Pracownia_programowania/venv/Lib/site-packages/Cython/Compiler/UtilityCode.py

from __future__ import absolute_import

from .TreeFragment import parse_from_strings, StringParseContext
from . import Symtab
from . import Naming
from . import Code


class NonManglingModuleScope(Symtab.ModuleScope):

    def __init__(self, prefix, *args, **kw):
        self.prefix = prefix
        self.cython_scope = None
        self.cpp = kw.pop('cpp', False)
        Symtab.ModuleScope.__init__(self, *args, **kw)

    def add_imported_entry(self, name, entry, pos):
        entry.used = True
        return super(NonManglingModuleScope, self).add_imported_entry(name, entry, pos)

    def mangle(self, prefix, name=None):
        if name:
            if prefix in (Naming.typeobj_prefix, Naming.func_prefix, Naming.var_prefix, Naming.pyfunc_prefix):
                # Functions, classes etc. gets a manually defined prefix easily
                # manually callable instead (the one passed to CythonUtilityCode)
                prefix = self.prefix
            return "%s%s" % (prefix, name)
        else:
            return Symtab.ModuleScope.mangle(self, prefix)


class CythonUtilityCodeContext(StringParseContext):
    scope = None

    def find_module(self, module_name, relative_to=None, pos=None, need_pxd=True, absolute_fallback=True):
        if relative_to:
            raise AssertionError("Relative imports not supported in utility code.")
        if module_name != self.module_name:
            if module_name not in self.modules:
                raise AssertionError("Only the cython cimport is supported.")
            else:
                return self.modules[module_name]

        if self.scope is None:
            self.scope = NonManglingModuleScope(
                self.prefix, module_name, parent_module=None, context=self, cpp=self.cpp)

        return self.scope


class CythonUtilityCode(Code.UtilityCodeBase):
    """
    Utility code written in the Cython language itself.

    The @cname decorator can set the cname for a function, method of cdef class.
    Functions decorated with @cname('c_func_name') get the given cname.

    For cdef classes the rules are as follows:
        obj struct      -> <cname>_obj
        obj type ptr    -> <cname>_type
        methods         -> <class_cname>_<method_cname>

    For methods the cname decorator is optional, but without the decorator the
    methods will not be prototyped. See Cython.Compiler.CythonScope and
    tests/run/cythonscope.pyx for examples.
    """

    is_cython_utility = True

    def __init__(self, impl, name="__pyxutil", prefix="", requires=None,
                 file=None, from_scope=None, context=None, compiler_directives=None,
                 outer_module_scope=None):
        # 1) We need to delay the parsing/processing, so that all modules can be
        #    imported without import loops
        # 2) The same utility code object can be used for multiple source files;
        #    while the generated node trees can be altered in the compilation of a
        #    single file.
        # Hence, delay any processing until later.
        context_types = {}
        if context is not None:
            from .PyrexTypes import BaseType
            for key, value in context.items():
                if isinstance(value, BaseType):
                    context[key] = key
                    context_types[key] = value
            impl = Code.sub_tempita(impl, context, file, name)
        self.impl = impl
        self.name = name
        self.file = file
        self.prefix = prefix
        self.requires = requires or []
        self.from_scope = from_scope
        self.outer_module_scope = outer_module_scope
        self.compiler_directives = compiler_directives
        self.context_types = context_types

    def __eq__(self, other):
        if isinstance(other, CythonUtilityCode):
            return self._equality_params() == other._equality_params()
        else:
            return False

    def _equality_params(self):
        outer_scope = self.outer_module_scope
        while isinstance(outer_scope, NonManglingModuleScope):
            outer_scope = outer_scope.outer_scope
        return self.impl, outer_scope, self.compiler_directives

    def __hash__(self):
        return hash(self.impl)

    def get_tree(self, entries_only=False, cython_scope=None):
        from .AnalysedTreeTransforms import AutoTestDictTransform
        # The AutoTestDictTransform creates the statement "__test__ = {}",
        # which when copied into the main ModuleNode overwrites
        # any __test__ in user code; not desired
        excludes = [AutoTestDictTransform]

        from . import Pipeline, ParseTreeTransforms
        context = CythonUtilityCodeContext(
            self.name, compiler_directives=self.compiler_directives,
            cpp=cython_scope.is_cpp() if cython_scope else False)
        context.prefix = self.prefix
        context.cython_scope = cython_scope
        #context = StringParseContext(self.name)
        tree = parse_from_strings(
            self.name, self.impl, context=context, allow_struct_enum_decorator=True)
        pipeline = Pipeline.create_pipeline(context, 'pyx', exclude_classes=excludes)

