
|
for u, pos in zip(ustrings, positions):
|
|
if isinstance(u, list):
|
|
unicode_value += u
|
|
else:
|
|
# non-f-string concatenated into the f-string
|
|
unicode_value.append(ExprNodes.UnicodeNode(pos, value=EncodedString(u)))
|
|
return kind, bytes_value, unicode_value
|
|
|
|
|
|
def p_opt_string_literal(s, required_type='u'):
|
|
if s.sy != 'BEGIN_STRING':
|
|
return None
|
|
pos = s.position()
|
|
kind, bytes_value, unicode_value = p_string_literal(s, required_type)
|
|
if required_type == 'u':
|
|
if kind == 'f':
|
|
s.error("f-string not allowed here", pos)
|
|
return unicode_value
|
|
elif required_type == 'b':
|
|
return bytes_value
|
|
else:
|
|
s.error("internal parser configuration error")
|
|
|
|
|
|
def check_for_non_ascii_characters(string):
|
|
for c in string:
|
|
if c >= u'\x80':
|
|
return True
|
|
return False
|
|
|
|
|
|
def p_string_literal(s, kind_override=None):
|
|
# A single string or char literal. Returns (kind, bvalue, uvalue)
|
|
# where kind in ('b', 'c', 'u', 'f', ''). The 'bvalue' is the source
|
|
# code byte sequence of the string literal, 'uvalue' is the
|
|
# decoded Unicode string. Either of the two may be None depending
|
|
# on the 'kind' of string, only unprefixed strings have both
|
|
# representations. In f-strings, the uvalue is a list of the Unicode
|
|
# strings and f-string expressions that make up the f-string.
|
|
|
|
# s.sy == 'BEGIN_STRING'
|
|
pos = s.position()
|
|
is_python3_source = s.context.language_level >= 3
|
|
has_non_ascii_literal_characters = False
|
|
string_start_pos = (pos[0], pos[1], pos[2] + len(s.systring))
|
|
kind_string = s.systring.rstrip('"\'').lower()
|
|
if len(kind_string) > 1:
|
|
if len(set(kind_string)) != len(kind_string):
|
|
error(pos, 'Duplicate string prefix character')
|
|
if 'b' in kind_string and 'u' in kind_string:
|
|
error(pos, 'String prefixes b and u cannot be combined')
|
|
if 'b' in kind_string and 'f' in kind_string:
|
|
error(pos, 'String prefixes b and f cannot be combined')
|
|
if 'u' in kind_string and 'f' in kind_string:
|
|
error(pos, 'String prefixes u and f cannot be combined')
|
|
|
|
is_raw = 'r' in kind_string
|
|
|
|
if 'c' in kind_string:
|
|
# this should never happen, since the lexer does not allow combining c
|
|
# with other prefix characters
|
|
if len(kind_string) != 1:
|
|
error(pos, 'Invalid string prefix for character literal')
|
|
kind = 'c'
|
|
elif 'f' in kind_string:
|
|
kind = 'f' # u is ignored
|
|
is_raw = True # postpone the escape resolution
|
|
elif 'b' in kind_string:
|
|
kind = 'b'
|
|
elif 'u' in kind_string:
|
|
kind = 'u'
|
|
else:
|
|
kind = ''
|
|
|
|
if kind == '' and kind_override is None and Future.unicode_literals in s.context.future_directives:
|
|
chars = StringEncoding.StrLiteralBuilder(s.source_encoding)
|
|
kind = 'u'
|
|
else:
|
|
if kind_override is not None and kind_override in 'ub':
|
|
kind = kind_override
|
|
if kind in ('u', 'f'): # f-strings are scanned exactly like Unicode literals, but are parsed further later
|
|
chars = StringEncoding.UnicodeLiteralBuilder()
|
|
elif kind == '':
|
|
chars = StringEncoding.StrLiteralBuilder(s.source_encoding)
|
|
else:
|
|
chars = StringEncoding.BytesLiteralBuilder(s.source_encoding)
|
|
|
|
while 1:
|
|
s.next()
|
|
sy = s.sy
|
|
systr = s.systring
|
|
# print "p_string_literal: sy =", sy, repr(s.systring) ###
|
|
if sy == 'CHARS':
|
|
chars.append(systr)
|
|
if is_python3_source and not has_non_ascii_literal_characters and check_for_non_ascii_characters(systr):
|
|
has_non_ascii_literal_characters = True
|
|
elif sy == 'ESCAPE':
|
|
# in Py2, 'ur' raw unicode strings resolve unicode escapes but nothing else
|
|
if is_raw and (is_python3_source or kind != 'u' or systr[1] not in u'Uu'):
|
|
chars.append(systr)
|
|
if is_python3_source and not has_non_ascii_literal_characters and check_for_non_ascii_characters(systr):
|
|
has_non_ascii_literal_characters = True
|
|
else:
|
|
_append_escape_sequence(kind, chars, systr, s)
|
|
elif sy == 'NEWLINE':
|
|
chars.append(u'\n')
|
|
elif sy == 'END_STRING':
|
|
break
|
|
elif sy == 'EOF':
|
|
s.error("Unclosed string literal", pos=pos)
|
|
else:
|
|
s.error("Unexpected token %r:%r in string literal" % (
|
|
sy, s.systring))
|
|
|
|
if kind == 'c':
|
|
unicode_value = None
|
|
bytes_value = chars.getchar()
|
|
if len(bytes_value) != 1:
|
|
error(pos, u"invalid character literal: %r" % bytes_value)
|
|
else:
|
|
bytes_value, unicode_value = chars.getstrings()
|
|
if (has_non_ascii_literal_characters
|
|
and is_python3_source and Future.unicode_literals in s.context.future_directives):
|
|
# Python 3 forbids literal non-ASCII characters in byte strings
|
|
if kind == 'b':
|
|
s.error("bytes can only contain ASCII literal characters.", pos=pos)
|
|
bytes_value = None
|
|
if kind == 'f':
|
|
unicode_value = p_f_string(s, unicode_value, string_start_pos, is_raw='r' in kind_string)
|
|
s.next()
|
|
return (kind, bytes_value, unicode_value)
|
|
|
|
|
|
def _append_escape_sequence(kind, builder, escape_sequence, s):
|
|
c = escape_sequence[1]
|
|
if c in u"01234567":
|
|
builder.append_charval(int(escape_sequence[1:], 8))
|
|
elif c in u"'\"\\":
|
|
builder.append(c)
|
|
elif c in u"abfnrtv":
|
|
builder.append(StringEncoding.char_from_escape_sequence(escape_sequence))
|
|
elif c == u'\n':
|
|
pass # line continuation
|
|
elif c == u'x': # \xXX
|
|
if len(escape_sequence) == 4:
|
|
builder.append_charval(int(escape_sequence[2:], 16))
|
|
else:
|
|
s.error("Invalid hex escape '%s'" % escape_sequence, fatal=False)
|
|
elif c in u'NUu' and kind in ('u', 'f', ''): # \uxxxx, \Uxxxxxxxx, \N{...}
|
|
chrval = -1
|
|
if c == u'N':
|
|
uchar = None
|
|
try:
|
|
uchar = lookup_unicodechar(escape_sequence[3:-1])
|
|
chrval = ord(uchar)
|
|
except KeyError:
|
|
s.error("Unknown Unicode character name %s" %
|
|
repr(escape_sequence[3:-1]).lstrip('u'), fatal=False)
|
|
except TypeError:
|
|
# 2-byte unicode build of CPython?
|
|
if (uchar is not None and _IS_2BYTE_UNICODE and len(uchar) == 2 and
|
|
unicode_category(uchar[0]) == 'Cs' and unicode_category(uchar[1]) == 'Cs'):
|
|
# surrogate pair instead of single character
|
|
chrval = 0x10000 + (ord(uchar[0]) - 0xd800) >> 10 + (ord(uchar[1]) - 0xdc00)
|
|
else:
|
|
raise
|
|
elif len(escape_sequence) in (6, 10):
|
|
chrval = int(escape_sequence[2:], 16)
|
|
if chrval > 1114111: # sys.maxunicode:
|
|
s.error("Invalid unicode escape '%s'" % escape_sequence)
|
|
chrval = -1
|
|
else:
|
|
s.error("Invalid unicode escape '%s'" % escape_sequence, fatal=False)
|
|
if chrval >= 0:
|
|
builder.append_uescape(chrval, escape_sequence)
|
|
else:
|
|
builder.append(escape_sequence)
|
|
|
|
|
|
_parse_escape_sequences_raw, _parse_escape_sequences = [re.compile((
|
|
# escape sequences:
|
|
br'(\\(?:' +
|
|
(br'\\?' if is_raw else (
|
|
br'[\\abfnrtv"\'{]|'
|
|
br'[0-7]{2,3}|'
|
|
br'N\{[^}]*\}|'
|
|
br'x[0-9a-fA-F]{2}|'
|
|
br'u[0-9a-fA-F]{4}|'
|
|
br'U[0-9a-fA-F]{8}|'
|
|
br'[NxuU]|' # detect invalid escape sequences that do not match above
|
|
)) +
|
|
br')?|'
|
|
# non-escape sequences:
|
|
br'\{\{?|'
|
|
br'\}\}?|'
|
|
br'[^\\{}]+)'
|
|
).decode('us-ascii')).match
|
|
for is_raw in (True, False)]
|
|
|
|
|
|
def _f_string_error_pos(pos, string, i):
|
|
return (pos[0], pos[1], pos[2] + i + 1) # FIXME: handle newlines in string
|
|
|
|
|
|
def p_f_string(s, unicode_value, pos, is_raw):
|
|
# Parses a PEP 498 f-string literal into a list of nodes. Nodes are either UnicodeNodes
|
|
# or FormattedValueNodes.
|
|
values = []
|
|
next_start = 0
|
|
size = len(unicode_value)
|
|
builder = StringEncoding.UnicodeLiteralBuilder()
|
|
_parse_seq = _parse_escape_sequences_raw if is_raw else _parse_escape_sequences
|
|
|
|
while next_start < size:
|
|
end = next_start
|
|
match = _parse_seq(unicode_value, next_start)
|
|
if match is None:
|
|
error(_f_string_error_pos(pos, unicode_value, next_start), "Invalid escape sequence")
|
|
|
|
next_start = match.end()
|
|
part = match.group()
|
|
c = part[0]
|
|
if c == '\\':
|
|
if not is_raw and len(part) > 1:
|
|
_append_escape_sequence('f', builder, part, s)
|
|
else:
|
|
builder.append(part)
|
|
elif c == '{':
|
|
if part == '{{':
|
|
builder.append('{')
|
|
else:
|
|
# start of an expression
|
|
if builder.chars:
|
|
values.append(ExprNodes.UnicodeNode(pos, value=builder.getstring()))
|
|
builder = StringEncoding.UnicodeLiteralBuilder()
|
|
next_start, expr_node = p_f_string_expr(s, unicode_value, pos, next_start, is_raw)
|
|
values.append(expr_node)
|
|
elif c == '}':
|
|
if part == '}}':
|
|
builder.append('}')
|
|
else:
|
|
error(_f_string_error_pos(pos, unicode_value, end),
|
|
"f-string: single '}' is not allowed")
|
|
else:
|
|
builder.append(part)
|
|
|
|
if builder.chars:
|
|
values.append(ExprNodes.UnicodeNode(pos, value=builder.getstring()))
|
|
return values
|
|
|
|
|
|
def p_f_string_expr(s, unicode_value, pos, starting_index, is_raw):
|
|
# Parses a {}-delimited expression inside an f-string. Returns a FormattedValueNode
|
|
# and the index in the string that follows the expression.
|
|
i = starting_index
|
|
size = len(unicode_value)
|
|
conversion_char = terminal_char = format_spec = None
|
|
format_spec_str = None
|
|
NO_CHAR = 2**30
|
|
|
|
nested_depth = 0
|
|
quote_char = NO_CHAR
|
|
in_triple_quotes = False
|
|
backslash_reported = False
|
|
|
|
while True:
|
|
if i >= size:
|
|
break # error will be reported below
|
|
c = unicode_value[i]
|
|
|
|
if quote_char != NO_CHAR:
|
|
if c == '\\':
|
|
# avoid redundant error reports along '\' sequences
|
|
if not backslash_reported:
|
|
error(_f_string_error_pos(pos, unicode_value, i),
|
|
"backslashes not allowed in f-strings")
|
|
backslash_reported = True
|
|
elif c == quote_char:
|
|
if in_triple_quotes:
|
|
if i + 2 < size and unicode_value[i + 1] == c and unicode_value[i + 2] == c:
|
|
in_triple_quotes = False
|
|
quote_char = NO_CHAR
|
|
i += 2
|
|
else:
|
|
quote_char = NO_CHAR
|
|
elif c in '\'"':
|
|
quote_char = c
|
|
if i + 2 < size and unicode_value[i + 1] == c and unicode_value[i + 2] == c:
|
|
in_triple_quotes = True
|
|
i += 2
|
|
elif c in '{[(':
|
|
nested_depth += 1
|
|
elif nested_depth != 0 and c in '}])':
|
|
nested_depth -= 1
|
|
elif c == '#':
|
|
error(_f_string_error_pos(pos, unicode_value, i),
|
|
"format string cannot include #")
|
|
elif nested_depth == 0 and c in '!:}':
|
|
# allow != as a special case
|
|
if c == '!' and i + 1 < size and unicode_value[i + 1] == '=':
|
|
i += 1
|
|
continue
|
|
|
|
terminal_char = c
|
|
break
|
|
i += 1
|
|
|
|
# normalise line endings as the parser expects that
|
|
expr_str = unicode_value[starting_index:i].replace('\r\n', '\n').replace('\r', '\n')
|
|
expr_pos = (pos[0], pos[1], pos[2] + starting_index + 2) # TODO: find exact code position (concat, multi-line, ...)
|
|
|
|
if not expr_str.strip():
|
|
error(_f_string_error_pos(pos, unicode_value, starting_index),
|
|
"empty expression not allowed in f-string")
|
|
|
|
if terminal_char == '!':
|
|
i += 1
|
|
if i + 2 > size:
|
|
pass # error will be reported below
|
|
else:
|
|
conversion_char = unicode_value[i]
|
|
i += 1
|
|
terminal_char = unicode_value[i]
|
|
|
|
if terminal_char == ':':
|
|
in_triple_quotes = False
|
|
in_string = False
|
|
nested_depth = 0
|
|
start_format_spec = i + 1
|
|
while True:
|
|
if i >= size:
|
|
break # error will be reported below
|
|
c = unicode_value[i]
|
|
if not in_triple_quotes and not in_string:
|
|
if c == '{':
|
|
nested_depth += 1
|
|
elif c == '}':
|
|
if nested_depth > 0:
|
|
nested_depth -= 1
|
|
else:
|
|
terminal_char = c
|
|
break
|
|
if c in '\'"':
|
|
if not in_string and i + 2 < size and unicode_value[i + 1] == c and unicode_value[i + 2] == c:
|
|
in_triple_quotes = not in_triple_quotes
|
|
i += 2
|
|
elif not in_triple_quotes:
|
|
in_string = not in_string
|
|
i += 1
|
|
|
|
format_spec_str = unicode_value[start_format_spec:i]
|
|
|
|
if terminal_char != '}':
|
|
error(_f_string_error_pos(pos, unicode_value, i),
|
|
"missing '}' in format string expression" + (
|
|
", found '%s'" % terminal_char if terminal_char else ""))
|
|
|
|
# parse the expression as if it was surrounded by parentheses
|
|
buf = StringIO('(%s)' % expr_str)
|
|
scanner = PyrexScanner(buf, expr_pos[0], parent_scanner=s, source_encoding=s.source_encoding, initial_pos=expr_pos)
|
|
expr = p_testlist(scanner) # TODO is testlist right here?
