Lichen

Annotated common.py

96:2219668ae7d9
2016-10-14 Paul Boddie Introduced access mode information for unambiguously-traversed attributes so that the appropriate instruction can be generated. Removed the generation of augmented attribute access plans and the computation of general attribute position ambiguity, since the information will not be used: in cases where ambiguity might need to be determined, attributes must be checked to determine their exact nature even if unambiguous.
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#!/usr/bin/env python
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"""
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Common functions.
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Copyright (C) 2007, 2008, 2009, 2010, 2011, 2012, 2013,
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              2014, 2015, 2016 Paul Boddie <paul@boddie.org.uk>
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This program is free software; you can redistribute it and/or modify it under
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the terms of the GNU General Public License as published by the Free Software
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Foundation; either version 3 of the License, or (at your option) any later
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version.
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This program is distributed in the hope that it will be useful, but WITHOUT
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ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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FOR A PARTICULAR PURPOSE.  See the GNU General Public License for more
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details.
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You should have received a copy of the GNU General Public License along with
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this program.  If not, see <http://www.gnu.org/licenses/>.
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"""
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from errors import *
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from os import listdir, makedirs, remove
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from os.path import exists, isdir, join, split
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from results import ConstantValueRef, LiteralSequenceRef, NameRef
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import compiler
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class CommonOutput:
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    "Common output functionality."
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    def check_output(self):
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        "Check the existing output and remove it if irrelevant."
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        if not exists(self.output):
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            makedirs(self.output)
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        details = self.importer.get_cache_details()
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        recorded_details = self.get_output_details()
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        if recorded_details != details:
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            self.remove_output()
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        writefile(self.get_output_details_filename(), details)
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    def get_output_details_filename(self):
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        "Return the output details filename."
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        return join(self.output, "$details")
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    def get_output_details(self):
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        "Return details of the existing output."
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        details_filename = self.get_output_details_filename()
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        if not exists(details_filename):
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            return None
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        else:
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            return readfile(details_filename)
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    def remove_output(self, dirname=None):
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        "Remove the output."
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        dirname = dirname or self.output
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        for filename in listdir(dirname):
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            path = join(dirname, filename)
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            if isdir(path):
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                self.remove_output(path)
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            else:
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                remove(path)
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class CommonModule:
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    "A common module representation."
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    def __init__(self, name, importer):
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        """
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        Initialise this module with the given 'name' and an 'importer' which is
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        used to provide access to other modules when required.
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        """
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        self.name = name
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        self.importer = importer
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        self.filename = None
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        # Inspection-related attributes.
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        self.astnode = None
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        self.iterators = {}
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        self.temp = {}
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        self.lambdas = {}
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        # Constants, literals and values.
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        self.constants = {}
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        self.constant_values = {}
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        self.literals = {}
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        self.literal_types = {}
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        # Nested namespaces.
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        self.namespace_path = []
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        self.in_function = False
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        # Attribute chains.
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        self.attrs = []
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    def __repr__(self):
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        return "CommonModule(%r, %r)" % (self.name, self.importer)
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    def parse_file(self, filename):
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        "Parse the file with the given 'filename', initialising attributes."
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        self.filename = filename
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        self.astnode = compiler.parseFile(filename)
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    # Module-relative naming.
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    def get_global_path(self, name):
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        return "%s.%s" % (self.name, name)
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    def get_namespace_path(self):
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        return ".".join([self.name] + self.namespace_path)
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    def get_object_path(self, name):
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        return ".".join([self.name] + self.namespace_path + [name])
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    def get_parent_path(self):
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        return ".".join([self.name] + self.namespace_path[:-1])
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    # Namespace management.
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    def enter_namespace(self, name):
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        "Enter the namespace having the given 'name'."
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        self.namespace_path.append(name)
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    def exit_namespace(self):
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        "Exit the current namespace."
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        self.namespace_path.pop()
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    # Constant reference naming.
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    def get_constant_name(self, value):
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        "Add a new constant to the current namespace for 'value'."
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        path = self.get_namespace_path()
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        init_item(self.constants, path, dict)
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        return "$c%d" % add_counter_item(self.constants[path], value)
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    # Literal reference naming.
