13674 lines
535 KiB
Python
13674 lines
535 KiB
Python
#
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# Parse tree nodes for expressions
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#
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from __future__ import absolute_import
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import cython
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cython.declare(error=object, warning=object, warn_once=object, InternalError=object,
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CompileError=object, UtilityCode=object, TempitaUtilityCode=object,
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StringEncoding=object, operator=object, local_errors=object, report_error=object,
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Naming=object, Nodes=object, PyrexTypes=object, py_object_type=object,
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list_type=object, tuple_type=object, set_type=object, dict_type=object,
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unicode_type=object, str_type=object, bytes_type=object, type_type=object,
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Builtin=object, Symtab=object, Utils=object, find_coercion_error=object,
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debug_disposal_code=object, debug_temp_alloc=object, debug_coercion=object,
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bytearray_type=object, slice_type=object, _py_int_types=object,
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IS_PYTHON3=cython.bint)
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import re
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import sys
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import copy
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import os.path
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import operator
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from .Errors import (
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error, warning, InternalError, CompileError, report_error, local_errors)
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from .Code import UtilityCode, TempitaUtilityCode
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from . import StringEncoding
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from . import Naming
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from . import Nodes
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from .Nodes import Node, utility_code_for_imports, analyse_type_annotation
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from . import PyrexTypes
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from .PyrexTypes import py_object_type, c_long_type, typecast, error_type, \
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unspecified_type
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from . import TypeSlots
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from .Builtin import list_type, tuple_type, set_type, dict_type, type_type, \
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unicode_type, str_type, bytes_type, bytearray_type, basestring_type, slice_type
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from . import Builtin
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from . import Symtab
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from .. import Utils
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from .Annotate import AnnotationItem
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from . import Future
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from ..Debugging import print_call_chain
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from .DebugFlags import debug_disposal_code, debug_temp_alloc, \
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debug_coercion
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from .Pythran import (to_pythran, is_pythran_supported_type, is_pythran_supported_operation_type,
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is_pythran_expr, pythran_func_type, pythran_binop_type, pythran_unaryop_type, has_np_pythran,
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pythran_indexing_code, pythran_indexing_type, is_pythran_supported_node_or_none, pythran_type,
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pythran_is_numpy_func_supported, pythran_get_func_include_file, pythran_functor)
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from .PyrexTypes import PythranExpr
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try:
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from __builtin__ import basestring
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except ImportError:
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# Python 3
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basestring = str
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any_string_type = (bytes, str)
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else:
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# Python 2
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any_string_type = (bytes, unicode)
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if sys.version_info[0] >= 3:
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IS_PYTHON3 = True
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_py_int_types = int
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else:
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IS_PYTHON3 = False
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_py_int_types = (int, long)
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class NotConstant(object):
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_obj = None
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def __new__(cls):
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if NotConstant._obj is None:
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NotConstant._obj = super(NotConstant, cls).__new__(cls)
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return NotConstant._obj
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def __repr__(self):
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return "<NOT CONSTANT>"
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not_a_constant = NotConstant()
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constant_value_not_set = object()
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# error messages when coercing from key[0] to key[1]
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coercion_error_dict = {
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# string related errors
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(unicode_type, str_type): ("Cannot convert Unicode string to 'str' implicitly."
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" This is not portable and requires explicit encoding."),
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(unicode_type, bytes_type): "Cannot convert Unicode string to 'bytes' implicitly, encoding required.",
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(unicode_type, PyrexTypes.c_char_ptr_type): "Unicode objects only support coercion to Py_UNICODE*.",
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(unicode_type, PyrexTypes.c_const_char_ptr_type): "Unicode objects only support coercion to Py_UNICODE*.",
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(unicode_type, PyrexTypes.c_uchar_ptr_type): "Unicode objects only support coercion to Py_UNICODE*.",
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(unicode_type, PyrexTypes.c_const_uchar_ptr_type): "Unicode objects only support coercion to Py_UNICODE*.",
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(bytes_type, unicode_type): "Cannot convert 'bytes' object to unicode implicitly, decoding required",
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(bytes_type, str_type): "Cannot convert 'bytes' object to str implicitly. This is not portable to Py3.",
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(bytes_type, basestring_type): ("Cannot convert 'bytes' object to basestring implicitly."
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" This is not portable to Py3."),
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(bytes_type, PyrexTypes.c_py_unicode_ptr_type): "Cannot convert 'bytes' object to Py_UNICODE*, use 'unicode'.",
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(bytes_type, PyrexTypes.c_const_py_unicode_ptr_type): (
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"Cannot convert 'bytes' object to Py_UNICODE*, use 'unicode'."),
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(basestring_type, bytes_type): "Cannot convert 'basestring' object to bytes implicitly. This is not portable.",
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(str_type, unicode_type): ("str objects do not support coercion to unicode,"
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" use a unicode string literal instead (u'')"),
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(str_type, bytes_type): "Cannot convert 'str' to 'bytes' implicitly. This is not portable.",
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(str_type, PyrexTypes.c_char_ptr_type): "'str' objects do not support coercion to C types (use 'bytes'?).",
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(str_type, PyrexTypes.c_const_char_ptr_type): "'str' objects do not support coercion to C types (use 'bytes'?).",
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(str_type, PyrexTypes.c_uchar_ptr_type): "'str' objects do not support coercion to C types (use 'bytes'?).",
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(str_type, PyrexTypes.c_const_uchar_ptr_type): "'str' objects do not support coercion to C types (use 'bytes'?).",
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(str_type, PyrexTypes.c_py_unicode_ptr_type): "'str' objects do not support coercion to C types (use 'unicode'?).",
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(str_type, PyrexTypes.c_const_py_unicode_ptr_type): (
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"'str' objects do not support coercion to C types (use 'unicode'?)."),
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(PyrexTypes.c_char_ptr_type, unicode_type): "Cannot convert 'char*' to unicode implicitly, decoding required",
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(PyrexTypes.c_const_char_ptr_type, unicode_type): (
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"Cannot convert 'char*' to unicode implicitly, decoding required"),
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(PyrexTypes.c_uchar_ptr_type, unicode_type): "Cannot convert 'char*' to unicode implicitly, decoding required",
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(PyrexTypes.c_const_uchar_ptr_type, unicode_type): (
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"Cannot convert 'char*' to unicode implicitly, decoding required"),
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}
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def find_coercion_error(type_tuple, default, env):
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err = coercion_error_dict.get(type_tuple)
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if err is None:
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return default
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elif (env.directives['c_string_encoding'] and
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any(t in type_tuple for t in (PyrexTypes.c_char_ptr_type, PyrexTypes.c_uchar_ptr_type,
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PyrexTypes.c_const_char_ptr_type, PyrexTypes.c_const_uchar_ptr_type))):
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if type_tuple[1].is_pyobject:
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return default
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elif env.directives['c_string_encoding'] in ('ascii', 'default'):
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return default
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else:
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return "'%s' objects do not support coercion to C types with non-ascii or non-default c_string_encoding" % type_tuple[0].name
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else:
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return err
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def default_str_type(env):
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return {
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'bytes': bytes_type,
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'bytearray': bytearray_type,
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'str': str_type,
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'unicode': unicode_type
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}.get(env.directives['c_string_type'])
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def check_negative_indices(*nodes):
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"""
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Raise a warning on nodes that are known to have negative numeric values.
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Used to find (potential) bugs inside of "wraparound=False" sections.
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"""
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for node in nodes:
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if node is None or (
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not isinstance(node.constant_result, _py_int_types) and
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not isinstance(node.constant_result, float)):
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continue
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if node.constant_result < 0:
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warning(node.pos,
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"the result of using negative indices inside of "
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"code sections marked as 'wraparound=False' is "
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"undefined", level=1)
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def infer_sequence_item_type(env, seq_node, index_node=None, seq_type=None):
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if not seq_node.is_sequence_constructor:
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if seq_type is None:
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seq_type = seq_node.infer_type(env)
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if seq_type is tuple_type:
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# tuples are immutable => we can safely follow assignments
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if seq_node.cf_state and len(seq_node.cf_state) == 1:
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try:
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seq_node = seq_node.cf_state[0].rhs
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except AttributeError:
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pass
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if seq_node is not None and seq_node.is_sequence_constructor:
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if index_node is not None and index_node.has_constant_result():
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try:
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item = seq_node.args[index_node.constant_result]
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except (ValueError, TypeError, IndexError):
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pass
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else:
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return item.infer_type(env)
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# if we're lucky, all items have the same type
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item_types = set([item.infer_type(env) for item in seq_node.args])
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if len(item_types) == 1:
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return item_types.pop()
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return None
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def make_dedup_key(outer_type, item_nodes):
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"""
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Recursively generate a deduplication key from a sequence of values.
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Includes Cython node types to work around the fact that (1, 2.0) == (1.0, 2), for example.
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@param outer_type: The type of the outer container.
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@param item_nodes: A sequence of constant nodes that will be traversed recursively.
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@return: A tuple that can be used as a dict key for deduplication.
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"""
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item_keys = [
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(py_object_type, None, type(None)) if node is None
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# For sequences and their "mult_factor", see TupleNode.
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else make_dedup_key(node.type, [node.mult_factor if node.is_literal else None] + node.args) if node.is_sequence_constructor
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else make_dedup_key(node.type, (node.start, node.stop, node.step)) if node.is_slice
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# For constants, look at the Python value type if we don't know the concrete Cython type.
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else (node.type, node.constant_result,
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type(node.constant_result) if node.type is py_object_type else None) if node.has_constant_result()
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else None # something we cannot handle => short-circuit below
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for node in item_nodes
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]
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if None in item_keys:
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return None
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return outer_type, tuple(item_keys)
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# Returns a block of code to translate the exception,
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# plus a boolean indicating whether to check for Python exceptions.
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def get_exception_handler(exception_value):
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if exception_value is None:
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return "__Pyx_CppExn2PyErr();", False
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elif (exception_value.type == PyrexTypes.c_char_type
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and exception_value.value == '*'):
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return "__Pyx_CppExn2PyErr();", True
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elif exception_value.type.is_pyobject:
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return (
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'try { throw; } catch(const std::exception& exn) {'
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'PyErr_SetString(%s, exn.what());'
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'} catch(...) { PyErr_SetNone(%s); }' % (
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exception_value.entry.cname,
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exception_value.entry.cname),
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False)
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else:
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return (
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'%s(); if (!PyErr_Occurred())'
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'PyErr_SetString(PyExc_RuntimeError, '
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'"Error converting c++ exception.");' % (
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exception_value.entry.cname),
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False)
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def maybe_check_py_error(code, check_py_exception, pos, nogil):
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if check_py_exception:
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if nogil:
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code.putln(code.error_goto_if("__Pyx_ErrOccurredWithGIL()", pos))
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else:
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code.putln(code.error_goto_if("PyErr_Occurred()", pos))
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def translate_cpp_exception(code, pos, inside, py_result, exception_value, nogil):
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raise_py_exception, check_py_exception = get_exception_handler(exception_value)
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code.putln("try {")
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code.putln("%s" % inside)
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if py_result:
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code.putln(code.error_goto_if_null(py_result, pos))
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maybe_check_py_error(code, check_py_exception, pos, nogil)
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code.putln("} catch(...) {")
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if nogil:
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code.put_ensure_gil(declare_gilstate=True)
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code.putln(raise_py_exception)
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if nogil:
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code.put_release_ensured_gil()
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code.putln(code.error_goto(pos))
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code.putln("}")
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# Used to handle the case where an lvalue expression and an overloaded assignment
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# both have an exception declaration.
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def translate_double_cpp_exception(code, pos, lhs_type, lhs_code, rhs_code,
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lhs_exc_val, assign_exc_val, nogil):
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handle_lhs_exc, lhc_check_py_exc = get_exception_handler(lhs_exc_val)
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handle_assignment_exc, assignment_check_py_exc = get_exception_handler(assign_exc_val)
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code.putln("try {")
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code.putln(lhs_type.declaration_code("__pyx_local_lvalue = %s;" % lhs_code))
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maybe_check_py_error(code, lhc_check_py_exc, pos, nogil)
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code.putln("try {")
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code.putln("__pyx_local_lvalue = %s;" % rhs_code)
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maybe_check_py_error(code, assignment_check_py_exc, pos, nogil)
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# Catch any exception from the overloaded assignment.
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code.putln("} catch(...) {")
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if nogil:
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code.put_ensure_gil(declare_gilstate=True)
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code.putln(handle_assignment_exc)
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if nogil:
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code.put_release_ensured_gil()
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code.putln(code.error_goto(pos))
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code.putln("}")
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# Catch any exception from evaluating lhs.
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code.putln("} catch(...) {")
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if nogil:
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code.put_ensure_gil(declare_gilstate=True)
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code.putln(handle_lhs_exc)
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if nogil:
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code.put_release_ensured_gil()
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code.putln(code.error_goto(pos))
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code.putln('}')
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class ExprNode(Node):
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# subexprs [string] Class var holding names of subexpr node attrs
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# type PyrexType Type of the result
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# result_code string Code fragment
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# result_ctype string C type of result_code if different from type
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# is_temp boolean Result is in a temporary variable
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# is_sequence_constructor
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# boolean Is a list or tuple constructor expression
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# is_starred boolean Is a starred expression (e.g. '*a')
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# saved_subexpr_nodes
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# [ExprNode or [ExprNode or None] or None]
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# Cached result of subexpr_nodes()
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# use_managed_ref boolean use ref-counted temps/assignments/etc.
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# result_is_used boolean indicates that the result will be dropped and the
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# is_numpy_attribute boolean Is a Numpy module attribute
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# result_code/temp_result can safely be set to None
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# annotation ExprNode or None PEP526 annotation for names or expressions
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result_ctype = None
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type = None
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annotation = None
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temp_code = None
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old_temp = None # error checker for multiple frees etc.
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use_managed_ref = True # can be set by optimisation transforms
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result_is_used = True
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is_numpy_attribute = False
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# The Analyse Expressions phase for expressions is split
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# into two sub-phases:
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#
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# Analyse Types
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# Determines the result type of the expression based
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# on the types of its sub-expressions, and inserts
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# coercion nodes into the expression tree where needed.
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# Marks nodes which will need to have temporary variables
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# allocated.
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#
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# Allocate Temps
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# Allocates temporary variables where needed, and fills
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# in the result_code field of each node.
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#
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# ExprNode provides some convenience routines which
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# perform both of the above phases. These should only
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# be called from statement nodes, and only when no
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# coercion nodes need to be added around the expression
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# being analysed. In that case, the above two phases
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# should be invoked separately.
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#
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# Framework code in ExprNode provides much of the common
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# processing for the various phases. It makes use of the
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# 'subexprs' class attribute of ExprNodes, which should
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# contain a list of the names of attributes which can
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# hold sub-nodes or sequences of sub-nodes.
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#
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# The framework makes use of a number of abstract methods.
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# Their responsibilities are as follows.
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#
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# Declaration Analysis phase
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#
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# analyse_target_declaration
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# Called during the Analyse Declarations phase to analyse
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# the LHS of an assignment or argument of a del statement.
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# Nodes which cannot be the LHS of an assignment need not
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# implement it.
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#
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# Expression Analysis phase
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#
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# analyse_types
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# - Call analyse_types on all sub-expressions.
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# - Check operand types, and wrap coercion nodes around
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# sub-expressions where needed.
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# - Set the type of this node.
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# - If a temporary variable will be required for the
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# result, set the is_temp flag of this node.
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#
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# analyse_target_types
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# Called during the Analyse Types phase to analyse
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# the LHS of an assignment or argument of a del
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# statement. Similar responsibilities to analyse_types.
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#
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# target_code
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# Called by the default implementation of allocate_target_temps.
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# Should return a C lvalue for assigning to the node. The default
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# implementation calls calculate_result_code.
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#
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# check_const
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# - Check that this node and its subnodes form a
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# legal constant expression. If so, do nothing,
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# otherwise call not_const.
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#
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# The default implementation of check_const
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# assumes that the expression is not constant.
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#
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# check_const_addr
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# - Same as check_const, except check that the
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# expression is a C lvalue whose address is
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# constant. Otherwise, call addr_not_const.
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#
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# The default implementation of calc_const_addr
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# assumes that the expression is not a constant
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# lvalue.
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#
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# Code Generation phase
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|
#
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# generate_evaluation_code
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# - Call generate_evaluation_code for sub-expressions.
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# - Perform the functions of generate_result_code
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# (see below).
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# - If result is temporary, call generate_disposal_code
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# on all sub-expressions.
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#
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# A default implementation of generate_evaluation_code
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# is provided which uses the following abstract methods:
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#
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# generate_result_code
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# - Generate any C statements necessary to calculate
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# the result of this node from the results of its
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# sub-expressions.
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#
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# calculate_result_code
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# - Should return a C code fragment evaluating to the
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# result. This is only called when the result is not
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# a temporary.
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#
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# generate_assignment_code
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# Called on the LHS of an assignment.
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# - Call generate_evaluation_code for sub-expressions.
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# - Generate code to perform the assignment.
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# - If the assignment absorbed a reference, call
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# generate_post_assignment_code on the RHS,
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# otherwise call generate_disposal_code on it.
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#
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# generate_deletion_code
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# Called on an argument of a del statement.
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|
# - Call generate_evaluation_code for sub-expressions.
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# - Generate code to perform the deletion.
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|
# - Call generate_disposal_code on all sub-expressions.
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|
#
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|
#
|
|
|
|
is_sequence_constructor = False
|
|
is_dict_literal = False
|
|
is_set_literal = False
|
|
is_string_literal = False
|
|
is_attribute = False
|
|
is_subscript = False
|
|
is_slice = False
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|
|
is_buffer_access = False
|
|
is_memview_index = False
|
|
is_memview_slice = False
|
|
is_memview_broadcast = False
|
|
is_memview_copy_assignment = False
|
|
|
|
saved_subexpr_nodes = None
|
|
is_temp = False
|
|
is_target = False
|
|
is_starred = False
|
|
|
|
constant_result = constant_value_not_set
|
|
|
|
child_attrs = property(fget=operator.attrgetter('subexprs'))
|
|
|
|
def not_implemented(self, method_name):
|
|
print_call_chain(method_name, "not implemented") ###
|
|
raise InternalError(
|
|
"%s.%s not implemented" %
|
|
(self.__class__.__name__, method_name))
|
|
|
|
def is_lvalue(self):
|
|
return 0
|
|
|
|
def is_addressable(self):
|
|
return self.is_lvalue() and not self.type.is_memoryviewslice
|
|
|
|
def is_ephemeral(self):
|
|
# An ephemeral node is one whose result is in
|
|
# a Python temporary and we suspect there are no
|
|
# other references to it. Certain operations are
|
|
# disallowed on such values, since they are
|
|
# likely to result in a dangling pointer.
|
|
return self.type.is_pyobject and self.is_temp
|
|
|
|
def subexpr_nodes(self):
|
|
# Extract a list of subexpression nodes based
|
|
# on the contents of the subexprs class attribute.
|
|
nodes = []
|
|
for name in self.subexprs:
|
|
item = getattr(self, name)
|
|
if item is not None:
|
|
if type(item) is list:
|
|
nodes.extend(item)
|
|
else:
|
|
nodes.append(item)
|
|
return nodes
|
|
|
|
def result(self):
|
|
if self.is_temp:
|
|
#if not self.temp_code:
|
|
# pos = (os.path.basename(self.pos[0].get_description()),) + self.pos[1:] if self.pos else '(?)'
|
|
# raise RuntimeError("temp result name not set in %s at %r" % (
|
|
# self.__class__.__name__, pos))
|
|
return self.temp_code
|
|
else:
|
|
return self.calculate_result_code()
|
|
|
|
def pythran_result(self, type_=None):
|
|
if is_pythran_supported_node_or_none(self):
|
|
return to_pythran(self)
|
|
|
|
assert(type_ is not None)
|
|
return to_pythran(self, type_)
|
|
|
|
def is_c_result_required(self):
|
|
"""
|
|
Subtypes may return False here if result temp allocation can be skipped.
|
|
"""
|
|
return True
|
|
|
|
def result_as(self, type = None):
|
|
# Return the result code cast to the specified C type.
|
|
if (self.is_temp and self.type.is_pyobject and
|
|
type != py_object_type):
|
|
# Allocated temporaries are always PyObject *, which may not
|
|
# reflect the actual type (e.g. an extension type)
|
|
return typecast(type, py_object_type, self.result())
|
|
return typecast(type, self.ctype(), self.result())
|
|
|
|
def py_result(self):
|
|
# Return the result code cast to PyObject *.
|
|
return self.result_as(py_object_type)
|
|
|
|
def ctype(self):
|
|
# Return the native C type of the result (i.e. the
|
|
# C type of the result_code expression).
|
|
return self.result_ctype or self.type
|
|
|
|
def get_constant_c_result_code(self):
|
|
# Return the constant value of this node as a result code
|
|
# string, or None if the node is not constant. This method
|
|
# can be called when the constant result code is required
|
|
# before the code generation phase.
|
|
#
|
|
# The return value is a string that can represent a simple C
|
|
# value, a constant C name or a constant C expression. If the
|
|
# node type depends on Python code, this must return None.
|
|
return None
|
|
|
|
def calculate_constant_result(self):
|
|
# Calculate the constant compile time result value of this
|
|
# expression and store it in ``self.constant_result``. Does
|
|
# nothing by default, thus leaving ``self.constant_result``
|
|
# unknown. If valid, the result can be an arbitrary Python
|
|
# value.
|
|
#
|
|
# This must only be called when it is assured that all
|
|
# sub-expressions have a valid constant_result value. The
|
|
# ConstantFolding transform will do this.
|
|
pass
|
|
|
|
def has_constant_result(self):
|
|
return self.constant_result is not constant_value_not_set and \
|
|
self.constant_result is not not_a_constant
|
|
|
|
def compile_time_value(self, denv):
|
|
# Return value of compile-time expression, or report error.
|
|
error(self.pos, "Invalid compile-time expression")
|
|
|
|
def compile_time_value_error(self, e):
|
|
error(self.pos, "Error in compile-time expression: %s: %s" % (
|
|
e.__class__.__name__, e))
|
|
|
|
# ------------- Declaration Analysis ----------------
|
|
|
|
def analyse_target_declaration(self, env):
|
|
error(self.pos, "Cannot assign to or delete this")
|
|
|
|
# ------------- Expression Analysis ----------------
|
|
|
|
def analyse_const_expression(self, env):
|
|
# Called during the analyse_declarations phase of a
|
|
# constant expression. Analyses the expression's type,
|
|
# checks whether it is a legal const expression,
|
|
# and determines its value.
|
|
node = self.analyse_types(env)
|
|
node.check_const()
|
|
return node
|
|
|
|
def analyse_expressions(self, env):
|
|
# Convenience routine performing both the Type
|
|
# Analysis and Temp Allocation phases for a whole
|
|
# expression.
|
|
return self.analyse_types(env)
|
|
|
|
def analyse_target_expression(self, env, rhs):
|
|
# Convenience routine performing both the Type
|
|
# Analysis and Temp Allocation phases for the LHS of
|
|
# an assignment.
|
|
return self.analyse_target_types(env)
|
|
|
|
def analyse_boolean_expression(self, env):
|
|
# Analyse expression and coerce to a boolean.
|
|
node = self.analyse_types(env)
|
|
bool = node.coerce_to_boolean(env)
|
|
return bool
|
|
|
|
def analyse_temp_boolean_expression(self, env):
|
|
# Analyse boolean expression and coerce result into
|
|
# a temporary. This is used when a branch is to be
|
|
# performed on the result and we won't have an
|
|
# opportunity to ensure disposal code is executed
|
|
# afterwards. By forcing the result into a temporary,
|
|
# we ensure that all disposal has been done by the
|
|
# time we get the result.
|
|
node = self.analyse_types(env)
|
|
return node.coerce_to_boolean(env).coerce_to_simple(env)
|
|
|
|
# --------------- Type Inference -----------------
|
|
|
|
def type_dependencies(self, env):
|
|
# Returns the list of entries whose types must be determined
|
|
# before the type of self can be inferred.
|
|
if hasattr(self, 'type') and self.type is not None:
|
|
return ()
|
|
return sum([node.type_dependencies(env) for node in self.subexpr_nodes()], ())
|
|
|
|
def infer_type(self, env):
|
|
# Attempt to deduce the type of self.
|
|
# Differs from analyse_types as it avoids unnecessary
|
|
# analysis of subexpressions, but can assume everything
|
|
# in self.type_dependencies() has been resolved.
|
|
if hasattr(self, 'type') and self.type is not None:
|
|
return self.type
|
|
elif hasattr(self, 'entry') and self.entry is not None:
|
|
return self.entry.type
|
|
else:
|
|
self.not_implemented("infer_type")
|
|
|
|
def nonlocally_immutable(self):
|
|
# Returns whether this variable is a safe reference, i.e.
|
|
# can't be modified as part of globals or closures.
|
|
return self.is_literal or self.is_temp or self.type.is_array or self.type.is_cfunction
|
|
|
|
def inferable_item_node(self, index=0):
|
|
"""
|
|
Return a node that represents the (type) result of an indexing operation,
|
|
e.g. for tuple unpacking or iteration.