        if entries_only:
            p = []
            for t in pipeline:
                p.append(t)
                if isinstance(p, ParseTreeTransforms.AnalyseDeclarationsTransform):
                    break

            pipeline = p

        transform = ParseTreeTransforms.CnameDirectivesTransform(context)
        # InterpretCompilerDirectives already does a cdef declarator check
        #before = ParseTreeTransforms.DecoratorTransform
        before = ParseTreeTransforms.InterpretCompilerDirectives
        pipeline = Pipeline.insert_into_pipeline(pipeline, transform,
                                                 before=before)

        def merge_scope(scope):
            def merge_scope_transform(module_node):
                module_node.scope.merge_in(scope)
                return module_node
            return merge_scope_transform

        if self.from_scope:
            pipeline = Pipeline.insert_into_pipeline(
                pipeline, merge_scope(self.from_scope),
                before=ParseTreeTransforms.AnalyseDeclarationsTransform)

        for dep in self.requires:
            if isinstance(dep, CythonUtilityCode) and hasattr(dep, 'tree') and not cython_scope:
                pipeline = Pipeline.insert_into_pipeline(
                    pipeline, merge_scope(dep.tree.scope),
                    before=ParseTreeTransforms.AnalyseDeclarationsTransform)

        if self.outer_module_scope:
            # inject outer module between utility code module and builtin module
            def scope_transform(module_node):
                module_node.scope.outer_scope = self.outer_module_scope
                return module_node

            pipeline = Pipeline.insert_into_pipeline(
                pipeline, scope_transform,
                before=ParseTreeTransforms.AnalyseDeclarationsTransform)

        if self.context_types:
            # inject types into module scope
            def scope_transform(module_node):
                for name, type in self.context_types.items():
                    entry = module_node.scope.declare_type(name, type, None, visibility='extern')
                    entry.in_cinclude = True
                return module_node

            pipeline = Pipeline.insert_into_pipeline(
                pipeline, scope_transform,
                before=ParseTreeTransforms.AnalyseDeclarationsTransform)

        (err, tree) = Pipeline.run_pipeline(pipeline, tree, printtree=False)
        assert not err, err
        self.tree = tree
        return tree

    def put_code(self, output):
        pass

    @classmethod
    def load_as_string(cls, util_code_name, from_file=None, **kwargs):
        """
        Load a utility code as a string. Returns (proto, implementation)
        """
        util = cls.load(util_code_name, from_file, **kwargs)
        return util.proto, util.impl # keep line numbers => no lstrip()

    def declare_in_scope(self, dest_scope, used=False, cython_scope=None,
                         whitelist=None):
        """
        Declare all entries from the utility code in dest_scope. Code will only
        be included for used entries. If module_name is given, declare the
        type entries with that name.
        """
        tree = self.get_tree(entries_only=True, cython_scope=cython_scope)

        entries = tree.scope.entries
        entries.pop('__name__')
        entries.pop('__file__')
        entries.pop('__builtins__')
        entries.pop('__doc__')

        for entry in entries.values():
            entry.utility_code_definition = self
            entry.used = used

        original_scope = tree.scope
        dest_scope.merge_in(original_scope, merge_unused=True, whitelist=whitelist)
        tree.scope = dest_scope

        for dep in self.requires:
            if dep.is_cython_utility:
                dep.declare_in_scope(dest_scope, cython_scope=cython_scope)

        return original_scope


def declare_declarations_in_scope(declaration_string, env, private_type=True,
                                  *args, **kwargs):
    """
    Declare some declarations given as Cython code in declaration_string
    in scope env.
    """
    CythonUtilityCode(declaration_string, *args, **kwargs).declare_in_scope(env)
Projekt 2020-02-01 19:54:00 +01:00			`from __future__ import absolute_import`

			`from .TreeFragment import parse_from_strings, StringParseContext`
			`from . import Symtab`
			`from . import Naming`
			`from . import Code`


			`class NonManglingModuleScope(Symtab.ModuleScope):`

			`def __init__(self, prefix, args, *kw):`
			`self.prefix = prefix`
			`self.cython_scope = None`
			`self.cpp = kw.pop('cpp', False)`
			`Symtab.ModuleScope.__init__(self, args, *kw)`