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    def get_literal_name(self):
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        "Add a new literal to the current namespace."
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        path = self.get_namespace_path()
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        init_item(self.literals, path, lambda: 0)
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        return "$C%d" % self.literals[path]
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    def next_literal(self):
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        self.literals[self.get_namespace_path()] += 1
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    # Temporary iterator naming.
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    def get_iterator_path(self):
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        return self.in_function and self.get_namespace_path() or self.name
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    def get_iterator_name(self):
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        path = self.get_iterator_path()
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        init_item(self.iterators, path, lambda: 0)
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        return "$i%d" % self.iterators[path]
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    def next_iterator(self):
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        self.iterators[self.get_iterator_path()] += 1
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    # Temporary variable naming.
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    def get_temporary_name(self):
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        path = self.get_namespace_path()
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        init_item(self.temp, path, lambda: 0)
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        return "$t%d" % self.temp[path]
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    def next_temporary(self):
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        self.temp[self.get_namespace_path()] += 1
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    # Arbitrary function naming.
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    def get_lambda_name(self):
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        path = self.get_namespace_path()
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        init_item(self.lambdas, path, lambda: 0)
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        name = "$l%d" % self.lambdas[path]
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        self.lambdas[path] += 1
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        return name
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    def reset_lambdas(self):
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        self.lambdas = {}
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    # Constant and literal recording.
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    def get_constant_reference(self, ref, value):
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        "Return a constant reference for the given 'ref' type and 'value'."
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        constant_name = self.get_constant_name(value)
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        # Return a reference for the constant.
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        objpath = self.get_object_path(constant_name)
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        name_ref = ConstantValueRef(constant_name, ref.instance_of(), value)
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        # Record the value and type for the constant.
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        self.constant_values[objpath] = name_ref.value, name_ref.get_origin()
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        return name_ref
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    def get_literal_reference(self, name, ref, items, cls):
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        """
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        Return a literal reference for the given type 'name', literal 'ref',
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        node 'items' and employing the given 'cls' as the class of the returned
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        reference object.
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        """
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        # Construct an invocation using the items as arguments.
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        typename = "$L%s" % name
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        invocation = compiler.ast.CallFunc(
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            compiler.ast.Name(typename),
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            items
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            )
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        # Get a name for the actual literal.
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        instname = self.get_literal_name()
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        self.next_literal()
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        # Record the type for the literal.
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        objpath = self.get_object_path(instname)
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        self.literal_types[objpath] = ref.get_origin()
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        # Return a wrapper for the invocation exposing the items.
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        return cls(
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            instname,
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            ref.instance_of(),
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            self.process_structure_node(invocation),
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            invocation.args
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            )
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    # Node handling.
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    def process_structure(self, node):
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        """
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        Within the given 'node', process the program structure.
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        During inspection, this will process global declarations, adjusting the
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        module namespace, and import statements, building a module dependency
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        hierarchy.
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        During translation, this will consult deduced program information and
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        output translated code.
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        """
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        l = []
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        for n in node.getChildNodes():
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            l.append(self.process_structure_node(n))
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        return l
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    def process_augassign_node(self, n):
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        "Process the given augmented assignment node 'n'."
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        op = operator_functions[n.op]
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        if isinstance(n.node, compiler.ast.Getattr):
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            target = compiler.ast.AssAttr(n.node.expr, n.node.attrname, "OP_ASSIGN")
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        elif isinstance(n.node, compiler.ast.Name):
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            target = compiler.ast.AssName(n.node.name, "OP_ASSIGN")
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        else:
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            target = n.node
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        assignment = compiler.ast.Assign(
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            [target],
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            compiler.ast.CallFunc(
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                compiler.ast.Name("$op%s" % op),
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                [n.node, n.expr]))
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        return self.process_structure_node(assignment)
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    def process_assignment_for_function(self, original_name, name):
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        """
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        Return an assignment operation making 'original_name' refer to the given
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        'name'.
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        """
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        assignment = compiler.ast.Assign(
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            [compiler.ast.AssName(original_name, "OP_ASSIGN")],
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            compiler.ast.Name(name)
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            )
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        return self.process_structure_node(assignment)
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    def process_assignment_node_items(self, n, expr):
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        """
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        Process the given assignment node 'n' whose children are to be assigned
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        items of 'expr'.