|
|
"""
|
|
return IndexNode(self.pos, base=self, index=IntNode(
|
|
self.pos, value=str(index), constant_result=index, type=PyrexTypes.c_py_ssize_t_type))
|
|
|
|
# --------------- Type Analysis ------------------
|
|
|
|
def analyse_as_module(self, env):
|
|
# If this node can be interpreted as a reference to a
|
|
# cimported module, return its scope, else None.
|
|
return None
|
|
|
|
def analyse_as_type(self, env):
|
|
# If this node can be interpreted as a reference to a
|
|
# type, return that type, else None.
|
|
return None
|
|
|
|
def analyse_as_extension_type(self, env):
|
|
# If this node can be interpreted as a reference to an
|
|
# extension type or builtin type, return its type, else None.
|
|
return None
|
|
|
|
def analyse_types(self, env):
|
|
self.not_implemented("analyse_types")
|
|
|
|
def analyse_target_types(self, env):
|
|
return self.analyse_types(env)
|
|
|
|
def nogil_check(self, env):
|
|
# By default, any expression based on Python objects is
|
|
# prevented in nogil environments. Subtypes must override
|
|
# this if they can work without the GIL.
|
|
if self.type and self.type.is_pyobject:
|
|
self.gil_error()
|
|
|
|
def gil_assignment_check(self, env):
|
|
if env.nogil and self.type.is_pyobject:
|
|
error(self.pos, "Assignment of Python object not allowed without gil")
|
|
|
|
def check_const(self):
|
|
self.not_const()
|
|
return False
|
|
|
|
def not_const(self):
|
|
error(self.pos, "Not allowed in a constant expression")
|
|
|
|
def check_const_addr(self):
|
|
self.addr_not_const()
|
|
return False
|
|
|
|
def addr_not_const(self):
|
|
error(self.pos, "Address is not constant")
|
|
|
|
# ----------------- Result Allocation -----------------
|
|
|
|
def result_in_temp(self):
|
|
# Return true if result is in a temporary owned by
|
|
# this node or one of its subexpressions. Overridden
|
|
# by certain nodes which can share the result of
|
|
# a subnode.
|
|
return self.is_temp
|
|
|
|
def target_code(self):
|
|
# Return code fragment for use as LHS of a C assignment.
|
|
return self.calculate_result_code()
|
|
|
|
def calculate_result_code(self):
|
|
self.not_implemented("calculate_result_code")
|
|
|
|
# def release_target_temp(self, env):
|
|
# # Release temporaries used by LHS of an assignment.
|
|
# self.release_subexpr_temps(env)
|
|
|
|
def allocate_temp_result(self, code):
|
|
if self.temp_code:
|
|
raise RuntimeError("Temp allocated multiple times in %r: %r" % (self.__class__.__name__, self.pos))
|
|
type = self.type
|
|
if not type.is_void:
|
|
if type.is_pyobject:
|
|
type = PyrexTypes.py_object_type
|
|
elif not (self.result_is_used or type.is_memoryviewslice or self.is_c_result_required()):
|
|
self.temp_code = None
|
|
return
|
|
self.temp_code = code.funcstate.allocate_temp(
|
|
type, manage_ref=self.use_managed_ref)
|
|
else:
|
|
self.temp_code = None
|
|
|
|
def release_temp_result(self, code):
|
|
if not self.temp_code:
|
|
if not self.result_is_used:
|
|
# not used anyway, so ignore if not set up
|
|
return
|
|
pos = (os.path.basename(self.pos[0].get_description()),) + self.pos[1:] if self.pos else '(?)'
|
|
if self.old_temp:
|
|
raise RuntimeError("temp %s released multiple times in %s at %r" % (
|
|
self.old_temp, self.__class__.__name__, pos))
|
|
else:
|
|
raise RuntimeError("no temp, but release requested in %s at %r" % (
|
|
self.__class__.__name__, pos))
|
|
code.funcstate.release_temp(self.temp_code)
|
|
self.old_temp = self.temp_code
|
|
self.temp_code = None
|
|
|
|
# ---------------- Code Generation -----------------
|
|
|
|
def make_owned_reference(self, code):
|
|
"""
|
|
If result is a pyobject, make sure we own a reference to it.
|
|
If the result is in a temp, it is already a new reference.
|
|
"""
|
|
if self.type.is_pyobject and not self.result_in_temp():
|
|
code.put_incref(self.result(), self.ctype())
|
|
|
|
def make_owned_memoryviewslice(self, code):
|
|
"""
|
|
Make sure we own the reference to this memoryview slice.
|
|
"""
|
|
if not self.result_in_temp():
|
|
code.put_incref_memoryviewslice(self.result(),
|
|
have_gil=self.in_nogil_context)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
# Generate code to evaluate this node and
|
|
# its sub-expressions, and dispose of any
|
|
# temporary results of its sub-expressions.
|
|
self.generate_subexpr_evaluation_code(code)
|
|
|
|
code.mark_pos(self.pos)
|
|
if self.is_temp:
|
|
self.allocate_temp_result(code)
|
|
|
|
self.generate_result_code(code)
|
|
if self.is_temp and not (self.type.is_string or self.type.is_pyunicode_ptr):
|
|
# If we are temp we do not need to wait until this node is disposed
|
|
# before disposing children.
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
|
|
def generate_subexpr_evaluation_code(self, code):
|
|
for node in self.subexpr_nodes():
|
|
node.generate_evaluation_code(code)
|
|
|
|
def generate_result_code(self, code):
|
|
self.not_implemented("generate_result_code")
|
|
|
|
def generate_disposal_code(self, code):
|
|
if self.is_temp:
|
|
if self.type.is_string or self.type.is_pyunicode_ptr:
|
|
# postponed from self.generate_evaluation_code()
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
if self.result():
|
|
if self.type.is_pyobject:
|
|
code.put_decref_clear(self.result(), self.ctype())
|
|
elif self.type.is_memoryviewslice:
|
|
code.put_xdecref_memoryviewslice(
|
|
self.result(), have_gil=not self.in_nogil_context)
|
|
code.putln("%s.memview = NULL;" % self.result())
|
|
code.putln("%s.data = NULL;" % self.result())
|
|
else:
|
|
# Already done if self.is_temp
|
|
self.generate_subexpr_disposal_code(code)
|
|
|
|
def generate_subexpr_disposal_code(self, code):
|
|
# Generate code to dispose of temporary results
|
|
# of all sub-expressions.
|
|
for node in self.subexpr_nodes():
|
|
node.generate_disposal_code(code)
|
|
|
|
def generate_post_assignment_code(self, code):
|
|
if self.is_temp:
|
|
if self.type.is_string or self.type.is_pyunicode_ptr:
|
|
# postponed from self.generate_evaluation_code()
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
elif self.type.is_pyobject:
|
|
code.putln("%s = 0;" % self.result())
|
|
elif self.type.is_memoryviewslice:
|
|
code.putln("%s.memview = NULL;" % self.result())
|
|
code.putln("%s.data = NULL;" % self.result())
|
|
else:
|
|
self.generate_subexpr_disposal_code(code)
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False,
|
|
exception_check=None, exception_value=None):
|
|
# Stub method for nodes which are not legal as
|
|
# the LHS of an assignment. An error will have
|
|
# been reported earlier.
|
|
pass
|
|
|
|
def generate_deletion_code(self, code, ignore_nonexisting=False):
|
|
# Stub method for nodes that are not legal as
|
|
# the argument of a del statement. An error
|
|
# will have been reported earlier.
|
|
pass
|
|
|
|
def free_temps(self, code):
|
|
if self.is_temp:
|
|
if not self.type.is_void:
|
|
self.release_temp_result(code)
|
|
else:
|
|
self.free_subexpr_temps(code)
|
|
|
|
def free_subexpr_temps(self, code):
|
|
for sub in self.subexpr_nodes():
|
|
sub.free_temps(code)
|
|
|
|
def generate_function_definitions(self, env, code):
|
|
pass
|
|
|
|
# ---------------- Annotation ---------------------
|
|
|
|
def annotate(self, code):
|
|
for node in self.subexpr_nodes():
|
|
node.annotate(code)
|
|
|
|
# ----------------- Coercion ----------------------
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
# Coerce the result so that it can be assigned to
|
|
# something of type dst_type. If processing is necessary,
|
|
# wraps this node in a coercion node and returns that.
|
|
# Otherwise, returns this node unchanged.
|
|
#
|
|
# This method is called during the analyse_expressions
|
|
# phase of the src_node's processing.
|
|
#
|
|
# Note that subclasses that override this (especially
|
|
# ConstNodes) must not (re-)set their own .type attribute
|
|
# here. Since expression nodes may turn up in different
|
|
# places in the tree (e.g. inside of CloneNodes in cascaded
|
|
# assignments), this method must return a new node instance
|
|
# if it changes the type.
|
|
#
|
|
src = self
|
|
src_type = self.type
|
|
|
|
if self.check_for_coercion_error(dst_type, env):
|
|
return self
|
|
|
|
used_as_reference = dst_type.is_reference
|
|
if used_as_reference and not src_type.is_reference:
|
|
dst_type = dst_type.ref_base_type
|
|
|
|
if src_type.is_const:
|
|
src_type = src_type.const_base_type
|
|
|
|
if src_type.is_fused or dst_type.is_fused:
|
|
# See if we are coercing a fused function to a pointer to a
|
|
# specialized function
|
|
if (src_type.is_cfunction and not dst_type.is_fused and
|
|
dst_type.is_ptr and dst_type.base_type.is_cfunction):
|
|
|
|
dst_type = dst_type.base_type
|
|
|
|
for signature in src_type.get_all_specialized_function_types():
|
|
if signature.same_as(dst_type):
|
|
src.type = signature
|
|
src.entry = src.type.entry
|
|
src.entry.used = True
|
|
return self
|
|
|
|
if src_type.is_fused:
|
|
error(self.pos, "Type is not specialized")
|
|
elif src_type.is_null_ptr and dst_type.is_ptr:
|
|
# NULL can be implicitly cast to any pointer type
|
|
return self
|
|
else:
|
|
error(self.pos, "Cannot coerce to a type that is not specialized")
|
|
|
|
self.type = error_type
|
|
return self
|
|
|
|
if self.coercion_type is not None:
|
|
# This is purely for error checking purposes!
|
|
node = NameNode(self.pos, name='', type=self.coercion_type)
|
|
node.coerce_to(dst_type, env)
|
|
|
|
if dst_type.is_memoryviewslice:
|
|
from . import MemoryView
|
|
if not src.type.is_memoryviewslice:
|
|
if src.type.is_pyobject:
|
|
src = CoerceToMemViewSliceNode(src, dst_type, env)
|
|
elif src.type.is_array:
|
|
src = CythonArrayNode.from_carray(src, env).coerce_to(dst_type, env)
|
|
elif not src_type.is_error:
|
|
error(self.pos,
|
|
"Cannot convert '%s' to memoryviewslice" % (src_type,))
|
|
else:
|
|
if src.type.writable_needed:
|
|
dst_type.writable_needed = True
|
|
if not src.type.conforms_to(dst_type, broadcast=self.is_memview_broadcast,
|
|
copying=self.is_memview_copy_assignment):
|
|
if src.type.dtype.same_as(dst_type.dtype):
|
|
msg = "Memoryview '%s' not conformable to memoryview '%s'."
|
|
tup = src.type, dst_type
|
|
else:
|
|
msg = "Different base types for memoryviews (%s, %s)"
|
|
tup = src.type.dtype, dst_type.dtype
|
|
|
|
error(self.pos, msg % tup)
|
|
|
|
elif dst_type.is_pyobject:
|
|
if not src.type.is_pyobject:
|
|
if dst_type is bytes_type and src.type.is_int:
|
|
src = CoerceIntToBytesNode(src, env)
|
|
else:
|
|
src = CoerceToPyTypeNode(src, env, type=dst_type)
|
|
if not src.type.subtype_of(dst_type):
|
|
if src.constant_result is not None:
|
|
src = PyTypeTestNode(src, dst_type, env)
|
|
elif is_pythran_expr(dst_type) and is_pythran_supported_type(src.type):
|
|
# We let the compiler decide whether this is valid
|
|
return src
|
|
elif is_pythran_expr(src.type):
|
|
if is_pythran_supported_type(dst_type):
|
|
# Match the case were a pythran expr is assigned to a value, or vice versa.
|
|
# We let the C++ compiler decide whether this is valid or not!
|
|
return src
|
|
# Else, we need to convert the Pythran expression to a Python object
|
|
src = CoerceToPyTypeNode(src, env, type=dst_type)
|
|
elif src.type.is_pyobject:
|
|
if used_as_reference and dst_type.is_cpp_class:
|
|
warning(
|
|
self.pos,
|
|
"Cannot pass Python object as C++ data structure reference (%s &), will pass by copy." % dst_type)
|
|
src = CoerceFromPyTypeNode(dst_type, src, env)
|
|
elif (dst_type.is_complex
|
|
and src_type != dst_type
|
|
and dst_type.assignable_from(src_type)):
|
|
src = CoerceToComplexNode(src, dst_type, env)
|
|
else: # neither src nor dst are py types
|
|
# Added the string comparison, since for c types that
|
|
# is enough, but Cython gets confused when the types are
|
|
# in different pxi files.
|
|
# TODO: Remove this hack and require shared declarations.
|
|
if not (src.type == dst_type or str(src.type) == str(dst_type) or dst_type.assignable_from(src_type)):
|
|
self.fail_assignment(dst_type)
|
|
return src
|
|
|
|
def fail_assignment(self, dst_type):
|
|
error(self.pos, "Cannot assign type '%s' to '%s'" % (self.type, dst_type))
|
|
|
|
def check_for_coercion_error(self, dst_type, env, fail=False, default=None):
|
|
if fail and not default:
|
|
default = "Cannot assign type '%(FROM)s' to '%(TO)s'"
|
|
message = find_coercion_error((self.type, dst_type), default, env)
|
|
if message is not None:
|
|
error(self.pos, message % {'FROM': self.type, 'TO': dst_type})
|
|
return True
|
|
if fail:
|
|
self.fail_assignment(dst_type)
|
|
return True
|
|
return False
|
|
|
|
def coerce_to_pyobject(self, env):
|
|
return self.coerce_to(PyrexTypes.py_object_type, env)
|
|
|
|
def coerce_to_boolean(self, env):
|
|
# Coerce result to something acceptable as
|
|
# a boolean value.
|
|
|
|
# if it's constant, calculate the result now
|
|
if self.has_constant_result():
|
|
bool_value = bool(self.constant_result)
|
|
return BoolNode(self.pos, value=bool_value,
|
|
constant_result=bool_value)
|
|
|
|
type = self.type
|
|
if type.is_enum or type.is_error:
|
|
return self
|
|
elif type.is_pyobject or type.is_int or type.is_ptr or type.is_float:
|
|
return CoerceToBooleanNode(self, env)
|
|
elif type.is_cpp_class:
|
|
return SimpleCallNode(
|
|
self.pos,
|
|
function=AttributeNode(
|
|
self.pos, obj=self, attribute='operator bool'),
|
|
args=[]).analyse_types(env)
|
|
elif type.is_ctuple:
|
|
bool_value = len(type.components) == 0
|
|
return BoolNode(self.pos, value=bool_value,
|
|
constant_result=bool_value)
|
|
else:
|
|
error(self.pos, "Type '%s' not acceptable as a boolean" % type)
|
|
return self
|
|
|
|
def coerce_to_integer(self, env):
|
|
# If not already some C integer type, coerce to longint.
|
|
if self.type.is_int:
|
|
return self
|
|
else:
|
|
return self.coerce_to(PyrexTypes.c_long_type, env)
|
|
|
|
def coerce_to_temp(self, env):
|
|
# Ensure that the result is in a temporary.
|
|
if self.result_in_temp():
|
|
return self
|
|
else:
|
|
return CoerceToTempNode(self, env)
|
|
|
|
def coerce_to_simple(self, env):
|
|
# Ensure that the result is simple (see is_simple).
|
|
if self.is_simple():
|
|
return self
|
|
else:
|
|
return self.coerce_to_temp(env)
|
|
|
|
def is_simple(self):
|
|
# A node is simple if its result is something that can
|
|
# be referred to without performing any operations, e.g.
|
|
# a constant, local var, C global var, struct member
|
|
# reference, or temporary.
|
|
return self.result_in_temp()
|
|
|
|
def may_be_none(self):
|
|
if self.type and not (self.type.is_pyobject or
|
|
self.type.is_memoryviewslice):
|
|
return False
|
|
if self.has_constant_result():
|
|
return self.constant_result is not None
|
|
return True
|
|
|
|
def as_cython_attribute(self):
|
|
return None
|
|
|
|
def as_none_safe_node(self, message, error="PyExc_TypeError", format_args=()):
|
|
# Wraps the node in a NoneCheckNode if it is not known to be
|
|
# not-None (e.g. because it is a Python literal).
|
|
if self.may_be_none():
|
|
return NoneCheckNode(self, error, message, format_args)
|
|
else:
|
|
return self
|
|
|
|
@classmethod
|
|
def from_node(cls, node, **kwargs):
|
|
"""Instantiate this node class from another node, properly
|
|
copying over all attributes that one would forget otherwise.
|
|
"""
|
|
attributes = "cf_state cf_maybe_null cf_is_null constant_result".split()
|
|
for attr_name in attributes:
|
|
if attr_name in kwargs:
|
|
continue
|
|
try:
|
|
value = getattr(node, attr_name)
|
|
except AttributeError:
|
|
pass
|
|
else:
|
|
kwargs[attr_name] = value
|
|
return cls(node.pos, **kwargs)
|
|
|
|
|
|
class AtomicExprNode(ExprNode):
|
|
# Abstract base class for expression nodes which have
|
|
# no sub-expressions.
|
|
|
|
subexprs = []
|
|
|
|
# Override to optimize -- we know we have no children
|
|
def generate_subexpr_evaluation_code(self, code):
|
|
pass
|
|
def generate_subexpr_disposal_code(self, code):
|
|
pass
|
|
|
|
class PyConstNode(AtomicExprNode):
|
|
# Abstract base class for constant Python values.
|
|
|
|
is_literal = 1
|
|
type = py_object_type
|
|
|
|
def is_simple(self):
|
|
return 1
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def calculate_result_code(self):
|
|
return self.value
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
class NoneNode(PyConstNode):
|
|
# The constant value None
|
|
|
|
is_none = 1
|
|
value = "Py_None"
|
|
|
|
constant_result = None
|
|
|
|
nogil_check = None
|
|
|
|
def compile_time_value(self, denv):
|
|
return None
|
|
|
|
def may_be_none(self):
|
|
return True
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if not (dst_type.is_pyobject or dst_type.is_memoryviewslice or dst_type.is_error):
|
|
# Catch this error early and loudly.
|
|
error(self.pos, "Cannot assign None to %s" % dst_type)
|
|
return super(NoneNode, self).coerce_to(dst_type, env)
|
|
|
|
|
|
class EllipsisNode(PyConstNode):
|
|
# '...' in a subscript list.
|
|
|
|
value = "Py_Ellipsis"
|
|
|
|
constant_result = Ellipsis
|
|
|
|
def compile_time_value(self, denv):
|
|
return Ellipsis
|
|
|
|
|
|
class ConstNode(AtomicExprNode):
