# capnp.pyx # distutils: language = c++ # distutils: extra_compile_args = --std=c++11 -fpermissive # distutils: libraries = capnpc # cython: c_string_type = str # cython: c_string_encoding = default # cython: embedsignature = True cimport cython cimport capnp_cpp as capnp cimport schema_cpp from capnp_cpp cimport Schema as C_Schema, StructSchema as C_StructSchema, DynamicStruct as C_DynamicStruct, DynamicValue as C_DynamicValue, Type as C_Type, DynamicList as C_DynamicList, fixMaybe, getEnumString, SchemaParser as C_SchemaParser, ParsedSchema as C_ParsedSchema, VOID, ArrayPtr, StringPtr, String, StringTree, DynamicOrphan as C_DynamicOrphan from schema_cpp cimport Node as C_Node, EnumNode as C_EnumNode from cython.operator cimport dereference as deref from libc.stdint cimport * ctypedef unsigned int uint ctypedef uint8_t UInt8 ctypedef uint16_t UInt16 ctypedef uint32_t UInt32 ctypedef uint64_t UInt64 ctypedef int8_t Int8 ctypedef int16_t Int16 ctypedef int32_t Int32 ctypedef int64_t Int64 ctypedef char * Object ctypedef bint Bool ctypedef float Float32 ctypedef double Float64 from libc.stdlib cimport malloc, free from libcpp cimport bool as cbool ctypedef fused _DynamicStructReaderOrBuilder: _DynamicStructReader _DynamicStructBuilder ctypedef fused _DynamicSetterClasses: C_DynamicList.Builder C_DynamicStruct.Builder def _make_enum(enum_name, *sequential, **named): enums = dict(zip(sequential, range(len(sequential))), **named) reverse = dict((value, key) for key, value in enums.iteritems()) enums['reverse_mapping'] = reverse return type(enum_name, (), enums) _Type = _make_enum('DynamicValue.Type', UNKNOWN = capnp.TYPE_UNKNOWN, VOID = capnp.TYPE_VOID, BOOL = capnp.TYPE_BOOL, INT = capnp.TYPE_INT, UINT = capnp.TYPE_UINT, FLOAT = capnp.TYPE_FLOAT, TEXT = capnp.TYPE_TEXT, DATA = capnp.TYPE_DATA, LIST = capnp.TYPE_LIST, ENUM = capnp.TYPE_ENUM, STRUCT = capnp.TYPE_STRUCT, INTERFACE = capnp.TYPE_INTERFACE, OBJECT = capnp.TYPE_OBJECT) # Templated classes are weird in cython. I couldn't put it in a pxd header for some reason cdef extern from "capnp/list.h" namespace " ::capnp": cdef cppclass List[T]: cppclass Reader: T operator[](uint) except +ValueError uint size() cppclass Builder: T operator[](uint) except +ValueError uint size() cdef extern from "" namespace "std": C_DynamicOrphan moveOrphan"std::move"(C_DynamicOrphan) cdef extern from "" namespace " ::capnp": StringTree printStructReader" ::capnp::prettyPrint"(C_DynamicStruct.Reader) StringTree printStructBuilder" ::capnp::prettyPrint"(C_DynamicStruct.Builder) StringTree printListReader" ::capnp::prettyPrint"(C_DynamicList.Reader) StringTree printListBuilder" ::capnp::prettyPrint"(C_DynamicList.Builder) cdef extern from "" namespace " ::kj": String strStructReader" ::kj::str"(C_DynamicStruct.Reader) String strStructBuilder" ::kj::str"(C_DynamicStruct.Builder) String strListReader" ::kj::str"(C_DynamicList.Reader) String strListBuilder" ::kj::str"(C_DynamicList.Builder) cdef class _NodeReader: cdef C_Node.Reader thisptr cdef init(self, C_Node.Reader other): self.thisptr = other return self property displayName: def __get__(self): return self.thisptr.getDisplayName().cStr() property scopeId: def __get__(self): return self.thisptr.getScopeId() property id: def __get__(self): return self.thisptr.getId() property nestedNodes: def __get__(self): return _List_NestedNode_Reader()._init(self.thisptr.getNestedNodes()) property isStruct: def __get__(self): return self.thisptr.isStruct() property isConst: def __get__(self): return self.thisptr.isConst() cdef class _NestedNodeReader: cdef C_Node.NestedNode.Reader thisptr cdef init(self, C_Node.NestedNode.Reader other): self.thisptr = other return self property name: def __get__(self): return self.thisptr.getName().cStr() property id: def __get__(self): return self.thisptr.getId() cdef class _DynamicListReader: """Class for reading Cap'n Proto Lists This class thinly wraps the C++ Cap'n Proto DynamicList::Reader class. __getitem__ and __len__ have been defined properly, so you can treat this class mostly like any other iterable class:: ... person = addressbook.Person.read(file) phones = person.phones # This returns a _DynamicListReader phone = phones[0] print phone.number for phone in phones: print phone.number """ cdef C_DynamicList.Reader thisptr cdef public object _parent cdef _init(self, C_DynamicList.Reader other, object parent): self.thisptr = other self._parent = parent return self def __getitem__(self, index): size = self.thisptr.size() if index >= size: raise IndexError('Out of bounds') index = index % size return to_python_reader(self.thisptr[index], self._parent) def __len__(self): return self.thisptr.size() def __str__(self): return printListReader(self.thisptr).flatten().cStr() def __repr__(self): # TODO: Print the list type. return '' % strListReader(self.thisptr).cStr() cdef class _DynamicResizableListBuilder: """Class for building growable Cap'n Proto Lists .. warning:: You need to call :meth:`finish` on this object before serializing the Cap'n Proto message. Failure to do so will cause your objects not to be written out as well as leaking orphan structs into your message. This class works much like :class:`_DynamicListBuilder`, but