|
|
|
|
# validate the conversion char
|
|
if conversion_char is not None and not ExprNodes.FormattedValueNode.find_conversion_func(conversion_char):
|
|
error(expr_pos, "invalid conversion character '%s'" % conversion_char)
|
|
|
|
# the format spec is itself treated like an f-string
|
|
if format_spec_str:
|
|
format_spec = ExprNodes.JoinedStrNode(pos, values=p_f_string(s, format_spec_str, pos, is_raw))
|
|
|
|
return i + 1, ExprNodes.FormattedValueNode(
|
|
pos, value=expr, conversion_char=conversion_char, format_spec=format_spec)
|
|
|
|
|
|
# since PEP 448:
|
|
# list_display ::= "[" [listmaker] "]"
|
|
# listmaker ::= (test|star_expr) ( comp_for | (',' (test|star_expr))* [','] )
|
|
# comp_iter ::= comp_for | comp_if
|
|
# comp_for ::= ["async"] "for" expression_list "in" testlist [comp_iter]
|
|
# comp_if ::= "if" test [comp_iter]
|
|
|
|
def p_list_maker(s):
|
|
# s.sy == '['
|
|
pos = s.position()
|
|
s.next()
|
|
if s.sy == ']':
|
|
s.expect(']')
|
|
return ExprNodes.ListNode(pos, args=[])
|
|
|
|
expr = p_test_or_starred_expr(s)
|
|
if s.sy in ('for', 'async'):
|
|
if expr.is_starred:
|
|
s.error("iterable unpacking cannot be used in comprehension")
|
|
append = ExprNodes.ComprehensionAppendNode(pos, expr=expr)
|
|
loop = p_comp_for(s, append)
|
|
s.expect(']')
|
|
return ExprNodes.ComprehensionNode(
|
|
pos, loop=loop, append=append, type=Builtin.list_type,
|
|
# list comprehensions leak their loop variable in Py2
|
|
has_local_scope=s.context.language_level >= 3)
|
|
|
|
# (merged) list literal
|
|
if s.sy == ',':
|
|
s.next()
|
|
exprs = p_test_or_starred_expr_list(s, expr)
|
|
else:
|
|
exprs = [expr]
|
|
s.expect(']')
|
|
return ExprNodes.ListNode(pos, args=exprs)
|
|
|
|
|
|
def p_comp_iter(s, body):
|
|
if s.sy in ('for', 'async'):
|
|
return p_comp_for(s, body)
|
|
elif s.sy == 'if':
|
|
return p_comp_if(s, body)
|
|
else:
|
|
# insert the 'append' operation into the loop
|
|
return body
|
|
|
|
def p_comp_for(s, body):
|
|
pos = s.position()
|
|
# [async] for ...
|
|
is_async = False
|
|
if s.sy == 'async':
|
|
is_async = True
|
|
s.next()
|
|
|
|
# s.sy == 'for'
|
|
s.expect('for')
|
|
kw = p_for_bounds(s, allow_testlist=False, is_async=is_async)
|
|
kw.update(else_clause=None, body=p_comp_iter(s, body), is_async=is_async)
|
|
return Nodes.ForStatNode(pos, **kw)
|
|
|
|
def p_comp_if(s, body):
|
|
# s.sy == 'if'
|
|
pos = s.position()
|
|
s.next()
|
|
test = p_test_nocond(s)
|
|
return Nodes.IfStatNode(pos,
|
|
if_clauses = [Nodes.IfClauseNode(pos, condition = test,
|
|
body = p_comp_iter(s, body))],
|
|
else_clause = None )
|
|
|
|
|
|
# since PEP 448:
|
|
#dictorsetmaker: ( ((test ':' test | '**' expr)
|
|
# (comp_for | (',' (test ':' test | '**' expr))* [','])) |
|
|
# ((test | star_expr)
|
|
# (comp_for | (',' (test | star_expr))* [','])) )
|
|
|
|
def p_dict_or_set_maker(s):
|
|
# s.sy == '{'
|
|
pos = s.position()
|
|
s.next()
|
|
if s.sy == '}':
|
|
s.next()
|
|
return ExprNodes.DictNode(pos, key_value_pairs=[])
|
|
|
|
parts = []
|
|
target_type = 0
|
|
last_was_simple_item = False
|
|
while True:
|
|
if s.sy in ('*', '**'):
|
|
# merged set/dict literal
|
|
if target_type == 0:
|
|
target_type = 1 if s.sy == '*' else 2 # 'stars'
|
|
elif target_type != len(s.sy):
|
|
s.error("unexpected %sitem found in %s literal" % (
|
|
s.sy, 'set' if target_type == 1 else 'dict'))
|
|
s.next()
|
|
if s.sy == '*':
|
|
s.error("expected expression, found '*'")
|
|
item = p_starred_expr(s)
|
|
parts.append(item)
|
|
last_was_simple_item = False
|
|
else:
|
|
item = p_test(s)
|
|
if target_type == 0:
|
|
target_type = 2 if s.sy == ':' else 1 # dict vs. set
|
|
if target_type == 2:
|
|
# dict literal
|
|
s.expect(':')
|
|
key = item
|
|
value = p_test(s)
|
|
item = ExprNodes.DictItemNode(key.pos, key=key, value=value)
|
|
if last_was_simple_item:
|
|
parts[-1].append(item)
|
|
else:
|
|
parts.append([item])
|
|
last_was_simple_item = True
|
|
|
|
if s.sy == ',':
|
|
s.next()
|
|
if s.sy == '}':
|
|
break
|
|
else:
|
|
break
|
|
|
|
if s.sy in ('for', 'async'):
|
|
# dict/set comprehension
|
|
if len(parts) == 1 and isinstance(parts[0], list) and len(parts[0]) == 1:
|
|
item = parts[0][0]
|
|
if target_type == 2:
|
|
assert isinstance(item, ExprNodes.DictItemNode), type(item)
|
|
comprehension_type = Builtin.dict_type
|
|
append = ExprNodes.DictComprehensionAppendNode(
|
|
item.pos, key_expr=item.key, value_expr=item.value)
|
|
else:
|
|
comprehension_type = Builtin.set_type
|
|
append = ExprNodes.ComprehensionAppendNode(item.pos, expr=item)
|
|
loop = p_comp_for(s, append)
|
|
s.expect('}')
|
|
return ExprNodes.ComprehensionNode(pos, loop=loop, append=append, type=comprehension_type)
|
|
else:
|
|
# syntax error, try to find a good error message
|
|
if len(parts) == 1 and not isinstance(parts[0], list):
|
|
s.error("iterable unpacking cannot be used in comprehension")
|
|
else:
|
|
# e.g. "{1,2,3 for ..."
|
|
s.expect('}')
|
|
return ExprNodes.DictNode(pos, key_value_pairs=[])
|
|
|
|
s.expect('}')
|
|
if target_type == 1:
|
|
# (merged) set literal
|
|
items = []
|
|
set_items = []
|
|
for part in parts:
|
|
if isinstance(part, list):
|
|
set_items.extend(part)
|
|
else:
|
|
if set_items:
|
|
items.append(ExprNodes.SetNode(set_items[0].pos, args=set_items))
|
|
set_items = []
|
|
items.append(part)
|
|
if set_items:
|
|
items.append(ExprNodes.SetNode(set_items[0].pos, args=set_items))
|
|
if len(items) == 1 and items[0].is_set_literal:
|
|
return items[0]
|
|
return ExprNodes.MergedSequenceNode(pos, args=items, type=Builtin.set_type)
|
|
else:
|
|
# (merged) dict literal
|
|
items = []
|
|
dict_items = []
|
|
for part in parts:
|
|
if isinstance(part, list):
|
|
dict_items.extend(part)
|
|
else:
|
|
if dict_items:
|
|
items.append(ExprNodes.DictNode(dict_items[0].pos, key_value_pairs=dict_items))
|
|
dict_items = []
|
|
items.append(part)
|
|
if dict_items:
|
|
items.append(ExprNodes.DictNode(dict_items[0].pos, key_value_pairs=dict_items))
|
|
if len(items) == 1 and items[0].is_dict_literal:
|
|
return items[0]
|
|
return ExprNodes.MergedDictNode(pos, keyword_args=items, reject_duplicates=False)
|
|
|
|
|
|
# NOTE: no longer in Py3 :)
|
|
def p_backquote_expr(s):
|
|
# s.sy == '`'
|
|
pos = s.position()
|
|
s.next()
|
|
args = [p_test(s)]
|
|
while s.sy == ',':
|
|
s.next()
|
|
args.append(p_test(s))
|
|
s.expect('`')
|
|
if len(args) == 1:
|
|
arg = args[0]
|
|
else:
|
|
arg = ExprNodes.TupleNode(pos, args = args)
|
|
return ExprNodes.BackquoteNode(pos, arg = arg)
|
|
|
|
def p_simple_expr_list(s, expr=None):
|
|
exprs = expr is not None and [expr] or []
|
|
while s.sy not in expr_terminators:
|
|
exprs.append( p_test(s) )
|
|
if s.sy != ',':
|
|
break
|
|
s.next()
|
|
return exprs
|
|
|
|
|
|
def p_test_or_starred_expr_list(s, expr=None):
|
|
exprs = expr is not None and [expr] or []
|
|
while s.sy not in expr_terminators:
|
|
exprs.append(p_test_or_starred_expr(s))
|
|
if s.sy != ',':
|
|
break
|
|
s.next()
|
|
return exprs
|
|
|
|
|
|
#testlist: test (',' test)* [',']
|
|
|
|
def p_testlist(s):
|
|
pos = s.position()
|
|
expr = p_test(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
exprs = p_simple_expr_list(s, expr)
|
|
return ExprNodes.TupleNode(pos, args = exprs)
|
|
else:
|
|
return expr
|
|
|
|
# testlist_star_expr: (test|star_expr) ( comp_for | (',' (test|star_expr))* [','] )
|
|
|
|
def p_testlist_star_expr(s):
|
|
pos = s.position()
|
|
expr = p_test_or_starred_expr(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
exprs = p_test_or_starred_expr_list(s, expr)
|
|
return ExprNodes.TupleNode(pos, args = exprs)
|
|
else:
|
|
return expr
|
|
|
|
# testlist_comp: (test|star_expr) ( comp_for | (',' (test|star_expr))* [','] )
|
|
|
|
def p_testlist_comp(s):
|
|
pos = s.position()
|
|
expr = p_test_or_starred_expr(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
exprs = p_test_or_starred_expr_list(s, expr)
|
|
return ExprNodes.TupleNode(pos, args = exprs)
|
|
elif s.sy in ('for', 'async'):
|
|
return p_genexp(s, expr)
|
|
else:
|
|
return expr
|
|
|
|
def p_genexp(s, expr):
|
|
# s.sy == 'async' | 'for'
|
|
loop = p_comp_for(s, Nodes.ExprStatNode(
|
|
expr.pos, expr = ExprNodes.YieldExprNode(expr.pos, arg=expr)))
|
|
return ExprNodes.GeneratorExpressionNode(expr.pos, loop=loop)
|
|
|
|
expr_terminators = cython.declare(set, set([
|
|
')', ']', '}', ':', '=', 'NEWLINE']))
|
|
|
|
|
|
#-------------------------------------------------------
|
|
#
|
|
# Statements
|
|
#
|
|
#-------------------------------------------------------
|
|
|
|
def p_global_statement(s):
|
|
# assume s.sy == 'global'
|
|
pos = s.position()
|
|
s.next()
|
|
names = p_ident_list(s)
|
|
return Nodes.GlobalNode(pos, names = names)
|
|
|
|
|
|
def p_nonlocal_statement(s):
|
|
pos = s.position()
|
|
s.next()
|
|
names = p_ident_list(s)
|
|
return Nodes.NonlocalNode(pos, names = names)
|
|
|
|
|
|
def p_expression_or_assignment(s):
|
|
expr = p_testlist_star_expr(s)
|
|
if s.sy == ':' and (expr.is_name or expr.is_subscript or expr.is_attribute):
|
|
s.next()
|
|
expr.annotation = p_test(s)
|
|
if s.sy == '=' and expr.is_starred:
|
|
# This is a common enough error to make when learning Cython to let
|
|
# it fail as early as possible and give a very clear error message.
|
|
s.error("a starred assignment target must be in a list or tuple"
|
|
" - maybe you meant to use an index assignment: var[0] = ...",
|
|
pos=expr.pos)
|
|
expr_list = [expr]
|
|
while s.sy == '=':
|
|
s.next()
|
|
if s.sy == 'yield':
|
|
expr = p_yield_expression(s)
|
|
else:
|
|
expr = p_testlist_star_expr(s)
|
|
expr_list.append(expr)
|
|
if len(expr_list) == 1:
|
|
if re.match(r"([-+*/%^&|]|<<|>>|\*\*|//|@)=", s.sy):
|
|
lhs = expr_list[0]
|
|
if isinstance(lhs, ExprNodes.SliceIndexNode):
|
|
# implementation requires IndexNode
|
|
lhs = ExprNodes.IndexNode(
|
|
lhs.pos,
|
|
base=lhs.base,
|
|
index=make_slice_node(lhs.pos, lhs.start, lhs.stop))
|
|
elif not isinstance(lhs, (ExprNodes.AttributeNode, ExprNodes.IndexNode, ExprNodes.NameNode)):
|
|
error(lhs.pos, "Illegal operand for inplace operation.")