|
|
# Abstract base type for literal constant nodes.
|
|
#
|
|
# value string C code fragment
|
|
|
|
is_literal = 1
|
|
nogil_check = None
|
|
|
|
def is_simple(self):
|
|
return 1
|
|
|
|
def nonlocally_immutable(self):
|
|
return 1
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def analyse_types(self, env):
|
|
return self # Types are held in class variables
|
|
|
|
def check_const(self):
|
|
return True
|
|
|
|
def get_constant_c_result_code(self):
|
|
return self.calculate_result_code()
|
|
|
|
def calculate_result_code(self):
|
|
return str(self.value)
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
class BoolNode(ConstNode):
|
|
type = PyrexTypes.c_bint_type
|
|
# The constant value True or False
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = self.value
|
|
|
|
def compile_time_value(self, denv):
|
|
return self.value
|
|
|
|
def calculate_result_code(self):
|
|
if self.type.is_pyobject:
|
|
return self.value and 'Py_True' or 'Py_False'
|
|
else:
|
|
return str(int(self.value))
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type == self.type:
|
|
return self
|
|
if dst_type is py_object_type and self.type is Builtin.bool_type:
|
|
return self
|
|
if dst_type.is_pyobject and self.type.is_int:
|
|
return BoolNode(
|
|
self.pos, value=self.value,
|
|
constant_result=self.constant_result,
|
|
type=Builtin.bool_type)
|
|
if dst_type.is_int and self.type.is_pyobject:
|
|
return BoolNode(
|
|
self.pos, value=self.value,
|
|
constant_result=self.constant_result,
|
|
type=PyrexTypes.c_bint_type)
|
|
return ConstNode.coerce_to(self, dst_type, env)
|
|
|
|
|
|
class NullNode(ConstNode):
|
|
type = PyrexTypes.c_null_ptr_type
|
|
value = "NULL"
|
|
constant_result = 0
|
|
|
|
def get_constant_c_result_code(self):
|
|
return self.value
|
|
|
|
|
|
class CharNode(ConstNode):
|
|
type = PyrexTypes.c_char_type
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = ord(self.value)
|
|
|
|
def compile_time_value(self, denv):
|
|
return ord(self.value)
|
|
|
|
def calculate_result_code(self):
|
|
return "'%s'" % StringEncoding.escape_char(self.value)
|
|
|
|
|
|
class IntNode(ConstNode):
|
|
|
|
# unsigned "" or "U"
|
|
# longness "" or "L" or "LL"
|
|
# is_c_literal True/False/None creator considers this a C integer literal
|
|
|
|
unsigned = ""
|
|
longness = ""
|
|
is_c_literal = None # unknown
|
|
|
|
def __init__(self, pos, **kwds):
|
|
ExprNode.__init__(self, pos, **kwds)
|
|
if 'type' not in kwds:
|
|
self.type = self.find_suitable_type_for_value()
|
|
|
|
def find_suitable_type_for_value(self):
|
|
if self.constant_result is constant_value_not_set:
|
|
try:
|
|
self.calculate_constant_result()
|
|
except ValueError:
|
|
pass
|
|
# we ignore 'is_c_literal = True' and instead map signed 32bit
|
|
# integers as C long values
|
|
if self.is_c_literal or \
|
|
not self.has_constant_result() or \
|
|
self.unsigned or self.longness == 'LL':
|
|
# clearly a C literal
|
|
rank = (self.longness == 'LL') and 2 or 1
|
|
suitable_type = PyrexTypes.modifiers_and_name_to_type[not self.unsigned, rank, "int"]
|
|
if self.type:
|
|
suitable_type = PyrexTypes.widest_numeric_type(suitable_type, self.type)
|
|
else:
|
|
# C literal or Python literal - split at 32bit boundary
|
|
if -2**31 <= self.constant_result < 2**31:
|
|
if self.type and self.type.is_int:
|
|
suitable_type = self.type
|
|
else:
|
|
suitable_type = PyrexTypes.c_long_type
|
|
else:
|
|
suitable_type = PyrexTypes.py_object_type
|
|
return suitable_type
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if self.type is dst_type:
|
|
return self
|
|
elif dst_type.is_float:
|
|
if self.has_constant_result():
|
|
return FloatNode(self.pos, value='%d.0' % int(self.constant_result), type=dst_type,
|
|
constant_result=float(self.constant_result))
|
|
else:
|
|
return FloatNode(self.pos, value=self.value, type=dst_type,
|
|
constant_result=not_a_constant)
|
|
if dst_type.is_numeric and not dst_type.is_complex:
|
|
node = IntNode(self.pos, value=self.value, constant_result=self.constant_result,
|
|
type=dst_type, is_c_literal=True,
|
|
unsigned=self.unsigned, longness=self.longness)
|
|
return node
|
|
elif dst_type.is_pyobject:
|
|
node = IntNode(self.pos, value=self.value, constant_result=self.constant_result,
|
|
type=PyrexTypes.py_object_type, is_c_literal=False,
|
|
unsigned=self.unsigned, longness=self.longness)
|
|
else:
|
|
# FIXME: not setting the type here to keep it working with
|
|
# complex numbers. Should they be special cased?
|
|
node = IntNode(self.pos, value=self.value, constant_result=self.constant_result,
|
|
unsigned=self.unsigned, longness=self.longness)
|
|
# We still need to perform normal coerce_to processing on the
|
|
# result, because we might be coercing to an extension type,
|
|
# in which case a type test node will be needed.
|
|
return ConstNode.coerce_to(node, dst_type, env)
|
|
|
|
def coerce_to_boolean(self, env):
|
|
return IntNode(
|
|
self.pos, value=self.value,
|
|
constant_result=self.constant_result,
|
|
type=PyrexTypes.c_bint_type,
|
|
unsigned=self.unsigned, longness=self.longness)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if self.type.is_pyobject:
|
|
# pre-allocate a Python version of the number
|
|
plain_integer_string = str(Utils.str_to_number(self.value))
|
|
self.result_code = code.get_py_int(plain_integer_string, self.longness)
|
|
else:
|
|
self.result_code = self.get_constant_c_result_code()
|
|
|
|
def get_constant_c_result_code(self):
|
|
unsigned, longness = self.unsigned, self.longness
|
|
literal = self.value_as_c_integer_string()
|
|
if not (unsigned or longness) and self.type.is_int and literal[0] == '-' and literal[1] != '0':
|
|
# negative decimal literal => guess longness from type to prevent wrap-around
|
|
if self.type.rank >= PyrexTypes.c_longlong_type.rank:
|
|
longness = 'LL'
|
|
elif self.type.rank >= PyrexTypes.c_long_type.rank:
|
|
longness = 'L'
|
|
return literal + unsigned + longness
|
|
|
|
def value_as_c_integer_string(self):
|
|
value = self.value
|
|
if len(value) <= 2:
|
|
# too short to go wrong (and simplifies code below)
|
|
return value
|
|
neg_sign = ''
|
|
if value[0] == '-':
|
|
neg_sign = '-'
|
|
value = value[1:]
|
|
if value[0] == '0':
|
|
literal_type = value[1] # 0'o' - 0'b' - 0'x'
|
|
# 0x123 hex literals and 0123 octal literals work nicely in C
|
|
# but C-incompatible Py3 oct/bin notations need conversion
|
|
if neg_sign and literal_type in 'oOxX0123456789' and value[2:].isdigit():
|
|
# negative hex/octal literal => prevent C compiler from using
|
|
# unsigned integer types by converting to decimal (see C standard 6.4.4.1)
|
|
value = str(Utils.str_to_number(value))
|
|
elif literal_type in 'oO':
|
|
value = '0' + value[2:] # '0o123' => '0123'
|
|
elif literal_type in 'bB':
|
|
value = str(int(value[2:], 2))
|
|
elif value.isdigit() and not self.unsigned and not self.longness:
|
|
if not neg_sign:
|
|
# C compilers do not consider unsigned types for decimal literals,
|
|
# but they do for hex (see C standard 6.4.4.1)
|
|
value = '0x%X' % int(value)
|
|
return neg_sign + value
|
|
|
|
def calculate_result_code(self):
|
|
return self.result_code
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = Utils.str_to_number(self.value)
|
|
|
|
def compile_time_value(self, denv):
|
|
return Utils.str_to_number(self.value)
|
|
|
|
class FloatNode(ConstNode):
|
|
type = PyrexTypes.c_double_type
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = float(self.value)
|
|
|
|
def compile_time_value(self, denv):
|
|
return float(self.value)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type.is_pyobject and self.type.is_float:
|
|
return FloatNode(
|
|
self.pos, value=self.value,
|
|
constant_result=self.constant_result,
|
|
type=Builtin.float_type)
|
|
if dst_type.is_float and self.type.is_pyobject:
|
|
return FloatNode(
|
|
self.pos, value=self.value,
|
|
constant_result=self.constant_result,
|
|
type=dst_type)
|
|
return ConstNode.coerce_to(self, dst_type, env)
|
|
|
|
def calculate_result_code(self):
|
|
return self.result_code
|
|
|
|
def get_constant_c_result_code(self):
|
|
strval = self.value
|
|
assert isinstance(strval, basestring)
|
|
cmpval = repr(float(strval))
|
|
if cmpval == 'nan':
|
|
return "(Py_HUGE_VAL * 0)"
|
|
elif cmpval == 'inf':
|
|
return "Py_HUGE_VAL"
|
|
elif cmpval == '-inf':
|
|
return "(-Py_HUGE_VAL)"
|
|
else:
|
|
return strval
|
|
|
|
def generate_evaluation_code(self, code):
|
|
c_value = self.get_constant_c_result_code()
|
|
if self.type.is_pyobject:
|
|
self.result_code = code.get_py_float(self.value, c_value)
|
|
else:
|
|
self.result_code = c_value
|
|
|
|
|
|
def _analyse_name_as_type(name, pos, env):
|
|
type = PyrexTypes.parse_basic_type(name)
|
|
if type is not None:
|
|
return type
|
|
|
|
global_entry = env.global_scope().lookup(name)
|
|
if global_entry and global_entry.type and (
|
|
global_entry.type.is_extension_type
|
|
or global_entry.type.is_struct_or_union
|
|
or global_entry.type.is_builtin_type
|
|
or global_entry.type.is_cpp_class):
|
|
return global_entry.type
|
|
|
|
from .TreeFragment import TreeFragment
|
|
with local_errors(ignore=True):
|
|
pos = (pos[0], pos[1], pos[2]-7)
|
|
try:
|
|
declaration = TreeFragment(u"sizeof(%s)" % name, name=pos[0].filename, initial_pos=pos)
|
|
except CompileError:
|
|
pass
|
|
else:
|
|
sizeof_node = declaration.root.stats[0].expr
|
|
if isinstance(sizeof_node, SizeofTypeNode):
|
|
sizeof_node = sizeof_node.analyse_types(env)
|
|
if isinstance(sizeof_node, SizeofTypeNode):
|
|
return sizeof_node.arg_type
|
|
return None
|
|
|
|
|
|
class BytesNode(ConstNode):
|
|
# A char* or bytes literal
|
|
#
|
|
# value BytesLiteral
|
|
|
|
is_string_literal = True
|
|
# start off as Python 'bytes' to support len() in O(1)
|
|
type = bytes_type
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = self.value
|
|
|
|
def as_sliced_node(self, start, stop, step=None):
|
|
value = StringEncoding.bytes_literal(self.value[start:stop:step], self.value.encoding)
|
|
return BytesNode(self.pos, value=value, constant_result=value)
|
|
|
|
def compile_time_value(self, denv):
|
|
return self.value.byteencode()
|
|
|
|
def analyse_as_type(self, env):
|
|
return _analyse_name_as_type(self.value.decode('ISO8859-1'), self.pos, env)
|
|
|
|
def can_coerce_to_char_literal(self):
|
|
return len(self.value) == 1
|
|
|
|
def coerce_to_boolean(self, env):
|
|
# This is special because testing a C char* for truth directly
|
|
# would yield the wrong result.
|
|
bool_value = bool(self.value)
|
|
return BoolNode(self.pos, value=bool_value, constant_result=bool_value)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if self.type == dst_type:
|
|
return self
|
|
if dst_type.is_int:
|
|
if not self.can_coerce_to_char_literal():
|
|
error(self.pos, "Only single-character string literals can be coerced into ints.")
|
|
return self
|
|
if dst_type.is_unicode_char:
|
|
error(self.pos, "Bytes literals cannot coerce to Py_UNICODE/Py_UCS4, use a unicode literal instead.")
|
|
return self
|
|
return CharNode(self.pos, value=self.value,
|
|
constant_result=ord(self.value))
|
|
|
|
node = BytesNode(self.pos, value=self.value, constant_result=self.constant_result)
|
|
if dst_type.is_pyobject:
|
|
if dst_type in (py_object_type, Builtin.bytes_type):
|
|
node.type = Builtin.bytes_type
|
|
else:
|
|
self.check_for_coercion_error(dst_type, env, fail=True)
|
|
return node
|
|
elif dst_type in (PyrexTypes.c_char_ptr_type, PyrexTypes.c_const_char_ptr_type):
|
|
node.type = dst_type
|
|
return node
|
|
elif dst_type in (PyrexTypes.c_uchar_ptr_type, PyrexTypes.c_const_uchar_ptr_type, PyrexTypes.c_void_ptr_type):
|
|
node.type = (PyrexTypes.c_const_char_ptr_type if dst_type == PyrexTypes.c_const_uchar_ptr_type
|
|
else PyrexTypes.c_char_ptr_type)
|
|
return CastNode(node, dst_type)
|
|
elif dst_type.assignable_from(PyrexTypes.c_char_ptr_type):
|
|
# Exclude the case of passing a C string literal into a non-const C++ string.
|
|
if not dst_type.is_cpp_class or dst_type.is_const:
|
|
node.type = dst_type
|
|
return node
|
|
|
|
# We still need to perform normal coerce_to processing on the
|
|
# result, because we might be coercing to an extension type,
|
|
# in which case a type test node will be needed.
|
|
return ConstNode.coerce_to(node, dst_type, env)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if self.type.is_pyobject:
|
|
result = code.get_py_string_const(self.value)
|
|
elif self.type.is_const:
|
|
result = code.get_string_const(self.value)
|
|
else:
|
|
# not const => use plain C string literal and cast to mutable type
|
|
literal = self.value.as_c_string_literal()
|
|
# C++ may require a cast
|
|
result = typecast(self.type, PyrexTypes.c_void_ptr_type, literal)
|
|
self.result_code = result
|
|
|
|
def get_constant_c_result_code(self):
|
|
return None # FIXME
|
|
|
|
def calculate_result_code(self):
|
|
return self.result_code
|
|
|
|
|
|
class UnicodeNode(ConstNode):
|
|
# A Py_UNICODE* or unicode literal
|
|
#
|
|
# value EncodedString
|
|
# bytes_value BytesLiteral the literal parsed as bytes string
|
|
# ('-3' unicode literals only)
|
|
|
|
is_string_literal = True
|
|
bytes_value = None
|
|
type = unicode_type
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = self.value
|
|
|
|
def analyse_as_type(self, env):
|
|
return _analyse_name_as_type(self.value, self.pos, env)
|
|
|
|
def as_sliced_node(self, start, stop, step=None):
|
|
if StringEncoding.string_contains_surrogates(self.value[:stop]):
|
|
# this is unsafe as it may give different results
|
|
# in different runtimes
|
|
return None
|
|
value = StringEncoding.EncodedString(self.value[start:stop:step])
|
|
value.encoding = self.value.encoding
|
|
if self.bytes_value is not None:
|
|
bytes_value = StringEncoding.bytes_literal(
|
|
self.bytes_value[start:stop:step], self.bytes_value.encoding)
|
|
else:
|
|
bytes_value = None
|
|
return UnicodeNode(
|
|
self.pos, value=value, bytes_value=bytes_value,
|
|
constant_result=value)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type is self.type:
|
|
pass
|
|
elif dst_type.is_unicode_char:
|
|
if not self.can_coerce_to_char_literal():
|
|
error(self.pos,
|
|
"Only single-character Unicode string literals or "
|
|
"surrogate pairs can be coerced into Py_UCS4/Py_UNICODE.")
|
|
return self
|
|
int_value = ord(self.value)
|
|
return IntNode(self.pos, type=dst_type, value=str(int_value),
|
|
constant_result=int_value)
|
|
elif not dst_type.is_pyobject:
|
|
if dst_type.is_string and self.bytes_value is not None:
|
|
# special case: '-3' enforced unicode literal used in a
|
|
# C char* context
|
|
return BytesNode(self.pos, value=self.bytes_value
|
|
).coerce_to(dst_type, env)
|
|
if dst_type.is_pyunicode_ptr:
|
|
node = UnicodeNode(self.pos, value=self.value)
|
|
node.type = dst_type
|
|
return node
|
|
error(self.pos,
|
|
"Unicode literals do not support coercion to C types other "
|
|
"than Py_UNICODE/Py_UCS4 (for characters) or Py_UNICODE* "
|
|
"(for strings).")
|
|
elif dst_type not in (py_object_type, Builtin.basestring_type):
|
|
self.check_for_coercion_error(dst_type, env, fail=True)
|
|
return self
|
|
|
|
def can_coerce_to_char_literal(self):
|
|
return len(self.value) == 1
|
|
## or (len(self.value) == 2
|
|
## and (0xD800 <= self.value[0] <= 0xDBFF)
|
|
## and (0xDC00 <= self.value[1] <= 0xDFFF))
|
|
|
|
def coerce_to_boolean(self, env):
|
|
bool_value = bool(self.value)
|
|
return BoolNode(self.pos, value=bool_value, constant_result=bool_value)
|
|
|
|
def contains_surrogates(self):
|
|
return StringEncoding.string_contains_surrogates(self.value)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if self.type.is_pyobject:
|
|
if self.contains_surrogates():
|
|
# surrogates are not really portable and cannot be
|
|
# decoded by the UTF-8 codec in Py3.3
|
|
self.result_code = code.get_py_const(py_object_type, 'ustring')
|
|
data_cname = code.get_pyunicode_ptr_const(self.value)
|
|
const_code = code.get_cached_constants_writer(self.result_code)
|
|
if const_code is None:
|
|
return # already initialised
|
|
const_code.mark_pos(self.pos)
|
|
const_code.putln(
|
|
"%s = PyUnicode_FromUnicode(%s, (sizeof(%s) / sizeof(Py_UNICODE))-1); %s" % (
|
|
self.result_code,
|
|
data_cname,
|
|
data_cname,
|
|
const_code.error_goto_if_null(self.result_code, self.pos)))
|
|
const_code.put_error_if_neg(
|
|
self.pos, "__Pyx_PyUnicode_READY(%s)" % self.result_code)
|
|
else:
|
|
self.result_code = code.get_py_string_const(self.value)
|
|
else:
|
|
self.result_code = code.get_pyunicode_ptr_const(self.value)
|
|
|
|
def calculate_result_code(self):
|
|
return self.result_code
|
|
|
|
def compile_time_value(self, env):
|
|
return self.value
|
|
|
|
|
|
class StringNode(PyConstNode):
|
|
# A Python str object, i.e. a byte string in Python 2.x and a
|
|
# unicode string in Python 3.x
|
|
#
|
|
# value BytesLiteral (or EncodedString with ASCII content)
|
|
# unicode_value EncodedString or None
|
|
# is_identifier boolean
|
|
|
|
type = str_type
|
|
is_string_literal = True
|
|
is_identifier = None
|
|
unicode_value = None
|
|
|
|
def calculate_constant_result(self):
|
|
if self.unicode_value is not None:
|
|
# only the Unicode value is portable across Py2/3
|
|
self.constant_result = self.unicode_value
|
|
|
|
def analyse_as_type(self, env):
|
|
return _analyse_name_as_type(self.unicode_value or self.value.decode('ISO8859-1'), self.pos, env)
|
|
|
|
def as_sliced_node(self, start, stop, step=None):
|
|
value = type(self.value)(self.value[start:stop:step])
|
|
value.encoding = self.value.encoding
|
|
if self.unicode_value is not None:
|
|
if StringEncoding.string_contains_surrogates(self.unicode_value[:stop]):
|
|
# this is unsafe as it may give different results in different runtimes
|
|
return None
|
|
unicode_value = StringEncoding.EncodedString(
|
|
self.unicode_value[start:stop:step])
|
|
else:
|
|
unicode_value = None
|
|
return StringNode(
|
|
self.pos, value=value, unicode_value=unicode_value,
|
|
constant_result=value, is_identifier=self.is_identifier)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type is not py_object_type and not str_type.subtype_of(dst_type):
|
|
# if dst_type is Builtin.bytes_type:
|
|
# # special case: bytes = 'str literal'
|
|
# return BytesNode(self.pos, value=self.value)
|
|
if not dst_type.is_pyobject:
|
|
return BytesNode(self.pos, value=self.value).coerce_to(dst_type, env)
|
|
if dst_type is not Builtin.basestring_type:
|
|
self.check_for_coercion_error(dst_type, env, fail=True)
|
|
return self
|
|
|
|
def can_coerce_to_char_literal(self):
|
|
return not self.is_identifier and len(self.value) == 1
|
|
|
|
def generate_evaluation_code(self, code):
|
|
self.result_code = code.get_py_string_const(
|
|
self.value, identifier=self.is_identifier, is_str=True,
|
|
unicode_value=self.unicode_value)
|
|
|
|
def get_constant_c_result_code(self):
|
|
return None
|
|
|
|
def calculate_result_code(self):
|
|
return self.result_code
|
|
|
|
def compile_time_value(self, env):
|
|
if self.value.is_unicode:
|
|
return self.value
|
|
if not IS_PYTHON3:
|
|
# use plain str/bytes object in Py2
|
|
return self.value.byteencode()
|
|
# in Py3, always return a Unicode string
|
|
if self.unicode_value is not None:
|
|
return self.unicode_value
|
|
return self.value.decode('iso8859-1')
|
|
|
|
|
|
class IdentifierStringNode(StringNode):
|
|
# A special str value that represents an identifier (bytes in Py2,
|
|
# unicode in Py3).
|
|
is_identifier = True
|
|
|
|
|
|
class ImagNode(AtomicExprNode):
|
|
# Imaginary number literal
|
|
#
|
|
# value string imaginary part (float value)
|
|
|
|
type = PyrexTypes.c_double_complex_type
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = complex(0.0, float(self.value))
|
|
|
|
def compile_time_value(self, denv):
|
|
return complex(0.0, float(self.value))
|
|
|
|
def analyse_types(self, env):
|
|
self.type.create_declaration_utility_code(env)
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if self.type is dst_type:
|
|
return self
|
|
node = ImagNode(self.pos, value=self.value)
|
|
if dst_type.is_pyobject:
|
|
node.is_temp = 1
|
|
node.type = Builtin.complex_type
|
|
# We still need to perform normal coerce_to processing on the
|
|
# result, because we might be coercing to an extension type,
|
|
# in which case a type test node will be needed.
|
|
return AtomicExprNode.coerce_to(node, dst_type, env)
|
|
|
|
gil_message = "Constructing complex number"
|
|
|
|
def calculate_result_code(self):
|
|
if self.type.is_pyobject:
|
|
return self.result()
|
|
else:
|
|
return "%s(0, %r)" % (self.type.from_parts, float(self.value))
|
|
|
|
def generate_result_code(self, code):
|
|
if self.type.is_pyobject:
|
|
code.putln(
|
|
"%s = PyComplex_FromDoubles(0.0, %r); %s" % (
|
|
self.result(),
|
|
float(self.value),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class NewExprNode(AtomicExprNode):
|
|
|
|
# C++ new statement
|
|
#
|
|
# cppclass node c++ class to create
|
|
|
|
type = None
|
|
|
|
def infer_type(self, env):
|
|
type = self.cppclass.analyse_as_type(env)
|
|
if type is None or not type.is_cpp_class:
|
|
error(self.pos, "new operator can only be applied to a C++ class")
|
|
self.type = error_type
|
|
return
|
|
self.cpp_check(env)
|
|
constructor = type.get_constructor(self.pos)
|
|
self.class_type = type
|
|
self.entry = constructor
|
|
self.type = constructor.type
|
|
return self.type
|
|
|
|
def analyse_types(self, env):
|
|
if self.type is None:
|
|
self.infer_type(env)
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
def calculate_result_code(self):
|
|
return "new " + self.class_type.empty_declaration_code()
|
|
|
|
|
|
class NameNode(AtomicExprNode):