it allows growing the list dynamically. It is meant for lists of structs, since for primitive types like int or float, you're much better off using a normal python list and then serializing straight to a Cap'n Proto list. It has __getitem__ and __len__ defined, but not __setitem__:: ... person = addressbook.Person.new_message() phones = person.init_resizable_list('phones') # This returns a _DynamicResizableListBuilder phone = phones.add() phone.number = 'foo' phone = phones.add() phone.number = 'bar' people.finish() f = open('example', 'w') person.write(f) """ cdef public object _parent, _message, _field, _schema cdef public list _list def __init__(self, parent, field, schema): self._parent = parent self._message = parent._parent self._field = field self._schema = schema self._list = list() cpdef add(self): """A method for adding a new struct to the list This will return a struct, in which you can set fields that will be reflected in the serialized Cap'n Proto message. :rtype: :class:`_DynamicStructBuilder` """ orphan = self._message.new_orphan(self._schema) orphan_val = orphan.get() self._list.append((orphan, orphan_val)) return orphan_val def __getitem__(self, index): return self._list[index][1] # def __setitem__(self, index, val): # self._list[index] = val def __len__(self): return len(self._list) def finish(self): """A method for closing this list and serializing all its members to the message If you don't call this method, the items you previously added from this object will leak into the message, ie. inaccessible but still taking up space. """ cdef int i = 0 new_list = self._parent.init(self._field, len(self)) for orphan, _ in self._list: new_list.adopt(i, orphan) i += 1 cdef class _DynamicListBuilder: """Class for building Cap'n Proto Lists This class thinly wraps the C++ Cap'n Proto DynamicList::Bulder class. __getitem__, __setitem__, and __len__ have been defined properly, so you can treat this class mostly like any other iterable class:: ... person = addressbook.Person.new_message() phones = person.init('phones', 2) # This returns a _DynamicListBuilder phone = phones[0] phone.number = 'foo' phone = phones[1] phone.number = 'bar' for phone in phones: print phone.number """ cdef C_DynamicList.Builder thisptr cdef public object _parent cdef _init(self, C_DynamicList.Builder other, object parent): self.thisptr = other self._parent = parent return self cdef _get(self, index): return to_python_builder(self.thisptr[index], self._parent) def __getitem__(self, index): size = self.thisptr.size() if index >= size: raise IndexError('Out of bounds') index = index % size return self._get(index) def __setitem__(self, index, value): # TODO: share code with _DynamicStructBuilder.__setattr__ size = self.thisptr.size() if index >= size: raise IndexError('Out of bounds') index = index % size _setDynamicField(self.thisptr, index, value, self._parent) def __len__(self): return self.thisptr.size() cpdef adopt(self, index, _DynamicOrphan orphan): """A method for adopting Cap'n Proto orphans Don't use this method unless you know what you're doing. Orphans are useful for dynamically allocating objects for an unkown sized list. :type index: int :param index: The index of the element in the list to replace with the newly adopted object :type orphan: :class:`_DynamicOrphan` :param orphan: A Cap'n proto orphan to adopt. It will be unusable after this operation. :rtype: void """ self.thisptr.adopt(index, orphan.move()) cpdef disown(self, index): """A method for disowning Cap'n Proto orphans Don't use this method unless you know what you're doing. :type index: int :param index: The index of the element in the list to disown :rtype: :class:`_DynamicOrphan` """ return _DynamicOrphan()._init(self.thisptr.disown(index), self._parent) def __str__(self): return printListBuilder(self.thisptr).flatten().cStr() def __repr__(self): # TODO: Print the list type. return '' % strListBuilder(self.thisptr).cStr() cdef class _List_NestedNode_Reader: cdef List[C_Node.NestedNode].Reader thisptr cdef _init(self, List[C_Node.NestedNode].Reader other): self.thisptr = other return self def __getitem__(self, index): size = self.thisptr.size() if index >= size: raise IndexError('Out of bounds') index = index % size return _NestedNodeReader().init(self.thisptr[index]) def __len__(self): return self.thisptr.size() cdef to_python_reader(C_DynamicValue.Reader self, object parent): cdef int type = self.getType() if type == capnp.TYPE_BOOL: return self.asBool() elif type == capnp.TYPE_INT: return self.asInt() elif type == capnp.TYPE_UINT: return self.asUint() elif type == capnp.TYPE_FLOAT: return self.asDouble() elif type == capnp.TYPE_TEXT: return self.asText()[:] elif type == capnp.TYPE_DATA: temp = self.asData() return (temp.begin())[:temp.size()] elif type == capnp.TYPE_LIST: return _DynamicListReader()._init(self.asList(), parent) elif type == capnp.TYPE_STRUCT: return _DynamicStructReader()._init(self.asStruct(), parent) elif type == capnp.TYPE_ENUM: return fixMaybe(self.asEnum().getEnumerant()).getProto().getName().cStr() elif type == capnp.TYPE_VOID: return None elif type == capnp.TYPE_UNKOWN: raise ValueError("Cannot convert type to Python. Type is unknown by