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        """
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        name_ref = self.process_structure_node(expr)
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        # Either unpack the items and present them directly to each assignment
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        # node.
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        if isinstance(name_ref, LiteralSequenceRef):
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            self.process_literal_sequence_items(n, name_ref)
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        # Or have the assignment nodes access each item via the sequence API.
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        else:
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            self.process_assignment_node_items_by_position(n, expr, name_ref)
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    def process_assignment_node_items_by_position(self, n, expr, name_ref):
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        """
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        Process the given sequence assignment node 'n', converting the node to
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        the separate assignment of each target using positional access on a
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        temporary variable representing the sequence. Use 'expr' as the assigned
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        value and 'name_ref' as the reference providing any existing temporary
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        variable.
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        """
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        assignments = []
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        if isinstance(name_ref, NameRef):
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            temp = name_ref.name
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        else:
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            temp = self.get_temporary_name()
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            self.next_temporary()
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            assignments.append(
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                compiler.ast.Assign([compiler.ast.AssName(temp, "OP_ASSIGN")], expr)
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                )
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        for i, node in enumerate(n.nodes):
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            assignments.append(
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                compiler.ast.Assign([node], compiler.ast.Subscript(
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                    compiler.ast.Name(temp), "OP_APPLY", [compiler.ast.Const(i)]))
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                )
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        return self.process_structure_node(compiler.ast.Stmt(assignments))
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    def process_literal_sequence_items(self, n, name_ref):
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        """
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        Process the given assignment node 'n', obtaining from the given
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        'name_ref' the items to be assigned to the assignment targets.
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        """
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        if len(n.nodes) == len(name_ref.items):
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            for node, item in zip(n.nodes, name_ref.items):
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                self.process_assignment_node(node, item)
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        else:
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            raise InspectError("In %s, item assignment needing %d items is given %d items." % (
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                self.get_namespace_path(), len(n.nodes), len(name_ref.items)))
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    def process_compare_node(self, n):
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        """
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        Process the given comparison node 'n', converting an operator sequence
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        from...
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        <expr1> <op1> <expr2> <op2> <expr3>
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        ...to...
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        <op1>(<expr1>, <expr2>) and <op2>(<expr2>, <expr3>)
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        """
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        invocations = []
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        last = n.expr
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        for op, op_node in n.ops:
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            op = operator_functions.get(op)
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            invocations.append(compiler.ast.CallFunc(
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                compiler.ast.Name("$op%s" % op),
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                [last, op_node]))
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            last = op_node
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        if len(invocations) > 1:
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            result = compiler.ast.And(invocations)
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        else:
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            result = invocations[0]
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        return self.process_structure_node(result)
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    def process_dict_node(self, node):
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        """
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        Process the given dictionary 'node', returning a list of (key, value)
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        tuples.
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        """
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        l = []
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        for key, value in node.items:
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            l.append((
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                self.process_structure_node(key),
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                self.process_structure_node(value)))
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        return l
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    def process_for_node(self, n):
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        """
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        Generate attribute accesses for {n.list}.__iter__ and the next method on
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        the iterator, producing a replacement node for the original.
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        """
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        node = compiler.ast.Stmt([
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            # <iterator> = {n.list}.__iter__
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            compiler.ast.Assign(
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                [compiler.ast.AssName(self.get_iterator_name(), "OP_ASSIGN")],
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                compiler.ast.CallFunc(
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                    compiler.ast.Getattr(n.list, "__iter__"),
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                    []
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                    )),
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            # try:
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            #     while True:
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            #         <var>... = <iterator>.next()
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            #         ...