|
|
# Reference to a local or global variable name.
|
|
#
|
|
# name string Python name of the variable
|
|
# entry Entry Symbol table entry
|
|
# type_entry Entry For extension type names, the original type entry
|
|
# cf_is_null boolean Is uninitialized before this node
|
|
# cf_maybe_null boolean Maybe uninitialized before this node
|
|
# allow_null boolean Don't raise UnboundLocalError
|
|
# nogil boolean Whether it is used in a nogil context
|
|
|
|
is_name = True
|
|
is_cython_module = False
|
|
cython_attribute = None
|
|
lhs_of_first_assignment = False # TODO: remove me
|
|
is_used_as_rvalue = 0
|
|
entry = None
|
|
type_entry = None
|
|
cf_maybe_null = True
|
|
cf_is_null = False
|
|
allow_null = False
|
|
nogil = False
|
|
inferred_type = None
|
|
|
|
def as_cython_attribute(self):
|
|
return self.cython_attribute
|
|
|
|
def type_dependencies(self, env):
|
|
if self.entry is None:
|
|
self.entry = env.lookup(self.name)
|
|
if self.entry is not None and self.entry.type.is_unspecified:
|
|
return (self,)
|
|
else:
|
|
return ()
|
|
|
|
def infer_type(self, env):
|
|
if self.entry is None:
|
|
self.entry = env.lookup(self.name)
|
|
if self.entry is None or self.entry.type is unspecified_type:
|
|
if self.inferred_type is not None:
|
|
return self.inferred_type
|
|
return py_object_type
|
|
elif (self.entry.type.is_extension_type or self.entry.type.is_builtin_type) and \
|
|
self.name == self.entry.type.name:
|
|
# Unfortunately the type attribute of type objects
|
|
# is used for the pointer to the type they represent.
|
|
return type_type
|
|
elif self.entry.type.is_cfunction:
|
|
if self.entry.scope.is_builtin_scope:
|
|
# special case: optimised builtin functions must be treated as Python objects
|
|
return py_object_type
|
|
else:
|
|
# special case: referring to a C function must return its pointer
|
|
return PyrexTypes.CPtrType(self.entry.type)
|
|
else:
|
|
# If entry is inferred as pyobject it's safe to use local
|
|
# NameNode's inferred_type.
|
|
if self.entry.type.is_pyobject and self.inferred_type:
|
|
# Overflow may happen if integer
|
|
if not (self.inferred_type.is_int and self.entry.might_overflow):
|
|
return self.inferred_type
|
|
return self.entry.type
|
|
|
|
def compile_time_value(self, denv):
|
|
try:
|
|
return denv.lookup(self.name)
|
|
except KeyError:
|
|
error(self.pos, "Compile-time name '%s' not defined" % self.name)
|
|
|
|
def get_constant_c_result_code(self):
|
|
if not self.entry or self.entry.type.is_pyobject:
|
|
return None
|
|
return self.entry.cname
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
# If coercing to a generic pyobject and this is a builtin
|
|
# C function with a Python equivalent, manufacture a NameNode
|
|
# referring to the Python builtin.
|
|
#print "NameNode.coerce_to:", self.name, dst_type ###
|
|
if dst_type is py_object_type:
|
|
entry = self.entry
|
|
if entry and entry.is_cfunction:
|
|
var_entry = entry.as_variable
|
|
if var_entry:
|
|
if var_entry.is_builtin and var_entry.is_const:
|
|
var_entry = env.declare_builtin(var_entry.name, self.pos)
|
|
node = NameNode(self.pos, name = self.name)
|
|
node.entry = var_entry
|
|
node.analyse_rvalue_entry(env)
|
|
return node
|
|
|
|
return super(NameNode, self).coerce_to(dst_type, env)
|
|
|
|
def declare_from_annotation(self, env, as_target=False):
|
|
"""Implements PEP 526 annotation typing in a fairly relaxed way.
|
|
|
|
Annotations are ignored for global variables, Python class attributes and already declared variables.
|
|
String literals are allowed and ignored.
|
|
The ambiguous Python types 'int' and 'long' are ignored and the 'cython.int' form must be used instead.
|
|
"""
|
|
if not env.directives['annotation_typing']:
|
|
return
|
|
if env.is_module_scope or env.is_py_class_scope:
|
|
# annotations never create global cdef names and Python classes don't support them anyway
|
|
return
|
|
name = self.name
|
|
if self.entry or env.lookup_here(name) is not None:
|
|
# already declared => ignore annotation
|
|
return
|
|
|
|
annotation = self.annotation
|
|
if annotation.is_string_literal:
|
|
# name: "description" => not a type, but still a declared variable or attribute
|
|
atype = None
|
|
else:
|
|
_, atype = analyse_type_annotation(annotation, env)
|
|
if atype is None:
|
|
atype = unspecified_type if as_target and env.directives['infer_types'] != False else py_object_type
|
|
self.entry = env.declare_var(name, atype, self.pos, is_cdef=not as_target)
|
|
self.entry.annotation = annotation
|
|
|
|
def analyse_as_module(self, env):
|
|
# Try to interpret this as a reference to a cimported module.
|
|
# Returns the module scope, or None.
|
|
entry = self.entry
|
|
if not entry:
|
|
entry = env.lookup(self.name)
|
|
if entry and entry.as_module:
|
|
return entry.as_module
|
|
return None
|
|
|
|
def analyse_as_type(self, env):
|
|
if self.cython_attribute:
|
|
type = PyrexTypes.parse_basic_type(self.cython_attribute)
|
|
else:
|
|
type = PyrexTypes.parse_basic_type(self.name)
|
|
if type:
|
|
return type
|
|
entry = self.entry
|
|
if not entry:
|
|
entry = env.lookup(self.name)
|
|
if entry and entry.is_type:
|
|
return entry.type
|
|
else:
|
|
return None
|
|
|
|
def analyse_as_extension_type(self, env):
|
|
# Try to interpret this as a reference to an extension type.
|
|
# Returns the extension type, or None.
|
|
entry = self.entry
|
|
if not entry:
|
|
entry = env.lookup(self.name)
|
|
if entry and entry.is_type:
|
|
if entry.type.is_extension_type or entry.type.is_builtin_type:
|
|
return entry.type
|
|
return None
|
|
|
|
def analyse_target_declaration(self, env):
|
|
if not self.entry:
|
|
self.entry = env.lookup_here(self.name)
|
|
if not self.entry and self.annotation is not None:
|
|
# name : type = ...
|
|
self.declare_from_annotation(env, as_target=True)
|
|
if not self.entry:
|
|
if env.directives['warn.undeclared']:
|
|
warning(self.pos, "implicit declaration of '%s'" % self.name, 1)
|
|
if env.directives['infer_types'] != False:
|
|
type = unspecified_type
|
|
else:
|
|
type = py_object_type
|
|
self.entry = env.declare_var(self.name, type, self.pos)
|
|
if self.entry.is_declared_generic:
|
|
self.result_ctype = py_object_type
|
|
if self.entry.as_module:
|
|
# cimported modules namespace can shadow actual variables
|
|
self.entry.is_variable = 1
|
|
|
|
def analyse_types(self, env):
|
|
self.initialized_check = env.directives['initializedcheck']
|
|
entry = self.entry
|
|
if entry is None:
|
|
entry = env.lookup(self.name)
|
|
if not entry:
|
|
entry = env.declare_builtin(self.name, self.pos)
|
|
if entry and entry.is_builtin and entry.is_const:
|
|
self.is_literal = True
|
|
if not entry:
|
|
self.type = PyrexTypes.error_type
|
|
return self
|
|
self.entry = entry
|
|
entry.used = 1
|
|
if entry.type.is_buffer:
|
|
from . import Buffer
|
|
Buffer.used_buffer_aux_vars(entry)
|
|
self.analyse_rvalue_entry(env)
|
|
return self
|
|
|
|
def analyse_target_types(self, env):
|
|
self.analyse_entry(env, is_target=True)
|
|
|
|
entry = self.entry
|
|
if entry.is_cfunction and entry.as_variable:
|
|
# FIXME: unify "is_overridable" flags below
|
|
if (entry.is_overridable or entry.type.is_overridable) or not self.is_lvalue() and entry.fused_cfunction:
|
|
# We need this for assigning to cpdef names and for the fused 'def' TreeFragment
|
|
entry = self.entry = entry.as_variable
|
|
self.type = entry.type
|
|
|
|
if self.type.is_const:
|
|
error(self.pos, "Assignment to const '%s'" % self.name)
|
|
if self.type.is_reference:
|
|
error(self.pos, "Assignment to reference '%s'" % self.name)
|
|
if not self.is_lvalue():
|
|
error(self.pos, "Assignment to non-lvalue '%s'" % self.name)
|
|
self.type = PyrexTypes.error_type
|
|
entry.used = 1
|
|
if entry.type.is_buffer:
|
|
from . import Buffer
|
|
Buffer.used_buffer_aux_vars(entry)
|
|
return self
|
|
|
|
def analyse_rvalue_entry(self, env):
|
|
#print "NameNode.analyse_rvalue_entry:", self.name ###
|
|
#print "Entry:", self.entry.__dict__ ###
|
|
self.analyse_entry(env)
|
|
entry = self.entry
|
|
|
|
if entry.is_declared_generic:
|
|
self.result_ctype = py_object_type
|
|
|
|
if entry.is_pyglobal or entry.is_builtin:
|
|
if entry.is_builtin and entry.is_const:
|
|
self.is_temp = 0
|
|
else:
|
|
self.is_temp = 1
|
|
|
|
self.is_used_as_rvalue = 1
|
|
elif entry.type.is_memoryviewslice:
|
|
self.is_temp = False
|
|
self.is_used_as_rvalue = True
|
|
self.use_managed_ref = True
|
|
return self
|
|
|
|
def nogil_check(self, env):
|
|
self.nogil = True
|
|
if self.is_used_as_rvalue:
|
|
entry = self.entry
|
|
if entry.is_builtin:
|
|
if not entry.is_const: # cached builtins are ok
|
|
self.gil_error()
|
|
elif entry.is_pyglobal:
|
|
self.gil_error()
|
|
|
|
gil_message = "Accessing Python global or builtin"
|
|
|
|
def analyse_entry(self, env, is_target=False):
|
|
#print "NameNode.analyse_entry:", self.name ###
|
|
self.check_identifier_kind()
|
|
entry = self.entry
|
|
type = entry.type
|
|
if (not is_target and type.is_pyobject and self.inferred_type and
|
|
self.inferred_type.is_builtin_type):
|
|
# assume that type inference is smarter than the static entry
|
|
type = self.inferred_type
|
|
self.type = type
|
|
|
|
def check_identifier_kind(self):
|
|
# Check that this is an appropriate kind of name for use in an
|
|
# expression. Also finds the variable entry associated with
|
|
# an extension type.
|
|
entry = self.entry
|
|
if entry.is_type and entry.type.is_extension_type:
|
|
self.type_entry = entry
|
|
if entry.is_type and entry.type.is_enum:
|
|
py_entry = Symtab.Entry(self.name, None, py_object_type)
|
|
py_entry.is_pyglobal = True
|
|
py_entry.scope = self.entry.scope
|
|
self.entry = py_entry
|
|
elif not (entry.is_const or entry.is_variable or
|
|
entry.is_builtin or entry.is_cfunction or
|
|
entry.is_cpp_class):
|
|
if self.entry.as_variable:
|
|
self.entry = self.entry.as_variable
|
|
elif not self.is_cython_module:
|
|
error(self.pos, "'%s' is not a constant, variable or function identifier" % self.name)
|
|
|
|
def is_cimported_module_without_shadow(self, env):
|
|
if self.is_cython_module or self.cython_attribute:
|
|
return False
|
|
entry = self.entry or env.lookup(self.name)
|
|
return entry.as_module and not entry.is_variable
|
|
|
|
def is_simple(self):
|
|
# If it's not a C variable, it'll be in a temp.
|
|
return 1
|
|
|
|
def may_be_none(self):
|
|
if self.cf_state and self.type and (self.type.is_pyobject or
|
|
self.type.is_memoryviewslice):
|
|
# gard against infinite recursion on self-dependencies
|
|
if getattr(self, '_none_checking', False):
|
|
# self-dependency - either this node receives a None
|
|
# value from *another* node, or it can not reference
|
|
# None at this point => safe to assume "not None"
|
|
return False
|
|
self._none_checking = True
|
|
# evaluate control flow state to see if there were any
|
|
# potential None values assigned to the node so far
|
|
may_be_none = False
|
|
for assignment in self.cf_state:
|
|
if assignment.rhs.may_be_none():
|
|
may_be_none = True
|
|
break
|
|
del self._none_checking
|
|
return may_be_none
|
|
return super(NameNode, self).may_be_none()
|
|
|
|
def nonlocally_immutable(self):
|
|
if ExprNode.nonlocally_immutable(self):
|
|
return True
|
|
entry = self.entry
|
|
if not entry or entry.in_closure:
|
|
return False
|
|
return entry.is_local or entry.is_arg or entry.is_builtin or entry.is_readonly
|
|
|
|
def calculate_target_results(self, env):
|
|
pass
|
|
|
|
def check_const(self):
|
|
entry = self.entry
|
|
if entry is not None and not (
|
|
entry.is_const or
|
|
entry.is_cfunction or
|
|
entry.is_builtin or
|
|
entry.type.is_const):
|
|
self.not_const()
|
|
return False
|
|
return True
|
|
|
|
def check_const_addr(self):
|
|
entry = self.entry
|
|
if not (entry.is_cglobal or entry.is_cfunction or entry.is_builtin):
|
|
self.addr_not_const()
|
|
return False
|
|
return True
|
|
|
|
def is_lvalue(self):
|
|
return (
|
|
self.entry.is_variable and
|
|
not self.entry.is_readonly
|
|
) or (
|
|
self.entry.is_cfunction and
|
|
self.entry.is_overridable
|
|
)
|
|
|
|
def is_addressable(self):
|
|
return self.entry.is_variable and not self.type.is_memoryviewslice
|
|
|
|
def is_ephemeral(self):
|
|
# Name nodes are never ephemeral, even if the
|
|
# result is in a temporary.
|
|
return 0
|
|
|
|
def calculate_result_code(self):
|
|
entry = self.entry
|
|
if not entry:
|
|
return "<error>" # There was an error earlier
|
|
return entry.cname
|
|
|
|
def generate_result_code(self, code):
|
|
assert hasattr(self, 'entry')
|
|
entry = self.entry
|
|
if entry is None:
|
|
return # There was an error earlier
|
|
if entry.utility_code:
|
|
code.globalstate.use_utility_code(entry.utility_code)
|
|
if entry.is_builtin and entry.is_const:
|
|
return # Lookup already cached
|
|
elif entry.is_pyclass_attr:
|
|
assert entry.type.is_pyobject, "Python global or builtin not a Python object"
|
|
interned_cname = code.intern_identifier(self.entry.name)
|
|
if entry.is_builtin:
|
|
namespace = Naming.builtins_cname
|
|
else: # entry.is_pyglobal
|
|
namespace = entry.scope.namespace_cname
|
|
if not self.cf_is_null:
|
|
code.putln(
|
|
'%s = PyObject_GetItem(%s, %s);' % (
|
|
self.result(),
|
|
namespace,
|
|
interned_cname))
|
|
code.putln('if (unlikely(!%s)) {' % self.result())
|
|
code.putln('PyErr_Clear();')
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("GetModuleGlobalName", "ObjectHandling.c"))
|
|
code.putln(
|
|
'__Pyx_GetModuleGlobalName(%s, %s);' % (
|
|
self.result(),
|
|
interned_cname))
|
|
if not self.cf_is_null:
|
|
code.putln("}")
|
|
code.putln(code.error_goto_if_null(self.result(), self.pos))
|
|
code.put_gotref(self.py_result())
|
|
|
|
elif entry.is_builtin and not entry.scope.is_module_scope:
|
|
# known builtin
|
|
assert entry.type.is_pyobject, "Python global or builtin not a Python object"
|
|
interned_cname = code.intern_identifier(self.entry.name)
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("GetBuiltinName", "ObjectHandling.c"))
|
|
code.putln(
|
|
'%s = __Pyx_GetBuiltinName(%s); %s' % (
|
|
self.result(),
|
|
interned_cname,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
elif entry.is_pyglobal or (entry.is_builtin and entry.scope.is_module_scope):
|
|
# name in class body, global name or unknown builtin
|
|
assert entry.type.is_pyobject, "Python global or builtin not a Python object"
|
|
interned_cname = code.intern_identifier(self.entry.name)
|
|
if entry.scope.is_module_scope:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("GetModuleGlobalName", "ObjectHandling.c"))
|
|
code.putln(
|
|
'__Pyx_GetModuleGlobalName(%s, %s); %s' % (
|
|
self.result(),
|
|
interned_cname,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
else:
|
|
# FIXME: is_pyglobal is also used for class namespace
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("GetNameInClass", "ObjectHandling.c"))
|
|
code.putln(
|
|
'__Pyx_GetNameInClass(%s, %s, %s); %s' % (
|
|
self.result(),
|
|
entry.scope.namespace_cname,
|
|
interned_cname,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
elif entry.is_local or entry.in_closure or entry.from_closure or entry.type.is_memoryviewslice:
|
|
# Raise UnboundLocalError for objects and memoryviewslices
|
|
raise_unbound = (
|
|
(self.cf_maybe_null or self.cf_is_null) and not self.allow_null)
|
|
null_code = entry.type.check_for_null_code(entry.cname)
|
|
|
|
memslice_check = entry.type.is_memoryviewslice and self.initialized_check
|
|
|
|
if null_code and raise_unbound and (entry.type.is_pyobject or memslice_check):
|
|
code.put_error_if_unbound(self.pos, entry, self.in_nogil_context)
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False,
|
|
exception_check=None, exception_value=None):
|
|
#print "NameNode.generate_assignment_code:", self.name ###
|
|
entry = self.entry
|
|
if entry is None:
|
|
return # There was an error earlier
|
|
|
|
if (self.entry.type.is_ptr and isinstance(rhs, ListNode)
|
|
and not self.lhs_of_first_assignment and not rhs.in_module_scope):
|
|
error(self.pos, "Literal list must be assigned to pointer at time of declaration")
|
|
|
|
# is_pyglobal seems to be True for module level-globals only.
|
|
# We use this to access class->tp_dict if necessary.
|
|
if entry.is_pyglobal:
|
|
assert entry.type.is_pyobject, "Python global or builtin not a Python object"
|
|
interned_cname = code.intern_identifier(self.entry.name)
|
|
namespace = self.entry.scope.namespace_cname
|
|
if entry.is_member:
|
|
# if the entry is a member we have to cheat: SetAttr does not work
|
|
# on types, so we create a descriptor which is then added to tp_dict
|
|
setter = 'PyDict_SetItem'
|
|
namespace = '%s->tp_dict' % namespace
|
|
elif entry.scope.is_module_scope:
|
|
setter = 'PyDict_SetItem'
|
|
namespace = Naming.moddict_cname
|
|
elif entry.is_pyclass_attr:
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("SetNameInClass", "ObjectHandling.c"))
|
|
setter = '__Pyx_SetNameInClass'
|
|
else:
|
|
assert False, repr(entry)
|
|
code.put_error_if_neg(
|
|
self.pos,
|
|
'%s(%s, %s, %s)' % (
|
|
setter,
|
|
namespace,
|
|
interned_cname,
|
|
rhs.py_result()))
|
|
if debug_disposal_code:
|
|
print("NameNode.generate_assignment_code:")
|
|
print("...generating disposal code for %s" % rhs)
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
if entry.is_member:
|
|
# in Py2.6+, we need to invalidate the method cache
|
|
code.putln("PyType_Modified(%s);" %
|
|
entry.scope.parent_type.typeptr_cname)
|
|
else:
|
|
if self.type.is_memoryviewslice:
|
|
self.generate_acquire_memoryviewslice(rhs, code)
|
|
|
|
elif self.type.is_buffer:
|
|
# Generate code for doing the buffer release/acquisition.
|
|
# This might raise an exception in which case the assignment (done
|
|
# below) will not happen.
|
|
#
|
|
# The reason this is not in a typetest-like node is because the
|
|
# variables that the acquired buffer info is stored to is allocated
|
|
# per entry and coupled with it.
|
|
self.generate_acquire_buffer(rhs, code)
|
|
assigned = False
|
|
if self.type.is_pyobject:
|
|
#print "NameNode.generate_assignment_code: to", self.name ###
|
|
#print "...from", rhs ###
|
|
#print "...LHS type", self.type, "ctype", self.ctype() ###
|
|
#print "...RHS type", rhs.type, "ctype", rhs.ctype() ###
|
|
if self.use_managed_ref:
|
|
rhs.make_owned_reference(code)
|
|
is_external_ref = entry.is_cglobal or self.entry.in_closure or self.entry.from_closure
|
|
if is_external_ref:
|
|
if not self.cf_is_null:
|
|
if self.cf_maybe_null:
|
|
code.put_xgotref(self.py_result())
|
|
else:
|
|
code.put_gotref(self.py_result())
|
|
assigned = True
|
|
if entry.is_cglobal:
|
|
code.put_decref_set(
|
|
self.result(), rhs.result_as(self.ctype()))
|
|
else:
|
|
if not self.cf_is_null:
|
|
if self.cf_maybe_null:
|
|
code.put_xdecref_set(
|
|
self.result(), rhs.result_as(self.ctype()))
|
|
else:
|
|
code.put_decref_set(
|
|
self.result(), rhs.result_as(self.ctype()))
|
|
else:
|
|
assigned = False
|
|
if is_external_ref:
|
|
code.put_giveref(rhs.py_result())
|
|
if not self.type.is_memoryviewslice:
|
|
if not assigned:
|
|
if overloaded_assignment:
|
|
result = rhs.result()
|
|
if exception_check == '+':
|
|
translate_cpp_exception(
|
|
code, self.pos,
|
|
'%s = %s;' % (self.result(), result),
|
|
self.result() if self.type.is_pyobject else None,
|
|
exception_value, self.in_nogil_context)
|
|
else:
|
|
code.putln('%s = %s;' % (self.result(), result))
|
|
else:
|
|
result = rhs.result_as(self.ctype())
|
|
|
|
if is_pythran_expr(self.type):
|
|
code.putln('new (&%s) decltype(%s){%s};' % (self.result(), self.result(), result))
|
|
elif result != self.result():
|
|
code.putln('%s = %s;' % (self.result(), result))
|
|
if debug_disposal_code:
|
|
print("NameNode.generate_assignment_code:")
|
|
print("...generating post-assignment code for %s" % rhs)
|
|
rhs.generate_post_assignment_code(code)
|
|
elif rhs.result_in_temp():
|
|
rhs.generate_post_assignment_code(code)
|
|
|
|
rhs.free_temps(code)
|
|
|
|
def generate_acquire_memoryviewslice(self, rhs, code):
|
|
"""
|
|
Slices, coercions from objects, return values etc are new references.