|
|
operator = s.sy[:-1]
|
|
s.next()
|
|
if s.sy == 'yield':
|
|
rhs = p_yield_expression(s)
|
|
else:
|
|
rhs = p_testlist(s)
|
|
return Nodes.InPlaceAssignmentNode(lhs.pos, operator=operator, lhs=lhs, rhs=rhs)
|
|
expr = expr_list[0]
|
|
return Nodes.ExprStatNode(expr.pos, expr=expr)
|
|
|
|
rhs = expr_list[-1]
|
|
if len(expr_list) == 2:
|
|
return Nodes.SingleAssignmentNode(rhs.pos, lhs=expr_list[0], rhs=rhs)
|
|
else:
|
|
return Nodes.CascadedAssignmentNode(rhs.pos, lhs_list=expr_list[:-1], rhs=rhs)
|
|
|
|
|
|
def p_print_statement(s):
|
|
# s.sy == 'print'
|
|
pos = s.position()
|
|
ends_with_comma = 0
|
|
s.next()
|
|
if s.sy == '>>':
|
|
s.next()
|
|
stream = p_test(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
ends_with_comma = s.sy in ('NEWLINE', 'EOF')
|
|
else:
|
|
stream = None
|
|
args = []
|
|
if s.sy not in ('NEWLINE', 'EOF'):
|
|
args.append(p_test(s))
|
|
while s.sy == ',':
|
|
s.next()
|
|
if s.sy in ('NEWLINE', 'EOF'):
|
|
ends_with_comma = 1
|
|
break
|
|
args.append(p_test(s))
|
|
arg_tuple = ExprNodes.TupleNode(pos, args=args)
|
|
return Nodes.PrintStatNode(pos,
|
|
arg_tuple=arg_tuple, stream=stream,
|
|
append_newline=not ends_with_comma)
|
|
|
|
|
|
def p_exec_statement(s):
|
|
# s.sy == 'exec'
|
|
pos = s.position()
|
|
s.next()
|
|
code = p_bit_expr(s)
|
|
if isinstance(code, ExprNodes.TupleNode):
|
|
# Py3 compatibility syntax
|
|
tuple_variant = True
|
|
args = code.args
|
|
if len(args) not in (2, 3):
|
|
s.error("expected tuple of length 2 or 3, got length %d" % len(args),
|
|
pos=pos, fatal=False)
|
|
args = [code]
|
|
else:
|
|
tuple_variant = False
|
|
args = [code]
|
|
if s.sy == 'in':
|
|
if tuple_variant:
|
|
s.error("tuple variant of exec does not support additional 'in' arguments",
|
|
fatal=False)
|
|
s.next()
|
|
args.append(p_test(s))
|
|
if s.sy == ',':
|
|
s.next()
|
|
args.append(p_test(s))
|
|
return Nodes.ExecStatNode(pos, args=args)
|
|
|
|
def p_del_statement(s):
|
|
# s.sy == 'del'
|
|
pos = s.position()
|
|
s.next()
|
|
# FIXME: 'exprlist' in Python
|
|
args = p_simple_expr_list(s)
|
|
return Nodes.DelStatNode(pos, args = args)
|
|
|
|
def p_pass_statement(s, with_newline = 0):
|
|
pos = s.position()
|
|
s.expect('pass')
|
|
if with_newline:
|
|
s.expect_newline("Expected a newline", ignore_semicolon=True)
|
|
return Nodes.PassStatNode(pos)
|
|
|
|
def p_break_statement(s):
|
|
# s.sy == 'break'
|
|
pos = s.position()
|
|
s.next()
|
|
return Nodes.BreakStatNode(pos)
|
|
|
|
def p_continue_statement(s):
|
|
# s.sy == 'continue'
|
|
pos = s.position()
|
|
s.next()
|
|
return Nodes.ContinueStatNode(pos)
|
|
|
|
def p_return_statement(s):
|
|
# s.sy == 'return'
|
|
pos = s.position()
|
|
s.next()
|
|
if s.sy not in statement_terminators:
|
|
value = p_testlist(s)
|
|
else:
|
|
value = None
|
|
return Nodes.ReturnStatNode(pos, value = value)
|
|
|
|
def p_raise_statement(s):
|
|
# s.sy == 'raise'
|
|
pos = s.position()
|
|
s.next()
|
|
exc_type = None
|
|
exc_value = None
|
|
exc_tb = None
|
|
cause = None
|
|
if s.sy not in statement_terminators:
|
|
exc_type = p_test(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
exc_value = p_test(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
exc_tb = p_test(s)
|
|
elif s.sy == 'from':
|
|
s.next()
|
|
cause = p_test(s)
|
|
if exc_type or exc_value or exc_tb:
|
|
return Nodes.RaiseStatNode(pos,
|
|
exc_type = exc_type,
|
|
exc_value = exc_value,
|
|
exc_tb = exc_tb,
|
|
cause = cause)
|
|
else:
|
|
return Nodes.ReraiseStatNode(pos)
|
|
|
|
|
|
def p_import_statement(s):
|
|
# s.sy in ('import', 'cimport')
|
|
pos = s.position()
|
|
kind = s.sy
|
|
s.next()
|
|
items = [p_dotted_name(s, as_allowed=1)]
|
|
while s.sy == ',':
|
|
s.next()
|
|
items.append(p_dotted_name(s, as_allowed=1))
|
|
stats = []
|
|
is_absolute = Future.absolute_import in s.context.future_directives
|
|
for pos, target_name, dotted_name, as_name in items:
|
|
if kind == 'cimport':
|
|
stat = Nodes.CImportStatNode(
|
|
pos,
|
|
module_name=dotted_name,
|
|
as_name=as_name,
|
|
is_absolute=is_absolute)
|
|
else:
|
|
if as_name and "." in dotted_name:
|
|
name_list = ExprNodes.ListNode(pos, args=[
|
|
ExprNodes.IdentifierStringNode(pos, value=s.context.intern_ustring("*"))])
|
|
else:
|
|
name_list = None
|
|
stat = Nodes.SingleAssignmentNode(
|
|
pos,
|
|
lhs=ExprNodes.NameNode(pos, name=as_name or target_name),
|
|
rhs=ExprNodes.ImportNode(
|
|
pos,
|
|
module_name=ExprNodes.IdentifierStringNode(pos, value=dotted_name),
|
|
level=0 if is_absolute else None,
|
|
name_list=name_list))
|
|
stats.append(stat)
|
|
return Nodes.StatListNode(pos, stats=stats)
|
|
|
|
|
|
def p_from_import_statement(s, first_statement = 0):
|
|
# s.sy == 'from'
|
|
pos = s.position()
|
|
s.next()
|
|
if s.sy == '.':
|
|
# count relative import level
|
|
level = 0
|
|
while s.sy == '.':
|
|
level += 1
|
|
s.next()
|
|
else:
|
|
level = None
|
|
if level is not None and s.sy in ('import', 'cimport'):
|
|
# we are dealing with "from .. import foo, bar"
|
|
dotted_name_pos, dotted_name = s.position(), s.context.intern_ustring('')
|
|
else:
|
|
if level is None and Future.absolute_import in s.context.future_directives:
|
|
level = 0
|
|
(dotted_name_pos, _, dotted_name, _) = p_dotted_name(s, as_allowed=False)
|
|
if s.sy not in ('import', 'cimport'):
|
|
s.error("Expected 'import' or 'cimport'")
|
|
kind = s.sy
|
|
s.next()
|
|
|
|
is_cimport = kind == 'cimport'
|
|
is_parenthesized = False
|
|
if s.sy == '*':
|
|
imported_names = [(s.position(), s.context.intern_ustring("*"), None, None)]
|
|
s.next()
|
|
else:
|
|
if s.sy == '(':
|
|
is_parenthesized = True
|
|
s.next()
|
|
imported_names = [p_imported_name(s, is_cimport)]
|
|
while s.sy == ',':
|
|
s.next()
|
|
if is_parenthesized and s.sy == ')':
|
|
break
|
|
imported_names.append(p_imported_name(s, is_cimport))
|
|
if is_parenthesized:
|
|
s.expect(')')
|
|
if dotted_name == '__future__':
|
|
if not first_statement:
|
|
s.error("from __future__ imports must occur at the beginning of the file")
|
|
elif level:
|
|
s.error("invalid syntax")
|
|
else:
|
|
for (name_pos, name, as_name, kind) in imported_names:
|
|
if name == "braces":
|
|
s.error("not a chance", name_pos)
|
|
break
|
|
try:
|
|
directive = getattr(Future, name)
|
|
except AttributeError:
|
|
s.error("future feature %s is not defined" % name, name_pos)
|
|
break
|
|
s.context.future_directives.add(directive)
|
|
return Nodes.PassStatNode(pos)
|
|
elif kind == 'cimport':
|
|
return Nodes.FromCImportStatNode(
|
|
pos, module_name=dotted_name,
|
|
relative_level=level,
|
|
imported_names=imported_names)
|
|
else:
|
|
imported_name_strings = []
|
|
items = []
|
|
for (name_pos, name, as_name, kind) in imported_names:
|
|
imported_name_strings.append(
|
|
ExprNodes.IdentifierStringNode(name_pos, value=name))
|
|
items.append(
|
|
(name, ExprNodes.NameNode(name_pos, name=as_name or name)))
|
|
import_list = ExprNodes.ListNode(
|
|
imported_names[0][0], args=imported_name_strings)
|
|
return Nodes.FromImportStatNode(pos,
|
|
module = ExprNodes.ImportNode(dotted_name_pos,
|
|
module_name = ExprNodes.IdentifierStringNode(pos, value = dotted_name),
|
|
level = level,
|
|
name_list = import_list),
|
|
items = items)
|
|
|
|
|
|
imported_name_kinds = cython.declare(set, set(['class', 'struct', 'union']))
|
|
|
|
def p_imported_name(s, is_cimport):
|
|
pos = s.position()
|
|
kind = None
|
|
if is_cimport and s.systring in imported_name_kinds:
|
|
kind = s.systring
|
|
warning(pos, 'the "from module cimport %s name" syntax is deprecated and '
|
|
'will be removed in Cython 3.0' % kind, 2)
|
|
s.next()
|
|
name = p_ident(s)
|
|
as_name = p_as_name(s)
|
|
return (pos, name, as_name, kind)
|
|
|
|
|
|
def p_dotted_name(s, as_allowed):
|
|
pos = s.position()
|
|
target_name = p_ident(s)
|
|
as_name = None
|
|
names = [target_name]
|
|
while s.sy == '.':
|
|
s.next()
|
|
names.append(p_ident(s))
|
|
if as_allowed:
|
|
as_name = p_as_name(s)
|
|
return (pos, target_name, s.context.intern_ustring(u'.'.join(names)), as_name)
|
|
|
|
|
|
def p_as_name(s):
|
|
if s.sy == 'IDENT' and s.systring == 'as':
|
|
s.next()
|
|
return p_ident(s)
|
|
else:
|
|
return None
|
|
|
|
|
|
def p_assert_statement(s):
|
|
# s.sy == 'assert'
|
|
pos = s.position()
|
|
s.next()
|
|
cond = p_test(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
value = p_test(s)
|
|
else:
|
|
value = None
|
|
return Nodes.AssertStatNode(pos, cond = cond, value = value)
|
|
|
|
|
|
statement_terminators = cython.declare(set, set([';', 'NEWLINE', 'EOF']))
|
|
|
|
def p_if_statement(s):
|
|
# s.sy == 'if'
|
|
pos = s.position()
|
|
s.next()
|
|
if_clauses = [p_if_clause(s)]
|
|
while s.sy == 'elif':
|
|
s.next()
|
|
if_clauses.append(p_if_clause(s))
|
|
else_clause = p_else_clause(s)
|
|
return Nodes.IfStatNode(pos,
|
|
if_clauses = if_clauses, else_clause = else_clause)
|
|
|
|
def p_if_clause(s):
|
|
pos = s.position()
|
|
test = p_test(s)
|
|
body = p_suite(s)
|
|
return Nodes.IfClauseNode(pos,
|
|
condition = test, body = body)
|
|
|
|
def p_else_clause(s):
|
|
if s.sy == 'else':
|
|
s.next()
|
|
return p_suite(s)
|
|
else:
|
|
return None
|
|
|
|
def p_while_statement(s):
|
|
# s.sy == 'while'
|
|
pos = s.position()
|
|
s.next()
|
|
test = p_test(s)
|
|
body = p_suite(s)
|
|
else_clause = p_else_clause(s)
|
|
return Nodes.WhileStatNode(pos,
|
|
condition = test, body = body,
|
|
else_clause = else_clause)
|
|
|
|
|
|
def p_for_statement(s, is_async=False):
|
|
# s.sy == 'for'
|
|
pos = s.position()
|
|
s.next()
|
|
kw = p_for_bounds(s, allow_testlist=True, is_async=is_async)
|
|
body = p_suite(s)
|
|
else_clause = p_else_clause(s)
|
|
kw.update(body=body, else_clause=else_clause, is_async=is_async)
|
|
return Nodes.ForStatNode(pos, **kw)
|
|
|
|
|
|
def p_for_bounds(s, allow_testlist=True, is_async=False):
|
|
target = p_for_target(s)
|
|
if s.sy == 'in':
|
|
s.next()
|
|
iterator = p_for_iterator(s, allow_testlist, is_async=is_async)
|
|
return dict(target=target, iterator=iterator)
|
|
elif not s.in_python_file and not is_async:
|
|
if s.sy == 'from':
|
|
s.next()
|
|
bound1 = p_bit_expr(s)
|
|
else:
|
|
# Support shorter "for a <= x < b" syntax
|
|
bound1, target = target, None
|
|
rel1 = p_for_from_relation(s)
|
|
name2_pos = s.position()
|
|
name2 = p_ident(s)
|
|
rel2_pos = s.position()
|
|
rel2 = p_for_from_relation(s)
|
|
bound2 = p_bit_expr(s)
|
|
step = p_for_from_step(s)
|
|
if target is None:
|
|
target = ExprNodes.NameNode(name2_pos, name = name2)
|
|
else:
|
|
if not target.is_name:
|
|
error(target.pos,
|
|
"Target of for-from statement must be a variable name")
|
|
elif name2 != target.name:
|
|
error(name2_pos,
|
|
"Variable name in for-from range does not match target")
|
|
if rel1[0] != rel2[0]:
|
|
error(rel2_pos,
|
|
"Relation directions in for-from do not match")
|
|
return dict(target = target,
|
|
bound1 = bound1,
|
|
relation1 = rel1,
|
|
relation2 = rel2,
|
|
bound2 = bound2,
|
|
step = step,
|
|
)
|
|
else:
|
|
s.expect('in')
|
|
return {}
|
|
|
|
def p_for_from_relation(s):
|
|
if s.sy in inequality_relations:
|
|
op = s.sy
|
|
s.next()
|
|
return op
|
|
else:
|
|
s.error("Expected one of '<', '<=', '>' '>='")
|
|
|
|
def p_for_from_step(s):
|
|
if s.sy == 'IDENT' and s.systring == 'by':
|
|
s.next()
|
|
step = p_bit_expr(s)
|
|
return step
|
|
else:
|
|
return None
|
|
|
|
inequality_relations = cython.declare(set, set(['<', '<=', '>', '>=']))
|
|
|
|
def p_target(s, terminator):
|
|
pos = s.position()
|
|
expr = p_starred_expr(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
exprs = [expr]
|
|
while s.sy != terminator:
|
|
exprs.append(p_starred_expr(s))
|
|
if s.sy != ',':
|
|
break
|
|
s.next()
|
|
return ExprNodes.TupleNode(pos, args = exprs)
|
|
else:
|
|
return expr
|
|
|
|
|
|
def p_for_target(s):
|
|
return p_target(s, 'in')
|
|
|
|
|
|
def p_for_iterator(s, allow_testlist=True, is_async=False):
|
|
pos = s.position()
|
|
if allow_testlist:
|
|
expr = p_testlist(s)
|
|
else:
|
|
expr = p_or_test(s)
|
|
return (ExprNodes.AsyncIteratorNode if is_async else ExprNodes.IteratorNode)(pos, sequence=expr)
|
|
|
|
|
|
def p_try_statement(s):
|
|
# s.sy == 'try'
|
|
pos = s.position()
|
|
s.next()
|
|
body = p_suite(s)
|
|
except_clauses = []
|
|
else_clause = None
|
|
if s.sy in ('except', 'else'):
|
|
while s.sy == 'except':
|
|
except_clauses.append(p_except_clause(s))
|
|
if s.sy == 'else':
|
|
s.next()
|
|
else_clause = p_suite(s)
|
|
body = Nodes.TryExceptStatNode(pos,
|
|
body = body, except_clauses = except_clauses,