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            # except StopIteration:
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            #     pass
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            compiler.ast.TryExcept(
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                compiler.ast.While(
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                    compiler.ast.Name("True"),
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                    compiler.ast.Stmt([
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                        compiler.ast.Assign(
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                            [n.assign],
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                            compiler.ast.CallFunc(
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                                compiler.ast.Getattr(compiler.ast.Name(self.get_iterator_name()), "next"),
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                                []
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                                )),
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                        n.body]),
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                    None),
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                [(compiler.ast.Name("StopIteration"), None, compiler.ast.Stmt([compiler.ast.Pass()]))],
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                None)
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            ])
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        self.next_iterator()
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        self.process_structure_node(node)
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    def process_literal_sequence_node(self, n, name, ref, cls):
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        """
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        Process the given literal sequence node 'n' as a function invocation,
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        with 'name' indicating the type of the sequence, and 'ref' being a
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        reference to the type. The 'cls' is used to instantiate a suitable name
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        reference.
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        """
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        if name == "dict":
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            items = []
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            for key, value in n.items:
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                items.append(compiler.ast.Tuple([key, value]))
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        else: # name in ("list", "tuple"):
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            items = n.nodes
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        return self.get_literal_reference(name, ref, items, cls)
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    def process_operator_node(self, n):
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        """
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        Process the given operator node 'n' as an operator function invocation.
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        """
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        op = operator_functions[n.__class__.__name__]
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        invocation = compiler.ast.CallFunc(
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            compiler.ast.Name("$op%s" % op),
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            list(n.getChildNodes())
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            )
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        return self.process_structure_node(invocation)
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    def process_slice_node(self, n, expr=None):
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        """
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        Process the given slice node 'n' as an operator function invocation.
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        """
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        op = n.flags == "OP_ASSIGN" and "setslice" or "getslice"
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        invocation = compiler.ast.CallFunc(
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            compiler.ast.Name("$op%s" % op),
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            [n.expr, n.lower or compiler.ast.Name("None"), n.upper or compiler.ast.Name("None")] +
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                (expr and [expr] or [])
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            )
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        return self.process_structure_node(invocation)
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    def process_sliceobj_node(self, n):
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paul@0 522
        """
paul@0 523
        Process the given slice object node 'n' as a slice constructor.
paul@0 524
        """
paul@0 525
paul@0 526
        op = "slice"
paul@0 527
        invocation = compiler.ast.CallFunc(
paul@0 528
            compiler.ast.Name("$op%s" % op),
paul@0 529
            n.nodes
paul@0 530
            )
paul@0 531
        return self.process_structure_node(invocation)
paul@0 532
paul@0 533
    def process_subscript_node(self, n, expr=None):
paul@0 534
paul@0 535
        """
paul@0 536
        Process the given subscript node 'n' as an operator function invocation.
paul@0 537
        """
paul@0 538
paul@0 539
        op = n.flags == "OP_ASSIGN" and "setitem" or "getitem"
paul@0 540
        invocation = compiler.ast.CallFunc(
paul@0 541
            compiler.ast.Name("$op%s" % op),
paul@0 542
            [n.expr] + list(n.subs) + (expr and [expr] or [])
paul@0 543
            )
paul@0 544
        return self.process_structure_node(invocation)
paul@0 545
paul@0 546
    def process_attribute_chain(self, n):
paul@0 547
paul@0 548
        """
paul@0 549
        Process the given attribute access node 'n'. Return a reference
paul@0 550
        describing the expression.
paul@0 551
        """
paul@0 552
paul@0 553
        # AssAttr/Getattr are nested with the outermost access being the last
paul@0 554
        # access in any chain.
paul@0 555
paul@0 556
        self.attrs.insert(0, n.attrname)
paul@0 557
        attrs = self.attrs
paul@0 558
paul@0 559
        # Break attribute chains where non-access nodes are found.
paul@0 560
paul@0 561
        if not self.have_access_expression(n):
paul@0 562
            self.attrs = []
paul@0 563
paul@0 564
        # Descend into the expression, extending backwards any existing chain,
paul@0 565
        # or building another for the expression.
paul@0 566
paul@0 567
        name_ref = self.process_structure_node(n.expr)
paul@0 568
paul@0 569
        # Restore chain information applying to this node.
paul@0 570
paul@0 571
        self.attrs = attrs
paul@0 572
paul@0 573
        # Return immediately if the expression was another access and thus a
paul@0 574
        # continuation backwards along the chain. The above processing will
paul@0 575
        # have followed the chain all the way to its conclusion.
paul@0 576
paul@0 577
        if self.have_access_expression(n):
paul@0 578
            del self.attrs[0]
paul@0 579
paul@0 580
        return name_ref
paul@0 581
paul@0 582
    def have_access_expression(self, node):
paul@0 583
paul@0 584
        "Return whether the expression associated with 'node' is Getattr."