|
|
We have a borrowed reference in case of dst = src
|
|
"""
|
|
from . import MemoryView
|
|
|
|
MemoryView.put_acquire_memoryviewslice(
|
|
lhs_cname=self.result(),
|
|
lhs_type=self.type,
|
|
lhs_pos=self.pos,
|
|
rhs=rhs,
|
|
code=code,
|
|
have_gil=not self.in_nogil_context,
|
|
first_assignment=self.cf_is_null)
|
|
|
|
def generate_acquire_buffer(self, rhs, code):
|
|
# rhstmp is only used in case the rhs is a complicated expression leading to
|
|
# the object, to avoid repeating the same C expression for every reference
|
|
# to the rhs. It does NOT hold a reference.
|
|
pretty_rhs = isinstance(rhs, NameNode) or rhs.is_temp
|
|
if pretty_rhs:
|
|
rhstmp = rhs.result_as(self.ctype())
|
|
else:
|
|
rhstmp = code.funcstate.allocate_temp(self.entry.type, manage_ref=False)
|
|
code.putln('%s = %s;' % (rhstmp, rhs.result_as(self.ctype())))
|
|
|
|
from . import Buffer
|
|
Buffer.put_assign_to_buffer(self.result(), rhstmp, self.entry,
|
|
is_initialized=not self.lhs_of_first_assignment,
|
|
pos=self.pos, code=code)
|
|
|
|
if not pretty_rhs:
|
|
code.putln("%s = 0;" % rhstmp)
|
|
code.funcstate.release_temp(rhstmp)
|
|
|
|
def generate_deletion_code(self, code, ignore_nonexisting=False):
|
|
if self.entry is None:
|
|
return # There was an error earlier
|
|
elif self.entry.is_pyclass_attr:
|
|
namespace = self.entry.scope.namespace_cname
|
|
interned_cname = code.intern_identifier(self.entry.name)
|
|
if ignore_nonexisting:
|
|
key_error_code = 'PyErr_Clear(); else'
|
|
else:
|
|
# minor hack: fake a NameError on KeyError
|
|
key_error_code = (
|
|
'{ PyErr_Clear(); PyErr_Format(PyExc_NameError, "name \'%%s\' is not defined", "%s"); }' %
|
|
self.entry.name)
|
|
code.putln(
|
|
'if (unlikely(PyObject_DelItem(%s, %s) < 0)) {'
|
|
' if (likely(PyErr_ExceptionMatches(PyExc_KeyError))) %s'
|
|
' %s '
|
|
'}' % (namespace, interned_cname,
|
|
key_error_code,
|
|
code.error_goto(self.pos)))
|
|
elif self.entry.is_pyglobal:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectSetAttrStr", "ObjectHandling.c"))
|
|
interned_cname = code.intern_identifier(self.entry.name)
|
|
del_code = '__Pyx_PyObject_DelAttrStr(%s, %s)' % (
|
|
Naming.module_cname, interned_cname)
|
|
if ignore_nonexisting:
|
|
code.putln(
|
|
'if (unlikely(%s < 0)) {'
|
|
' if (likely(PyErr_ExceptionMatches(PyExc_AttributeError))) PyErr_Clear(); else %s '
|
|
'}' % (del_code, code.error_goto(self.pos)))
|
|
else:
|
|
code.put_error_if_neg(self.pos, del_code)
|
|
elif self.entry.type.is_pyobject or self.entry.type.is_memoryviewslice:
|
|
if not self.cf_is_null:
|
|
if self.cf_maybe_null and not ignore_nonexisting:
|
|
code.put_error_if_unbound(self.pos, self.entry)
|
|
|
|
if self.entry.type.is_pyobject:
|
|
if self.entry.in_closure:
|
|
# generator
|
|
if ignore_nonexisting and self.cf_maybe_null:
|
|
code.put_xgotref(self.result())
|
|
else:
|
|
code.put_gotref(self.result())
|
|
if ignore_nonexisting and self.cf_maybe_null:
|
|
code.put_xdecref(self.result(), self.ctype())
|
|
else:
|
|
code.put_decref(self.result(), self.ctype())
|
|
code.putln('%s = NULL;' % self.result())
|
|
else:
|
|
code.put_xdecref_memoryviewslice(self.entry.cname,
|
|
have_gil=not self.nogil)
|
|
else:
|
|
error(self.pos, "Deletion of C names not supported")
|
|
|
|
def annotate(self, code):
|
|
if hasattr(self, 'is_called') and self.is_called:
|
|
pos = (self.pos[0], self.pos[1], self.pos[2] - len(self.name) - 1)
|
|
if self.type.is_pyobject:
|
|
style, text = 'py_call', 'python function (%s)'
|
|
else:
|
|
style, text = 'c_call', 'c function (%s)'
|
|
code.annotate(pos, AnnotationItem(style, text % self.type, size=len(self.name)))
|
|
|
|
class BackquoteNode(ExprNode):
|
|
# `expr`
|
|
#
|
|
# arg ExprNode
|
|
|
|
type = py_object_type
|
|
|
|
subexprs = ['arg']
|
|
|
|
def analyse_types(self, env):
|
|
self.arg = self.arg.analyse_types(env)
|
|
self.arg = self.arg.coerce_to_pyobject(env)
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
gil_message = "Backquote expression"
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = repr(self.arg.constant_result)
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln(
|
|
"%s = PyObject_Repr(%s); %s" % (
|
|
self.result(),
|
|
self.arg.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class ImportNode(ExprNode):
|
|
# Used as part of import statement implementation.
|
|
# Implements result =
|
|
# __import__(module_name, globals(), None, name_list, level)
|
|
#
|
|
# module_name StringNode dotted name of module. Empty module
|
|
# name means importing the parent package according
|
|
# to level
|
|
# name_list ListNode or None list of names to be imported
|
|
# level int relative import level:
|
|
# -1: attempt both relative import and absolute import;
|
|
# 0: absolute import;
|
|
# >0: the number of parent directories to search
|
|
# relative to the current module.
|
|
# None: decide the level according to language level and
|
|
# directives
|
|
|
|
type = py_object_type
|
|
|
|
subexprs = ['module_name', 'name_list']
|
|
|
|
def analyse_types(self, env):
|
|
if self.level is None:
|
|
if (env.directives['py2_import'] or
|
|
Future.absolute_import not in env.global_scope().context.future_directives):
|
|
self.level = -1
|
|
else:
|
|
self.level = 0
|
|
module_name = self.module_name.analyse_types(env)
|
|
self.module_name = module_name.coerce_to_pyobject(env)
|
|
if self.name_list:
|
|
name_list = self.name_list.analyse_types(env)
|
|
self.name_list = name_list.coerce_to_pyobject(env)
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
gil_message = "Python import"
|
|
|
|
def generate_result_code(self, code):
|
|
if self.name_list:
|
|
name_list_code = self.name_list.py_result()
|
|
else:
|
|
name_list_code = "0"
|
|
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("Import", "ImportExport.c"))
|
|
import_code = "__Pyx_Import(%s, %s, %d)" % (
|
|
self.module_name.py_result(),
|
|
name_list_code,
|
|
self.level)
|
|
|
|
if (self.level <= 0 and
|
|
self.module_name.is_string_literal and
|
|
self.module_name.value in utility_code_for_imports):
|
|
helper_func, code_name, code_file = utility_code_for_imports[self.module_name.value]
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(code_name, code_file))
|
|
import_code = '%s(%s)' % (helper_func, import_code)
|
|
|
|
code.putln("%s = %s; %s" % (
|
|
self.result(),
|
|
import_code,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class IteratorNode(ExprNode):
|
|
# Used as part of for statement implementation.
|
|
#
|
|
# Implements result = iter(sequence)
|
|
#
|
|
# sequence ExprNode
|
|
|
|
type = py_object_type
|
|
iter_func_ptr = None
|
|
counter_cname = None
|
|
cpp_iterator_cname = None
|
|
reversed = False # currently only used for list/tuple types (see Optimize.py)
|
|
is_async = False
|
|
|
|
subexprs = ['sequence']
|
|
|
|
def analyse_types(self, env):
|
|
self.sequence = self.sequence.analyse_types(env)
|
|
if (self.sequence.type.is_array or self.sequence.type.is_ptr) and \
|
|
not self.sequence.type.is_string:
|
|
# C array iteration will be transformed later on
|
|
self.type = self.sequence.type
|
|
elif self.sequence.type.is_cpp_class:
|
|
self.analyse_cpp_types(env)
|
|
else:
|
|
self.sequence = self.sequence.coerce_to_pyobject(env)
|
|
if self.sequence.type in (list_type, tuple_type):
|
|
self.sequence = self.sequence.as_none_safe_node("'NoneType' object is not iterable")
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
gil_message = "Iterating over Python object"
|
|
|
|
_func_iternext_type = PyrexTypes.CPtrType(PyrexTypes.CFuncType(
|
|
PyrexTypes.py_object_type, [
|
|
PyrexTypes.CFuncTypeArg("it", PyrexTypes.py_object_type, None),
|
|
]))
|
|
|
|
def type_dependencies(self, env):
|
|
return self.sequence.type_dependencies(env)
|
|
|
|
def infer_type(self, env):
|
|
sequence_type = self.sequence.infer_type(env)
|
|
if sequence_type.is_array or sequence_type.is_ptr:
|
|
return sequence_type
|
|
elif sequence_type.is_cpp_class:
|
|
begin = sequence_type.scope.lookup("begin")
|
|
if begin is not None:
|
|
return begin.type.return_type
|
|
elif sequence_type.is_pyobject:
|
|
return sequence_type
|
|
return py_object_type
|
|
|
|
def analyse_cpp_types(self, env):
|
|
sequence_type = self.sequence.type
|
|
if sequence_type.is_ptr:
|
|
sequence_type = sequence_type.base_type
|
|
begin = sequence_type.scope.lookup("begin")
|
|
end = sequence_type.scope.lookup("end")
|
|
if (begin is None
|
|
or not begin.type.is_cfunction
|
|
or begin.type.args):
|
|
error(self.pos, "missing begin() on %s" % self.sequence.type)
|
|
self.type = error_type
|
|
return
|
|
if (end is None
|
|
or not end.type.is_cfunction
|
|
or end.type.args):
|
|
error(self.pos, "missing end() on %s" % self.sequence.type)
|
|
self.type = error_type
|
|
return
|
|
iter_type = begin.type.return_type
|
|
if iter_type.is_cpp_class:
|
|
if env.lookup_operator_for_types(
|
|
self.pos,
|
|
"!=",
|
|
[iter_type, end.type.return_type]) is None:
|
|
error(self.pos, "missing operator!= on result of begin() on %s" % self.sequence.type)
|
|
self.type = error_type
|
|
return
|
|
if env.lookup_operator_for_types(self.pos, '++', [iter_type]) is None:
|
|
error(self.pos, "missing operator++ on result of begin() on %s" % self.sequence.type)
|
|
self.type = error_type
|
|
return
|
|
if env.lookup_operator_for_types(self.pos, '*', [iter_type]) is None:
|
|
error(self.pos, "missing operator* on result of begin() on %s" % self.sequence.type)
|
|
self.type = error_type
|
|
return
|
|
self.type = iter_type
|
|
elif iter_type.is_ptr:
|
|
if not (iter_type == end.type.return_type):
|
|
error(self.pos, "incompatible types for begin() and end()")
|
|
self.type = iter_type
|
|
else:
|
|
error(self.pos, "result type of begin() on %s must be a C++ class or pointer" % self.sequence.type)
|
|
self.type = error_type
|
|
return
|
|
|
|
def generate_result_code(self, code):
|
|
sequence_type = self.sequence.type
|
|
if sequence_type.is_cpp_class:
|
|
if self.sequence.is_name:
|
|
# safe: C++ won't allow you to reassign to class references
|
|
begin_func = "%s.begin" % self.sequence.result()
|
|
else:
|
|
sequence_type = PyrexTypes.c_ptr_type(sequence_type)
|
|
self.cpp_iterator_cname = code.funcstate.allocate_temp(sequence_type, manage_ref=False)
|
|
code.putln("%s = &%s;" % (self.cpp_iterator_cname, self.sequence.result()))
|
|
begin_func = "%s->begin" % self.cpp_iterator_cname
|
|
# TODO: Limit scope.
|
|
code.putln("%s = %s();" % (self.result(), begin_func))
|
|
return
|
|
if sequence_type.is_array or sequence_type.is_ptr:
|
|
raise InternalError("for in carray slice not transformed")
|
|
|
|
is_builtin_sequence = sequence_type in (list_type, tuple_type)
|
|
if not is_builtin_sequence:
|
|
# reversed() not currently optimised (see Optimize.py)
|
|
assert not self.reversed, "internal error: reversed() only implemented for list/tuple objects"
|
|
self.may_be_a_sequence = not sequence_type.is_builtin_type
|
|
if self.may_be_a_sequence:
|
|
code.putln(
|
|
"if (likely(PyList_CheckExact(%s)) || PyTuple_CheckExact(%s)) {" % (
|
|
self.sequence.py_result(),
|
|
self.sequence.py_result()))
|
|
|
|
if is_builtin_sequence or self.may_be_a_sequence:
|
|
self.counter_cname = code.funcstate.allocate_temp(
|
|
PyrexTypes.c_py_ssize_t_type, manage_ref=False)
|
|
if self.reversed:
|
|
if sequence_type is list_type:
|
|
init_value = 'PyList_GET_SIZE(%s) - 1' % self.result()
|
|
else:
|
|
init_value = 'PyTuple_GET_SIZE(%s) - 1' % self.result()
|
|
else:
|
|
init_value = '0'
|
|
code.putln("%s = %s; __Pyx_INCREF(%s); %s = %s;" % (
|
|
self.result(),
|
|
self.sequence.py_result(),
|
|
self.result(),
|
|
self.counter_cname,
|
|
init_value))
|
|
if not is_builtin_sequence:
|
|
self.iter_func_ptr = code.funcstate.allocate_temp(self._func_iternext_type, manage_ref=False)
|
|
if self.may_be_a_sequence:
|
|
code.putln("%s = NULL;" % self.iter_func_ptr)
|
|
code.putln("} else {")
|
|
code.put("%s = -1; " % self.counter_cname)
|
|
|
|
code.putln("%s = PyObject_GetIter(%s); %s" % (
|
|
self.result(),
|
|
self.sequence.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
# PyObject_GetIter() fails if "tp_iternext" is not set, but the check below
|
|
# makes it visible to the C compiler that the pointer really isn't NULL, so that
|
|
# it can distinguish between the special cases and the generic case
|
|
code.putln("%s = Py_TYPE(%s)->tp_iternext; %s" % (
|
|
self.iter_func_ptr, self.py_result(),
|
|
code.error_goto_if_null(self.iter_func_ptr, self.pos)))
|
|
if self.may_be_a_sequence:
|
|
code.putln("}")
|
|
|
|
def generate_next_sequence_item(self, test_name, result_name, code):
|
|
assert self.counter_cname, "internal error: counter_cname temp not prepared"
|
|
final_size = 'Py%s_GET_SIZE(%s)' % (test_name, self.py_result())
|
|
if self.sequence.is_sequence_constructor:
|
|
item_count = len(self.sequence.args)
|
|
if self.sequence.mult_factor is None:
|
|
final_size = item_count
|
|
elif isinstance(self.sequence.mult_factor.constant_result, _py_int_types):
|
|
final_size = item_count * self.sequence.mult_factor.constant_result
|
|
code.putln("if (%s >= %s) break;" % (self.counter_cname, final_size))
|
|
if self.reversed:
|
|
inc_dec = '--'
|
|
else:
|
|
inc_dec = '++'
|
|
code.putln("#if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS")
|
|
code.putln(
|
|
"%s = Py%s_GET_ITEM(%s, %s); __Pyx_INCREF(%s); %s%s; %s" % (
|
|
result_name,
|
|
test_name,
|
|
self.py_result(),
|
|
self.counter_cname,
|
|
result_name,
|
|
self.counter_cname,
|
|
inc_dec,
|
|
# use the error label to avoid C compiler warnings if we only use it below
|
|
code.error_goto_if_neg('0', self.pos)
|
|
))
|
|
code.putln("#else")
|
|
code.putln(
|
|
"%s = PySequence_ITEM(%s, %s); %s%s; %s" % (
|
|
result_name,
|
|
self.py_result(),
|
|
self.counter_cname,
|
|
self.counter_cname,
|
|
inc_dec,
|
|
code.error_goto_if_null(result_name, self.pos)))
|
|
code.put_gotref(result_name)
|
|
code.putln("#endif")
|
|
|
|
def generate_iter_next_result_code(self, result_name, code):
|
|
sequence_type = self.sequence.type
|
|
if self.reversed:
|
|
code.putln("if (%s < 0) break;" % self.counter_cname)
|
|
if sequence_type.is_cpp_class:
|
|
if self.cpp_iterator_cname:
|
|
end_func = "%s->end" % self.cpp_iterator_cname
|
|
else:
|
|
end_func = "%s.end" % self.sequence.result()
|
|
# TODO: Cache end() call?
|
|
code.putln("if (!(%s != %s())) break;" % (
|
|
self.result(),
|
|
end_func))
|
|
code.putln("%s = *%s;" % (
|
|
result_name,
|
|
self.result()))
|
|
code.putln("++%s;" % self.result())
|
|
return
|
|
elif sequence_type is list_type:
|
|
self.generate_next_sequence_item('List', result_name, code)
|
|
return
|
|
elif sequence_type is tuple_type:
|
|
self.generate_next_sequence_item('Tuple', result_name, code)
|
|
return
|
|
|
|
if self.may_be_a_sequence:
|
|
code.putln("if (likely(!%s)) {" % self.iter_func_ptr)
|
|
code.putln("if (likely(PyList_CheckExact(%s))) {" % self.py_result())
|
|
self.generate_next_sequence_item('List', result_name, code)
|
|
code.putln("} else {")
|
|
self.generate_next_sequence_item('Tuple', result_name, code)
|
|
code.putln("}")
|
|
code.put("} else ")
|
|
|
|
code.putln("{")
|
|
code.putln(
|
|
"%s = %s(%s);" % (
|
|
result_name,
|
|
self.iter_func_ptr,
|
|
self.py_result()))
|
|
code.putln("if (unlikely(!%s)) {" % result_name)
|
|
code.putln("PyObject* exc_type = PyErr_Occurred();")
|
|
code.putln("if (exc_type) {")
|
|
code.putln("if (likely(__Pyx_PyErr_GivenExceptionMatches(exc_type, PyExc_StopIteration))) PyErr_Clear();")
|
|
code.putln("else %s" % code.error_goto(self.pos))
|
|
code.putln("}")
|
|
code.putln("break;")
|
|
code.putln("}")
|
|
code.put_gotref(result_name)
|
|
code.putln("}")
|
|
|
|
def free_temps(self, code):
|
|
if self.counter_cname:
|
|
code.funcstate.release_temp(self.counter_cname)
|
|
if self.iter_func_ptr:
|
|
code.funcstate.release_temp(self.iter_func_ptr)
|
|
self.iter_func_ptr = None
|
|
if self.cpp_iterator_cname:
|
|
code.funcstate.release_temp(self.cpp_iterator_cname)
|
|
ExprNode.free_temps(self, code)
|
|
|
|
|
|
class NextNode(AtomicExprNode):
|
|
# Used as part of for statement implementation.
|
|
# Implements result = next(iterator)
|
|
# Created during analyse_types phase.
|
|
# The iterator is not owned by this node.
|
|
#
|
|
# iterator IteratorNode
|
|
|
|
def __init__(self, iterator):
|
|
AtomicExprNode.__init__(self, iterator.pos)
|
|
self.iterator = iterator
|
|
|
|
def nogil_check(self, env):
|
|
# ignore - errors (if any) are already handled by IteratorNode
|
|
pass
|
|
|
|
def type_dependencies(self, env):
|
|
return self.iterator.type_dependencies(env)
|
|
|
|
def infer_type(self, env, iterator_type=None):
|
|
if iterator_type is None:
|
|
iterator_type = self.iterator.infer_type(env)
|
|
if iterator_type.is_ptr or iterator_type.is_array:
|
|
return iterator_type.base_type
|
|
elif iterator_type.is_cpp_class:
|
|
item_type = env.lookup_operator_for_types(self.pos, "*", [iterator_type]).type.return_type
|
|
if item_type.is_reference:
|
|
item_type = item_type.ref_base_type
|
|
if item_type.is_const:
|
|
item_type = item_type.const_base_type
|
|
return item_type
|
|
else:
|
|
# Avoid duplication of complicated logic.
|
|
fake_index_node = IndexNode(
|
|
self.pos,
|
|
base=self.iterator.sequence,
|
|
index=IntNode(self.pos, value='PY_SSIZE_T_MAX',
|
|
type=PyrexTypes.c_py_ssize_t_type))
|
|
return fake_index_node.infer_type(env)
|
|
|
|
def analyse_types(self, env):
|
|
self.type = self.infer_type(env, self.iterator.type)
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
self.iterator.generate_iter_next_result_code(self.result(), code)
|
|
|
|
|
|
class AsyncIteratorNode(ExprNode):
|
|
# Used as part of 'async for' statement implementation.
|
|
#
|
|
# Implements result = sequence.__aiter__()
|
|
#
|
|
# sequence ExprNode
|
|
|
|
subexprs = ['sequence']
|
|
|
|
is_async = True
|
|
type = py_object_type
|
|
is_temp = 1
|
|
|
|
def infer_type(self, env):
|
|
return py_object_type
|
|
|
|
def analyse_types(self, env):
|
|
self.sequence = self.sequence.analyse_types(env)
|
|
if not self.sequence.type.is_pyobject:
|
|
error(self.pos, "async for loops not allowed on C/C++ types")
|
|
self.sequence = self.sequence.coerce_to_pyobject(env)
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("AsyncIter", "Coroutine.c"))
|
|
code.putln("%s = __Pyx_Coroutine_GetAsyncIter(%s); %s" % (
|
|
self.result(),
|
|
self.sequence.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
|
|
|
|
class AsyncNextNode(AtomicExprNode):
|
|
# Used as part of 'async for' statement implementation.
|
|
# Implements result = iterator.__anext__()
|
|
# Created during analyse_types phase.
|
|
# The iterator is not owned by this node.
|
|
#
|
|
# iterator IteratorNode
|
|
|
|
type = py_object_type
|
|
is_temp = 1
|
|
|
|
def __init__(self, iterator):
|
|
AtomicExprNode.__init__(self, iterator.pos)
|
|
self.iterator = iterator
|
|
|
|
def infer_type(self, env):
|
|
return py_object_type
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("AsyncIter", "Coroutine.c"))
|
|
code.putln("%s = __Pyx_Coroutine_AsyncIterNext(%s); %s" % (
|
|
self.result(),
|
|
self.iterator.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
|
|
|
|
class WithExitCallNode(ExprNode):