capnproto library") else: raise ValueError("Cannot convert type to Python. Type is unhandled by capnproto library") cdef to_python_builder(C_DynamicValue.Builder self, object parent): cdef int type = self.getType() if type == capnp.TYPE_BOOL: return self.asBool() elif type == capnp.TYPE_INT: return self.asInt() elif type == capnp.TYPE_UINT: return self.asUint() elif type == capnp.TYPE_FLOAT: return self.asDouble() elif type == capnp.TYPE_TEXT: return self.asText()[:] elif type == capnp.TYPE_DATA: temp = self.asData() return (temp.begin())[:temp.size()] elif type == capnp.TYPE_LIST: return _DynamicListBuilder()._init(self.asList(), parent) elif type == capnp.TYPE_STRUCT: return _DynamicStructBuilder()._init(self.asStruct(), parent) elif type == capnp.TYPE_ENUM: return fixMaybe(self.asEnum().getEnumerant()).getProto().getName().cStr() elif type == capnp.TYPE_VOID: return None elif type == capnp.TYPE_UNKOWN: raise ValueError("Cannot convert type to Python. Type is unknown by capnproto library") else: raise ValueError("Cannot convert type to Python. Type is unhandled by capnproto library") cdef C_DynamicValue.Reader _extract_dynamic_struct_builder(_DynamicStructBuilder value): return C_DynamicValue.Reader(value.thisptr.asReader()) cdef C_DynamicValue.Reader _extract_dynamic_struct_reader(_DynamicStructReader value): return C_DynamicValue.Reader(value.thisptr) cdef _setDynamicField(_DynamicSetterClasses thisptr, field, value, parent): cdef C_DynamicValue.Reader temp value_type = type(value) if value_type is int or value_type is long: if value < 0: temp = C_DynamicValue.Reader(value) else: temp = C_DynamicValue.Reader(value) thisptr.set(field, temp) elif value_type is float: temp = C_DynamicValue.Reader(value) thisptr.set(field, temp) elif value_type is bool: temp = C_DynamicValue.Reader(value) thisptr.set(field, temp) elif value_type is str: temp = C_DynamicValue.Reader(value) thisptr.set(field, temp) elif value_type is list: builder = to_python_builder(thisptr.init(field, len(value)), parent) for (i, v) in enumerate(value): builder[i] = v elif value is None: temp = C_DynamicValue.Reader(VOID) thisptr.set(field, temp) elif value_type is _DynamicStructBuilder: thisptr.set(field, _extract_dynamic_struct_builder(value)) elif value_type is _DynamicStructReader: thisptr.set(field, _extract_dynamic_struct_reader(value)) else: raise ValueError("Non primitive type") cdef _to_dict(msg): msg_type = type(msg) if msg_type is _DynamicListBuilder or msg_type is _DynamicListReader or msg_type is _DynamicResizableListBuilder: return [_to_dict(x) for x in msg] if msg_type is _DynamicStructBuilder or msg_type is _DynamicStructReader: ret = {} try: which = msg.which() ret['which'] = which ret[which] = getattr(msg, which) except ValueError: pass for field in msg.schema.non_union_fields: ret[field] = _to_dict(getattr(msg, field)) return ret return msg import collections as _collections cdef _from_dict_helper(msg, field, d): if isinstance(d, dict): sub_msg = getattr(msg, field) for key, val in d.iteritems(): if key != 'which': _from_dict_helper(sub_msg, key, val) elif isinstance(d, _collections.Iterable) and not isinstance(d, basestring): l = msg.init(field, len(d)) for i in range(len(d)): if isinstance(d[i], dict): for key, val in d[i].iteritems(): if key != 'which': _from_dict_helper(l[i], key, val) else: l[i] = d[i] else: setattr(msg, field, d) cdef _from_dict(msg, d): for key, val in d.iteritems(): if key != 'which': _from_dict_helper(msg, key, val) cdef class _DynamicStructReader: """Reads Cap'n Proto structs This class is almost a 1 for 1 wrapping of the Cap'n Proto C++ DynamicStruct::Reader. The only difference is that instead of a `get` method, __getattr__ is overloaded and the field name is passed onto the C++ equivalent `get`. This means you just use . syntax to access any field. For field names that don't follow valid python naming convention for fields, use the global function :py:func:`getattr`:: person = addressbook.Person.read(file) # This returns a _DynamicStructReader print person.name # using . syntax print getattr(person, 'field-with-hyphens') # for names that are invalid for python, use getattr """ cdef C_DynamicStruct.Reader thisptr cdef public object _parent cdef object _obj_to_pin cdef _init(self, C_DynamicStruct.Reader other, object parent): self.thisptr = other self._parent = parent return self def __getattr__(self, field): return to_python_reader(self.thisptr.get(field), self._parent) def _has(self, field): return self.thisptr.has(field) cpdef which(self): """Returns the enum corresponding to the union in this struct Enums are just strings in the python Cap'n Proto API, so this function will either return a string equal to the field name of the active field in the union, or throw a ValueError if this isn't a union, or a struct with an unnamed union:: person = addressbook.Person.new_message() person.which() # ValueError: member was null a.employment.employer = 'foo' print employment.which() # 'employer' :rtype: str :return: A string/enum corresponding to what field is set in the union :Raises: :exc:`exceptions.ValueError` if this struct doesn't contain a union """ cdef object which = getEnumString(self.thisptr) if len(which) == 