|
|
else_clause = else_clause)
|
|
if s.sy != 'finally':
|
|
return body
|
|
# try-except-finally is equivalent to nested try-except/try-finally
|
|
if s.sy == 'finally':
|
|
s.next()
|
|
finally_clause = p_suite(s)
|
|
return Nodes.TryFinallyStatNode(pos,
|
|
body = body, finally_clause = finally_clause)
|
|
else:
|
|
s.error("Expected 'except' or 'finally'")
|
|
|
|
def p_except_clause(s):
|
|
# s.sy == 'except'
|
|
pos = s.position()
|
|
s.next()
|
|
exc_type = None
|
|
exc_value = None
|
|
is_except_as = False
|
|
if s.sy != ':':
|
|
exc_type = p_test(s)
|
|
# normalise into list of single exception tests
|
|
if isinstance(exc_type, ExprNodes.TupleNode):
|
|
exc_type = exc_type.args
|
|
else:
|
|
exc_type = [exc_type]
|
|
if s.sy == ',' or (s.sy == 'IDENT' and s.systring == 'as'
|
|
and s.context.language_level == 2):
|
|
s.next()
|
|
exc_value = p_test(s)
|
|
elif s.sy == 'IDENT' and s.systring == 'as':
|
|
# Py3 syntax requires a name here
|
|
s.next()
|
|
pos2 = s.position()
|
|
name = p_ident(s)
|
|
exc_value = ExprNodes.NameNode(pos2, name = name)
|
|
is_except_as = True
|
|
body = p_suite(s)
|
|
return Nodes.ExceptClauseNode(pos,
|
|
pattern = exc_type, target = exc_value,
|
|
body = body, is_except_as=is_except_as)
|
|
|
|
def p_include_statement(s, ctx):
|
|
pos = s.position()
|
|
s.next() # 'include'
|
|
unicode_include_file_name = p_string_literal(s, 'u')[2]
|
|
s.expect_newline("Syntax error in include statement")
|
|
if s.compile_time_eval:
|
|
include_file_name = unicode_include_file_name
|
|
include_file_path = s.context.find_include_file(include_file_name, pos)
|
|
if include_file_path:
|
|
s.included_files.append(include_file_name)
|
|
with Utils.open_source_file(include_file_path) as f:
|
|
source_desc = FileSourceDescriptor(include_file_path)
|
|
s2 = PyrexScanner(f, source_desc, s, source_encoding=f.encoding, parse_comments=s.parse_comments)
|
|
tree = p_statement_list(s2, ctx)
|
|
return tree
|
|
else:
|
|
return None
|
|
else:
|
|
return Nodes.PassStatNode(pos)
|
|
|
|
|
|
def p_with_statement(s):
|
|
s.next() # 'with'
|
|
if s.systring == 'template' and not s.in_python_file:
|
|
node = p_with_template(s)
|
|
else:
|
|
node = p_with_items(s)
|
|
return node
|
|
|
|
|
|
def p_with_items(s, is_async=False):
|
|
pos = s.position()
|
|
if not s.in_python_file and s.sy == 'IDENT' and s.systring in ('nogil', 'gil'):
|
|
if is_async:
|
|
s.error("with gil/nogil cannot be async")
|
|
state = s.systring
|
|
s.next()
|
|
if s.sy == ',':
|
|
s.next()
|
|
body = p_with_items(s)
|
|
else:
|
|
body = p_suite(s)
|
|
return Nodes.GILStatNode(pos, state=state, body=body)
|
|
else:
|
|
manager = p_test(s)
|
|
target = None
|
|
if s.sy == 'IDENT' and s.systring == 'as':
|
|
s.next()
|
|
target = p_starred_expr(s)
|
|
if s.sy == ',':
|
|
s.next()
|
|
body = p_with_items(s, is_async=is_async)
|
|
else:
|
|
body = p_suite(s)
|
|
return Nodes.WithStatNode(pos, manager=manager, target=target, body=body, is_async=is_async)
|
|
|
|
|
|
def p_with_template(s):
|
|
pos = s.position()
|
|
templates = []
|
|
s.next()
|
|
s.expect('[')
|
|
templates.append(s.systring)
|
|
s.next()
|
|
while s.systring == ',':
|
|
s.next()
|
|
templates.append(s.systring)
|
|
s.next()
|
|
s.expect(']')
|
|
if s.sy == ':':
|
|
s.next()
|
|
s.expect_newline("Syntax error in template function declaration")
|
|
s.expect_indent()
|
|
body_ctx = Ctx()
|
|
body_ctx.templates = templates
|
|
func_or_var = p_c_func_or_var_declaration(s, pos, body_ctx)
|
|
s.expect_dedent()
|
|
return func_or_var
|
|
else:
|
|
error(pos, "Syntax error in template function declaration")
|
|
|
|
def p_simple_statement(s, first_statement = 0):
|
|
#print "p_simple_statement:", s.sy, s.systring ###
|
|
if s.sy == 'global':
|
|
node = p_global_statement(s)
|
|
elif s.sy == 'nonlocal':
|
|
node = p_nonlocal_statement(s)
|
|
elif s.sy == 'print':
|
|
node = p_print_statement(s)
|
|
elif s.sy == 'exec':
|
|
node = p_exec_statement(s)
|
|
elif s.sy == 'del':
|
|
node = p_del_statement(s)
|
|
elif s.sy == 'break':
|
|
node = p_break_statement(s)
|
|
elif s.sy == 'continue':
|
|
node = p_continue_statement(s)
|
|
elif s.sy == 'return':
|
|
node = p_return_statement(s)
|
|
elif s.sy == 'raise':
|
|
node = p_raise_statement(s)
|
|
elif s.sy in ('import', 'cimport'):
|
|
node = p_import_statement(s)
|
|
elif s.sy == 'from':
|
|
node = p_from_import_statement(s, first_statement = first_statement)
|
|
elif s.sy == 'yield':
|
|
node = p_yield_statement(s)
|
|
elif s.sy == 'assert':
|
|
node = p_assert_statement(s)
|
|
elif s.sy == 'pass':
|
|
node = p_pass_statement(s)
|
|
else:
|
|
node = p_expression_or_assignment(s)
|
|
return node
|
|
|
|
def p_simple_statement_list(s, ctx, first_statement = 0):
|
|
# Parse a series of simple statements on one line
|
|
# separated by semicolons.
|
|
stat = p_simple_statement(s, first_statement = first_statement)
|
|
pos = stat.pos
|
|
stats = []
|
|
if not isinstance(stat, Nodes.PassStatNode):
|
|
stats.append(stat)
|
|
while s.sy == ';':
|
|
#print "p_simple_statement_list: maybe more to follow" ###
|
|
s.next()
|
|
if s.sy in ('NEWLINE', 'EOF'):
|
|
break
|
|
stat = p_simple_statement(s, first_statement = first_statement)
|
|
if isinstance(stat, Nodes.PassStatNode):
|
|
continue
|
|
stats.append(stat)
|
|
first_statement = False
|
|
|
|
if not stats:
|
|
stat = Nodes.PassStatNode(pos)
|
|
elif len(stats) == 1:
|
|
stat = stats[0]
|
|
else:
|
|
stat = Nodes.StatListNode(pos, stats = stats)
|
|
|
|
if s.sy not in ('NEWLINE', 'EOF'):
|
|
# provide a better error message for users who accidentally write Cython code in .py files
|
|
if isinstance(stat, Nodes.ExprStatNode):
|
|
if stat.expr.is_name and stat.expr.name == 'cdef':
|
|
s.error("The 'cdef' keyword is only allowed in Cython files (pyx/pxi/pxd)", pos)
|
|
s.expect_newline("Syntax error in simple statement list")
|
|
|
|
return stat
|
|
|
|
def p_compile_time_expr(s):
|
|
old = s.compile_time_expr
|
|
s.compile_time_expr = 1
|
|
expr = p_testlist(s)
|
|
s.compile_time_expr = old
|
|
return expr
|
|
|
|
def p_DEF_statement(s):
|
|
pos = s.position()
|
|
denv = s.compile_time_env
|
|
s.next() # 'DEF'
|
|
name = p_ident(s)
|
|
s.expect('=')
|
|
expr = p_compile_time_expr(s)
|
|
if s.compile_time_eval:
|
|
value = expr.compile_time_value(denv)
|
|
#print "p_DEF_statement: %s = %r" % (name, value) ###
|
|
denv.declare(name, value)
|
|
s.expect_newline("Expected a newline", ignore_semicolon=True)
|
|
return Nodes.PassStatNode(pos)
|
|
|
|
def p_IF_statement(s, ctx):
|
|
pos = s.position()
|
|
saved_eval = s.compile_time_eval
|
|
current_eval = saved_eval
|
|
denv = s.compile_time_env
|
|
result = None
|
|
while 1:
|
|
s.next() # 'IF' or 'ELIF'
|
|
expr = p_compile_time_expr(s)
|
|
s.compile_time_eval = current_eval and bool(expr.compile_time_value(denv))
|
|
body = p_suite(s, ctx)
|
|
if s.compile_time_eval:
|
|
result = body
|
|
current_eval = 0
|
|
if s.sy != 'ELIF':
|
|
break
|
|
if s.sy == 'ELSE':
|
|
s.next()
|
|
s.compile_time_eval = current_eval
|
|
body = p_suite(s, ctx)
|
|
if current_eval:
|
|
result = body
|
|
if not result:
|
|
result = Nodes.PassStatNode(pos)
|
|
s.compile_time_eval = saved_eval
|
|
return result
|
|
|
|
def p_statement(s, ctx, first_statement = 0):
|
|
cdef_flag = ctx.cdef_flag
|
|
decorators = None
|
|
if s.sy == 'ctypedef':
|
|
if ctx.level not in ('module', 'module_pxd'):
|
|
s.error("ctypedef statement not allowed here")
|
|
#if ctx.api:
|
|
# error(s.position(), "'api' not allowed with 'ctypedef'")
|
|
return p_ctypedef_statement(s, ctx)
|
|
elif s.sy == 'DEF':
|
|
return p_DEF_statement(s)
|
|
elif s.sy == 'IF':
|
|
return p_IF_statement(s, ctx)
|
|
elif s.sy == '@':
|
|
if ctx.level not in ('module', 'class', 'c_class', 'function', 'property', 'module_pxd', 'c_class_pxd', 'other'):
|
|
s.error('decorator not allowed here')
|
|
s.level = ctx.level
|
|
decorators = p_decorators(s)
|
|
if not ctx.allow_struct_enum_decorator and s.sy not in ('def', 'cdef', 'cpdef', 'class', 'async'):
|
|
if s.sy == 'IDENT' and s.systring == 'async':
|
|
pass # handled below
|
|
else:
|
|
s.error("Decorators can only be followed by functions or classes")
|
|
elif s.sy == 'pass' and cdef_flag:
|
|
# empty cdef block
|
|
return p_pass_statement(s, with_newline=1)
|
|
|
|
overridable = 0
|
|
if s.sy == 'cdef':
|
|
cdef_flag = 1
|
|
s.next()
|
|
elif s.sy == 'cpdef':
|
|
cdef_flag = 1
|
|
overridable = 1
|
|
s.next()
|
|
if cdef_flag:
|
|
if ctx.level not in ('module', 'module_pxd', 'function', 'c_class', 'c_class_pxd'):
|
|
s.error('cdef statement not allowed here')
|
|
s.level = ctx.level
|
|
node = p_cdef_statement(s, ctx(overridable=overridable))
|
|
if decorators is not None:
|
|
tup = (Nodes.CFuncDefNode, Nodes.CVarDefNode, Nodes.CClassDefNode)
|
|
if ctx.allow_struct_enum_decorator:
|
|
tup += (Nodes.CStructOrUnionDefNode, Nodes.CEnumDefNode)
|
|
if not isinstance(node, tup):
|
|
s.error("Decorators can only be followed by functions or classes")
|
|
node.decorators = decorators
|
|
return node
|
|
else:
|
|
if ctx.api:
|
|
s.error("'api' not allowed with this statement", fatal=False)
|
|
elif s.sy == 'def':
|
|
# def statements aren't allowed in pxd files, except
|
|
# as part of a cdef class
|
|
if ('pxd' in ctx.level) and (ctx.level != 'c_class_pxd'):
|
|
s.error('def statement not allowed here')
|
|
s.level = ctx.level
|
|
return p_def_statement(s, decorators)
|
|
elif s.sy == 'class':
|
|
if ctx.level not in ('module', 'function', 'class', 'other'):
|
|
s.error("class definition not allowed here")
|
|
return p_class_statement(s, decorators)
|
|
elif s.sy == 'include':
|
|
if ctx.level not in ('module', 'module_pxd'):
|
|
s.error("include statement not allowed here")
|
|
return p_include_statement(s, ctx)
|
|
elif ctx.level == 'c_class' and s.sy == 'IDENT' and s.systring == 'property':
|
|
return p_property_decl(s)
|
|
elif s.sy == 'pass' and ctx.level != 'property':
|
|
return p_pass_statement(s, with_newline=True)
|
|
else:
|
|
if ctx.level in ('c_class_pxd', 'property'):
|
|
node = p_ignorable_statement(s)
|
|
if node is not None:
|
|
return node
|
|
s.error("Executable statement not allowed here")
|
|
if s.sy == 'if':
|
|
return p_if_statement(s)
|
|
elif s.sy == 'while':
|
|
return p_while_statement(s)
|
|
elif s.sy == 'for':
|
|
return p_for_statement(s)
|
|
elif s.sy == 'try':
|
|
return p_try_statement(s)
|
|
elif s.sy == 'with':
|
|
return p_with_statement(s)
|
|
elif s.sy == 'async':
|
|
s.next()
|
|
return p_async_statement(s, ctx, decorators)
|
|
else:
|
|
if s.sy == 'IDENT' and s.systring == 'async':
|
|
ident_name = s.systring
|
|
# PEP 492 enables the async/await keywords when it spots "async def ..."
|
|
s.next()
|
|
if s.sy == 'def':
|
|
return p_async_statement(s, ctx, decorators)
|
|
elif decorators:
|
|
s.error("Decorators can only be followed by functions or classes")
|
|
s.put_back('IDENT', ident_name) # re-insert original token
|
|
return p_simple_statement_list(s, ctx, first_statement=first_statement)
|
|
|
|
|
|
def p_statement_list(s, ctx, first_statement = 0):
|
|
# Parse a series of statements separated by newlines.
|
|
pos = s.position()
|
|
stats = []
|
|
while s.sy not in ('DEDENT', 'EOF'):
|
|
stat = p_statement(s, ctx, first_statement = first_statement)
|
|
if isinstance(stat, Nodes.PassStatNode):
|
|
continue
|
|
stats.append(stat)
|
|
first_statement = False
|
|
if not stats:
|
|
return Nodes.PassStatNode(pos)
|
|
elif len(stats) == 1:
|
|
return stats[0]
|
|
else:
|
|
return Nodes.StatListNode(pos, stats = stats)
|
|
|
|
|
|
def p_suite(s, ctx=Ctx()):
|
|
return p_suite_with_docstring(s, ctx, with_doc_only=False)[1]
|
|
|
|
|
|
def p_suite_with_docstring(s, ctx, with_doc_only=False):
|
|
s.expect(':')
|
|
doc = None
|
|
if s.sy == 'NEWLINE':
|
|
s.next()
|
|
s.expect_indent()
|
|
if with_doc_only:
|
|
doc = p_doc_string(s)
|
|
body = p_statement_list(s, ctx)
|
|
s.expect_dedent()
|
|
else:
|
|
if ctx.api:
|
|
s.error("'api' not allowed with this statement", fatal=False)
|
|
if ctx.level in ('module', 'class', 'function', 'other'):
|
|
body = p_simple_statement_list(s, ctx)
|
|
else:
|
|
body = p_pass_statement(s)
|
|
s.expect_newline("Syntax error in declarations", ignore_semicolon=True)
|
|
if not with_doc_only:
|
|
doc, body = _extract_docstring(body)
|
|
return doc, body
|
|
|
|
|
|
def p_positional_and_keyword_args(s, end_sy_set, templates = None):
|
|
"""
|
|
Parses positional and keyword arguments. end_sy_set
|
|
should contain any s.sy that terminate the argument list.