|
|
# The __exit__() call of a 'with' statement. Used in both the
|
|
# except and finally clauses.
|
|
|
|
# with_stat WithStatNode the surrounding 'with' statement
|
|
# args TupleNode or ResultStatNode the exception info tuple
|
|
# await_expr AwaitExprNode the await expression of an 'async with' statement
|
|
|
|
subexprs = ['args', 'await_expr']
|
|
test_if_run = True
|
|
await_expr = None
|
|
|
|
def analyse_types(self, env):
|
|
self.args = self.args.analyse_types(env)
|
|
if self.await_expr:
|
|
self.await_expr = self.await_expr.analyse_types(env)
|
|
self.type = PyrexTypes.c_bint_type
|
|
self.is_temp = True
|
|
return self
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if self.test_if_run:
|
|
# call only if it was not already called (and decref-cleared)
|
|
code.putln("if (%s) {" % self.with_stat.exit_var)
|
|
|
|
self.args.generate_evaluation_code(code)
|
|
result_var = code.funcstate.allocate_temp(py_object_type, manage_ref=False)
|
|
|
|
code.mark_pos(self.pos)
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(
|
|
"PyObjectCall", "ObjectHandling.c"))
|
|
code.putln("%s = __Pyx_PyObject_Call(%s, %s, NULL);" % (
|
|
result_var,
|
|
self.with_stat.exit_var,
|
|
self.args.result()))
|
|
code.put_decref_clear(self.with_stat.exit_var, type=py_object_type)
|
|
self.args.generate_disposal_code(code)
|
|
self.args.free_temps(code)
|
|
|
|
code.putln(code.error_goto_if_null(result_var, self.pos))
|
|
code.put_gotref(result_var)
|
|
|
|
if self.await_expr:
|
|
# FIXME: result_var temp currently leaks into the closure
|
|
self.await_expr.generate_evaluation_code(code, source_cname=result_var, decref_source=True)
|
|
code.putln("%s = %s;" % (result_var, self.await_expr.py_result()))
|
|
self.await_expr.generate_post_assignment_code(code)
|
|
self.await_expr.free_temps(code)
|
|
|
|
if self.result_is_used:
|
|
self.allocate_temp_result(code)
|
|
code.putln("%s = __Pyx_PyObject_IsTrue(%s);" % (self.result(), result_var))
|
|
code.put_decref_clear(result_var, type=py_object_type)
|
|
if self.result_is_used:
|
|
code.put_error_if_neg(self.pos, self.result())
|
|
code.funcstate.release_temp(result_var)
|
|
if self.test_if_run:
|
|
code.putln("}")
|
|
|
|
|
|
class ExcValueNode(AtomicExprNode):
|
|
# Node created during analyse_types phase
|
|
# of an ExceptClauseNode to fetch the current
|
|
# exception value.
|
|
|
|
type = py_object_type
|
|
|
|
def __init__(self, pos):
|
|
ExprNode.__init__(self, pos)
|
|
|
|
def set_var(self, var):
|
|
self.var = var
|
|
|
|
def calculate_result_code(self):
|
|
return self.var
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
|
|
class TempNode(ExprNode):
|
|
# Node created during analyse_types phase
|
|
# of some nodes to hold a temporary value.
|
|
#
|
|
# Note: One must call "allocate" and "release" on
|
|
# the node during code generation to get/release the temp.
|
|
# This is because the temp result is often used outside of
|
|
# the regular cycle.
|
|
|
|
subexprs = []
|
|
|
|
def __init__(self, pos, type, env=None):
|
|
ExprNode.__init__(self, pos)
|
|
self.type = type
|
|
if type.is_pyobject:
|
|
self.result_ctype = py_object_type
|
|
self.is_temp = 1
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def analyse_target_declaration(self, env):
|
|
pass
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
def allocate(self, code):
|
|
self.temp_cname = code.funcstate.allocate_temp(self.type, manage_ref=True)
|
|
|
|
def release(self, code):
|
|
code.funcstate.release_temp(self.temp_cname)
|
|
self.temp_cname = None
|
|
|
|
def result(self):
|
|
try:
|
|
return self.temp_cname
|
|
except:
|
|
assert False, "Remember to call allocate/release on TempNode"
|
|
raise
|
|
|
|
# Do not participate in normal temp alloc/dealloc:
|
|
def allocate_temp_result(self, code):
|
|
pass
|
|
|
|
def release_temp_result(self, code):
|
|
pass
|
|
|
|
class PyTempNode(TempNode):
|
|
# TempNode holding a Python value.
|
|
|
|
def __init__(self, pos, env):
|
|
TempNode.__init__(self, pos, PyrexTypes.py_object_type, env)
|
|
|
|
class RawCNameExprNode(ExprNode):
|
|
subexprs = []
|
|
|
|
def __init__(self, pos, type=None, cname=None):
|
|
ExprNode.__init__(self, pos, type=type)
|
|
if cname is not None:
|
|
self.cname = cname
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def set_cname(self, cname):
|
|
self.cname = cname
|
|
|
|
def result(self):
|
|
return self.cname
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# F-strings
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
|
|
class JoinedStrNode(ExprNode):
|
|
# F-strings
|
|
#
|
|
# values [UnicodeNode|FormattedValueNode] Substrings of the f-string
|
|
#
|
|
type = unicode_type
|
|
is_temp = True
|
|
|
|
subexprs = ['values']
|
|
|
|
def analyse_types(self, env):
|
|
self.values = [v.analyse_types(env).coerce_to_pyobject(env) for v in self.values]
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
# PyUnicode_Join() always returns a Unicode string or raises an exception
|
|
return False
|
|
|
|
def generate_evaluation_code(self, code):
|
|
code.mark_pos(self.pos)
|
|
num_items = len(self.values)
|
|
list_var = code.funcstate.allocate_temp(py_object_type, manage_ref=True)
|
|
ulength_var = code.funcstate.allocate_temp(PyrexTypes.c_py_ssize_t_type, manage_ref=False)
|
|
max_char_var = code.funcstate.allocate_temp(PyrexTypes.c_py_ucs4_type, manage_ref=False)
|
|
|
|
code.putln('%s = PyTuple_New(%s); %s' % (
|
|
list_var,
|
|
num_items,
|
|
code.error_goto_if_null(list_var, self.pos)))
|
|
code.put_gotref(list_var)
|
|
code.putln("%s = 0;" % ulength_var)
|
|
code.putln("%s = 127;" % max_char_var) # at least ASCII character range
|
|
|
|
for i, node in enumerate(self.values):
|
|
node.generate_evaluation_code(code)
|
|
node.make_owned_reference(code)
|
|
|
|
ulength = "__Pyx_PyUnicode_GET_LENGTH(%s)" % node.py_result()
|
|
max_char_value = "__Pyx_PyUnicode_MAX_CHAR_VALUE(%s)" % node.py_result()
|
|
is_ascii = False
|
|
if isinstance(node, UnicodeNode):
|
|
try:
|
|
# most strings will be ASCII or at least Latin-1
|
|
node.value.encode('iso8859-1')
|
|
max_char_value = '255'
|
|
node.value.encode('us-ascii')
|
|
is_ascii = True
|
|
except UnicodeEncodeError:
|
|
if max_char_value != '255':
|
|
# not ISO8859-1 => check BMP limit
|
|
max_char = max(map(ord, node.value))
|
|
if max_char < 0xD800:
|
|
# BMP-only, no surrogate pairs used
|
|
max_char_value = '65535'
|
|
ulength = str(len(node.value))
|
|
elif max_char >= 65536:
|
|
# cleary outside of BMP, and not on a 16-bit Unicode system
|
|
max_char_value = '1114111'
|
|
ulength = str(len(node.value))
|
|
else:
|
|
# not really worth implementing a check for surrogate pairs here
|
|
# drawback: C code can differ when generating on Py2 with 2-byte Unicode
|
|
pass
|
|
else:
|
|
ulength = str(len(node.value))
|
|
elif isinstance(node, FormattedValueNode) and node.value.type.is_numeric:
|
|
is_ascii = True # formatted C numbers are always ASCII
|
|
|
|
if not is_ascii:
|
|
code.putln("%s = (%s > %s) ? %s : %s;" % (
|
|
max_char_var, max_char_value, max_char_var, max_char_value, max_char_var))
|
|
code.putln("%s += %s;" % (ulength_var, ulength))
|
|
|
|
code.put_giveref(node.py_result())
|
|
code.putln('PyTuple_SET_ITEM(%s, %s, %s);' % (list_var, i, node.py_result()))
|
|
node.generate_post_assignment_code(code)
|
|
node.free_temps(code)
|
|
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("JoinPyUnicode", "StringTools.c"))
|
|
code.putln('%s = __Pyx_PyUnicode_Join(%s, %d, %s, %s); %s' % (
|
|
self.result(),
|
|
list_var,
|
|
num_items,
|
|
ulength_var,
|
|
max_char_var,
|
|
code.error_goto_if_null(self.py_result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
code.put_decref_clear(list_var, py_object_type)
|
|
code.funcstate.release_temp(list_var)
|
|
code.funcstate.release_temp(ulength_var)
|
|
code.funcstate.release_temp(max_char_var)
|
|
|
|
|
|
class FormattedValueNode(ExprNode):
|
|
# {}-delimited portions of an f-string
|
|
#
|
|
# value ExprNode The expression itself
|
|
# conversion_char str or None Type conversion (!s, !r, !a, or none, or 'd' for integer conversion)
|
|
# format_spec JoinedStrNode or None Format string passed to __format__
|
|
# c_format_spec str or None If not None, formatting can be done at the C level
|
|
|
|
subexprs = ['value', 'format_spec']
|
|
|
|
type = unicode_type
|
|
is_temp = True
|
|
c_format_spec = None
|
|
|
|
find_conversion_func = {
|
|
's': 'PyObject_Unicode',
|
|
'r': 'PyObject_Repr',
|
|
'a': 'PyObject_ASCII', # NOTE: mapped to PyObject_Repr() in Py2
|
|
'd': '__Pyx_PyNumber_IntOrLong', # NOTE: internal mapping for '%d' formatting
|
|
}.get
|
|
|
|
def may_be_none(self):
|
|
# PyObject_Format() always returns a Unicode string or raises an exception
|
|
return False
|
|
|
|
def analyse_types(self, env):
|
|
self.value = self.value.analyse_types(env)
|
|
if not self.format_spec or self.format_spec.is_string_literal:
|
|
c_format_spec = self.format_spec.value if self.format_spec else self.value.type.default_format_spec
|
|
if self.value.type.can_coerce_to_pystring(env, format_spec=c_format_spec):
|
|
self.c_format_spec = c_format_spec
|
|
|
|
if self.format_spec:
|
|
self.format_spec = self.format_spec.analyse_types(env).coerce_to_pyobject(env)
|
|
if self.c_format_spec is None:
|
|
self.value = self.value.coerce_to_pyobject(env)
|
|
if not self.format_spec and (not self.conversion_char or self.conversion_char == 's'):
|
|
if self.value.type is unicode_type and not self.value.may_be_none():
|
|
# value is definitely a unicode string and we don't format it any special
|
|
return self.value
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
if self.c_format_spec is not None and not self.value.type.is_pyobject:
|
|
convert_func_call = self.value.type.convert_to_pystring(
|
|
self.value.result(), code, self.c_format_spec)
|
|
code.putln("%s = %s; %s" % (
|
|
self.result(),
|
|
convert_func_call,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
return
|
|
|
|
value_result = self.value.py_result()
|
|
value_is_unicode = self.value.type is unicode_type and not self.value.may_be_none()
|
|
if self.format_spec:
|
|
format_func = '__Pyx_PyObject_Format'
|
|
format_spec = self.format_spec.py_result()
|
|
else:
|
|
# common case: expect simple Unicode pass-through if no format spec
|
|
format_func = '__Pyx_PyObject_FormatSimple'
|
|
# passing a Unicode format string in Py2 forces PyObject_Format() to also return a Unicode string
|
|
format_spec = Naming.empty_unicode
|
|
|
|
conversion_char = self.conversion_char
|
|
if conversion_char == 's' and value_is_unicode:
|
|
# no need to pipe unicode strings through str()
|
|
conversion_char = None
|
|
|
|
if conversion_char:
|
|
fn = self.find_conversion_func(conversion_char)
|
|
assert fn is not None, "invalid conversion character found: '%s'" % conversion_char
|
|
value_result = '%s(%s)' % (fn, value_result)
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectFormatAndDecref", "StringTools.c"))
|
|
format_func += 'AndDecref'
|
|
elif self.format_spec:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectFormat", "StringTools.c"))
|
|
else:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectFormatSimple", "StringTools.c"))
|
|
|
|
code.putln("%s = %s(%s, %s); %s" % (
|
|
self.result(),
|
|
format_func,
|
|
value_result,
|
|
format_spec,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# Parallel nodes (cython.parallel.thread(savailable|id))
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
class ParallelThreadsAvailableNode(AtomicExprNode):
|
|
"""
|
|
Note: this is disabled and not a valid directive at this moment
|
|
|
|
Implements cython.parallel.threadsavailable(). If we are called from the
|
|
sequential part of the application, we need to call omp_get_max_threads(),
|
|
and in the parallel part we can just call omp_get_num_threads()
|
|
"""
|
|
|
|
type = PyrexTypes.c_int_type
|
|
|
|
def analyse_types(self, env):
|
|
self.is_temp = True
|
|
# env.add_include_file("omp.h")
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln("#ifdef _OPENMP")
|
|
code.putln("if (omp_in_parallel()) %s = omp_get_max_threads();" %
|
|
self.temp_code)
|
|
code.putln("else %s = omp_get_num_threads();" % self.temp_code)
|
|
code.putln("#else")
|
|
code.putln("%s = 1;" % self.temp_code)
|
|
code.putln("#endif")
|
|
|
|
def result(self):
|
|
return self.temp_code
|
|
|
|
|
|
class ParallelThreadIdNode(AtomicExprNode): #, Nodes.ParallelNode):
|
|
"""
|
|
Implements cython.parallel.threadid()
|
|
"""
|
|
|
|
type = PyrexTypes.c_int_type
|
|
|
|
def analyse_types(self, env):
|
|
self.is_temp = True
|
|
# env.add_include_file("omp.h")
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln("#ifdef _OPENMP")
|
|
code.putln("%s = omp_get_thread_num();" % self.temp_code)
|
|
code.putln("#else")
|
|
code.putln("%s = 0;" % self.temp_code)
|
|
code.putln("#endif")
|
|
|
|
def result(self):
|
|
return self.temp_code
|
|
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# Trailer nodes
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
|
|
class _IndexingBaseNode(ExprNode):
|
|
# Base class for indexing nodes.
|
|
#
|
|
# base ExprNode the value being indexed
|
|
|
|
def is_ephemeral(self):
|
|
# in most cases, indexing will return a safe reference to an object in a container,
|
|
# so we consider the result safe if the base object is
|
|
return self.base.is_ephemeral() or self.base.type in (
|
|
basestring_type, str_type, bytes_type, bytearray_type, unicode_type)
|
|
|
|
def check_const_addr(self):
|
|
return self.base.check_const_addr() and self.index.check_const()
|
|
|
|
def is_lvalue(self):
|
|
# NOTE: references currently have both is_reference and is_ptr
|
|
# set. Since pointers and references have different lvalue
|
|
# rules, we must be careful to separate the two.
|
|
if self.type.is_reference:
|
|
if self.type.ref_base_type.is_array:
|
|
# fixed-sized arrays aren't l-values
|
|
return False
|
|
elif self.type.is_ptr:
|
|
# non-const pointers can always be reassigned
|
|
return True
|
|
# Just about everything else returned by the index operator
|
|
# can be an lvalue.
|
|
return True
|
|
|
|
|
|
class IndexNode(_IndexingBaseNode):
|
|
# Sequence indexing.
|
|
#
|
|
# base ExprNode
|
|
# index ExprNode
|
|
# type_indices [PyrexType]
|
|
#
|
|
# is_fused_index boolean Whether the index is used to specialize a
|
|
# c(p)def function
|
|
|
|
subexprs = ['base', 'index']
|
|
type_indices = None
|
|
|
|
is_subscript = True
|
|
is_fused_index = False
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = self.base.constant_result[self.index.constant_result]
|
|
|
|
def compile_time_value(self, denv):
|
|
base = self.base.compile_time_value(denv)
|
|
index = self.index.compile_time_value(denv)
|
|
try:
|
|
return base[index]
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def is_simple(self):
|
|
base = self.base
|
|
return (base.is_simple() and self.index.is_simple()
|
|
and base.type and (base.type.is_ptr or base.type.is_array))
|
|
|
|
def may_be_none(self):
|
|
base_type = self.base.type
|
|
if base_type:
|
|
if base_type.is_string:
|
|
return False
|
|
if isinstance(self.index, SliceNode):
|
|
# slicing!
|
|
if base_type in (bytes_type, bytearray_type, str_type, unicode_type,
|
|
basestring_type, list_type, tuple_type):
|
|
return False
|
|
return ExprNode.may_be_none(self)
|
|
|
|
def analyse_target_declaration(self, env):
|
|
pass
|
|
|
|
def analyse_as_type(self, env):
|
|
base_type = self.base.analyse_as_type(env)
|
|
if base_type and not base_type.is_pyobject:
|
|
if base_type.is_cpp_class:
|
|
if isinstance(self.index, TupleNode):
|
|
template_values = self.index.args
|
|
else:
|
|
template_values = [self.index]
|
|
type_node = Nodes.TemplatedTypeNode(
|
|
pos=self.pos,
|
|
positional_args=template_values,
|
|
keyword_args=None)
|
|
return type_node.analyse(env, base_type=base_type)
|
|
elif self.index.is_slice or self.index.is_sequence_constructor:
|
|
# memory view
|
|
from . import MemoryView
|
|
env.use_utility_code(MemoryView.view_utility_code)
|
|
axes = [self.index] if self.index.is_slice else list(self.index.args)
|
|
return PyrexTypes.MemoryViewSliceType(base_type, MemoryView.get_axes_specs(env, axes))
|
|
else:
|
|
# C array
|
|
index = self.index.compile_time_value(env)
|
|
if index is not None:
|
|
try:
|
|
index = int(index)
|
|
except (ValueError, TypeError):
|
|
pass
|
|
else:
|
|
return PyrexTypes.CArrayType(base_type, index)
|
|
error(self.pos, "Array size must be a compile time constant")
|
|
return None
|
|
|
|
def type_dependencies(self, env):
|
|
return self.base.type_dependencies(env) + self.index.type_dependencies(env)
|
|
|
|
def infer_type(self, env):
|
|
base_type = self.base.infer_type(env)
|
|
if self.index.is_slice:
|
|
# slicing!
|
|
if base_type.is_string:
|
|
# sliced C strings must coerce to Python
|
|
return bytes_type
|
|
elif base_type.is_pyunicode_ptr:
|
|
# sliced Py_UNICODE* strings must coerce to Python
|
|
return unicode_type
|
|
elif base_type in (unicode_type, bytes_type, str_type,
|
|
bytearray_type, list_type, tuple_type):
|
|
# slicing these returns the same type
|
|
return base_type
|
|
else:
|
|
# TODO: Handle buffers (hopefully without too much redundancy).
|
|
return py_object_type
|
|
|
|
index_type = self.index.infer_type(env)
|
|
if index_type and index_type.is_int or isinstance(self.index, IntNode):
|
|
# indexing!
|
|
if base_type is unicode_type:
|
|
# Py_UCS4 will automatically coerce to a unicode string
|
|
# if required, so this is safe. We only infer Py_UCS4
|
|
# when the index is a C integer type. Otherwise, we may
|
|
# need to use normal Python item access, in which case
|
|
# it's faster to return the one-char unicode string than
|
|
# to receive it, throw it away, and potentially rebuild it
|
|
# on a subsequent PyObject coercion.
|
|
return PyrexTypes.c_py_ucs4_type
|
|
elif base_type is str_type:
|
|
# always returns str - Py2: bytes, Py3: unicode
|
|
return base_type
|
|
elif base_type is bytearray_type:
|
|
return PyrexTypes.c_uchar_type
|
|
elif isinstance(self.base, BytesNode):
|
|
#if env.global_scope().context.language_level >= 3:
|
|
# # inferring 'char' can be made to work in Python 3 mode
|
|
# return PyrexTypes.c_char_type
|
|
# Py2/3 return different types on indexing bytes objects
|
|
return py_object_type
|
|
elif base_type in (tuple_type, list_type):
|
|
# if base is a literal, take a look at its values
|
|
item_type = infer_sequence_item_type(
|
|
env, self.base, self.index, seq_type=base_type)
|
|
if item_type is not None:
|
|
return item_type
|
|
elif base_type.is_ptr or base_type.is_array:
|
|
return base_type.base_type
|
|
elif base_type.is_ctuple and isinstance(self.index, IntNode):
|
|
if self.index.has_constant_result():
|
|
index = self.index.constant_result
|
|
if index < 0:
|
|
index += base_type.size
|
|
if 0 <= index < base_type.size:
|
|
return base_type.components[index]
|
|
|
|
if base_type.is_cpp_class:
|
|
class FakeOperand:
|
|
def __init__(self, **kwds):
|
|
self.__dict__.update(kwds)
|
|
operands = [
|
|
FakeOperand(pos=self.pos, type=base_type),
|
|
FakeOperand(pos=self.pos, type=index_type),
|
|
]
|
|
index_func = env.lookup_operator('[]', operands)
|
|
if index_func is not None:
|
|
return index_func.type.return_type
|
|
|
|
if is_pythran_expr(base_type) and is_pythran_expr(index_type):
|
|
index_with_type = (self.index, index_type)
|
|
return PythranExpr(pythran_indexing_type(base_type, [index_with_type]))
|
|
|
|
# may be slicing or indexing, we don't know
|
|
if base_type in (unicode_type, str_type):
|
|
# these types always returns their own type on Python indexing/slicing
|
|
return base_type
|
|
else:
|
|
# TODO: Handle buffers (hopefully without too much redundancy).
|
|
return py_object_type
|
|
|
|
def analyse_types(self, env):
|
|
return self.analyse_base_and_index_types(env, getting=True)
|
|
|
|
def analyse_target_types(self, env):
|
|
node = self.analyse_base_and_index_types(env, setting=True)
|
|
if node.type.is_const:
|
|
error(self.pos, "Assignment to const dereference")
|
|
if node is self and not node.is_lvalue():
|
|
error(self.pos, "Assignment to non-lvalue of type '%s'" % node.type)
|
|
return node
|
|
|
|
def analyse_base_and_index_types(self, env, getting=False, setting=False,
|
|
analyse_base=True):
|
|
# Note: This might be cleaned up by having IndexNode
|
|
# parsed in a saner way and only construct the tuple if
|
|
# needed.
|
|
if analyse_base:
|
|
self.base = self.base.analyse_types(env)
|
|
|
|
if self.base.type.is_error:
|
|
# Do not visit child tree if base is undeclared to avoid confusing
|
|
# error messages
|
|
self.type = PyrexTypes.error_type
|
|
return self
|
|
|
|
is_slice = self.index.is_slice
|
|
if not env.directives['wraparound']:
|
|
if is_slice:
|
|
check_negative_indices(self.index.start, self.index.stop)
|
|
else:
|
|
check_negative_indices(self.index)