0: raise ValueError("Attempted to call which on a non-union type") return which property schema: """A property that returns the _StructSchema object matching this reader""" def __get__(self): return _StructSchema()._init(self.thisptr.getSchema()) def __dir__(self): return list(self.schema.fieldnames) def __str__(self): return printStructReader(self.thisptr).flatten().cStr() def __repr__(self): return '<%s reader %s>' % (self.schema.node.displayName, strStructReader(self.thisptr).cStr()) def to_dict(self): return _to_dict(self) cdef class _DynamicStructBuilder: """Builds Cap'n Proto structs This class is almost a 1 for 1 wrapping of the Cap'n Proto C++ DynamicStruct::Builder. The only difference is that instead of a `get`/`set` method, __getattr__/__setattr__ is overloaded and the field name is passed onto the C++ equivalent function. This means you just use . syntax to access or set any field. For field names that don't follow valid python naming convention for fields, use the global functions :py:func:`getattr`/:py:func:`setattr`:: person = addressbook.Person.new_message() # This returns a _DynamicStructBuilder person.name = 'foo' # using . syntax print person.name # using . syntax setattr(person, 'field-with-hyphens', 'foo') # for names that are invalid for python, use setattr print getattr(person, 'field-with-hyphens') # for names that are invalid for python, use getattr """ cdef C_DynamicStruct.Builder thisptr cdef public object _parent cdef bint _isRoot cdef _init(self, C_DynamicStruct.Builder other, object parent, bint isRoot = False): self.thisptr = other self._parent = parent self._isRoot = isRoot return self def write(self, file): """Writes the struct's containing message to the given file object in unpacked binary format. This is a shortcut for calling capnp._write_message_to_fd(). This can only be called on the message's root struct. :type file: file :param file: A file or socket object (or anything with a fileno() method), open for write. :rtype: void :Raises: :exc:`exceptions.ValueError` if this isn't the message's root struct. """ if not self._isRoot: raise ValueError("You can only call write() on the message's root struct.") _write_message_to_fd(file.fileno(), self._parent) def write_packed(self, file): """Writes the struct's containing message to the given file object in packed binary format. This is a shortcut for calling capnp._write_packed_message_to_fd(). This can only be called on the message's root struct. :type file: file :param file: A file or socket object (or anything with a fileno() method), open for write. :rtype: void :Raises: :exc:`exceptions.ValueError` if this isn't the message's root struct. """ if not self._isRoot: raise ValueError("You can only call write() on the message's root struct.") _write_packed_message_to_fd(file.fileno(), self._parent) cdef _get(self, field): return to_python_builder(self.thisptr.get(field), self._parent) def __getattr__(self, field): return self._get(field) def __setattr__(self, field, value): _setDynamicField(self.thisptr, field, value, self._parent) def _has(self, field): return self.thisptr.has(field) cpdef init(self, field, size=None): """Method for initializing fields that are of type union/struct/list Typically, you don't have to worry about initializing structs/unions, so this method is mainly for lists. :type field: str :param field: The field name to initialize :type size: int :param size: The size of the list to initiialize. This should be None for struct/union initialization. :rtype: :class:`_DynamicStructBuilder` or :class:`_DynamicListBuilder` :Raises: :exc:`exceptions.ValueError` if the field isn't in this struct """ if size is None: return to_python_builder(self.thisptr.init(field), self._parent) else: return to_python_builder(self.thisptr.init(field, size), self._parent) cpdef init_resizable_list(self, field): """Method for initializing fields that are of type list (of structs) This version of init returns a :class:`_DynamicResizableListBuilder` that allows you to add members one at a time (ie. if you don't know the size for sure). This is only meant for lists of Cap'n Proto objects, since for primitive types you can just define a normal python list and fill it yourself. .. warning:: You need to call :meth:`_DynamicResizableListBuilder.finish` on the list object before serializing the Cap'n Proto message. Failure to do so will cause your objects not to be written out as well as leaking orphan structs into your message. :type field: str :param field: The field name to initialize :rtype: :class:`_DynamicResizableListBuilder` :Raises: :exc:`exceptions.ValueError` if the field isn't in this struct """ return _DynamicResizableListBuilder(self, field, _StructSchema()._init((self.thisptr.get(field)).asList().getStructElementType())) cpdef which(self): """Returns the enum corresponding to the union in this struct Enums are just strings in the python Cap'n Proto API, so this function will either return a string equal to the field name of the active field in the union, or throw a ValueError if this isn't a union, or a struct with an unnamed union:: person = addressbook.Person.new_message() person.which() # ValueError: member was null a.employment.employer = 