|
|
Argument expansion (* and **) are not allowed.
|
|
|
|
Returns: (positional_args, keyword_args)
|
|
"""
|
|
positional_args = []
|
|
keyword_args = []
|
|
pos_idx = 0
|
|
|
|
while s.sy not in end_sy_set:
|
|
if s.sy == '*' or s.sy == '**':
|
|
s.error('Argument expansion not allowed here.', fatal=False)
|
|
|
|
parsed_type = False
|
|
if s.sy == 'IDENT' and s.peek()[0] == '=':
|
|
ident = s.systring
|
|
s.next() # s.sy is '='
|
|
s.next()
|
|
if looking_at_expr(s):
|
|
arg = p_test(s)
|
|
else:
|
|
base_type = p_c_base_type(s, templates = templates)
|
|
declarator = p_c_declarator(s, empty = 1)
|
|
arg = Nodes.CComplexBaseTypeNode(base_type.pos,
|
|
base_type = base_type, declarator = declarator)
|
|
parsed_type = True
|
|
keyword_node = ExprNodes.IdentifierStringNode(arg.pos, value=ident)
|
|
keyword_args.append((keyword_node, arg))
|
|
was_keyword = True
|
|
|
|
else:
|
|
if looking_at_expr(s):
|
|
arg = p_test(s)
|
|
else:
|
|
base_type = p_c_base_type(s, templates = templates)
|
|
declarator = p_c_declarator(s, empty = 1)
|
|
arg = Nodes.CComplexBaseTypeNode(base_type.pos,
|
|
base_type = base_type, declarator = declarator)
|
|
parsed_type = True
|
|
positional_args.append(arg)
|
|
pos_idx += 1
|
|
if len(keyword_args) > 0:
|
|
s.error("Non-keyword arg following keyword arg",
|
|
pos=arg.pos)
|
|
|
|
if s.sy != ',':
|
|
if s.sy not in end_sy_set:
|
|
if parsed_type:
|
|
s.error("Unmatched %s" % " or ".join(end_sy_set))
|
|
break
|
|
s.next()
|
|
return positional_args, keyword_args
|
|
|
|
def p_c_base_type(s, self_flag = 0, nonempty = 0, templates = None):
|
|
# If self_flag is true, this is the base type for the
|
|
# self argument of a C method of an extension type.
|
|
if s.sy == '(':
|
|
return p_c_complex_base_type(s, templates = templates)
|
|
else:
|
|
return p_c_simple_base_type(s, self_flag, nonempty = nonempty, templates = templates)
|
|
|
|
def p_calling_convention(s):
|
|
if s.sy == 'IDENT' and s.systring in calling_convention_words:
|
|
result = s.systring
|
|
s.next()
|
|
return result
|
|
else:
|
|
return ""
|
|
|
|
|
|
calling_convention_words = cython.declare(
|
|
set, set(["__stdcall", "__cdecl", "__fastcall"]))
|
|
|
|
|
|
def p_c_complex_base_type(s, templates = None):
|
|
# s.sy == '('
|
|
pos = s.position()
|
|
s.next()
|
|
base_type = p_c_base_type(s, templates=templates)
|
|
declarator = p_c_declarator(s, empty=True)
|
|
type_node = Nodes.CComplexBaseTypeNode(
|
|
pos, base_type=base_type, declarator=declarator)
|
|
if s.sy == ',':
|
|
components = [type_node]
|
|
while s.sy == ',':
|
|
s.next()
|
|
if s.sy == ')':
|
|
break
|
|
base_type = p_c_base_type(s, templates=templates)
|
|
declarator = p_c_declarator(s, empty=True)
|
|
components.append(Nodes.CComplexBaseTypeNode(
|
|
pos, base_type=base_type, declarator=declarator))
|
|
type_node = Nodes.CTupleBaseTypeNode(pos, components = components)
|
|
|
|
s.expect(')')
|
|
if s.sy == '[':
|
|
if is_memoryviewslice_access(s):
|
|
type_node = p_memoryviewslice_access(s, type_node)
|
|
else:
|
|
type_node = p_buffer_or_template(s, type_node, templates)
|
|
return type_node
|
|
|
|
|
|
def p_c_simple_base_type(s, self_flag, nonempty, templates = None):
|
|
#print "p_c_simple_base_type: self_flag =", self_flag, nonempty
|
|
is_basic = 0
|
|
signed = 1
|
|
longness = 0
|
|
complex = 0
|
|
module_path = []
|
|
pos = s.position()
|
|
if not s.sy == 'IDENT':
|
|
error(pos, "Expected an identifier, found '%s'" % s.sy)
|
|
if s.systring == 'const':
|
|
s.next()
|
|
base_type = p_c_base_type(s, self_flag=self_flag, nonempty=nonempty, templates=templates)
|
|
if isinstance(base_type, Nodes.MemoryViewSliceTypeNode):
|
|
# reverse order to avoid having to write "(const int)[:]"
|
|
base_type.base_type_node = Nodes.CConstTypeNode(pos, base_type=base_type.base_type_node)
|
|
return base_type
|
|
return Nodes.CConstTypeNode(pos, base_type=base_type)
|
|
if looking_at_base_type(s):
|
|
#print "p_c_simple_base_type: looking_at_base_type at", s.position()
|
|
is_basic = 1
|
|
if s.sy == 'IDENT' and s.systring in special_basic_c_types:
|
|
signed, longness = special_basic_c_types[s.systring]
|
|
name = s.systring
|
|
s.next()
|
|
else:
|
|
signed, longness = p_sign_and_longness(s)
|
|
if s.sy == 'IDENT' and s.systring in basic_c_type_names:
|
|
name = s.systring
|
|
s.next()
|
|
else:
|
|
name = 'int' # long [int], short [int], long [int] complex, etc.
|
|
if s.sy == 'IDENT' and s.systring == 'complex':
|
|
complex = 1
|
|
s.next()
|
|
elif looking_at_dotted_name(s):
|
|
#print "p_c_simple_base_type: looking_at_type_name at", s.position()
|
|
name = s.systring
|
|
s.next()
|
|
while s.sy == '.':
|
|
module_path.append(name)
|
|
s.next()
|
|
name = p_ident(s)
|
|
else:
|
|
name = s.systring
|
|
s.next()
|
|
if nonempty and s.sy != 'IDENT':
|
|
# Make sure this is not a declaration of a variable or function.
|
|
if s.sy == '(':
|
|
s.next()
|
|
if (s.sy == '*' or s.sy == '**' or s.sy == '&'
|
|
or (s.sy == 'IDENT' and s.systring in calling_convention_words)):
|
|
s.put_back('(', '(')
|
|
else:
|
|
s.put_back('(', '(')
|
|
s.put_back('IDENT', name)
|
|
name = None
|
|
elif s.sy not in ('*', '**', '[', '&'):
|
|
s.put_back('IDENT', name)
|
|
name = None
|
|
|
|
type_node = Nodes.CSimpleBaseTypeNode(pos,
|
|
name = name, module_path = module_path,
|
|
is_basic_c_type = is_basic, signed = signed,
|
|
complex = complex, longness = longness,
|
|
is_self_arg = self_flag, templates = templates)
|
|
|
|
# declarations here.
|
|
if s.sy == '[':
|
|
if is_memoryviewslice_access(s):
|
|
type_node = p_memoryviewslice_access(s, type_node)
|
|
else:
|
|
type_node = p_buffer_or_template(s, type_node, templates)
|
|
|
|
if s.sy == '.':
|
|
s.next()
|
|
name = p_ident(s)
|
|
type_node = Nodes.CNestedBaseTypeNode(pos, base_type = type_node, name = name)
|
|
|
|
return type_node
|
|
|
|
def p_buffer_or_template(s, base_type_node, templates):
|
|
# s.sy == '['
|
|
pos = s.position()
|
|
s.next()
|
|
# Note that buffer_positional_options_count=1, so the only positional argument is dtype.
|
|
# For templated types, all parameters are types.
|
|
positional_args, keyword_args = (
|
|
p_positional_and_keyword_args(s, (']',), templates)
|
|
)
|
|
s.expect(']')
|
|
|
|
if s.sy == '[':
|
|
base_type_node = p_buffer_or_template(s, base_type_node, templates)
|
|
|
|
keyword_dict = ExprNodes.DictNode(pos,
|
|
key_value_pairs = [
|
|
ExprNodes.DictItemNode(pos=key.pos, key=key, value=value)
|
|
for key, value in keyword_args
|
|
])
|
|
result = Nodes.TemplatedTypeNode(pos,
|
|
positional_args = positional_args,
|
|
keyword_args = keyword_dict,
|
|
base_type_node = base_type_node)
|
|
return result
|
|
|
|
def p_bracketed_base_type(s, base_type_node, nonempty, empty):
|
|
# s.sy == '['
|
|
if empty and not nonempty:
|
|
# sizeof-like thing. Only anonymous C arrays allowed (int[SIZE]).
|
|
return base_type_node
|
|
elif not empty and nonempty:
|
|
# declaration of either memoryview slice or buffer.
|
|
if is_memoryviewslice_access(s):
|
|
return p_memoryviewslice_access(s, base_type_node)
|
|
else:
|
|
return p_buffer_or_template(s, base_type_node, None)
|
|
# return p_buffer_access(s, base_type_node)
|
|
elif not empty and not nonempty:
|
|
# only anonymous C arrays and memoryview slice arrays here. We
|
|
# disallow buffer declarations for now, due to ambiguity with anonymous
|
|
# C arrays.
|
|
if is_memoryviewslice_access(s):
|
|
return p_memoryviewslice_access(s, base_type_node)
|
|
else:
|
|
return base_type_node
|
|
|
|
def is_memoryviewslice_access(s):
|
|
# s.sy == '['
|
|
# a memoryview slice declaration is distinguishable from a buffer access
|
|
# declaration by the first entry in the bracketed list. The buffer will
|
|
# not have an unnested colon in the first entry; the memoryview slice will.
|
|
saved = [(s.sy, s.systring)]
|
|
s.next()
|
|
retval = False
|
|
if s.systring == ':':
|
|
retval = True
|
|
elif s.sy == 'INT':
|
|
saved.append((s.sy, s.systring))
|
|
s.next()
|
|
if s.sy == ':':
|
|
retval = True
|
|
|
|
for sv in saved[::-1]:
|
|
s.put_back(*sv)
|
|
|
|
return retval
|
|
|
|
def p_memoryviewslice_access(s, base_type_node):
|
|
# s.sy == '['
|
|
pos = s.position()
|
|
s.next()
|
|
subscripts, _ = p_subscript_list(s)
|
|
# make sure each entry in subscripts is a slice
|
|
for subscript in subscripts:
|
|
if len(subscript) < 2:
|
|
s.error("An axis specification in memoryview declaration does not have a ':'.")
|
|
s.expect(']')
|
|
indexes = make_slice_nodes(pos, subscripts)
|
|
result = Nodes.MemoryViewSliceTypeNode(pos,
|
|
base_type_node = base_type_node,
|
|
axes = indexes)
|
|
return result
|
|
|
|
def looking_at_name(s):
|
|
return s.sy == 'IDENT' and not s.systring in calling_convention_words
|
|
|
|
def looking_at_expr(s):
|
|
if s.systring in base_type_start_words:
|
|
return False
|
|
elif s.sy == 'IDENT':
|
|
is_type = False
|
|
name = s.systring
|
|
dotted_path = []
|
|
s.next()
|
|
|
|
while s.sy == '.':
|
|
s.next()
|
|
dotted_path.append(s.systring)
|
|
s.expect('IDENT')
|
|
|
|
saved = s.sy, s.systring
|
|
if s.sy == 'IDENT':
|
|
is_type = True
|
|
elif s.sy == '*' or s.sy == '**':
|
|
s.next()
|
|
is_type = s.sy in (')', ']')
|
|
s.put_back(*saved)
|
|
elif s.sy == '(':
|
|
s.next()
|
|
is_type = s.sy == '*'
|
|
s.put_back(*saved)
|
|
elif s.sy == '[':
|
|
s.next()
|
|
is_type = s.sy == ']' or not looking_at_expr(s) # could be a nested template type
|
|
s.put_back(*saved)
|
|
|
|
dotted_path.reverse()
|
|
for p in dotted_path:
|
|
s.put_back('IDENT', p)
|
|
s.put_back('.', '.')
|
|
|
|
s.put_back('IDENT', name)
|
|
return not is_type and saved[0]
|
|
else:
|
|
return True
|
|
|
|
def looking_at_base_type(s):
|
|
#print "looking_at_base_type?", s.sy, s.systring, s.position()
|
|
return s.sy == 'IDENT' and s.systring in base_type_start_words
|
|
|
|
def looking_at_dotted_name(s):
|
|
if s.sy == 'IDENT':
|
|
name = s.systring
|
|
s.next()
|
|
result = s.sy == '.'