|
|
|
|
# Potentially overflowing index value.
|
|
if not is_slice and isinstance(self.index, IntNode) and Utils.long_literal(self.index.value):
|
|
self.index = self.index.coerce_to_pyobject(env)
|
|
|
|
is_memslice = self.base.type.is_memoryviewslice
|
|
# Handle the case where base is a literal char* (and we expect a string, not an int)
|
|
if not is_memslice and (isinstance(self.base, BytesNode) or is_slice):
|
|
if self.base.type.is_string or not (self.base.type.is_ptr or self.base.type.is_array):
|
|
self.base = self.base.coerce_to_pyobject(env)
|
|
|
|
replacement_node = self.analyse_as_buffer_operation(env, getting)
|
|
if replacement_node is not None:
|
|
return replacement_node
|
|
|
|
self.nogil = env.nogil
|
|
base_type = self.base.type
|
|
|
|
if not base_type.is_cfunction:
|
|
self.index = self.index.analyse_types(env)
|
|
self.original_index_type = self.index.type
|
|
|
|
if base_type.is_unicode_char:
|
|
# we infer Py_UNICODE/Py_UCS4 for unicode strings in some
|
|
# cases, but indexing must still work for them
|
|
if setting:
|
|
warning(self.pos, "cannot assign to Unicode string index", level=1)
|
|
elif self.index.constant_result in (0, -1):
|
|
# uchar[0] => uchar
|
|
return self.base
|
|
self.base = self.base.coerce_to_pyobject(env)
|
|
base_type = self.base.type
|
|
|
|
if base_type.is_pyobject:
|
|
return self.analyse_as_pyobject(env, is_slice, getting, setting)
|
|
elif base_type.is_ptr or base_type.is_array:
|
|
return self.analyse_as_c_array(env, is_slice)
|
|
elif base_type.is_cpp_class:
|
|
return self.analyse_as_cpp(env, setting)
|
|
elif base_type.is_cfunction:
|
|
return self.analyse_as_c_function(env)
|
|
elif base_type.is_ctuple:
|
|
return self.analyse_as_c_tuple(env, getting, setting)
|
|
else:
|
|
error(self.pos,
|
|
"Attempting to index non-array type '%s'" %
|
|
base_type)
|
|
self.type = PyrexTypes.error_type
|
|
return self
|
|
|
|
def analyse_as_pyobject(self, env, is_slice, getting, setting):
|
|
base_type = self.base.type
|
|
if self.index.type.is_unicode_char and base_type is not dict_type:
|
|
# TODO: eventually fold into case below and remove warning, once people have adapted their code
|
|
warning(self.pos,
|
|
"Item lookup of unicode character codes now always converts to a Unicode string. "
|
|
"Use an explicit C integer cast to get back the previous integer lookup behaviour.", level=1)
|
|
self.index = self.index.coerce_to_pyobject(env)
|
|
self.is_temp = 1
|
|
elif self.index.type.is_int and base_type is not dict_type:
|
|
if (getting
|
|
and (base_type in (list_type, tuple_type, bytearray_type))
|
|
and (not self.index.type.signed
|
|
or not env.directives['wraparound']
|
|
or (isinstance(self.index, IntNode) and
|
|
self.index.has_constant_result() and self.index.constant_result >= 0))
|
|
and not env.directives['boundscheck']):
|
|
self.is_temp = 0
|
|
else:
|
|
self.is_temp = 1
|
|
self.index = self.index.coerce_to(PyrexTypes.c_py_ssize_t_type, env).coerce_to_simple(env)
|
|
self.original_index_type.create_to_py_utility_code(env)
|
|
else:
|
|
self.index = self.index.coerce_to_pyobject(env)
|
|
self.is_temp = 1
|
|
|
|
if self.index.type.is_int and base_type is unicode_type:
|
|
# Py_UNICODE/Py_UCS4 will automatically coerce to a unicode string
|
|
# if required, so this is fast and safe
|
|
self.type = PyrexTypes.c_py_ucs4_type
|
|
elif self.index.type.is_int and base_type is bytearray_type:
|
|
if setting:
|
|
self.type = PyrexTypes.c_uchar_type
|
|
else:
|
|
# not using 'uchar' to enable fast and safe error reporting as '-1'
|
|
self.type = PyrexTypes.c_int_type
|
|
elif is_slice and base_type in (bytes_type, bytearray_type, str_type, unicode_type, list_type, tuple_type):
|
|
self.type = base_type
|
|
else:
|
|
item_type = None
|
|
if base_type in (list_type, tuple_type) and self.index.type.is_int:
|
|
item_type = infer_sequence_item_type(
|
|
env, self.base, self.index, seq_type=base_type)
|
|
if item_type is None:
|
|
item_type = py_object_type
|
|
self.type = item_type
|
|
if base_type in (list_type, tuple_type, dict_type):
|
|
# do the None check explicitly (not in a helper) to allow optimising it away
|
|
self.base = self.base.as_none_safe_node("'NoneType' object is not subscriptable")
|
|
|
|
self.wrap_in_nonecheck_node(env, getting)
|
|
return self
|
|
|
|
def analyse_as_c_array(self, env, is_slice):
|
|
base_type = self.base.type
|
|
self.type = base_type.base_type
|
|
if is_slice:
|
|
self.type = base_type
|
|
elif self.index.type.is_pyobject:
|
|
self.index = self.index.coerce_to(PyrexTypes.c_py_ssize_t_type, env)
|
|
elif not self.index.type.is_int:
|
|
error(self.pos, "Invalid index type '%s'" % self.index.type)
|
|
return self
|
|
|
|
def analyse_as_cpp(self, env, setting):
|
|
base_type = self.base.type
|
|
function = env.lookup_operator("[]", [self.base, self.index])
|
|
if function is None:
|
|
error(self.pos, "Indexing '%s' not supported for index type '%s'" % (base_type, self.index.type))
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
return self
|
|
func_type = function.type
|
|
if func_type.is_ptr:
|
|
func_type = func_type.base_type
|
|
self.exception_check = func_type.exception_check
|
|
self.exception_value = func_type.exception_value
|
|
if self.exception_check:
|
|
if not setting:
|
|
self.is_temp = True
|
|
if self.exception_value is None:
|
|
env.use_utility_code(UtilityCode.load_cached("CppExceptionConversion", "CppSupport.cpp"))
|
|
self.index = self.index.coerce_to(func_type.args[0].type, env)
|
|
self.type = func_type.return_type
|
|
if setting and not func_type.return_type.is_reference:
|
|
error(self.pos, "Can't set non-reference result '%s'" % self.type)
|
|
return self
|
|
|
|
def analyse_as_c_function(self, env):
|
|
base_type = self.base.type
|
|
if base_type.is_fused:
|
|
self.parse_indexed_fused_cdef(env)
|
|
else:
|
|
self.type_indices = self.parse_index_as_types(env)
|
|
self.index = None # FIXME: use a dedicated Node class instead of generic IndexNode
|
|
if base_type.templates is None:
|
|
error(self.pos, "Can only parameterize template functions.")
|
|
self.type = error_type
|
|
elif self.type_indices is None:
|
|
# Error recorded earlier.
|
|
self.type = error_type
|
|
elif len(base_type.templates) != len(self.type_indices):
|
|
error(self.pos, "Wrong number of template arguments: expected %s, got %s" % (
|
|
(len(base_type.templates), len(self.type_indices))))
|
|
self.type = error_type
|
|
else:
|
|
self.type = base_type.specialize(dict(zip(base_type.templates, self.type_indices)))
|
|
# FIXME: use a dedicated Node class instead of generic IndexNode
|
|
return self
|
|
|
|
def analyse_as_c_tuple(self, env, getting, setting):
|
|
base_type = self.base.type
|
|
if isinstance(self.index, IntNode) and self.index.has_constant_result():
|
|
index = self.index.constant_result
|
|
if -base_type.size <= index < base_type.size:
|
|
if index < 0:
|
|
index += base_type.size
|
|
self.type = base_type.components[index]
|
|
else:
|
|
error(self.pos,
|
|
"Index %s out of bounds for '%s'" %
|
|
(index, base_type))
|
|
self.type = PyrexTypes.error_type
|
|
return self
|
|
else:
|
|
self.base = self.base.coerce_to_pyobject(env)
|
|
return self.analyse_base_and_index_types(env, getting=getting, setting=setting, analyse_base=False)
|
|
|
|
def analyse_as_buffer_operation(self, env, getting):
|
|
"""
|
|
Analyse buffer indexing and memoryview indexing/slicing
|
|
"""
|
|
if isinstance(self.index, TupleNode):
|
|
indices = self.index.args
|
|
else:
|
|
indices = [self.index]
|
|
|
|
base = self.base
|
|
base_type = base.type
|
|
replacement_node = None
|
|
if base_type.is_memoryviewslice:
|
|
# memoryviewslice indexing or slicing
|
|
from . import MemoryView
|
|
if base.is_memview_slice:
|
|
# For memory views, "view[i][j]" is the same as "view[i, j]" => use the latter for speed.
|
|
merged_indices = base.merged_indices(indices)
|
|
if merged_indices is not None:
|
|
base = base.base
|
|
base_type = base.type
|
|
indices = merged_indices
|
|
have_slices, indices, newaxes = MemoryView.unellipsify(indices, base_type.ndim)
|
|
if have_slices:
|
|
replacement_node = MemoryViewSliceNode(self.pos, indices=indices, base=base)
|
|
else:
|
|
replacement_node = MemoryViewIndexNode(self.pos, indices=indices, base=base)
|
|
elif base_type.is_buffer or base_type.is_pythran_expr:
|
|
if base_type.is_pythran_expr or len(indices) == base_type.ndim:
|
|
# Buffer indexing
|
|
is_buffer_access = True
|
|
indices = [index.analyse_types(env) for index in indices]
|
|
if base_type.is_pythran_expr:
|
|
do_replacement = all(
|
|
index.type.is_int or index.is_slice or index.type.is_pythran_expr
|
|
for index in indices)
|
|
if do_replacement:
|
|
for i,index in enumerate(indices):
|
|
if index.is_slice:
|
|
index = SliceIntNode(index.pos, start=index.start, stop=index.stop, step=index.step)
|
|
index = index.analyse_types(env)
|
|
indices[i] = index
|
|
else:
|
|
do_replacement = all(index.type.is_int for index in indices)
|
|
if do_replacement:
|
|
replacement_node = BufferIndexNode(self.pos, indices=indices, base=base)
|
|
# On cloning, indices is cloned. Otherwise, unpack index into indices.
|
|
assert not isinstance(self.index, CloneNode)
|
|
|
|
if replacement_node is not None:
|
|
replacement_node = replacement_node.analyse_types(env, getting)
|
|
return replacement_node
|
|
|
|
def wrap_in_nonecheck_node(self, env, getting):
|
|
if not env.directives['nonecheck'] or not self.base.may_be_none():
|
|
return
|
|
self.base = self.base.as_none_safe_node("'NoneType' object is not subscriptable")
|
|
|
|
def parse_index_as_types(self, env, required=True):
|
|
if isinstance(self.index, TupleNode):
|
|
indices = self.index.args
|
|
else:
|
|
indices = [self.index]
|
|
type_indices = []
|
|
for index in indices:
|
|
type_indices.append(index.analyse_as_type(env))
|
|
if type_indices[-1] is None:
|
|
if required:
|
|
error(index.pos, "not parsable as a type")
|
|
return None
|
|
return type_indices
|
|
|
|
def parse_indexed_fused_cdef(self, env):
|
|
"""
|
|
Interpret fused_cdef_func[specific_type1, ...]
|
|
|
|
Note that if this method is called, we are an indexed cdef function
|
|
with fused argument types, and this IndexNode will be replaced by the
|
|
NameNode with specific entry just after analysis of expressions by
|
|
AnalyseExpressionsTransform.
|
|
"""
|
|
self.type = PyrexTypes.error_type
|
|
|
|
self.is_fused_index = True
|
|
|
|
base_type = self.base.type
|
|
positions = []
|
|
|
|
if self.index.is_name or self.index.is_attribute:
|
|
positions.append(self.index.pos)
|
|
elif isinstance(self.index, TupleNode):
|
|
for arg in self.index.args:
|
|
positions.append(arg.pos)
|
|
specific_types = self.parse_index_as_types(env, required=False)
|
|
|
|
if specific_types is None:
|
|
self.index = self.index.analyse_types(env)
|
|
|
|
if not self.base.entry.as_variable:
|
|
error(self.pos, "Can only index fused functions with types")
|
|
else:
|
|
# A cpdef function indexed with Python objects
|
|
self.base.entry = self.entry = self.base.entry.as_variable
|
|
self.base.type = self.type = self.entry.type
|
|
|
|
self.base.is_temp = True
|
|
self.is_temp = True
|
|
|
|
self.entry.used = True
|
|
|
|
self.is_fused_index = False
|
|
return
|
|
|
|
for i, type in enumerate(specific_types):
|
|
specific_types[i] = type.specialize_fused(env)
|
|
|
|
fused_types = base_type.get_fused_types()
|
|
if len(specific_types) > len(fused_types):
|
|
return error(self.pos, "Too many types specified")
|
|
elif len(specific_types) < len(fused_types):
|
|
t = fused_types[len(specific_types)]
|
|
return error(self.pos, "Not enough types specified to specialize "
|
|
"the function, %s is still fused" % t)
|
|
|
|
# See if our index types form valid specializations
|
|
for pos, specific_type, fused_type in zip(positions,
|
|
specific_types,
|
|
fused_types):
|
|
if not any([specific_type.same_as(t) for t in fused_type.types]):
|
|
return error(pos, "Type not in fused type")
|
|
|
|
if specific_type is None or specific_type.is_error:
|
|
return
|
|
|
|
fused_to_specific = dict(zip(fused_types, specific_types))
|
|
type = base_type.specialize(fused_to_specific)
|
|
|
|
if type.is_fused:
|
|
# Only partially specific, this is invalid
|
|
error(self.pos,
|
|
"Index operation makes function only partially specific")
|
|
else:
|
|
# Fully specific, find the signature with the specialized entry
|
|
for signature in self.base.type.get_all_specialized_function_types():
|
|
if type.same_as(signature):
|
|
self.type = signature
|
|
|
|
if self.base.is_attribute:
|
|
# Pretend to be a normal attribute, for cdef extension
|
|
# methods
|
|
self.entry = signature.entry
|
|
self.is_attribute = True
|
|
self.obj = self.base.obj
|
|
|
|
self.type.entry.used = True
|
|
self.base.type = signature
|
|
self.base.entry = signature.entry
|
|
|
|
break
|
|
else:
|
|
# This is a bug
|
|
raise InternalError("Couldn't find the right signature")
|
|
|
|
gil_message = "Indexing Python object"
|
|
|
|
def calculate_result_code(self):
|
|
if self.base.type in (list_type, tuple_type, bytearray_type):
|
|
if self.base.type is list_type:
|
|
index_code = "PyList_GET_ITEM(%s, %s)"
|
|
elif self.base.type is tuple_type:
|
|
index_code = "PyTuple_GET_ITEM(%s, %s)"
|
|
elif self.base.type is bytearray_type:
|
|
index_code = "((unsigned char)(PyByteArray_AS_STRING(%s)[%s]))"
|
|
else:
|
|
assert False, "unexpected base type in indexing: %s" % self.base.type
|
|
elif self.base.type.is_cfunction:
|
|
return "%s<%s>" % (
|
|
self.base.result(),
|
|
",".join([param.empty_declaration_code() for param in self.type_indices]))
|
|
elif self.base.type.is_ctuple:
|
|
index = self.index.constant_result
|
|
if index < 0:
|
|
index += self.base.type.size
|
|
return "%s.f%s" % (self.base.result(), index)
|
|
else:
|
|
if (self.type.is_ptr or self.type.is_array) and self.type == self.base.type:
|
|
error(self.pos, "Invalid use of pointer slice")
|
|
return
|
|
index_code = "(%s[%s])"
|
|
return index_code % (self.base.result(), self.index.result())
|
|
|
|
def extra_index_params(self, code):
|
|
if self.index.type.is_int:
|
|
is_list = self.base.type is list_type
|
|
wraparound = (
|
|
bool(code.globalstate.directives['wraparound']) and
|
|
self.original_index_type.signed and
|
|
not (isinstance(self.index.constant_result, _py_int_types)
|
|
and self.index.constant_result >= 0))
|
|
boundscheck = bool(code.globalstate.directives['boundscheck'])
|
|
return ", %s, %d, %s, %d, %d, %d" % (
|
|
self.original_index_type.empty_declaration_code(),
|
|
self.original_index_type.signed and 1 or 0,
|
|
self.original_index_type.to_py_function,
|
|
is_list, wraparound, boundscheck)
|
|
else:
|
|
return ""
|
|
|
|
def generate_result_code(self, code):
|
|
if not self.is_temp:
|
|
# all handled in self.calculate_result_code()
|
|
return
|
|
|
|
utility_code = None
|
|
if self.type.is_pyobject:
|
|
error_value = 'NULL'
|
|
if self.index.type.is_int:
|
|
if self.base.type is list_type:
|
|
function = "__Pyx_GetItemInt_List"
|
|
elif self.base.type is tuple_type:
|
|
function = "__Pyx_GetItemInt_Tuple"
|
|
else:
|
|
function = "__Pyx_GetItemInt"
|
|
utility_code = TempitaUtilityCode.load_cached("GetItemInt", "ObjectHandling.c")
|
|
else:
|
|
if self.base.type is dict_type:
|
|
function = "__Pyx_PyDict_GetItem"
|
|
utility_code = UtilityCode.load_cached("DictGetItem", "ObjectHandling.c")
|
|
elif self.base.type is py_object_type and self.index.type in (str_type, unicode_type):
|
|
# obj[str] is probably doing a dict lookup
|
|
function = "__Pyx_PyObject_Dict_GetItem"
|
|
utility_code = UtilityCode.load_cached("DictGetItem", "ObjectHandling.c")
|
|
else:
|
|
function = "__Pyx_PyObject_GetItem"
|
|
code.globalstate.use_utility_code(
|
|
TempitaUtilityCode.load_cached("GetItemInt", "ObjectHandling.c"))
|
|
utility_code = UtilityCode.load_cached("ObjectGetItem", "ObjectHandling.c")
|
|
elif self.type.is_unicode_char and self.base.type is unicode_type:
|
|
assert self.index.type.is_int
|
|
function = "__Pyx_GetItemInt_Unicode"
|
|
error_value = '(Py_UCS4)-1'
|
|
utility_code = UtilityCode.load_cached("GetItemIntUnicode", "StringTools.c")
|
|
elif self.base.type is bytearray_type:
|
|
assert self.index.type.is_int
|
|
assert self.type.is_int
|
|
function = "__Pyx_GetItemInt_ByteArray"
|
|
error_value = '-1'
|
|
utility_code = UtilityCode.load_cached("GetItemIntByteArray", "StringTools.c")
|
|
elif not (self.base.type.is_cpp_class and self.exception_check):
|
|
assert False, "unexpected type %s and base type %s for indexing" % (
|
|
self.type, self.base.type)
|
|
|
|
if utility_code is not None:
|
|
code.globalstate.use_utility_code(utility_code)
|
|
|
|
if self.index.type.is_int:
|
|
index_code = self.index.result()
|
|
else:
|
|
index_code = self.index.py_result()
|
|
|
|
if self.base.type.is_cpp_class and self.exception_check:
|
|
translate_cpp_exception(code, self.pos,
|
|
"%s = %s[%s];" % (self.result(), self.base.result(),
|
|
self.index.result()),
|
|
self.result() if self.type.is_pyobject else None,
|
|
self.exception_value, self.in_nogil_context)
|
|
else:
|
|
error_check = '!%s' if error_value == 'NULL' else '%%s == %s' % error_value
|
|
code.putln(
|
|
"%s = %s(%s, %s%s); %s" % (
|
|
self.result(),
|
|
function,
|
|
self.base.py_result(),
|
|
index_code,
|
|
self.extra_index_params(code),
|
|
code.error_goto_if(error_check % self.result(), self.pos)))
|
|
if self.type.is_pyobject:
|
|
code.put_gotref(self.py_result())
|
|
|
|
def generate_setitem_code(self, value_code, code):
|
|
if self.index.type.is_int:
|
|
if self.base.type is bytearray_type:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("SetItemIntByteArray", "StringTools.c"))
|
|
function = "__Pyx_SetItemInt_ByteArray"
|
|
else:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("SetItemInt", "ObjectHandling.c"))
|
|
function = "__Pyx_SetItemInt"
|
|
index_code = self.index.result()
|
|
else:
|
|
index_code = self.index.py_result()
|
|
if self.base.type is dict_type:
|
|
function = "PyDict_SetItem"
|
|
# It would seem that we could specialized lists/tuples, but that
|
|
# shouldn't happen here.
|
|
# Both PyList_SetItem() and PyTuple_SetItem() take a Py_ssize_t as
|
|
# index instead of an object, and bad conversion here would give
|
|
# the wrong exception. Also, tuples are supposed to be immutable,
|
|
# and raise a TypeError when trying to set their entries
|
|
# (PyTuple_SetItem() is for creating new tuples from scratch).
|
|
else:
|
|
function = "PyObject_SetItem"
|
|
code.putln(code.error_goto_if_neg(
|
|
"%s(%s, %s, %s%s)" % (
|
|
function,
|
|
self.base.py_result(),
|
|
index_code,
|
|
value_code,
|
|
self.extra_index_params(code)),
|
|
self.pos))
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False,
|
|
exception_check=None, exception_value=None):
|
|
self.generate_subexpr_evaluation_code(code)
|
|
|
|
if self.type.is_pyobject:
|
|
self.generate_setitem_code(rhs.py_result(), code)
|
|
elif self.base.type is bytearray_type:
|
|
value_code = self._check_byte_value(code, rhs)
|
|
self.generate_setitem_code(value_code, code)
|
|
elif self.base.type.is_cpp_class and self.exception_check and self.exception_check == '+':
|
|
if overloaded_assignment and exception_check and \
|
|
self.exception_value != exception_value:
|
|
# Handle the case that both the index operator and the assignment
|
|
# operator have a c++ exception handler and they are not the same.
|
|
translate_double_cpp_exception(code, self.pos, self.type,
|
|
self.result(), rhs.result(), self.exception_value,
|
|
exception_value, self.in_nogil_context)
|
|
else:
|
|
# Handle the case that only the index operator has a
|
|
# c++ exception handler, or that
|
|
# both exception handlers are the same.
|
|
translate_cpp_exception(code, self.pos,
|
|
"%s = %s;" % (self.result(), rhs.result()),
|
|
self.result() if self.type.is_pyobject else None,
|
|
self.exception_value, self.in_nogil_context)
|
|
else:
|
|
code.putln(
|
|
"%s = %s;" % (self.result(), rhs.result()))
|
|
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
|
|
def _check_byte_value(self, code, rhs):
|
|
# TODO: should we do this generally on downcasts, or just here?
|
|
assert rhs.type.is_int, repr(rhs.type)
|
|
value_code = rhs.result()
|
|
if rhs.has_constant_result():
|
|
if 0 <= rhs.constant_result < 256:
|
|
return value_code
|
|
needs_cast = True # make at least the C compiler happy
|
|
warning(rhs.pos,
|
|
"value outside of range(0, 256)"
|
|
" when assigning to byte: %s" % rhs.constant_result,
|
|
level=1)
|
|
else:
|
|
needs_cast = rhs.type != PyrexTypes.c_uchar_type
|
|
|
|
if not self.nogil:
|
|
conditions = []
|
|
if rhs.is_literal or rhs.type.signed:
|
|
conditions.append('%s < 0' % value_code)
|
|
if (rhs.is_literal or not
|
|
(rhs.is_temp and rhs.type in (
|
|
PyrexTypes.c_uchar_type, PyrexTypes.c_char_type,
|
|
PyrexTypes.c_schar_type))):
|
|
conditions.append('%s > 255' % value_code)
|
|
if conditions:
|
|
code.putln("if (unlikely(%s)) {" % ' || '.join(conditions))
|
|
code.putln(
|
|
'PyErr_SetString(PyExc_ValueError,'
|
|
' "byte must be in range(0, 256)"); %s' %
|
|
code.error_goto(self.pos))
|
|
code.putln("}")
|
|
|
|
if needs_cast:
|
|
value_code = '((unsigned char)%s)' % value_code
|
|
return value_code
|
|
|
|
def generate_deletion_code(self, code, ignore_nonexisting=False):
|
|
self.generate_subexpr_evaluation_code(code)
|
|
#if self.type.is_pyobject:
|
|
if self.index.type.is_int:
|
|
function = "__Pyx_DelItemInt"
|
|
index_code = self.index.result()
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("DelItemInt", "ObjectHandling.c"))
|
|
else:
|
|
index_code = self.index.py_result()
|
|
if self.base.type is dict_type:
|
|
function = "PyDict_DelItem"
|
|
else:
|
|
function = "PyObject_DelItem"
|
|
code.putln(code.error_goto_if_neg(
|
|
"%s(%s, %s%s)" % (
|
|
function,
|
|
self.base.py_result(),
|
|
index_code,
|
|
self.extra_index_params(code)),
|
|
self.pos))
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
|
|
|
|
class BufferIndexNode(_IndexingBaseNode):
|
|
"""
|
|
Indexing of buffers and memoryviews. This node is created during type
|
|
analysis from IndexNode and replaces it.
