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# -*- coding: utf-8 -*-
#
# Copyright (C) 2008-2009 Edgewall Software
# All rights reserved.
#
# This software is licensed as described in the file COPYING, which
# you should have received as part of this distribution. The terms
# are also available at http://genshi.edgewall.org/wiki/License.
#
# This software consists of voluntary contributions made by many
# individuals. For the exact contribution history, see the revision
# history and logs, available at http://genshi.edgewall.org/log/.
"""Emulation of the proper abstract syntax tree API for Python 2.4."""
import compiler
import compiler.ast
from genshi.template import _ast24 as _ast
__all__ = ['_ast', 'parse']
__docformat__ = 'restructuredtext en'
def _new(cls, *args, **kwargs):
ret = cls()
if ret._fields:
for attr, value in zip(ret._fields, args):
if attr in kwargs:
raise ValueError('Field set both in args and kwargs')
setattr(ret, attr, value)
for attr in kwargs:
if (getattr(ret, '_fields', None) and attr in ret._fields) \
or (getattr(ret, '_attributes', None) and
attr in ret._attributes):
setattr(ret, attr, kwargs[attr])
return ret
class ASTUpgrader(object):
"""Transformer changing structure of Python 2.4 ASTs to
Python 2.5 ones.
Transforms ``compiler.ast`` Abstract Syntax Tree to builtin ``_ast``.
It can use fake`` _ast`` classes and this way allow ``_ast`` emulation
in Python 2.4.
"""
def __init__(self):
self.out_flags = None
self.lines = [-1]
def _new(self, *args, **kwargs):
return _new(lineno = self.lines[-1], *args, **kwargs)
def visit(self, node):
if node is None:
return None
if type(node) is tuple:
return tuple([self.visit(n) for n in node])
lno = getattr(node, 'lineno', None)
if lno is not None:
self.lines.append(lno)
visitor = getattr(self, 'visit_%s' % node.__class__.__name__, None)
if visitor is None:
raise Exception('Unhandled node type %r' % type(node))
retval = visitor(node)
if lno is not None:
self.lines.pop()
return retval
def visit_Module(self, node):
body = self.visit(node.node)
if node.doc:
body = [self._new(_ast.Expr, self._new(_ast.Str, node.doc))] + body
return self._new(_ast.Module, body)
def visit_Expression(self, node):
return self._new(_ast.Expression, self.visit(node.node))
def _extract_args(self, node):
tab = node.argnames[:]
if node.flags & compiler.ast.CO_VARKEYWORDS:
kwarg = tab[-1]
tab = tab[:-1]
else:
kwarg = None
if node.flags & compiler.ast.CO_VARARGS:
vararg = tab[-1]
tab = tab[:-1]
else:
vararg = None
def _tup(t):
if isinstance(t, str):
return self._new(_ast.Name, t, _ast.Store())
elif isinstance(t, tuple):
elts = [_tup(x) for x in t]
return self._new(_ast.Tuple, elts, _ast.Store())
else:
raise NotImplemented
args = []
for arg in tab:
if isinstance(arg, str):
args.append(self._new(_ast.Name, arg, _ast.Param()))
elif isinstance(arg, tuple):
args.append(_tup(arg))
else:
assert False, node.__class__
defaults = [self.visit(d) for d in node.defaults]
return self._new(_ast.arguments, args, vararg, kwarg, defaults)
def visit_Function(self, node):
if getattr(node, 'decorators', ()):
decorators = [self.visit(d) for d in node.decorators.nodes]
else:
decorators = []
args = self._extract_args(node)
body = self.visit(node.code)
if node.doc:
body = [self._new(_ast.Expr, self._new(_ast.Str, node.doc))] + body
return self._new(_ast.FunctionDef, node.name, args, body, decorators)
def visit_Class(self, node):
#self.name_types.append(_ast.Load)
bases = [self.visit(b) for b in node.bases]
#self.name_types.pop()