			`def add_imported_entry(self, name, entry, pos):`
			`entry.used = True`
			`return super(NonManglingModuleScope, self).add_imported_entry(name, entry, pos)`

			`def mangle(self, prefix, name=None):`
			`if name:`
			`if prefix in (Naming.typeobj_prefix, Naming.func_prefix, Naming.var_prefix, Naming.pyfunc_prefix):`
			`# Functions, classes etc. gets a manually defined prefix easily`
			`# manually callable instead (the one passed to CythonUtilityCode)`
			`prefix = self.prefix`
			`return "%s%s" % (prefix, name)`
			`else:`
			`return Symtab.ModuleScope.mangle(self, prefix)`


			`class CythonUtilityCodeContext(StringParseContext):`
			`scope = None`

			`def find_module(self, module_name, relative_to=None, pos=None, need_pxd=True, absolute_fallback=True):`
			`if relative_to:`
			`raise AssertionError("Relative imports not supported in utility code.")`
			`if module_name != self.module_name:`
			`if module_name not in self.modules:`
			`raise AssertionError("Only the cython cimport is supported.")`
			`else:`
			`return self.modules[module_name]`

			`if self.scope is None:`
			`self.scope = NonManglingModuleScope(`
			`self.prefix, module_name, parent_module=None, context=self, cpp=self.cpp)`

			`return self.scope`


			`class CythonUtilityCode(Code.UtilityCodeBase):`
			`"""`
			`Utility code written in the Cython language itself.`

			`The @cname decorator can set the cname for a function, method of cdef class.`
			`Functions decorated with @cname('c_func_name') get the given cname.`

			`For cdef classes the rules are as follows:`
			`obj struct -> <cname>_obj`
			`obj type ptr -> <cname>_type`
			`methods -> <class_cname>_<method_cname>`

			`For methods the cname decorator is optional, but without the decorator the`
			`methods will not be prototyped. See Cython.Compiler.CythonScope and`
			`tests/run/cythonscope.pyx for examples.`
			`"""`

			`is_cython_utility = True`

			`def __init__(self, impl, name="__pyxutil", prefix="", requires=None,`
			`file=None, from_scope=None, context=None, compiler_directives=None,`
			`outer_module_scope=None):`
			`# 1) We need to delay the parsing/processing, so that all modules can be`
			`# imported without import loops`
			`# 2) The same utility code object can be used for multiple source files;`
			`# while the generated node trees can be altered in the compilation of a`
			`# single file.`
			`# Hence, delay any processing until later.`
			`context_types = {}`
			`if context is not None:`
			`from .PyrexTypes import BaseType`
			`for key, value in context.items():`
			`if isinstance(value, BaseType):`
			`context[key] = key`
			`context_types[key] = value`
			`impl = Code.sub_tempita(impl, context, file, name)`
			`self.impl = impl`
			`self.name = name`
			`self.file = file`
			`self.prefix = prefix`
			`self.requires = requires or []`
			`self.from_scope = from_scope`
			`self.outer_module_scope = outer_module_scope`
			`self.compiler_directives = compiler_directives`
			`self.context_types = context_types`

			`def __eq__(self, other):`
			`if isinstance(other, CythonUtilityCode):`
			`return self._equality_params() == other._equality_params()`
			`else:`
			`return False`

			`def _equality_params(self):`
			`outer_scope = self.outer_module_scope`
			`while isinstance(outer_scope, NonManglingModuleScope):`
			`outer_scope = outer_scope.outer_scope`
			`return self.impl, outer_scope, self.compiler_directives`

			`def __hash__(self):`
			`return hash(self.impl)`

			`def get_tree(self, entries_only=False, cython_scope=None):`
			`from .AnalysedTreeTransforms import AutoTestDictTransform`
			`# The AutoTestDictTransform creates the statement "__test__ = {}",`
			`# which when copied into the main ModuleNode overwrites`
			`# any __test__ in user code; not desired`
			`excludes = [AutoTestDictTransform]`

			`from . import Pipeline, ParseTreeTransforms`
			`context = CythonUtilityCodeContext(`
			`self.name, compiler_directives=self.compiler_directives,`
			`cpp=cython_scope.is_cpp() if cython_scope else False)`
			`context.prefix = self.prefix`
			`context.cython_scope = cython_scope`
			`#context = StringParseContext(self.name)`
			`tree = parse_from_strings(`
			`self.name, self.impl, context=context, allow_struct_enum_decorator=True)`
			`pipeline = Pipeline.create_pipeline(context, 'pyx', exclude_classes=excludes)`