paul@0 585
paul@0 586
        return isinstance(node.expr, compiler.ast.Getattr)
paul@0 587
paul@0 588
    def get_name_for_tracking(self, name, path=None):
paul@0 589
paul@0 590
        """
paul@0 591
        Return the name to be used for attribute usage observations involving
paul@0 592
        the given 'name' in the current namespace. If 'path' is indicated and
paul@0 593
        the name is being used outside a function, return the path value;
paul@0 594
        otherwise, return a path computed using the current namespace and the
paul@0 595
        given name.
paul@0 596
paul@0 597
        The intention of this method is to provide a suitably-qualified name
paul@0 598
        that can be tracked across namespaces. Where globals are being
paul@0 599
        referenced in class namespaces, they should be referenced using their
paul@0 600
        path within the module, not using a path within each class.
paul@0 601
paul@0 602
        It may not be possible to identify a global within a function at the
paul@0 603
        time of inspection (since a global may appear later in a file).
paul@0 604
        Consequently, globals are identified by their local name rather than
paul@0 605
        their module-qualified path.
paul@0 606
        """
paul@0 607
paul@0 608
        # For functions, use the appropriate local names.
paul@0 609
paul@0 610
        if self.in_function:
paul@0 611
            return name
paul@0 612
paul@0 613
        # For static namespaces, use the given qualified name.
paul@0 614
paul@0 615
        elif path:
paul@0 616
            return path
paul@0 617
paul@0 618
        # Otherwise, establish a name in the current (module) namespace.
paul@0 619
paul@0 620
        else:
paul@0 621
            return self.get_object_path(name)
paul@0 622
paul@0 623
    def get_path_for_access(self):
paul@0 624
paul@0 625
        "Outside functions, register accesses at the module level."
paul@0 626
paul@0 627
        if not self.in_function:
paul@0 628
            return self.name
paul@0 629
        else:
paul@0 630
            return self.get_namespace_path()
paul@0 631
paul@0 632
    def get_module_name(self, node):
paul@0 633
paul@0 634
        """
paul@0 635
        Using the given From 'node' in this module, calculate any relative import
paul@0 636
        information, returning a tuple containing a module to import along with any
paul@0 637
        names to import based on the node's name information.
paul@0 638
paul@0 639
        Where the returned module is given as None, whole module imports should
paul@0 640
        be performed for the returned modules using the returned names.
paul@0 641
        """
paul@0 642
paul@0 643
        # Absolute import.
paul@0 644
paul@0 645
        if node.level == 0:
paul@0 646
            return node.modname, node.names
paul@0 647
paul@0 648
        # Relative to an ancestor of this module.
paul@0 649
paul@0 650
        else:
paul@0 651
            path = self.name.split(".")
paul@0 652
            level = node.level
paul@0 653
paul@0 654
            # Relative imports treat package roots as submodules.
paul@0 655
paul@0 656
            if split(self.filename)[-1] == "__init__.py":
paul@0 657
                level -= 1
paul@0 658
paul@0 659
            if level > len(path):
paul@0 660
                raise InspectError("Relative import %r involves too many levels up from module %r" % (
paul@0 661
                    ("%s%s" % ("." * node.level, node.modname or "")), self.name))
paul@0 662
paul@0 663
            basename = ".".join(path[:len(path)-level])
paul@0 664
paul@0 665
        # Name imports from a module.
paul@0 666
paul@0 667
        if node.modname:
paul@0 668
            return "%s.%s" % (basename, node.modname), node.names
paul@0 669
paul@0 670
        # Relative whole module imports.
paul@0 671
paul@0 672
        else:
paul@0 673
            return basename, node.names
paul@0 674
paul@0 675
def get_argnames(args):
paul@0 676
paul@0 677
    """
paul@0 678
    Return a list of all names provided by 'args'. Since tuples may be
paul@0 679
    employed, the arguments are traversed depth-first.