body = self.visit(node.code)
if node.doc:
body = [self._new(_ast.Expr, self._new(_ast.Str, node.doc))] + body
return self._new(_ast.ClassDef, node.name, bases, body)
def visit_Return(self, node):
return self._new(_ast.Return, self.visit(node.value))
def visit_Assign(self, node):
#self.name_types.append(_ast.Store)
targets = [self.visit(t) for t in node.nodes]
#self.name_types.pop()
return self._new(_ast.Assign, targets, self.visit(node.expr))
aug_operators = {
'+=': _ast.Add,
'/=': _ast.Div,
'//=': _ast.FloorDiv,
'<<=': _ast.LShift,
'%=': _ast.Mod,
'*=': _ast.Mult,
'**=': _ast.Pow,
'>>=': _ast.RShift,
'-=': _ast.Sub,
}
def visit_AugAssign(self, node):
target = self.visit(node.node)
# Because it's AugAssign target can't be list nor tuple
# so we only have to change context of one node
target.ctx = _ast.Store()
op = self.aug_operators[node.op]()
return self._new(_ast.AugAssign, target, op, self.visit(node.expr))
def _visit_Print(nl):
def _visit(self, node):
values = [self.visit(v) for v in node.nodes]
return self._new(_ast.Print, self.visit(node.dest), values, nl)
return _visit
visit_Print = _visit_Print(False)
visit_Printnl = _visit_Print(True)
del _visit_Print
def visit_For(self, node):
return self._new(_ast.For, self.visit(node.assign), self.visit(node.list),
self.visit(node.body), self.visit(node.else_))
def visit_While(self, node):
return self._new(_ast.While, self.visit(node.test), self.visit(node.body),
self.visit(node.else_))
def visit_If(self, node):
def _level(tests, else_):
test = self.visit(tests[0][0])
body = self.visit(tests[0][1])
if len(tests) == 1:
orelse = self.visit(else_)
else:
orelse = [_level(tests[1:], else_)]
return self._new(_ast.If, test, body, orelse)
return _level(node.tests, node.else_)
def visit_With(self, node):
return self._new(_ast.With, self.visit(node.expr),
self.visit(node.vars), self.visit(node.body))
def visit_Raise(self, node):
return self._new(_ast.Raise, self.visit(node.expr1),
self.visit(node.expr2), self.visit(node.expr3))
def visit_TryExcept(self, node):
handlers = []
for type, name, body in node.handlers:
handlers.append(self._new(_ast.excepthandler, self.visit(type),
self.visit(name), self.visit(body)))
return self._new(_ast.TryExcept, self.visit(node.body),
handlers, self.visit(node.else_))
def visit_TryFinally(self, node):
return self._new(_ast.TryFinally, self.visit(node.body),
self.visit(node.final))
def visit_Assert(self, node):
return self._new(_ast.Assert, self.visit(node.test), self.visit(node.fail))
def visit_Import(self, node):
names = [self._new(_ast.alias, n[0], n[1]) for n in node.names]
return self._new(_ast.Import, names)
def visit_From(self, node):
names = [self._new(_ast.alias, n[0], n[1]) for n in node.names]
return self._new(_ast.ImportFrom, node.modname, names, 0)
def visit_Exec(self, node):
return self._new(_ast.Exec, self.visit(node.expr),
self.visit(node.locals), self.visit(node.globals))
def visit_Global(self, node):
return self._new(_ast.Global, node.names[:])
def visit_Discard(self, node):
return self._new(_ast.Expr, self.visit(node.expr))
def _map_class(to):
def _visit(self, node):
return self._new(to)
return _visit
visit_Pass = _map_class(_ast.Pass)
visit_Break = _map_class(_ast.Break)
visit_Continue = _map_class(_ast.Continue)
def _visit_BinOperator(opcls):
def _visit(self, node):
return self._new(_ast.BinOp, self.visit(node.left),
opcls(), self.visit(node.right))
return _visit
visit_Add = _visit_BinOperator(_ast.Add)
visit_Div = _visit_BinOperator(_ast.Div)