			`if entries_only:`
			`p = []`
			`for t in pipeline:`
			`p.append(t)`
			`if isinstance(p, ParseTreeTransforms.AnalyseDeclarationsTransform):`
			`break`

			`pipeline = p`

			`transform = ParseTreeTransforms.CnameDirectivesTransform(context)`
			`# InterpretCompilerDirectives already does a cdef declarator check`
			`#before = ParseTreeTransforms.DecoratorTransform`
			`before = ParseTreeTransforms.InterpretCompilerDirectives`
			`pipeline = Pipeline.insert_into_pipeline(pipeline, transform,`
			`before=before)`

			`def merge_scope(scope):`
			`def merge_scope_transform(module_node):`
			`module_node.scope.merge_in(scope)`
			`return module_node`
			`return merge_scope_transform`

			`if self.from_scope:`
			`pipeline = Pipeline.insert_into_pipeline(`
			`pipeline, merge_scope(self.from_scope),`
			`before=ParseTreeTransforms.AnalyseDeclarationsTransform)`

			`for dep in self.requires:`
			`if isinstance(dep, CythonUtilityCode) and hasattr(dep, 'tree') and not cython_scope:`
			`pipeline = Pipeline.insert_into_pipeline(`
			`pipeline, merge_scope(dep.tree.scope),`
			`before=ParseTreeTransforms.AnalyseDeclarationsTransform)`

			`if self.outer_module_scope:`
			`# inject outer module between utility code module and builtin module`
			`def scope_transform(module_node):`
			`module_node.scope.outer_scope = self.outer_module_scope`
			`return module_node`

			`pipeline = Pipeline.insert_into_pipeline(`
			`pipeline, scope_transform,`
			`before=ParseTreeTransforms.AnalyseDeclarationsTransform)`

			`if self.context_types:`
			`# inject types into module scope`
			`def scope_transform(module_node):`
			`for name, type in self.context_types.items():`
			`entry = module_node.scope.declare_type(name, type, None, visibility='extern')`
			`entry.in_cinclude = True`
			`return module_node`

			`pipeline = Pipeline.insert_into_pipeline(`
			`pipeline, scope_transform,`
			`before=ParseTreeTransforms.AnalyseDeclarationsTransform)`

			`(err, tree) = Pipeline.run_pipeline(pipeline, tree, printtree=False)`
			`assert not err, err`
			`self.tree = tree`
			`return tree`

			`def put_code(self, output):`
			`pass`

			`@classmethod`
			`def load_as_string(cls, util_code_name, from_file=None, **kwargs):`
			`"""`
			`Load a utility code as a string. Returns (proto, implementation)`
			`"""`
			`util = cls.load(util_code_name, from_file, **kwargs)`
			`return util.proto, util.impl # keep line numbers => no lstrip()`

			`def declare_in_scope(self, dest_scope, used=False, cython_scope=None,`
			`whitelist=None):`
			`"""`
			`Declare all entries from the utility code in dest_scope. Code will only`
			`be included for used entries. If module_name is given, declare the`
			`type entries with that name.`
			`"""`
			`tree = self.get_tree(entries_only=True, cython_scope=cython_scope)`

			`entries = tree.scope.entries`
			`entries.pop('__name__')`
			`entries.pop('__file__')`
			`entries.pop('__builtins__')`
			`entries.pop('__doc__')`

			`for entry in entries.values():`
			`entry.utility_code_definition = self`
			`entry.used = used`

			`original_scope = tree.scope`
			`dest_scope.merge_in(original_scope, merge_unused=True, whitelist=whitelist)`
			`tree.scope = dest_scope`

			`for dep in self.requires:`
			`if dep.is_cython_utility:`
			`dep.declare_in_scope(dest_scope, cython_scope=cython_scope)`

			`return original_scope`


			`def declare_declarations_in_scope(declaration_string, env, private_type=True,`
			`args, *kwargs):`
			`"""`
			`Declare some declarations given as Cython code in declaration_string`
			`in scope env.`
			`"""`
			`CythonUtilityCode(declaration_string, args, *kwargs).declare_in_scope(env)`