'foo' print employment.which() # 'employer' :rtype: str :return: A string/enum corresponding to what field is set in the union :Raises: :exc:`exceptions.ValueError` if this struct doesn't contain a union """ cdef object which = getEnumString(self.thisptr) if len(which) == 0: raise ValueError("Attempted to call which on a non-union type") return which cpdef adopt(self, field, _DynamicOrphan orphan): """A method for adopting Cap'n Proto orphans Don't use this method unless you know what you're doing. Orphans are useful for dynamically allocating objects for an unkown sized list. :type field: str :param field: The field name in the struct :type orphan: :class:`_DynamicOrphan` :param orphan: A Cap'n proto orphan to adopt. It will be unusable after this operation. :rtype: void """ self.thisptr.adopt(field, orphan.move()) cpdef disown(self, field): """A method for disowning Cap'n Proto orphans Don't use this method unless you know what you're doing. :type field: str :param field: The field name in the struct :rtype: :class:`_DynamicOrphan` """ return _DynamicOrphan()._init(self.thisptr.disown(field), self._parent) cpdef as_reader(self): """A method for casting this Builder to a Reader Don't use this method unless you know what you're doing. :rtype: :class:`_DynamicStructReader` """ cdef _DynamicStructReader reader reader = _DynamicStructReader()._init(self.thisptr.asReader(), self._parent) reader._obj_to_pin = self return reader property schema: """A property that returns the _StructSchema object matching this writer""" def __get__(self): return _StructSchema()._init(self.thisptr.getSchema()) def __dir__(self): return list(self.schema.fieldnames) def __str__(self): return printStructBuilder(self.thisptr).flatten().cStr() def __repr__(self): return '<%s builder %s>' % (self.schema.node.displayName, strStructBuilder(self.thisptr).cStr()) def to_dict(self): return _to_dict(self) cdef class _DynamicOrphan: cdef C_DynamicOrphan thisptr cdef public object _parent cdef _init(self, C_DynamicOrphan other, object parent): self.thisptr = moveOrphan(other) self._parent = parent return self cdef C_DynamicOrphan move(self): return moveOrphan(self.thisptr) cpdef get(self): """Returns a python object corresponding to the DynamicValue owned by this orphan Use this DynamicValue to set fields inside the orphan """ return to_python_builder(self.thisptr.get(), self._parent) def __str__(self): return str(self.get()) def __repr__(self): return repr(self.get()) cdef class _Schema: cdef C_Schema thisptr cdef _init(self, C_Schema other): self.thisptr = other return self cpdef as_const_value(self): return to_python_reader(self.thisptr.asConst(), self) cpdef as_struct(self): return _StructSchema()._init(self.thisptr.asStruct()) cpdef get_dependency(self, id): return _Schema()._init(self.thisptr.getDependency(id)) cpdef get_proto(self): return _NodeReader().init(self.thisptr.getProto()) cdef class _StructSchema: cdef C_StructSchema thisptr cdef object __fieldnames, __union_fields, __non_union_fields cdef _init(self, C_StructSchema other): self.thisptr = other self.__fieldnames = None self.__union_fields = None self.__non_union_fields = None return self property fieldnames: """A tuple of the field names in the struct.""" def __get__(self): if self.__fieldnames is not None: return self.__fieldnames fieldlist = self.thisptr.getFields() nfields = fieldlist.size() self.__fieldnames = tuple(fieldlist[i].getProto().getName().cStr() for i in xrange(nfields)) return self.__fieldnames property union_fields: """A tuple of the field names in the struct.""" def __get__(self): if self.__union_fields is not None: return self.__union_fields fieldlist = self.thisptr.getUnionFields() nfields = fieldlist.size() self.__union_fields = tuple(fieldlist[i].getProto().getName().cStr() for i in xrange(nfields)) return self.__union_fields property non_union_fields: """A tuple of the field names in the struct.""" def __get__(self): if self.__non_union_fields is not None: return self.__non_union_fields fieldlist = self.thisptr.getNonUnionFields() nfields = fieldlist.size() self.__non_union_fields = tuple(fieldlist[i].getProto().getName().cStr() for i in xrange(nfields)) return self.__non_union_fields property node: """The raw schema node""" def __get__(self): return _DynamicStructReader()._init(self.thisptr.getProto(), None) def __richcmp__(_StructSchema self, _StructSchema other, mode): if mode == 2: return self.thisptr == other.thisptr elif mode == 3: return not (self.thisptr == other.thisptr) else: raise NotImplementedError() def __repr__(self): return '' % self.node.displayName cdef class _ParsedSchema: cdef C_ParsedSchema thisptr cdef _init(self, C_ParsedSchema other): self.thisptr = other return self cpdef as_const_value(self): return to_python_reader(self.thisptr.asConst(), self) cpdef as_struct(self): return _StructSchema()._init(self.thisptr.asStruct()) cpdef get_dependency(self, id): return _Schema()._init(self.thisptr.getDependency(id)) cpdef get_proto(self): return _NodeReader().init(self.thisptr.getProto()) cpdef getNested(self, name): return _ParsedSchema()._init(self.thisptr.getNested(name)) class _StructABCMeta(type): """A metaclass for the Type.Reader and Type.Builder ABCs.""" def __instancecheck__(cls, obj): return isinstance(obj, cls.