visit_FloorDiv = _visit_BinOperator(_ast.FloorDiv)
visit_LeftShift = _visit_BinOperator(_ast.LShift)
visit_Mod = _visit_BinOperator(_ast.Mod)
visit_Mul = _visit_BinOperator(_ast.Mult)
visit_Power = _visit_BinOperator(_ast.Pow)
visit_RightShift = _visit_BinOperator(_ast.RShift)
visit_Sub = _visit_BinOperator(_ast.Sub)
del _visit_BinOperator
def _visit_BitOperator(opcls):
def _visit(self, node):
def _make(nodes):
if len(nodes) == 1:
return self.visit(nodes[0])
left = _make(nodes[:-1])
right = self.visit(nodes[-1])
return self._new(_ast.BinOp, left, opcls(), right)
return _make(node.nodes)
return _visit
visit_Bitand = _visit_BitOperator(_ast.BitAnd)
visit_Bitor = _visit_BitOperator(_ast.BitOr)
visit_Bitxor = _visit_BitOperator(_ast.BitXor)
del _visit_BitOperator
def _visit_UnaryOperator(opcls):
def _visit(self, node):
return self._new(_ast.UnaryOp, opcls(), self.visit(node.expr))
return _visit
visit_Invert = _visit_UnaryOperator(_ast.Invert)
visit_Not = _visit_UnaryOperator(_ast.Not)
visit_UnaryAdd = _visit_UnaryOperator(_ast.UAdd)
visit_UnarySub = _visit_UnaryOperator(_ast.USub)
del _visit_UnaryOperator
def _visit_BoolOperator(opcls):
def _visit(self, node):
values = [self.visit(n) for n in node.nodes]
return self._new(_ast.BoolOp, opcls(), values)
return _visit
visit_And = _visit_BoolOperator(_ast.And)
visit_Or = _visit_BoolOperator(_ast.Or)
del _visit_BoolOperator
cmp_operators = {
'==': _ast.Eq,
'!=': _ast.NotEq,
'<': _ast.Lt,
'<=': _ast.LtE,
'>': _ast.Gt,
'>=': _ast.GtE,
'is': _ast.Is,
'is not': _ast.IsNot,
'in': _ast.In,
'not in': _ast.NotIn,
}
def visit_Compare(self, node):
left = self.visit(node.expr)
ops = []
comparators = []
for optype, expr in node.ops:
ops.append(self.cmp_operators[optype]())
comparators.append(self.visit(expr))
return self._new(_ast.Compare, left, ops, comparators)
def visit_Lambda(self, node):
args = self._extract_args(node)
body = self.visit(node.code)
return self._new(_ast.Lambda, args, body)
def visit_IfExp(self, node):
return self._new(_ast.IfExp, self.visit(node.test), self.visit(node.then),
self.visit(node.else_))
def visit_Dict(self, node):
keys = [self.visit(x[0]) for x in node.items]
values = [self.visit(x[1]) for x in node.items]
return self._new(_ast.Dict, keys, values)
def visit_ListComp(self, node):
generators = [self.visit(q) for q in node.quals]
return self._new(_ast.ListComp, self.visit(node.expr), generators)
def visit_GenExprInner(self, node):
generators = [self.visit(q) for q in node.quals]
return self._new(_ast.GeneratorExp, self.visit(node.expr), generators)
def visit_GenExpr(self, node):
return self.visit(node.code)
def visit_GenExprFor(self, node):
ifs = [self.visit(i) for i in node.ifs]
return self._new(_ast.comprehension, self.visit(node.assign),
self.visit(node.iter), ifs)
def visit_ListCompFor(self, node):
ifs = [self.visit(i) for i in node.ifs]
return self._new(_ast.comprehension, self.visit(node.assign),
self.visit(node.list), ifs)
def visit_GenExprIf(self, node):
return self.visit(node.test)
visit_ListCompIf = visit_GenExprIf
def visit_Yield(self, node):
return self._new(_ast.Yield, self.visit(node.value))
def visit_CallFunc(self, node):
args = []
keywords = []
for arg in node.args:
if isinstance(arg, compiler.ast.Keyword):
keywords.append(self._new(_ast.keyword, arg.name,
self.visit(arg.expr)))
else:
args.append(self.visit(arg))
return self._new(_ast.Call, self.visit(node.node), args, keywords,
self.visit(node.star_args), self.visit(node.dstar_args))