|
|
s.put_back('IDENT', name)
|
|
return result
|
|
else:
|
|
return 0
|
|
|
|
def looking_at_call(s):
|
|
"See if we're looking at a.b.c("
|
|
# Don't mess up the original position, so save and restore it.
|
|
# Unfortunately there's no good way to handle this, as a subsequent call
|
|
# to next() will not advance the position until it reads a new token.
|
|
position = s.start_line, s.start_col
|
|
result = looking_at_expr(s) == u'('
|
|
if not result:
|
|
s.start_line, s.start_col = position
|
|
return result
|
|
|
|
basic_c_type_names = cython.declare(
|
|
set, set(["void", "char", "int", "float", "double", "bint"]))
|
|
|
|
special_basic_c_types = cython.declare(dict, {
|
|
# name : (signed, longness)
|
|
"Py_UNICODE" : (0, 0),
|
|
"Py_UCS4" : (0, 0),
|
|
"Py_hash_t" : (2, 0),
|
|
"Py_ssize_t" : (2, 0),
|
|
"ssize_t" : (2, 0),
|
|
"size_t" : (0, 0),
|
|
"ptrdiff_t" : (2, 0),
|
|
"Py_tss_t" : (1, 0),
|
|
})
|
|
|
|
sign_and_longness_words = cython.declare(
|
|
set, set(["short", "long", "signed", "unsigned"]))
|
|
|
|
base_type_start_words = cython.declare(
|
|
set,
|
|
basic_c_type_names
|
|
| sign_and_longness_words
|
|
| set(special_basic_c_types))
|
|
|
|
struct_enum_union = cython.declare(
|
|
set, set(["struct", "union", "enum", "packed"]))
|
|
|
|
def p_sign_and_longness(s):
|
|
signed = 1
|
|
longness = 0
|
|
while s.sy == 'IDENT' and s.systring in sign_and_longness_words:
|
|
if s.systring == 'unsigned':
|
|
signed = 0
|
|
elif s.systring == 'signed':
|
|
signed = 2
|
|
elif s.systring == 'short':
|
|
longness = -1
|
|
elif s.systring == 'long':
|
|
longness += 1
|
|
s.next()
|
|
return signed, longness
|
|
|
|
def p_opt_cname(s):
|
|
literal = p_opt_string_literal(s, 'u')
|
|
if literal is not None:
|
|
cname = EncodedString(literal)
|
|
cname.encoding = s.source_encoding
|
|
else:
|
|
cname = None
|
|
return cname
|
|
|
|
def p_c_declarator(s, ctx = Ctx(), empty = 0, is_type = 0, cmethod_flag = 0,
|
|
assignable = 0, nonempty = 0,
|
|
calling_convention_allowed = 0):
|
|
# If empty is true, the declarator must be empty. If nonempty is true,
|
|
# the declarator must be nonempty. Otherwise we don't care.
|
|
# If cmethod_flag is true, then if this declarator declares
|
|
# a function, it's a C method of an extension type.
|
|
pos = s.position()
|
|
if s.sy == '(':
|
|
s.next()
|
|
if s.sy == ')' or looking_at_name(s):
|
|
base = Nodes.CNameDeclaratorNode(pos, name=s.context.intern_ustring(u""), cname=None)
|
|
result = p_c_func_declarator(s, pos, ctx, base, cmethod_flag)
|
|
else:
|
|
result = p_c_declarator(s, ctx, empty = empty, is_type = is_type,
|
|
cmethod_flag = cmethod_flag,
|
|
nonempty = nonempty,
|
|
calling_convention_allowed = 1)
|
|
s.expect(')')
|
|
else:
|
|
result = p_c_simple_declarator(s, ctx, empty, is_type, cmethod_flag,
|
|
assignable, nonempty)
|
|
if not calling_convention_allowed and result.calling_convention and s.sy != '(':
|
|
error(s.position(), "%s on something that is not a function"
|
|
% result.calling_convention)
|
|
while s.sy in ('[', '('):
|
|
pos = s.position()
|
|
if s.sy == '[':
|
|
result = p_c_array_declarator(s, result)
|
|
else: # sy == '('
|
|
s.next()
|
|
result = p_c_func_declarator(s, pos, ctx, result, cmethod_flag)
|
|
cmethod_flag = 0
|
|
return result
|
|
|
|
def p_c_array_declarator(s, base):
|
|
pos = s.position()
|
|
s.next() # '['
|
|
if s.sy != ']':
|
|
dim = p_testlist(s)
|
|
else:
|
|
dim = None
|
|
s.expect(']')
|
|
return Nodes.CArrayDeclaratorNode(pos, base = base, dimension = dim)
|
|
|
|
def p_c_func_declarator(s, pos, ctx, base, cmethod_flag):
|
|
# Opening paren has already been skipped
|
|
args = p_c_arg_list(s, ctx, cmethod_flag = cmethod_flag,
|
|
nonempty_declarators = 0)
|
|
ellipsis = p_optional_ellipsis(s)
|
|
s.expect(')')
|
|
nogil = p_nogil(s)
|
|
exc_val, exc_check = p_exception_value_clause(s)
|
|
# TODO - warning to enforce preferred exception specification order
|
|
nogil = nogil or p_nogil(s)
|
|
with_gil = p_with_gil(s)
|
|
return Nodes.CFuncDeclaratorNode(pos,
|
|
base = base, args = args, has_varargs = ellipsis,
|
|
exception_value = exc_val, exception_check = exc_check,
|
|
nogil = nogil or ctx.nogil or with_gil, with_gil = with_gil)
|
|
|
|
supported_overloaded_operators = cython.declare(set, set([
|
|
'+', '-', '*', '/', '%',
|
|
'++', '--', '~', '|', '&', '^', '<<', '>>', ',',
|
|
'==', '!=', '>=', '>', '<=', '<',
|
|
'[]', '()', '!', '=',
|
|
'bool',
|
|
]))
|
|
|
|
def p_c_simple_declarator(s, ctx, empty, is_type, cmethod_flag,
|
|
assignable, nonempty):
|
|
pos = s.position()
|
|
calling_convention = p_calling_convention(s)
|
|
if s.sy == '*':
|
|
s.next()
|
|
if s.systring == 'const':
|
|
const_pos = s.position()
|
|
s.next()
|
|
const_base = p_c_declarator(s, ctx, empty = empty,
|
|
is_type = is_type,
|
|
cmethod_flag = cmethod_flag,
|
|
assignable = assignable,
|
|
nonempty = nonempty)
|
|
base = Nodes.CConstDeclaratorNode(const_pos, base = const_base)
|
|
else:
|
|
base = p_c_declarator(s, ctx, empty = empty, is_type = is_type,
|
|
cmethod_flag = cmethod_flag,
|
|
assignable = assignable, nonempty = nonempty)
|
|
result = Nodes.CPtrDeclaratorNode(pos,
|
|
base = base)
|
|
elif s.sy == '**': # scanner returns this as a single token
|
|
s.next()
|
|
base = p_c_declarator(s, ctx, empty = empty, is_type = is_type,
|
|
cmethod_flag = cmethod_flag,
|
|
assignable = assignable, nonempty = nonempty)
|
|
result = Nodes.CPtrDeclaratorNode(pos,
|
|
base = Nodes.CPtrDeclaratorNode(pos,
|
|
base = base))
|
|
elif s.sy == '&':
|
|
s.next()
|
|
base = p_c_declarator(s, ctx, empty = empty, is_type = is_type,
|
|
cmethod_flag = cmethod_flag,
|
|
assignable = assignable, nonempty = nonempty)
|
|
result = Nodes.CReferenceDeclaratorNode(pos, base = base)
|
|
else:
|
|
rhs = None
|
|
if s.sy == 'IDENT':
|
|
name = s.systring
|
|
if empty:
|
|
error(s.position(), "Declarator should be empty")
|
|
s.next()
|
|
cname = p_opt_cname(s)
|
|
if name != 'operator' and s.sy == '=' and assignable:
|
|
s.next()
|
|
rhs = p_test(s)
|
|
else:
|
|
if nonempty:
|
|
error(s.position(), "Empty declarator")
|
|
name = ""
|
|
cname = None
|
|
if cname is None and ctx.namespace is not None and nonempty:
|
|
cname = ctx.namespace + "::" + name
|
|
if name == 'operator' and ctx.visibility == 'extern' and nonempty:
|
|
op = s.sy
|
|
if [1 for c in op if c in '+-*/<=>!%&|([^~,']:
|
|
s.next()
|
|
# Handle diphthong operators.
|
|
if op == '(':
|
|
s.expect(')')
|
|
op = '()'
|
|
elif op == '[':
|
|
s.expect(']')
|
|
op = '[]'
|
|
elif op in ('-', '+', '|', '&') and s.sy == op:
|
|
op *= 2 # ++, --, ...
|
|
s.next()
|
|
elif s.sy == '=':
|
|
op += s.sy # +=, -=, ...
|
|
s.next()
|
|
if op not in supported_overloaded_operators:
|
|
s.error("Overloading operator '%s' not yet supported." % op,
|
|
fatal=False)
|
|
name += op
|
|
elif op == 'IDENT':
|
|
op = s.systring;
|
|
if op not in supported_overloaded_operators:
|
|
s.error("Overloading operator '%s' not yet supported." % op,
|
|
fatal=False)
|
|
name = name + ' ' + op
|
|
s.next()
|
|
result = Nodes.CNameDeclaratorNode(pos,
|
|
name = name, cname = cname, default = rhs)
|
|
result.calling_convention = calling_convention
|
|
return result
|
|
|
|
def p_nogil(s):
|
|
if s.sy == 'IDENT' and s.systring == 'nogil':
|
|
s.next()
|
|
return 1
|
|
else:
|
|
return 0
|
|
|
|
def p_with_gil(s):
|
|
if s.sy == 'with':
|
|
s.next()
|
|
s.expect_keyword('gil')
|
|
return 1
|
|
else:
|
|
return 0
|
|
|
|
def p_exception_value_clause(s):
|
|
exc_val = None
|
|
exc_check = 0
|
|
|
|
if s.sy == 'IDENT' and s.systring == 'noexcept':
|
|
s.next()
|
|
exc_check = False # No-op in Cython 0.29.x
|
|
elif s.sy == 'except':
|
|
s.next()
|
|
if s.sy == '*':
|
|
exc_check = 1
|
|
s.next()
|
|
elif s.sy == '+':
|
|
exc_check = '+'
|
|
s.next()
|
|
if s.sy == 'IDENT':
|
|
name = s.systring
|
|
s.next()
|
|
exc_val = p_name(s, name)
|
|
elif s.sy == '*':
|
|
exc_val = ExprNodes.CharNode(s.position(), value=u'*')
|
|
s.next()
|
|
else:
|
|
if s.sy == '?':
|
|
exc_check = 1
|
|
s.next()
|
|
exc_val = p_test(s)
|
|
return exc_val, exc_check
|
|
|
|
c_arg_list_terminators = cython.declare(set, set(['*', '**', '.', ')', ':']))
|
|
|
|
def p_c_arg_list(s, ctx = Ctx(), in_pyfunc = 0, cmethod_flag = 0,
|
|
nonempty_declarators = 0, kw_only = 0, annotated = 1):
|
|
# Comma-separated list of C argument declarations, possibly empty.
|
|
# May have a trailing comma.
|
|
args = []
|
|
is_self_arg = cmethod_flag
|
|
while s.sy not in c_arg_list_terminators:
|
|
args.append(p_c_arg_decl(s, ctx, in_pyfunc, is_self_arg,
|
|
nonempty = nonempty_declarators, kw_only = kw_only,
|
|
annotated = annotated))
|
|
if s.sy != ',':
|
|
break
|
|
s.next()
|
|
is_self_arg = 0
|
|
return args
|
|
|
|
def p_optional_ellipsis(s):
|
|
if s.sy == '.':
|
|
expect_ellipsis(s)
|
|
return 1
|
|
else:
|
|
return 0
|
|
|
|
def p_c_arg_decl(s, ctx, in_pyfunc, cmethod_flag = 0, nonempty = 0,
|
|
kw_only = 0, annotated = 1):
|
|
pos = s.position()
|
|
not_none = or_none = 0
|
|
default = None
|
|
annotation = None
|
|
if s.in_python_file:
|
|
# empty type declaration
|
|
base_type = Nodes.CSimpleBaseTypeNode(pos,
|
|
name = None, module_path = [],
|
|
is_basic_c_type = 0, signed = 0,
|
|
complex = 0, longness = 0,
|
|
is_self_arg = cmethod_flag, templates = None)
|
|
else:
|
|
base_type = p_c_base_type(s, cmethod_flag, nonempty = nonempty)
|
|
declarator = p_c_declarator(s, ctx, nonempty = nonempty)
|
|
if s.sy in ('not', 'or') and not s.in_python_file:
|
|
kind = s.sy
|
|
s.next()
|
|
if s.sy == 'IDENT' and s.systring == 'None':
|
|
s.next()
|
|
else:
|
|
s.error("Expected 'None'")
|
|
if not in_pyfunc:
|
|
error(pos, "'%s None' only allowed in Python functions" % kind)
|
|
or_none = kind == 'or'
|
|
not_none = kind == 'not'
|
|
if annotated and s.sy == ':':
|
|
s.next()
|
|
annotation = p_test(s)
|
|
if s.sy == '=':
|
|
s.next()
|
|
if 'pxd' in ctx.level:
|
|
if s.sy in ['*', '?']:
|
|
# TODO(github/1736): Make this an error for inline declarations.
|
|
default = ExprNodes.NoneNode(pos)
|
|
s.next()
|
|
elif 'inline' in ctx.modifiers:
|
|
default = p_test(s)
|
|
else:
|
|
error(pos, "default values cannot be specified in pxd files, use ? or *")
|
|
else:
|
|
default = p_test(s)
|
|
return Nodes.CArgDeclNode(pos,
|
|
base_type = base_type,
|
|
declarator = declarator,
|
|
not_none = not_none,
|
|
or_none = or_none,
|
|
default = default,
|
|
annotation = annotation,
|
|
kw_only = kw_only)
|
|
|
|
def p_api(s):
|
|
if s.sy == 'IDENT' and s.systring == 'api':
|
|
s.next()
|
|
return 1
|
|
else:
|
|
return 0
|
|
|
|
def p_cdef_statement(s, ctx):
|
|
pos = s.position()
|
|
ctx.visibility = p_visibility(s, ctx.visibility)
|
|
ctx.api = ctx.api or p_api(s)
|
|
if ctx.api:
|
|
if ctx.visibility not in ('private', 'public'):
|
|
error(pos, "Cannot combine 'api' with '%s'" % ctx.visibility)
|
|
if (ctx.visibility == 'extern') and s.sy == 'from':
|
|
return p_cdef_extern_block(s, pos, ctx)
|
|
elif s.sy == 'import':
|
|
s.next()
|
|
return p_cdef_extern_block(s, pos, ctx)
|
|
elif p_nogil(s):
|
|
ctx.nogil = 1
|
|
if ctx.overridable:
|
|
error(pos, "cdef blocks cannot be declared cpdef")
|
|
return p_cdef_block(s, ctx)
|
|
elif s.sy == ':':
|
|
if ctx.overridable:
|
|
error(pos, "cdef blocks cannot be declared cpdef")
|
|
return p_cdef_block(s, ctx)
|
|
elif s.sy == 'class':
|
|
if ctx.level not in ('module', 'module_pxd'):
|
|
error(pos, "Extension type definition not allowed here")
|
|
if ctx.overridable:
|
|
error(pos, "Extension types cannot be declared cpdef")
|
|
return p_c_class_definition(s, pos, ctx)
|
|
elif s.sy == 'IDENT' and s.systring == 'cppclass':
|
|
return p_cpp_class_definition(s, pos, ctx)
|
|
elif s.sy == 'IDENT' and s.systring in struct_enum_union:
|
|
if ctx.level not in ('module', 'module_pxd'):
|
|
error(pos, "C struct/union/enum definition not allowed here")
|
|
if ctx.overridable:
|
|
if s.systring != 'enum':
|
|
error(pos, "C struct/union cannot be declared cpdef")
|
|
return p_struct_enum(s, pos, ctx)
|
|
elif s.sy == 'IDENT' and s.systring == 'fused':
|
|
return p_fused_definition(s, pos, ctx)
|
|
else:
|
|
return p_c_func_or_var_declaration(s, pos, ctx)
|
|
|
|
def p_cdef_block(s, ctx):
|
|
return p_suite(s, ctx(cdef_flag = 1))
|
|
|
|
def p_cdef_extern_block(s, pos, ctx):
|
|
if ctx.overridable:
|
|
error(pos, "cdef extern blocks cannot be declared cpdef")
|
|
include_file = None
|
|
s.expect('from')
|
|
if s.sy == '*':
|
|
s.next()
|
|
else:
|
|
include_file = p_string_literal(s, 'u')[2]
|
|
ctx = ctx(cdef_flag = 1, visibility = 'extern')
|
|
if s.systring == "namespace":
|
|
s.next()
|
|
ctx.namespace = p_string_literal(s, 'u')[2]
|
|
if p_nogil(s):
|
|
ctx.nogil = 1
|
|
|
|
# Use "docstring" as verbatim string to include
|
|
verbatim_include, body = p_suite_with_docstring(s, ctx, True)
|
|
|
|
return Nodes.CDefExternNode(pos,
|
|
include_file = include_file,
|
|
verbatim_include = verbatim_include,
|
|
body = body,
|
|
namespace = ctx.namespace)
|
|
|
|
def p_c_enum_definition(s, pos, ctx):
|
|
# s.sy == ident 'enum'
|
|
s.next()
|
|
if s.sy == 'IDENT':
|
|
name = s.systring
|
|
s.next()
|
|
cname = p_opt_cname(s)
|
|
if cname is None and ctx.namespace is not None:
|
|
cname = ctx.namespace + "::" + name
|
|
else:
|
|
name = None
|
|
cname = None
|
|
items = None
|
|
s.expect(':')
|
|
items = []
|
|
if s.sy != 'NEWLINE':
|
|
p_c_enum_line(s, ctx, items)
|
|
else:
|
|
s.next() # 'NEWLINE'
|
|
s.expect_indent()
|
|
while s.sy not in ('DEDENT', 'EOF'):
|
|
p_c_enum_line(s, ctx, items)
|
|
s.expect_dedent()
|
|
return Nodes.CEnumDefNode(
|
|
pos, name = name, cname = cname, items = items,
|
|
typedef_flag = ctx.typedef_flag, visibility = ctx.visibility,
|
|
create_wrapper = ctx.overridable,
|
|
api = ctx.api, in_pxd = ctx.level == 'module_pxd')
|
|
|
|
def p_c_enum_line(s, ctx, items):
|
|
if s.sy != 'pass':
|
|
p_c_enum_item(s, ctx, items)
|
|
while s.sy == ',':
|
|
s.next()
|
|
if s.sy in ('NEWLINE', 'EOF'):
|
|
break
|
|
p_c_enum_item(s, ctx, items)
|
|
else:
|
|
s.next()
|
|
s.expect_newline("Syntax error in enum item list")
|
|
|
|
def p_c_enum_item(s, ctx, items):
|
|
pos = s.position()
|
|
name = p_ident(s)
|
|
cname = p_opt_cname(s)
|
|
if cname is None and ctx.namespace is not None:
|
|
cname = ctx.namespace + "::" + name
|
|
value = None
|
|
if s.sy == '=':
|
|
s.next()
|
|
value = p_test(s)
|
|
items.append(Nodes.CEnumDefItemNode(pos,
|
|
name = name, cname = cname, value = value))
|
|
|
|
def p_c_struct_or_union_definition(s, pos, ctx):
|
|
packed = False
|
|
if s.systring == 'packed':
|
|
packed = True
|
|
s.next()
|
|
if s.sy != 'IDENT' or s.systring != 'struct':
|
|
s.expected('struct')
|
|
# s.sy == ident 'struct' or 'union'
|
|
kind = s.systring
|
|
s.next()
|
|
name = p_ident(s)
|
|
cname = p_opt_cname(s)
|
|
if cname is None and ctx.namespace is not None:
|
|
cname = ctx.namespace + "::" + name
|
|
attributes = None
|
|
if s.sy == ':':
|
|
s.next()
|
|
s.expect('NEWLINE')
|
|
s.expect_indent()
|
|
attributes = []
|
|
body_ctx = Ctx()
|
|
while s.sy != 'DEDENT':
|
|
if s.sy != 'pass':
|
|
attributes.append(
|
|
p_c_func_or_var_declaration(s, s.position(), body_ctx))
|
|
else:
|
|
s.next()
|
|
s.expect_newline("Expected a newline")
|
|
s.expect_dedent()
|
|
else:
|
|
s.expect_newline("Syntax error in struct or union definition")
|
|
return Nodes.CStructOrUnionDefNode(pos,
|
|
name = name, cname = cname, kind = kind, attributes = attributes,
|
|
typedef_flag = ctx.typedef_flag, visibility = ctx.visibility,
|
|
api = ctx.api, in_pxd = ctx.level == 'module_pxd', packed = packed)
|
|
|
|
def p_fused_definition(s, pos, ctx):
|
|
"""
|
|
c(type)def fused my_fused_type:
|
|
...
|
|
"""
|
|
# s.systring == 'fused'
|
|
|
|
if ctx.level not in ('module', 'module_pxd'):
|
|
error(pos, "Fused type definition not allowed here")
|
|
|
|
s.next()
|
|
name = p_ident(s)
|
|
|
|
s.expect(":")
|
|
s.expect_newline()
|
|
s.expect_indent()
|
|
|
|
types = []
|
|
while s.sy != 'DEDENT':
|
|
if s.sy != 'pass':
|
|
#types.append(p_c_declarator(s))
|
|
types.append(p_c_base_type(s)) #, nonempty=1))
|
|
else:
|
|
s.next()
|
|
|
|
s.expect_newline()
|
|
|
|
s.expect_dedent()
|
|
|
|
if not types:
|
|
error(pos, "Need at least one type")
|
|
|
|
return Nodes.FusedTypeNode(pos, name=name, types=types)
|
|
|
|
def p_struct_enum(s, pos, ctx):
|
|
if s.systring == 'enum':
|
|
return p_c_enum_definition(s, pos, ctx)
|
|
else:
|
|
return p_c_struct_or_union_definition(s, pos, ctx)
|
|
|
|
def p_visibility(s, prev_visibility):
|
|
pos = s.position()
|
|
visibility = prev_visibility
|
|
if s.sy == 'IDENT' and s.systring in ('extern', 'public', 'readonly'):
|
|
visibility = s.systring
|
|
if prev_visibility != 'private' and visibility != prev_visibility:
|
|
s.error("Conflicting visibility options '%s' and '%s'"
|
|
% (prev_visibility, visibility), fatal=False)
|
|
s.next()
|
|
return visibility
|
|
|
|
def p_c_modifiers(s):
|
|
if s.sy == 'IDENT' and s.systring in ('inline',):
|
|
modifier = s.systring
|
|
s.next()
|
|
return [modifier] + p_c_modifiers(s)
|
|
return []
|
|
|
|
def p_c_func_or_var_declaration(s, pos, ctx):
|
|
cmethod_flag = ctx.level in ('c_class', 'c_class_pxd')
|
|
modifiers = p_c_modifiers(s)
|
|
base_type = p_c_base_type(s, nonempty = 1, templates = ctx.templates)
|
|
declarator = p_c_declarator(s, ctx(modifiers=modifiers), cmethod_flag = cmethod_flag,
|
|
assignable = 1, nonempty = 1)
|
|
declarator.overridable = ctx.overridable
|
|
if s.sy == 'IDENT' and s.systring == 'const' and ctx.level == 'cpp_class':
|
|
s.next()
|
|
is_const_method = 1
|
|
else:
|
|
is_const_method = 0
|
|
if s.sy == '->':
|
|
# Special enough to give a better error message and keep going.
|
|
s.error(
|
|
"Return type annotation is not allowed in cdef/cpdef signatures. "
|
|
"Please define it before the function name, as in C signatures.",
|
|
fatal=False)
|
|
s.next()
|
|
p_test(s) # Keep going, but ignore result.
|
|
if s.sy == ':':
|
|
if ctx.level not in ('module', 'c_class', 'module_pxd', 'c_class_pxd', 'cpp_class') and not ctx.templates:
|
|
s.error("C function definition not allowed here")
|
|
doc, suite = p_suite_with_docstring(s, Ctx(level='function'))
|
|
result = Nodes.CFuncDefNode(pos,
|
|
visibility = ctx.visibility,
|
|
base_type = base_type,
|
|
declarator = declarator,
|
|
body = suite,
|
|
doc = doc,
|
|
modifiers = modifiers,
|
|
api = ctx.api,
|
|
overridable = ctx.overridable,
|
|
is_const_method = is_const_method)
|
|
else:
|
|
#if api:
|
|
# s.error("'api' not allowed with variable declaration")
|
|
if is_const_method:
|
|
declarator.is_const_method = is_const_method
|
|
declarators = [declarator]
|
|
while s.sy == ',':
|
|
s.next()
|
|
if s.sy == 'NEWLINE':
|
|
break
|
|
declarator = p_c_declarator(s, ctx, cmethod_flag = cmethod_flag,
|
|
assignable = 1, nonempty = 1)
|
|
declarators.append(declarator)
|
|
doc_line = s.start_line + 1
|
|
s.expect_newline("Syntax error in C variable declaration", ignore_semicolon=True)
|
|
if ctx.level in ('c_class', 'c_class_pxd') and s.start_line == doc_line:
|
|
doc = p_doc_string(s)
|
|
else:
|
|
doc = None
|
|
result = Nodes.CVarDefNode(pos,
|
|
visibility = ctx.visibility,
|
|
base_type = base_type,
|
|
declarators = declarators,
|
|
in_pxd = ctx.level in ('module_pxd', 'c_class_pxd'),
|
|
doc = doc,
|
|
api = ctx.api,
|
|
modifiers = modifiers,
|
|
overridable = ctx.overridable)
|
|
return result
|
|
|
|
def p_ctypedef_statement(s, ctx):
|
|
# s.sy == 'ctypedef'
|
|
pos = s.position()
|
|
s.next()
|
|
visibility = p_visibility(s, ctx.visibility)
|
|
api = p_api(s)
|
|
ctx = ctx(typedef_flag = 1, visibility = visibility)
|
|
if api:
|
|
ctx.api = 1
|
|
if s.sy == 'class':
|
|
return p_c_class_definition(s, pos, ctx)
|
|
elif s.sy == 'IDENT' and s.systring in struct_enum_union:
|
|
return p_struct_enum(s, pos, ctx)
|
|
elif s.sy == 'IDENT' and s.systring == 'fused':
|
|
return p_fused_definition(s, pos, ctx)
|
|
else:
|
|
base_type = p_c_base_type(s, nonempty = 1)
|
|
declarator = p_c_declarator(s, ctx, is_type = 1, nonempty = 1)
|
|
s.expect_newline("Syntax error in ctypedef statement", ignore_semicolon=True)
|
|
return Nodes.CTypeDefNode(
|
|
pos, base_type = base_type,
|
|
declarator = declarator,
|
|
visibility = visibility, api = api,
|
|
in_pxd = ctx.level == 'module_pxd')
|
|
|
|
def p_decorators(s):
|
|
decorators = []
|
|
while s.sy == '@':
|
|
pos = s.position()
|
|
s.next()
|
|
decstring = p_dotted_name(s, as_allowed=0)[2]
|
|
names = decstring.split('.')
|
|
decorator = ExprNodes.NameNode(pos, name=s.context.intern_ustring(names[0]))
|
|
for name in names[1:]:
|
|
decorator = ExprNodes.AttributeNode(
|
|
pos, attribute=s.context.intern_ustring(name), obj=decorator)
|
|
if s.sy == '(':
|
|
decorator = p_call(s, decorator)
|
|
decorators.append(Nodes.DecoratorNode(pos, decorator=decorator))
|
|
s.expect_newline("Expected a newline after decorator")
|
|
return decorators
|
|
|
|
|
|
def _reject_cdef_modifier_in_py(s, name):
|
|
"""Step over incorrectly placed cdef modifiers (@see _CDEF_MODIFIERS) to provide a good error message for them.
|
|
"""
|
|
if s.sy == 'IDENT' and name in _CDEF_MODIFIERS:
|
|
# Special enough to provide a good error message.
|
|
s.error("Cannot use cdef modifier '%s' in Python function signature. Use a decorator instead." % name, fatal=False)
|
|
return p_ident(s) # Keep going, in case there are other errors.
|
|
return name
|
|
|
|
|
|
def p_def_statement(s, decorators=None, is_async_def=False):
|
|
# s.sy == 'def'
|
|
pos = s.position()
|
|
# PEP 492 switches the async/await keywords on in "async def" functions
|
|
if is_async_def:
|
|
s.enter_async()
|
|
s.next()
|
|
name = _reject_cdef_modifier_in_py(s, p_ident(s))
|
|
s.expect(
|
|
'(',
|
|
"Expected '(', found '%s'. Did you use cdef syntax in a Python declaration? "
|
|
"Use decorators and Python type annotations instead." % (
|
|
s.systring if s.sy == 'IDENT' else s.sy))
|
|
args, star_arg, starstar_arg = p_varargslist(s, terminator=')')
|
|
s.expect(')')
|
|
_reject_cdef_modifier_in_py(s, s.systring)
|
|
return_type_annotation = None
|
|
if s.sy == '->':
|
|
s.next()
|
|
return_type_annotation = p_test(s)
|
|
_reject_cdef_modifier_in_py(s, s.systring)
|
|
|
|
doc, body = p_suite_with_docstring(s, Ctx(level='function'))
|
|
if is_async_def:
|
|
s.exit_async()
|
|
|
|
return Nodes.DefNode(
|
|
pos, name=name, args=args, star_arg=star_arg, starstar_arg=starstar_arg,
|
|
doc=doc, body=body, decorators=decorators, is_async_def=is_async_def,
|
|
return_type_annotation=return_type_annotation)
|
|
|
|
|
|
def p_varargslist(s, terminator=')', annotated=1):
|
|
args = p_c_arg_list(s, in_pyfunc = 1, nonempty_declarators = 1,
|
|
annotated = annotated)
|
|
star_arg = None
|
|
starstar_arg = None
|
|
if s.sy == '*':
|
|
s.next()
|
|
if s.sy == 'IDENT':
|
|
star_arg = p_py_arg_decl(s, annotated=annotated)
|
|
if s.sy == ',':
|
|
s.next()
|
|
args.extend(p_c_arg_list(s, in_pyfunc = 1,
|
|
nonempty_declarators = 1, kw_only = 1, annotated = annotated))
|
|
elif s.sy != terminator:
|
|
s.error("Syntax error in Python function argument list")
|
|
if s.sy == '**':
|
|
s.next()
|
|
starstar_arg = p_py_arg_decl(s, annotated=annotated)
|
|
if s.sy == ',':
|
|
s.next()
|
|
return (args, star_arg, starstar_arg)
|
|
|
|
def p_py_arg_decl(s, annotated = 1):
|
|
pos = s.position()
|
|
name = p_ident(s)
|
|
annotation = None
|
|
if annotated and s.sy == ':':
|
|
s.next()
|
|
annotation = p_test(s)
|
|
return Nodes.PyArgDeclNode(pos, name = name, annotation = annotation)
|
|
|
|
|
|
def p_class_statement(s, decorators):
|
|
# s.sy == 'class'
|
|
pos = s.position()
|
|
s.next()
|
|
class_name = EncodedString(p_ident(s))
|
|
class_name.encoding = s.source_encoding # FIXME: why is this needed?