__base__) and obj.schema == cls._schema cdef class SchemaParser: """A class for loading Cap'n Proto schema files. Do not use this class unless you're sure you know what you're doing. Use the convenience method :func:`load` instead. """ cdef C_SchemaParser * thisptr def __cinit__(self): self.thisptr = new C_SchemaParser() def __dealloc__(self): del self.thisptr def _parse_disk_file(self, displayName, diskPath, imports): cdef StringPtr * importArray = malloc(sizeof(StringPtr) * len(imports)) for i in range(len(imports)): importArray[i] = StringPtr(imports[i]) cdef ArrayPtr[StringPtr] importsPtr = ArrayPtr[StringPtr](importArray, len(imports)) ret = _ParsedSchema() ret._init(self.thisptr.parseDiskFile(displayName, diskPath, importsPtr)) free(importArray) return ret def load(self, file_name, display_name=None, imports=[]): """Load a Cap'n Proto schema from a file You will have to load a schema before you can begin doing anything meaningful with this library. Loading a schema is much like loading a Python module (and load even returns a `ModuleType`). Once it's been loaded, you use it much like any other Module:: parser = capnp.SchemaParser() addressbook = parser.load('addressbook.capnp') print addressbook.qux # qux is a top level constant # 123 person = addressbook.Person.new_message() :type file_name: str :param file_name: A relative or absolute path to a Cap'n Proto schema :type display_name: str :param display_name: The name internally used by the Cap'n Proto library for the loaded schema. By default, it's just os.path.basename(file_name) :type imports: list :param imports: A list of str directories to add to the import path. :rtype: ModuleType :return: A module corresponding to the loaded schema. You can access parsed schemas and constants with . syntax :Raises: - :exc:`exceptions.IOError` if `file_name` doesn't exist - :exc:`exceptions.RuntimeError` if the Cap'n Proto C++ library has any problems loading the schema """ def _load(nodeSchema, module): module._nodeSchema = nodeSchema nodeProto = nodeSchema.get_proto() module._nodeProto = nodeProto for node in nodeProto.nestedNodes: local_module = _ModuleType(node.name) module.__dict__[node.name] = local_module schema = nodeSchema.getNested(node.name) proto = schema.get_proto() if proto.isStruct: local_module.schema = schema.as_struct() def read(local_module): def read_helper(file): reader = _StreamFdMessageReader(file.fileno()) return reader.get_root(local_module) return read_helper def read_packed(file): def read_helper(file): reader = _PackedFdMessageReader(file.fileno()) return reader.get_root(local_module) return read_helper def new_message(local_module): def helper(): builder = _MallocMessageBuilder() return builder.init_root(local_module) return helper def from_dict(local_module): def helper(d): builder = _MallocMessageBuilder() msg = builder.init_root(local_module) _from_dict(msg, d) return msg return helper class Reader(_DynamicStructReader): """An abstract base class. Readers are 'instances' of this class.""" __metaclass__ = _StructABCMeta __slots__ = [] _schema = local_module.schema def __new__(self): raise TypeError('This is an abstract base class') Reader._module = local_module class Builder(_DynamicStructBuilder): """An abstract base class. Builders are 'instances' of this class.""" __metaclass__ = _StructABCMeta __slots__ = [] _schema = local_module.schema def __new__(self): raise TypeError('This is an abstract base class') local_module.read = read(local_module) local_module.read_packed = read_packed(local_module) local_module.new_message = new_message(local_module) local_module.from_dict = from_dict(local_module) local_module.Reader = Reader local_module.Builder = Builder elif proto.isConst: module.__dict__[node.name] = schema.as_const_value() _load(schema, local_module) if not _os.path.isfile(file_name): raise IOError("File not found: " + file_name) if display_name is None: display_name = _os.path.basename(file_name) module = _ModuleType(display_name) parser = self module._parser = parser fileSchema = parser._parse_disk_file(display_name, file_name, imports) _load(fileSchema, module) abs_path = _os.path.abspath(file_name) module.__path__ = _os.path.dirname(abs_path) module.__file__ = abs_path return module cdef class _MessageBuilder: """An abstract base class for building Cap'n Proto messages .. warning:: Don't ever instantiate this class directly. It is only used for inheritance. """ cdef schema_cpp.MessageBuilder * thisptr def __dealloc__(self): del self.thisptr def __init__(self): raise NotImplementedError("This is an abstract base class. You should use MallocMessageBuilder instead") cpdef init_root(self, schema): """A method for instantiating Cap'n Proto structs You will need to pass in a schema to specify which struct to instantiate. Schemas are available in a loaded Cap'n Proto module:: addressbook = capnp.load('addressbook.capnp') ... person = message.init_root(addressbook.Person) :type schema: Schema :param schema: A Cap'n proto schema specifying which struct to instantiate :rtype: :class:`_DynamicStructBuilder` :return: An object where you will set all the members """ cdef _StructSchema