def visit_Backquote(self, node):
return self._new(_ast.Repr, self.visit(node.expr))
def visit_Const(self, node):
if node.value is None: # appears in slices
return None
elif isinstance(node.value, basestring):
return self._new(_ast.Str, node.value)
else:
return self._new(_ast.Num, node.value)
def visit_Name(self, node):
return self._new(_ast.Name, node.name, _ast.Load())
def visit_Getattr(self, node):
return self._new(_ast.Attribute, self.visit(node.expr), node.attrname,
_ast.Load())
def visit_Tuple(self, node):
nodes = [self.visit(n) for n in node.nodes]
return self._new(_ast.Tuple, nodes, _ast.Load())
def visit_List(self, node):
nodes = [self.visit(n) for n in node.nodes]
return self._new(_ast.List, nodes, _ast.Load())
def get_ctx(self, flags):
if flags == 'OP_DELETE':
return _ast.Del()
elif flags == 'OP_APPLY':
return _ast.Load()
elif flags == 'OP_ASSIGN':
return _ast.Store()
else:
# FIXME Exception here
assert False, repr(flags)
def visit_AssName(self, node):
self.out_flags = node.flags
ctx = self.get_ctx(node.flags)
return self._new(_ast.Name, node.name, ctx)
def visit_AssAttr(self, node):
self.out_flags = node.flags
ctx = self.get_ctx(node.flags)
return self._new(_ast.Attribute, self.visit(node.expr),
node.attrname, ctx)
def _visit_AssCollection(cls):
def _visit(self, node):
flags = None
elts = []
for n in node.nodes:
elts.append(self.visit(n))
if flags is None:
flags = self.out_flags
else:
assert flags == self.out_flags
self.out_flags = flags
ctx = self.get_ctx(flags)
return self._new(cls, elts, ctx)
return _visit
visit_AssList = _visit_AssCollection(_ast.List)
visit_AssTuple = _visit_AssCollection(_ast.Tuple)
del _visit_AssCollection
def visit_Slice(self, node):
lower = self.visit(node.lower)
upper = self.visit(node.upper)
ctx = self.get_ctx(node.flags)
self.out_flags = node.flags
return self._new(_ast.Subscript, self.visit(node.expr),
self._new(_ast.Slice, lower, upper, None), ctx)
def visit_Subscript(self, node):
ctx = self.get_ctx(node.flags)
subs = [self.visit(s) for s in node.subs]
advanced = (_ast.Slice, _ast.Ellipsis)
slices = []
nonindex = False
for sub in subs:
if isinstance(sub, advanced):
nonindex = True
slices.append(sub)
else:
slices.append(self._new(_ast.Index, sub))
if len(slices) == 1:
slice = slices[0]
elif nonindex:
slice = self._new(_ast.ExtSlice, slices)
else:
slice = self._new(_ast.Tuple, slices, _ast.Load())
self.out_flags = node.flags
return self._new(_ast.Subscript, self.visit(node.expr), slice, ctx)
def visit_Sliceobj(self, node):
a = [self.visit(n) for n in node.nodes + [None]*(3 - len(node.nodes))]
return self._new(_ast.Slice, a[0], a[1], a[2])
def visit_Ellipsis(self, node):
return self._new(_ast.Ellipsis)
def visit_Stmt(self, node):
def _check_del(n):
# del x is just AssName('x', 'OP_DELETE')
# we want to transform it to Delete([Name('x', Del())])
dcls = (_ast.Name, _ast.List, _ast.Subscript, _ast.Attribute)
if isinstance(n, dcls) and isinstance(n.ctx, _ast.Del):
return self._new(_ast.Delete, [n])
elif isinstance(n, _ast.Tuple) and isinstance(n.ctx, _ast.Del):
# unpack last tuple to avoid making del (x, y, z,);
# out of del x, y, z; (there's no difference between
# this two in compiler.ast)
return self._new(_ast.Delete, n.elts)
else:
return n
def _keep(n):
if isinstance(n, _ast.Expr) and n.value is None:
return False
else:
return True
return [s for s in [_check_del(self.visit(n)) for n in node.nodes]
if _keep(s)]
def parse(source, mode):
node = compiler.parse(source, mode)
return ASTUpgrader().visit(node)
|