|
|
arg_tuple = None
|
|
keyword_dict = None
|
|
if s.sy == '(':
|
|
positional_args, keyword_args = p_call_parse_args(s, allow_genexp=False)
|
|
arg_tuple, keyword_dict = p_call_build_packed_args(pos, positional_args, keyword_args)
|
|
if arg_tuple is None:
|
|
# XXX: empty arg_tuple
|
|
arg_tuple = ExprNodes.TupleNode(pos, args=[])
|
|
doc, body = p_suite_with_docstring(s, Ctx(level='class'))
|
|
return Nodes.PyClassDefNode(
|
|
pos, name=class_name,
|
|
bases=arg_tuple,
|
|
keyword_args=keyword_dict,
|
|
doc=doc, body=body, decorators=decorators,
|
|
force_py3_semantics=s.context.language_level >= 3)
|
|
|
|
|
|
def p_c_class_definition(s, pos, ctx):
|
|
# s.sy == 'class'
|
|
s.next()
|
|
module_path = []
|
|
class_name = p_ident(s)
|
|
while s.sy == '.':
|
|
s.next()
|
|
module_path.append(class_name)
|
|
class_name = p_ident(s)
|
|
if module_path and ctx.visibility != 'extern':
|
|
error(pos, "Qualified class name only allowed for 'extern' C class")
|
|
if module_path and s.sy == 'IDENT' and s.systring == 'as':
|
|
s.next()
|
|
as_name = p_ident(s)
|
|
else:
|
|
as_name = class_name
|
|
objstruct_name = None
|
|
typeobj_name = None
|
|
bases = None
|
|
check_size = None
|
|
if s.sy == '(':
|
|
positional_args, keyword_args = p_call_parse_args(s, allow_genexp=False)
|
|
if keyword_args:
|
|
s.error("C classes cannot take keyword bases.")
|
|
bases, _ = p_call_build_packed_args(pos, positional_args, keyword_args)
|
|
if bases is None:
|
|
bases = ExprNodes.TupleNode(pos, args=[])
|
|
|
|
if s.sy == '[':
|
|
if ctx.visibility not in ('public', 'extern') and not ctx.api:
|
|
error(s.position(), "Name options only allowed for 'public', 'api', or 'extern' C class")
|
|
objstruct_name, typeobj_name, check_size = p_c_class_options(s)
|
|
if s.sy == ':':
|
|
if ctx.level == 'module_pxd':
|
|
body_level = 'c_class_pxd'
|
|
else:
|
|
body_level = 'c_class'
|
|
doc, body = p_suite_with_docstring(s, Ctx(level=body_level))
|
|
else:
|
|
s.expect_newline("Syntax error in C class definition")
|
|
doc = None
|
|
body = None
|
|
if ctx.visibility == 'extern':
|
|
if not module_path:
|
|
error(pos, "Module name required for 'extern' C class")
|
|
if typeobj_name:
|
|
error(pos, "Type object name specification not allowed for 'extern' C class")
|
|
elif ctx.visibility == 'public':
|
|
if not objstruct_name:
|
|
error(pos, "Object struct name specification required for 'public' C class")
|
|
if not typeobj_name:
|
|
error(pos, "Type object name specification required for 'public' C class")
|
|
elif ctx.visibility == 'private':
|
|
if ctx.api:
|
|
if not objstruct_name:
|
|
error(pos, "Object struct name specification required for 'api' C class")
|
|
if not typeobj_name:
|
|
error(pos, "Type object name specification required for 'api' C class")
|
|
else:
|
|
error(pos, "Invalid class visibility '%s'" % ctx.visibility)
|
|
return Nodes.CClassDefNode(pos,
|
|
visibility = ctx.visibility,
|
|
typedef_flag = ctx.typedef_flag,
|
|
api = ctx.api,
|
|
module_name = ".".join(module_path),
|
|
class_name = class_name,
|
|
as_name = as_name,
|
|
bases = bases,
|
|
objstruct_name = objstruct_name,
|
|
typeobj_name = typeobj_name,
|
|
check_size = check_size,
|
|
in_pxd = ctx.level == 'module_pxd',
|
|
doc = doc,
|
|
body = body)
|
|
|
|
|
|
def p_c_class_options(s):
|
|
objstruct_name = None
|
|
typeobj_name = None
|
|
check_size = None
|
|
s.expect('[')
|
|
while 1:
|
|
if s.sy != 'IDENT':
|
|
break
|
|
if s.systring == 'object':
|
|
s.next()
|
|
objstruct_name = p_ident(s)
|
|
elif s.systring == 'type':
|
|
s.next()
|
|
typeobj_name = p_ident(s)
|
|
elif s.systring == 'check_size':
|
|
s.next()
|
|
check_size = p_ident(s)
|
|
if check_size not in ('ignore', 'warn', 'error'):
|
|
s.error("Expected one of ignore, warn or error, found %r" % check_size)
|
|
if s.sy != ',':
|
|
break
|
|
s.next()
|
|
s.expect(']', "Expected 'object', 'type' or 'check_size'")
|
|
return objstruct_name, typeobj_name, check_size
|
|
|
|
|
|
def p_property_decl(s):
|
|
pos = s.position()
|
|
s.next() # 'property'
|
|
name = p_ident(s)
|
|
doc, body = p_suite_with_docstring(
|
|
s, Ctx(level='property'), with_doc_only=True)
|
|
return Nodes.PropertyNode(pos, name=name, doc=doc, body=body)
|
|
|
|
|
|
def p_ignorable_statement(s):
|
|
"""
|
|
Parses any kind of ignorable statement that is allowed in .pxd files.
|
|
"""
|
|
if s.sy == 'BEGIN_STRING':
|
|
pos = s.position()
|
|
string_node = p_atom(s)
|
|
s.expect_newline("Syntax error in string", ignore_semicolon=True)
|
|
return Nodes.ExprStatNode(pos, expr=string_node)
|
|
return None
|
|
|
|
|
|
def p_doc_string(s):
|
|
if s.sy == 'BEGIN_STRING':
|
|
pos = s.position()
|
|
kind, bytes_result, unicode_result = p_cat_string_literal(s)
|
|
s.expect_newline("Syntax error in doc string", ignore_semicolon=True)
|
|
if kind in ('u', ''):
|
|
return unicode_result
|
|
warning(pos, "Python 3 requires docstrings to be unicode strings")
|
|
return bytes_result
|
|
else:
|
|
return None
|
|
|
|
|
|
def _extract_docstring(node):
|
|
"""
|
|
Extract a docstring from a statement or from the first statement
|
|
in a list. Remove the statement if found. Return a tuple
|
|
(plain-docstring or None, node).
|
|
"""
|
|
doc_node = None
|
|
if node is None:
|
|
pass
|
|
elif isinstance(node, Nodes.ExprStatNode):
|
|
if node.expr.is_string_literal:
|
|
doc_node = node.expr
|
|
node = Nodes.StatListNode(node.pos, stats=[])
|
|
elif isinstance(node, Nodes.StatListNode) and node.stats:
|
|
stats = node.stats
|
|
if isinstance(stats[0], Nodes.ExprStatNode):
|
|
if stats[0].expr.is_string_literal:
|
|
doc_node = stats[0].expr
|
|
del stats[0]
|
|
|
|
if doc_node is None:
|
|
doc = None
|
|
elif isinstance(doc_node, ExprNodes.BytesNode):
|
|
warning(node.pos,
|
|
"Python 3 requires docstrings to be unicode strings")
|
|
doc = doc_node.value
|
|
elif isinstance(doc_node, ExprNodes.StringNode):
|
|
doc = doc_node.unicode_value
|
|
if doc is None:
|
|
doc = doc_node.value
|
|
else:
|
|
doc = doc_node.value
|
|
return doc, node
|
|
|
|
|
|
def p_code(s, level=None, ctx=Ctx):
|
|
body = p_statement_list(s, ctx(level = level), first_statement = 1)
|
|
if s.sy != 'EOF':
|
|
s.error("Syntax error in statement [%s,%s]" % (
|
|
repr(s.sy), repr(s.systring)))
|
|
return body
|
|
|
|
|
|
_match_compiler_directive_comment = cython.declare(object, re.compile(
|
|
r"^#\s*cython\s*:\s*((\w|[.])+\s*=.*)$").match)
|
|
|
|
|
|
def p_compiler_directive_comments(s):
|
|
result = {}
|
|
while s.sy == 'commentline':
|
|
pos = s.position()
|
|
m = _match_compiler_directive_comment(s.systring)
|
|
if m:
|
|
directives_string = m.group(1).strip()
|
|
try:
|
|
new_directives = Options.parse_directive_list(directives_string, ignore_unknown=True)
|
|
except ValueError as e:
|
|
s.error(e.args[0], fatal=False)
|
|
s.next()
|
|
continue
|
|
|
|
for name in new_directives:
|
|
if name not in result:
|
|
pass
|
|
elif new_directives[name] == result[name]:
|
|
warning(pos, "Duplicate directive found: %s" % (name,))
|
|
else:
|
|
s.error("Conflicting settings found for top-level directive %s: %r and %r" % (
|
|
name, result[name], new_directives[name]), pos=pos)
|
|
|
|
if 'language_level' in new_directives:
|
|
# Make sure we apply the language level already to the first token that follows the comments.
|
|
s.context.set_language_level(new_directives['language_level'])
|
|
|
|
result.update(new_directives)
|
|
|
|
s.next()
|
|
return result
|
|
|
|
|
|
def p_module(s, pxd, full_module_name, ctx=Ctx):
|
|
pos = s.position()
|
|
|
|
directive_comments = p_compiler_directive_comments(s)
|
|
s.parse_comments = False
|
|
|
|
if s.context.language_level is None:
|
|
s.context.set_language_level(2)
|
|
if pos[0].filename:
|
|
import warnings
|
|
warnings.warn(
|
|
"Cython directive 'language_level' not set, using 2 for now (Py2). "
|
|
"This will change in a later release! File: %s" % pos[0].filename,
|
|
FutureWarning,
|
|
stacklevel=1 if cython.compiled else 2,
|
|
)
|
|
|
|
doc = p_doc_string(s)
|
|
if pxd:
|
|
level = 'module_pxd'
|
|
else:
|
|
level = 'module'
|
|
|
|
body = p_statement_list(s, ctx(level=level), first_statement = 1)
|
|
if s.sy != 'EOF':
|
|
s.error("Syntax error in statement [%s,%s]" % (
|
|
repr(s.sy), repr(s.systring)))
|
|
return ModuleNode(pos, doc = doc, body = body,
|
|
full_module_name = full_module_name,
|
|
directive_comments = directive_comments)
|
|
|
|
def p_template_definition(s):
|
|
name = p_ident(s)
|
|
if s.sy == '=':
|
|
s.expect('=')
|
|
s.expect('*')
|
|
required = False
|
|
else:
|
|
required = True
|
|
return name, required
|
|
|
|
def p_cpp_class_definition(s, pos, ctx):
|
|
# s.sy == 'cppclass'
|
|
s.next()
|
|
module_path = []
|
|
class_name = p_ident(s)
|
|
cname = p_opt_cname(s)
|
|
if cname is None and ctx.namespace is not None:
|
|
cname = ctx.namespace + "::" + class_name
|
|
if s.sy == '.':
|
|
error(pos, "Qualified class name not allowed C++ class")
|
|
if s.sy == '[':
|
|
s.next()
|
|
templates = [p_template_definition(s)]
|
|
while s.sy == ',':
|
|
s.next()
|
|
templates.append(p_template_definition(s))
|
|
s.expect(']')
|
|
template_names = [name for name, required in templates]
|
|
else:
|
|
templates = None
|
|
template_names = None
|
|
if s.sy == '(':
|
|
s.next()
|
|
base_classes = [p_c_base_type(s, templates = template_names)]
|
|
while s.sy == ',':
|
|
s.next()
|
|
base_classes.append(p_c_base_type(s, templates = template_names))
|
|
s.expect(')')
|
|
else:
|
|
base_classes = []
|
|
if s.sy == '[':
|
|
error(s.position(), "Name options not allowed for C++ class")
|
|
nogil = p_nogil(s)
|
|
if s.sy == ':':
|
|
s.next()
|
|
s.expect('NEWLINE')
|
|
s.expect_indent()
|
|
attributes = []
|
|
body_ctx = Ctx(visibility = ctx.visibility, level='cpp_class', nogil=nogil or ctx.nogil)
|
|
body_ctx.templates = template_names
|
|
while s.sy != 'DEDENT':
|
|
if s.sy != 'pass':
|
|
attributes.append(p_cpp_class_attribute(s, body_ctx))
|
|
else:
|
|
s.next()
|
|
s.expect_newline("Expected a newline")
|
|
s.expect_dedent()
|
|
else:
|
|
attributes = None
|
|
s.expect_newline("Syntax error in C++ class definition")
|
|
return Nodes.CppClassNode(pos,
|
|
name = class_name,
|
|
cname = cname,
|
|
base_classes = base_classes,
|
|
visibility = ctx.visibility,
|
|
in_pxd = ctx.level == 'module_pxd',
|
|
attributes = attributes,
|
|
templates = templates)
|
|
|
|
def p_cpp_class_attribute(s, ctx):
|
|
decorators = None
|
|
if s.sy == '@':
|
|
decorators = p_decorators(s)
|
|
if s.systring == 'cppclass':
|
|
return p_cpp_class_definition(s, s.position(), ctx)
|
|
elif s.systring == 'ctypedef':
|
|
return p_ctypedef_statement(s, ctx)
|
|
elif s.sy == 'IDENT' and s.systring in struct_enum_union:
|
|
if s.systring != 'enum':
|
|
return p_cpp_class_definition(s, s.position(), ctx)
|
|
else:
|
|
return p_struct_enum(s, s.position(), ctx)
|
|
else:
|
|
node = p_c_func_or_var_declaration(s, s.position(), ctx)
|
|
if decorators is not None:
|
|
tup = Nodes.CFuncDefNode, Nodes.CVarDefNode, Nodes.CClassDefNode
|
|
if ctx.allow_struct_enum_decorator:
|
|
tup += Nodes.CStructOrUnionDefNode, Nodes.CEnumDefNode
|
|
if not isinstance(node, tup):
|
|
s.error("Decorators can only be followed by functions or classes")
|
|
node.decorators = decorators
|
|
return node
|
|
|
|
|
|
#----------------------------------------------
|
|
#
|
|
# Debugging
|
|
#
|
|
#----------------------------------------------
|
|
|
|
def print_parse_tree(f, node, level, key = None):
|
|
ind = " " * level
|
|
if node:
|
|
f.write(ind)
|
|
if key:
|
|
f.write("%s: " % key)
|
|
t = type(node)
|
|
if t is tuple:
|
|
f.write("(%s @ %s\n" % (node[0], node[1]))
|
|
for i in range(2, len(node)):
|
|
print_parse_tree(f, node[i], level+1)
|
|
f.write("%s)\n" % ind)
|
|
return
|
|
elif isinstance(node, Nodes.Node):
|
|
try:
|
|
tag = node.tag
|
|
except AttributeError:
|
|
tag = node.__class__.__name__
|
|
f.write("%s @ %s\n" % (tag, node.pos))
|
|
for name, value in node.__dict__.items():
|
|
if name != 'tag' and name != 'pos':
|
|
print_parse_tree(f, value, level+1, name)
|
|
return
|
|
elif t is list:
|
|
f.write("[\n")
|
|
for i in range(len(node)):
|
|
print_parse_tree(f, node[i], level+1)
|
|
f.write("%s]\n" % ind)
|
|
return
|
|
f.write("%s%s\n" % (ind, node))
|