s if hasattr(schema, 'schema'): s = schema.schema else: s = schema return _DynamicStructBuilder()._init(self.thisptr.initRootDynamicStruct(s.thisptr), self, True) cpdef get_root(self, schema): """A method for instantiating Cap'n Proto structs, from an already pre-written buffer Don't use this method unless you know what you're doing. You probably want to use init_root instead:: addressbook = capnp.load('addressbook.capnp') ... person = message.init_root(addressbook.Person) ... person = message.get_root(addressbook.Person) :type schema: Schema :param schema: A Cap'n proto schema specifying which struct to instantiate :rtype: :class:`_DynamicStructBuilder` :return: An object where you will set all the members """ cdef _StructSchema s if hasattr(schema, 'schema'): s = schema.schema else: s = schema return _DynamicStructBuilder()._init(self.thisptr.getRootDynamicStruct(s.thisptr), self, True) cpdef set_root(self, value): """A method for instantiating Cap'n Proto structs by copying from an existing struct :type value: :class:`_DynamicStructReader` :param value: A Cap'n Proto struct value to copy :rtype: void """ if type(value) is _DynamicStructBuilder: value = value.as_reader(); self.thisptr.setRootDynamicStruct((<_DynamicStructReader>value).thisptr) cpdef new_orphan(self, schema): """A method for instantiating Cap'n Proto orphans Don't use this method unless you know what you're doing. Orphans are useful for dynamically allocating objects for an unkown sized list, ie:: addressbook = capnp.load('addressbook.capnp') m = capnp._MallocMessageBuilder() alice = m.new_orphan(addressbook.Person) :type schema: Schema :param schema: A Cap'n proto schema specifying which struct to instantiate :rtype: :class:`_DynamicOrphan` :return: An orphan representing a :class:`_DynamicStructBuilder` """ cdef _StructSchema s if hasattr(schema, 'schema'): s = schema.schema else: s = schema return _DynamicOrphan()._init(self.thisptr.newOrphan(s.thisptr), self) cdef class _MallocMessageBuilder(_MessageBuilder): """The main class for building Cap'n Proto messages You will use this class to handle arena allocation of the Cap'n Proto messages. You also use this object when you're done assigning to Cap'n Proto objects, and wish to serialize them:: addressbook = capnp.load('addressbook.capnp') message = capnp._MallocMessageBuilder() person = message.init_root(addressbook.Person) person.name = 'alice' ... f = open('out.txt', 'w') _write_message_to_fd(f.fileno(), message) """ def __cinit__(self): self.thisptr = new schema_cpp.MallocMessageBuilder() def __init__(self): pass cdef class _MessageReader: """An abstract base class for reading Cap'n Proto messages .. warning:: Don't ever instantiate this class. It is only used for inheritance. """ cdef schema_cpp.MessageReader * thisptr def __dealloc__(self): del self.thisptr def __init__(self): raise NotImplementedError("This is an abstract base class") cpdef _get_root_node(self): return _NodeReader().init(self.thisptr.getRootNode()) cpdef get_root(self, schema): """A method for instantiating Cap'n Proto structs You will need to pass in a schema to specify which struct to instantiate. Schemas are available in a loaded Cap'n Proto module:: addressbook = capnp.load('addressbook.capnp') ... person = message.get_root(addressbook.Person) :type schema: Schema :param schema: A Cap'n proto schema specifying which struct to instantiate :rtype: :class:`_DynamicStructReader` :return: An object with all the data of the read Cap'n Proto message. Access members with . syntax. """ cdef _StructSchema s if hasattr(schema, 'schema'): s = schema.schema else: s = schema return _DynamicStructReader()._init(self.thisptr.getRootDynamicStruct(s.thisptr), self) cdef class _StreamFdMessageReader(_MessageReader): """Read a Cap'n Proto message from a file descriptor You use this class to for reading message(s) from a file. It's analagous to the inverse of :func:`_write_message_to_fd` and :class:`_MessageBuilder`, but in one class:: f = open('out.txt') message = _StreamFdMessageReader(f.fileno()) person = message.get_root(addressbook.Person) print person.name :Parameters: - fd (`int`) - A file descriptor """ def __init__(self, int fd): self.thisptr = new schema_cpp.StreamFdMessageReader(fd) cdef class _PackedFdMessageReader(_MessageReader): """Read a Cap'n Proto message from a file descriptor in a packed manner You use this class to for reading message(s) from a file. It's analagous to the inverse of :func:`_write_packed_message_to_fd` and :class:`_MessageBuilder`, but in one class.:: f = open('out.txt') message = _PackedFdMessageReader(f.fileno()) person = message.get_root(addressbook.Person) print person.name :Parameters: - fd (`int`) - A file descriptor """ def __init__(self, int fd): self.thisptr = new schema_cpp.PackedFdMessageReader(fd) def _write_message_to_fd(int fd, _MessageBuilder message): """Serialize a Cap'n Proto message to a file descriptor You use this method to serialize your message to a file. Please note that you must pass a file descriptor (ie. an int), not a file object. Make sure you use the proper reader to match this (ie. don't use _PackedFdMessageReader):: message = capnp._MallocMessageBuilder() ... f = open('out.txt', 