paul@0 680
    """
paul@0 681
paul@0 682
    l = []
paul@0 683
    for arg in args:
paul@0 684
        if isinstance(arg, tuple):
paul@0 685
            l += get_argnames(arg)
paul@0 686
        else:
paul@0 687
            l.append(arg)
paul@0 688
    return l
paul@0 689
paul@0 690
# Dictionary utilities.
paul@0 691
paul@0 692
def init_item(d, key, fn):
paul@0 693
paul@0 694
    """
paul@0 695
    Add to 'd' an entry for 'key' using the callable 'fn' to make an initial
paul@0 696
    value where no entry already exists.
paul@0 697
    """
paul@0 698
paul@0 699
    if not d.has_key(key):
paul@0 700
        d[key] = fn()
paul@0 701
    return d[key]
paul@0 702
paul@0 703
def dict_for_keys(d, keys):
paul@0 704
paul@0 705
    "Return a new dictionary containing entries from 'd' for the given 'keys'."
paul@0 706
paul@0 707
    nd = {}
paul@0 708
    for key in keys:
paul@0 709
        if d.has_key(key):
paul@0 710
            nd[key] = d[key]
paul@0 711
    return nd
paul@0 712
paul@0 713
def make_key(s):
paul@0 714
paul@0 715
    "Make sequence 's' into a tuple-based key, first sorting its contents."
paul@0 716
paul@0 717
    l = list(s)
paul@0 718
    l.sort()
paul@0 719
    return tuple(l)
paul@0 720
paul@0 721
def add_counter_item(d, key):
paul@0 722
paul@0 723
    """
paul@0 724
    Make a mapping in 'd' for 'key' to the number of keys added before it, thus
paul@0 725
    maintaining a mapping of keys to their order of insertion.
paul@0 726
    """
paul@0 727
paul@0 728
    if not d.has_key(key):
paul@0 729
        d[key] = len(d.keys())
paul@0 730
    return d[key] 
paul@0 731
paul@0 732
def remove_items(d1, d2):
paul@0 733
paul@0 734
    "Remove from 'd1' all items from 'd2'."
paul@0 735
paul@0 736
    for key in d2.keys():
paul@0 737
        if d1.has_key(key):
paul@0 738
            del d1[key]
paul@0 739
paul@0 740
# Set utilities.
paul@0 741
paul@0 742
def first(s):
paul@0 743
    return list(s)[0]
paul@0 744
paul@0 745
def same(s1, s2):
paul@0 746
    return set(s1) == set(s2)
paul@0 747
paul@0 748
# General input/output.
paul@0 749
paul@0 750
def readfile(filename):
paul@0 751
paul@0 752
    "Return the contents of 'filename'."
paul@0 753
paul@0 754
    f = open(filename)
paul@0 755
    try:
paul@0 756
        return f.read()
paul@0 757
    finally:
paul@0 758
        f.close()
paul@0 759
paul@0 760
def writefile(filename, s):
paul@0 761
paul@0 762
    "Write to 'filename' the string 's'."
paul@0 763
paul@0 764
    f = open(filename, "w")
paul@0 765
    try:
paul@0 766
        f.write(s)
paul@0 767
    finally:
paul@0 768
        f.close()
paul@0 769
paul@0 770
# General encoding.
paul@0 771
paul@0 772
def sorted_output(x):
paul@0 773
paul@0 774
    "Sort sequence 'x' and return a string with commas separating the values."
paul@0 775
paul@0 776
    x = map(str, x)
paul@0 777
    x.sort()
paul@0 778
    return ", ".join(x)
paul@0 779
paul@0 780
# Attribute chain decoding.
paul@0 781
paul@0 782
def get_attrnames(attrnames):
paul@11 783
paul@11 784
    """
paul@11 785
    Split the qualified attribute chain 'attrnames' into its components,
paul@11 786
    handling special attributes starting with "#" that indicate type
paul@11 787
    conformance.
paul@11 788
    """
paul@11 789
paul@0 790
    if attrnames.startswith("#"):
paul@0 791
        return [attrnames]
paul@0 792
    else:
paul@0 793
        return attrnames.split(".")