'w') _write_message_to_fd(f.fileno(), message) ... f = open('out.txt') _StreamFdMessageReader(f.fileno()) :type fd: int :param fd: A file descriptor :type message: :class:`_MessageBuilder` :param message: The Cap'n Proto message to serialize :rtype: void """ schema_cpp.writeMessageToFd(fd, deref(message.thisptr)) def _write_packed_message_to_fd(int fd, _MessageBuilder message): """Serialize a Cap'n Proto message to a file descriptor in a packed manner You use this method to serialize your message to a file. Please note that you must pass a file descriptor (ie. an int), not a file object. Also, note the difference in names with _write_message_to_fd. This method uses a different serialization specification, and your reader will need to match.:: message = capnp._MallocMessageBuilder() ... f = open('out.txt', 'w') _write_packed_message_to_fd(f.fileno(), message) ... f = open('out.txt') _PackedFdMessageReader(f.fileno()) :type fd: int :param fd: A file descriptor :type message: :class:`_MessageBuilder` :param message: The Cap'n Proto message to serialize :rtype: void """ schema_cpp.writePackedMessageToFd(fd, deref(message.thisptr)) from types import ModuleType as _ModuleType import os as _os import sys as _sys import imp as _imp _global_schema_parser = None def load(file_name, display_name=None, imports=[]): """Load a Cap'n Proto schema from a file You will have to load a schema before you can begin doing anything meaningful with this library. Loading a schema is much like loading a Python module (and load even returns a `ModuleType`). Once it's been loaded, you use it much like any other Module:: addressbook = capnp.load('addressbook.capnp') print addressbook.qux # qux is a top level constant in the addressbook.capnp schema # 123 person = addressbook.Person.new_message() :type file_name: str :param file_name: A relative or absolute path to a Cap'n Proto schema :type display_name: str :param display_name: The name internally used by the Cap'n Proto library for the loaded schema. By default, it's just os.path.basename(file_name) :type imports: list :param imports: A list of str directories to add to the import path. :rtype: ModuleType :return: A module corresponding to the loaded schema. You can access parsed schemas and constants with . syntax :Raises: :exc:`exceptions.ValueError` if `file_name` doesn't exist """ global _global_schema_parser if _global_schema_parser is None: _global_schema_parser = SchemaParser() return _global_schema_parser.load(file_name, display_name, imports) class _Loader: def __init__(self, fullname, path, additional_paths): self.fullname = fullname self.path = path # Add current directory of the capnp schema to search path dir_name = _os.path.dirname(path) if path is not '': additional_paths = [dir_name] + additional_paths self.additional_paths = additional_paths def load_module(self, fullname): assert self.fullname == fullname, ( "invalid module, expected %s, got %s" % ( self.fullname, fullname)) imports = self.additional_paths + _sys.path imports = [path if path != '' else '.' for path in imports] # convert empty path '' to '.' module = load(self.path, fullname, imports=imports) _sys.modules[fullname] = module return module class _Importer: def __init__(self, additional_paths): self.extension = '.capnp' self.additional_paths = additional_paths def find_module(self, fullname, package_path=None): if fullname in _sys.modules: # Don't allow re-imports return None if '.' in fullname: # only when package_path anyway? mod_parts = fullname.split('.') module_name = mod_parts[-1] else: module_name = fullname if not module_name.endswith('_capnp'): return None module_name = module_name[:-len('_capnp')] capnp_module_name = module_name + self.extension if package_path: paths = package_path else: paths = _sys.path join_path = _os.path.join is_file = _os.path.isfile is_abs = _os.path.isabs abspath = _os.path.abspath #is_dir = os.path.isdir sep = _os.path.sep paths = self.additional_paths + paths for path in paths: if not path: path = _os.getcwd() elif not is_abs(path): path = abspath(path) if is_file(path+sep+capnp_module_name): return _Loader(fullname, join_path(path, capnp_module_name), self.additional_paths) _importer = None def add_import_hook(additional_paths=[]): """Add a hook to the python import system, so that Cap'n Proto modules are directly importable After calling this function, you can use the python import syntax to directly import capnproto schemas:: import capnp capnp.add_import_hook() import addressbook # equivalent to capnp.load('addressbook.capnp', 'addressbook', sys.path), except it will search for 'addressbook.capnp' in all directories of sys.path :type additional_paths: list :param additional_paths: Additional paths, listed as strings, to be used to search for the .capnp files. It is prepended to the beginning of sys.path. It also affects imports inside of Cap'n Proto schemas. """ global _importer if _importer is not None: remove_import_hook() _importer = _Importer(additional_paths) _sys.meta_path.append(_importer) def remove_import_hook(): """Remove the import hook, and return python's import to normal""" global _importer if _importer is not None: _sys.meta_path.remove(_importer) _importer = None