paul@0 794
paul@0 795
def get_attrname_from_location(location):
paul@11 796
paul@11 797
    """
paul@11 798
    Extract the first attribute from the attribute names employed in a
paul@11 799
    'location'.
paul@11 800
    """
paul@11 801
paul@0 802
    path, name, attrnames, access = location
paul@91 803
    if not attrnames:
paul@91 804
        return attrnames
paul@0 805
    return get_attrnames(attrnames)[0]
paul@0 806
paul@85 807
def get_name_path(path, name):
paul@85 808
paul@85 809
    "Return a suitable qualified name from the given 'path' and 'name'."
paul@85 810
paul@85 811
    if "." in name:
paul@85 812
        return name
paul@85 813
    else:
paul@85 814
        return "%s.%s" % (path, name)
paul@85 815
paul@90 816
# Usage-related functions.
paul@89 817
paul@89 818
def get_types_for_usage(attrnames, objects):
paul@89 819
paul@89 820
    """
paul@89 821
    Identify the types that can support the given 'attrnames', using the
paul@89 822
    given 'objects' as the catalogue of type details.
paul@89 823
    """
paul@89 824
paul@89 825
    types = []
paul@89 826
    for name, _attrnames in objects.items():
paul@89 827
        if set(attrnames).issubset(_attrnames):
paul@89 828
            types.append(name)
paul@89 829
    return types
paul@89 830
paul@90 831
def get_invoked_attributes(usage):
paul@90 832
paul@90 833
    "Obtain invoked attribute from the given 'usage'."
paul@90 834
paul@90 835
    invoked = []
paul@90 836
    if usage:
paul@90 837
        for attrname, invocation in usage:
paul@90 838
            if invocation:
paul@90 839
                invoked.append(attrname)
paul@90 840
    return invoked
paul@90 841
paul@0 842
# Useful data.
paul@0 843
paul@11 844
predefined_constants = "False", "None", "NotImplemented", "True"
paul@0 845
paul@0 846
operator_functions = {
paul@0 847
paul@0 848
    # Fundamental operations.
paul@0 849
paul@0 850
    "is" : "is_",
paul@0 851
    "is not" : "is_not",
paul@0 852
paul@0 853
    # Binary operations.
paul@0 854
paul@0 855
    "in" : "in_",
paul@0 856
    "not in" : "not_in",
paul@0 857
    "Add" : "add",
paul@0 858
    "Bitand" : "and_",
paul@0 859
    "Bitor" : "or_",
paul@0 860
    "Bitxor" : "xor",
paul@0 861
    "Div" : "div",
paul@0 862
    "FloorDiv" : "floordiv",
paul@0 863
    "LeftShift" : "lshift",
paul@0 864
    "Mod" : "mod",
paul@0 865
    "Mul" : "mul",
paul@0 866
    "Power" : "pow",
paul@0 867
    "RightShift" : "rshift",
paul@0 868
    "Sub" : "sub",
paul@0 869
paul@0 870
    # Unary operations.
paul@0 871
paul@0 872
    "Invert" : "invert",
paul@0 873
    "UnaryAdd" : "pos",
paul@0 874
    "UnarySub" : "neg",
paul@0 875
paul@0 876
    # Augmented assignment.
paul@0 877
paul@0 878
    "+=" : "iadd",
paul@0 879
    "-=" : "isub",
paul@0 880
    "*=" : "imul",
paul@0 881
    "/=" : "idiv",
paul@0 882
    "//=" : "ifloordiv",
paul@0 883
    "%=" : "imod",
paul@0 884
    "**=" : "ipow",
paul@0 885
    "<<=" : "ilshift",
paul@0 886
    ">>=" : "irshift",
paul@0 887
    "&=" : "iand",
paul@0 888
    "^=" : "ixor",
paul@0 889
    "|=" : "ior",
paul@0 890
paul@0 891
    # Comparisons.
paul@0 892
paul@0 893
    "==" : "eq",
paul@0 894
    "!=" : "ne",
paul@0 895
    "<" : "lt",
paul@0 896
    "<=" : "le",
paul@0 897
    ">=" : "ge",
paul@0 898
    ">" : "gt",
paul@0 899
    }
paul@0 900
paul@0 901
# vim: tabstop=4 expandtab shiftwidth=4