|
|
|
|
Attributes:
|
|
base - base node being indexed
|
|
indices - list of indexing expressions
|
|
"""
|
|
|
|
subexprs = ['base', 'indices']
|
|
|
|
is_buffer_access = True
|
|
|
|
# Whether we're assigning to a buffer (in that case it needs to be writable)
|
|
writable_needed = False
|
|
|
|
# Any indexing temp variables that we need to clean up.
|
|
index_temps = ()
|
|
|
|
def analyse_target_types(self, env):
|
|
self.analyse_types(env, getting=False)
|
|
|
|
def analyse_types(self, env, getting=True):
|
|
"""
|
|
Analyse types for buffer indexing only. Overridden by memoryview
|
|
indexing and slicing subclasses
|
|
"""
|
|
# self.indices are already analyzed
|
|
if not self.base.is_name and not is_pythran_expr(self.base.type):
|
|
error(self.pos, "Can only index buffer variables")
|
|
self.type = error_type
|
|
return self
|
|
|
|
if not getting:
|
|
if not self.base.entry.type.writable:
|
|
error(self.pos, "Writing to readonly buffer")
|
|
else:
|
|
self.writable_needed = True
|
|
if self.base.type.is_buffer:
|
|
self.base.entry.buffer_aux.writable_needed = True
|
|
|
|
self.none_error_message = "'NoneType' object is not subscriptable"
|
|
self.analyse_buffer_index(env, getting)
|
|
self.wrap_in_nonecheck_node(env)
|
|
return self
|
|
|
|
def analyse_buffer_index(self, env, getting):
|
|
if is_pythran_expr(self.base.type):
|
|
index_with_type_list = [(idx, idx.type) for idx in self.indices]
|
|
self.type = PythranExpr(pythran_indexing_type(self.base.type, index_with_type_list))
|
|
else:
|
|
self.base = self.base.coerce_to_simple(env)
|
|
self.type = self.base.type.dtype
|
|
self.buffer_type = self.base.type
|
|
|
|
if getting and (self.type.is_pyobject or self.type.is_pythran_expr):
|
|
self.is_temp = True
|
|
|
|
def analyse_assignment(self, rhs):
|
|
"""
|
|
Called by IndexNode when this node is assigned to,
|
|
with the rhs of the assignment
|
|
"""
|
|
|
|
def wrap_in_nonecheck_node(self, env):
|
|
if not env.directives['nonecheck'] or not self.base.may_be_none():
|
|
return
|
|
self.base = self.base.as_none_safe_node(self.none_error_message)
|
|
|
|
def nogil_check(self, env):
|
|
if self.is_buffer_access or self.is_memview_index:
|
|
if self.type.is_pyobject:
|
|
error(self.pos, "Cannot access buffer with object dtype without gil")
|
|
self.type = error_type
|
|
|
|
def calculate_result_code(self):
|
|
return "(*%s)" % self.buffer_ptr_code
|
|
|
|
def buffer_entry(self):
|
|
base = self.base
|
|
if self.base.is_nonecheck:
|
|
base = base.arg
|
|
return base.type.get_entry(base)
|
|
|
|
def get_index_in_temp(self, code, ivar):
|
|
ret = code.funcstate.allocate_temp(
|
|
PyrexTypes.widest_numeric_type(
|
|
ivar.type,
|
|
PyrexTypes.c_ssize_t_type if ivar.type.signed else PyrexTypes.c_size_t_type),
|
|
manage_ref=False)
|
|
code.putln("%s = %s;" % (ret, ivar.result()))
|
|
return ret
|
|
|
|
def buffer_lookup_code(self, code):
|
|
"""
|
|
ndarray[1, 2, 3] and memslice[1, 2, 3]
|
|
"""
|
|
if self.in_nogil_context:
|
|
if self.is_buffer_access or self.is_memview_index:
|
|
if code.globalstate.directives['boundscheck']:
|
|
warning(self.pos, "Use boundscheck(False) for faster access", level=1)
|
|
|
|
# Assign indices to temps of at least (s)size_t to allow further index calculations.
|
|
self.index_temps = index_temps = [self.get_index_in_temp(code,ivar) for ivar in self.indices]
|
|
|
|
# Generate buffer access code using these temps
|
|
from . import Buffer
|
|
buffer_entry = self.buffer_entry()
|
|
if buffer_entry.type.is_buffer:
|
|
negative_indices = buffer_entry.type.negative_indices
|
|
else:
|
|
negative_indices = Buffer.buffer_defaults['negative_indices']
|
|
|
|
return buffer_entry, Buffer.put_buffer_lookup_code(
|
|
entry=buffer_entry,
|
|
index_signeds=[ivar.type.signed for ivar in self.indices],
|
|
index_cnames=index_temps,
|
|
directives=code.globalstate.directives,
|
|
pos=self.pos, code=code,
|
|
negative_indices=negative_indices,
|
|
in_nogil_context=self.in_nogil_context)
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False):
|
|
self.generate_subexpr_evaluation_code(code)
|
|
self.generate_buffer_setitem_code(rhs, code)
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
|
|
def generate_buffer_setitem_code(self, rhs, code, op=""):
|
|
base_type = self.base.type
|
|
if is_pythran_expr(base_type) and is_pythran_supported_type(rhs.type):
|
|
obj = code.funcstate.allocate_temp(PythranExpr(pythran_type(self.base.type)), manage_ref=False)
|
|
# We have got to do this because we have to declare pythran objects
|
|
# at the beginning of the functions.
|
|
# Indeed, Cython uses "goto" statement for error management, and
|
|
# RAII doesn't work with that kind of construction.
|
|
# Moreover, the way Pythran expressions are made is that they don't
|
|
# support move-assignation easily.
|
|
# This, we explicitly destroy then in-place new objects in this
|
|
# case.
|
|
code.putln("__Pyx_call_destructor(%s);" % obj)
|
|
code.putln("new (&%s) decltype(%s){%s};" % (obj, obj, self.base.pythran_result()))
|
|
code.putln("%s%s %s= %s;" % (
|
|
obj,
|
|
pythran_indexing_code(self.indices),
|
|
op,
|
|
rhs.pythran_result()))
|
|
return
|
|
|
|
# Used from generate_assignment_code and InPlaceAssignmentNode
|
|
buffer_entry, ptrexpr = self.buffer_lookup_code(code)
|
|
|
|
if self.buffer_type.dtype.is_pyobject:
|
|
# Must manage refcounts. Decref what is already there
|
|
# and incref what we put in.
|
|
ptr = code.funcstate.allocate_temp(buffer_entry.buf_ptr_type,
|
|
manage_ref=False)
|
|
rhs_code = rhs.result()
|
|
code.putln("%s = %s;" % (ptr, ptrexpr))
|
|
code.put_gotref("*%s" % ptr)
|
|
code.putln("__Pyx_INCREF(%s); __Pyx_DECREF(*%s);" % (
|
|
rhs_code, ptr))
|
|
code.putln("*%s %s= %s;" % (ptr, op, rhs_code))
|
|
code.put_giveref("*%s" % ptr)
|
|
code.funcstate.release_temp(ptr)
|
|
else:
|
|
# Simple case
|
|
code.putln("*%s %s= %s;" % (ptrexpr, op, rhs.result()))
|
|
|
|
def generate_result_code(self, code):
|
|
if is_pythran_expr(self.base.type):
|
|
res = self.result()
|
|
code.putln("__Pyx_call_destructor(%s);" % res)
|
|
code.putln("new (&%s) decltype(%s){%s%s};" % (
|
|
res,
|
|
res,
|
|
self.base.pythran_result(),
|
|
pythran_indexing_code(self.indices)))
|
|
return
|
|
buffer_entry, self.buffer_ptr_code = self.buffer_lookup_code(code)
|
|
if self.type.is_pyobject:
|
|
# is_temp is True, so must pull out value and incref it.
|
|
# NOTE: object temporary results for nodes are declared
|
|
# as PyObject *, so we need a cast
|
|
code.putln("%s = (PyObject *) *%s;" % (self.result(), self.buffer_ptr_code))
|
|
code.putln("__Pyx_INCREF((PyObject*)%s);" % self.result())
|
|
|
|
def free_temps(self, code):
|
|
for temp in self.index_temps:
|
|
code.funcstate.release_temp(temp)
|
|
self.index_temps = ()
|
|
super(BufferIndexNode, self).free_temps(code)
|
|
|
|
|
|
class MemoryViewIndexNode(BufferIndexNode):
|
|
|
|
is_memview_index = True
|
|
is_buffer_access = False
|
|
warned_untyped_idx = False
|
|
|
|
def analyse_types(self, env, getting=True):
|
|
# memoryviewslice indexing or slicing
|
|
from . import MemoryView
|
|
|
|
self.is_pythran_mode = has_np_pythran(env)
|
|
indices = self.indices
|
|
have_slices, indices, newaxes = MemoryView.unellipsify(indices, self.base.type.ndim)
|
|
|
|
if not getting:
|
|
self.writable_needed = True
|
|
if self.base.is_name or self.base.is_attribute:
|
|
self.base.entry.type.writable_needed = True
|
|
|
|
self.memslice_index = (not newaxes and len(indices) == self.base.type.ndim)
|
|
axes = []
|
|
|
|
index_type = PyrexTypes.c_py_ssize_t_type
|
|
new_indices = []
|
|
|
|
if len(indices) - len(newaxes) > self.base.type.ndim:
|
|
self.type = error_type
|
|
error(indices[self.base.type.ndim].pos,
|
|
"Too many indices specified for type %s" % self.base.type)
|
|
return self
|
|
|
|
axis_idx = 0
|
|
for i, index in enumerate(indices[:]):
|
|
index = index.analyse_types(env)
|
|
if index.is_none:
|
|
self.is_memview_slice = True
|
|
new_indices.append(index)
|
|
axes.append(('direct', 'strided'))
|
|
continue
|
|
|
|
access, packing = self.base.type.axes[axis_idx]
|
|
axis_idx += 1
|
|
|
|
if index.is_slice:
|
|
self.is_memview_slice = True
|
|
if index.step.is_none:
|
|
axes.append((access, packing))
|
|
else:
|
|
axes.append((access, 'strided'))
|
|
|
|
# Coerce start, stop and step to temps of the right type
|
|
for attr in ('start', 'stop', 'step'):
|
|
value = getattr(index, attr)
|
|
if not value.is_none:
|
|
value = value.coerce_to(index_type, env)
|
|
#value = value.coerce_to_temp(env)
|
|
setattr(index, attr, value)
|
|
new_indices.append(value)
|
|
|
|
elif index.type.is_int or index.type.is_pyobject:
|
|
if index.type.is_pyobject and not self.warned_untyped_idx:
|
|
warning(index.pos, "Index should be typed for more efficient access", level=2)
|
|
MemoryViewIndexNode.warned_untyped_idx = True
|
|
|
|
self.is_memview_index = True
|
|
index = index.coerce_to(index_type, env)
|
|
indices[i] = index
|
|
new_indices.append(index)
|
|
|
|
else:
|
|
self.type = error_type
|
|
error(index.pos, "Invalid index for memoryview specified, type %s" % index.type)
|
|
return self
|
|
|
|
### FIXME: replace by MemoryViewSliceNode if is_memview_slice ?
|
|
self.is_memview_index = self.is_memview_index and not self.is_memview_slice
|
|
self.indices = new_indices
|
|
# All indices with all start/stop/step for slices.
|
|
# We need to keep this around.
|
|
self.original_indices = indices
|
|
self.nogil = env.nogil
|
|
|
|
self.analyse_operation(env, getting, axes)
|
|
self.wrap_in_nonecheck_node(env)
|
|
return self
|
|
|
|
def analyse_operation(self, env, getting, axes):
|
|
self.none_error_message = "Cannot index None memoryview slice"
|
|
self.analyse_buffer_index(env, getting)
|
|
|
|
def analyse_broadcast_operation(self, rhs):
|
|
"""
|
|
Support broadcasting for slice assignment.
|
|
E.g.
|
|
m_2d[...] = m_1d # or,
|
|
m_1d[...] = m_2d # if the leading dimension has extent 1
|
|
"""
|
|
if self.type.is_memoryviewslice:
|
|
lhs = self
|
|
if lhs.is_memview_broadcast or rhs.is_memview_broadcast:
|
|
lhs.is_memview_broadcast = True
|
|
rhs.is_memview_broadcast = True
|
|
|
|
def analyse_as_memview_scalar_assignment(self, rhs):
|
|
lhs = self.analyse_assignment(rhs)
|
|
if lhs:
|
|
rhs.is_memview_copy_assignment = lhs.is_memview_copy_assignment
|
|
return lhs
|
|
return self
|
|
|
|
|
|
class MemoryViewSliceNode(MemoryViewIndexNode):
|
|
|
|
is_memview_slice = True
|
|
|
|
# No-op slicing operation, this node will be replaced
|
|
is_ellipsis_noop = False
|
|
is_memview_scalar_assignment = False
|
|
is_memview_index = False
|
|
is_memview_broadcast = False
|
|
|
|
def analyse_ellipsis_noop(self, env, getting):
|
|
"""Slicing operations needing no evaluation, i.e. m[...] or m[:, :]"""
|
|
### FIXME: replace directly
|
|
self.is_ellipsis_noop = all(
|
|
index.is_slice and index.start.is_none and index.stop.is_none and index.step.is_none
|
|
for index in self.indices)
|
|
|
|
if self.is_ellipsis_noop:
|
|
self.type = self.base.type
|
|
|
|
def analyse_operation(self, env, getting, axes):
|
|
from . import MemoryView
|
|
|
|
if not getting:
|
|
self.is_memview_broadcast = True
|
|
self.none_error_message = "Cannot assign to None memoryview slice"
|
|
else:
|
|
self.none_error_message = "Cannot slice None memoryview slice"
|
|
|
|
self.analyse_ellipsis_noop(env, getting)
|
|
if self.is_ellipsis_noop:
|
|
return
|
|
|
|
self.index = None
|
|
self.is_temp = True
|
|
self.use_managed_ref = True
|
|
|
|
if not MemoryView.validate_axes(self.pos, axes):
|
|
self.type = error_type
|
|
return
|
|
|
|
self.type = PyrexTypes.MemoryViewSliceType(self.base.type.dtype, axes)
|
|
|
|
if not (self.base.is_simple() or self.base.result_in_temp()):
|
|
self.base = self.base.coerce_to_temp(env)
|
|
|
|
def analyse_assignment(self, rhs):
|
|
if not rhs.type.is_memoryviewslice and (
|
|
self.type.dtype.assignable_from(rhs.type) or
|
|
rhs.type.is_pyobject):
|
|
# scalar assignment
|
|
return MemoryCopyScalar(self.pos, self)
|
|
else:
|
|
return MemoryCopySlice(self.pos, self)
|
|
|
|
def merged_indices(self, indices):
|
|
"""Return a new list of indices/slices with 'indices' merged into the current ones
|
|
according to slicing rules.
|
|
Is used to implement "view[i][j]" => "view[i, j]".
|
|
Return None if the indices cannot (easily) be merged at compile time.
|
|
"""
|
|
if not indices:
|
|
return None
|
|
# NOTE: Need to evaluate "self.original_indices" here as they might differ from "self.indices".
|
|
new_indices = self.original_indices[:]
|
|
indices = indices[:]
|
|
for i, s in enumerate(self.original_indices):
|
|
if s.is_slice:
|
|
if s.start.is_none and s.stop.is_none and s.step.is_none:
|
|
# Full slice found, replace by index.
|
|
new_indices[i] = indices[0]
|
|
indices.pop(0)
|
|
if not indices:
|
|
return new_indices
|
|
else:
|
|
# Found something non-trivial, e.g. a partial slice.
|
|
return None
|
|
elif not s.type.is_int:
|
|
# Not a slice, not an integer index => could be anything...
|
|
return None
|
|
if indices:
|
|
if len(new_indices) + len(indices) > self.base.type.ndim:
|
|
return None
|
|
new_indices += indices
|
|
return new_indices
|
|
|
|
def is_simple(self):
|
|
if self.is_ellipsis_noop:
|
|
# TODO: fix SimpleCallNode.is_simple()
|
|
return self.base.is_simple() or self.base.result_in_temp()
|
|
|
|
return self.result_in_temp()
|
|
|
|
def calculate_result_code(self):
|
|
"""This is called in case this is a no-op slicing node"""
|
|
return self.base.result()
|
|
|
|
def generate_result_code(self, code):
|
|
if self.is_ellipsis_noop:
|
|
return ### FIXME: remove
|
|
buffer_entry = self.buffer_entry()
|
|
have_gil = not self.in_nogil_context
|
|
|
|
# TODO Mark: this is insane, do it better
|
|
have_slices = False
|
|
it = iter(self.indices)
|
|
for index in self.original_indices:
|
|
if index.is_slice:
|
|
have_slices = True
|
|
if not index.start.is_none:
|
|
index.start = next(it)
|
|
if not index.stop.is_none:
|
|
index.stop = next(it)
|
|
if not index.step.is_none:
|
|
index.step = next(it)
|
|
else:
|
|
next(it)
|
|
|
|
assert not list(it)
|
|
|
|
buffer_entry.generate_buffer_slice_code(
|
|
code, self.original_indices, self.result(),
|
|
have_gil=have_gil, have_slices=have_slices,
|
|
directives=code.globalstate.directives)
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False):
|
|
if self.is_ellipsis_noop:
|
|
self.generate_subexpr_evaluation_code(code)
|
|
else:
|
|
self.generate_evaluation_code(code)
|
|
|
|
if self.is_memview_scalar_assignment:
|
|
self.generate_memoryviewslice_assign_scalar_code(rhs, code)
|
|
else:
|
|
self.generate_memoryviewslice_setslice_code(rhs, code)
|
|
|
|
if self.is_ellipsis_noop:
|
|
self.generate_subexpr_disposal_code(code)
|
|
else:
|
|
self.generate_disposal_code(code)
|
|
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
|
|
|
|
class MemoryCopyNode(ExprNode):
|
|
"""
|
|
Wraps a memoryview slice for slice assignment.
|
|
|
|
dst: destination mememoryview slice
|
|
"""
|
|
|
|
subexprs = ['dst']
|
|
|
|
def __init__(self, pos, dst):
|
|
super(MemoryCopyNode, self).__init__(pos)
|
|
self.dst = dst
|
|
self.type = dst.type
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False):
|
|
self.dst.generate_evaluation_code(code)
|
|
self._generate_assignment_code(rhs, code)
|
|
self.dst.generate_disposal_code(code)
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
|
|
|
|
class MemoryCopySlice(MemoryCopyNode):
|
|
"""
|
|
Copy the contents of slice src to slice dst. Does not support indirect
|
|
slices.
|
|
|
|
memslice1[...] = memslice2
|
|
memslice1[:] = memslice2
|
|
"""
|
|
|
|
is_memview_copy_assignment = True
|
|
copy_slice_cname = "__pyx_memoryview_copy_contents"
|
|
|
|
def _generate_assignment_code(self, src, code):
|
|
dst = self.dst
|
|
|
|
src.type.assert_direct_dims(src.pos)
|
|
dst.type.assert_direct_dims(dst.pos)
|
|
|
|
code.putln(code.error_goto_if_neg(
|
|
"%s(%s, %s, %d, %d, %d)" % (self.copy_slice_cname,
|
|
src.result(), dst.result(),
|
|
src.type.ndim, dst.type.ndim,
|
|
dst.type.dtype.is_pyobject),
|
|
dst.pos))
|
|
|
|
|
|
class MemoryCopyScalar(MemoryCopyNode):
|
|
"""
|
|
Assign a scalar to a slice. dst must be simple, scalar will be assigned
|
|
to a correct type and not just something assignable.
|
|
|
|
memslice1[...] = 0.0
|
|
memslice1[:] = 0.0
|
|
"""
|
|
|
|
def __init__(self, pos, dst):
|
|
super(MemoryCopyScalar, self).__init__(pos, dst)
|
|
self.type = dst.type.dtype
|
|
|
|
def _generate_assignment_code(self, scalar, code):
|
|
from . import MemoryView
|
|
|
|
self.dst.type.assert_direct_dims(self.dst.pos)
|
|
|
|
dtype = self.dst.type.dtype
|
|
type_decl = dtype.declaration_code("")
|
|
slice_decl = self.dst.type.declaration_code("")
|
|
|
|
code.begin_block()
|
|
code.putln("%s __pyx_temp_scalar = %s;" % (type_decl, scalar.result()))
|
|
if self.dst.result_in_temp() or self.dst.is_simple():
|
|
dst_temp = self.dst.result()
|
|
else:
|
|
code.putln("%s __pyx_temp_slice = %s;" % (slice_decl, self.dst.result()))
|
|
dst_temp = "__pyx_temp_slice"
|
|
|
|
slice_iter_obj = MemoryView.slice_iter(self.dst.type, dst_temp,
|
|
self.dst.type.ndim, code)
|
|
p = slice_iter_obj.start_loops()
|
|
|
|
if dtype.is_pyobject:
|
|
code.putln("Py_DECREF(*(PyObject **) %s);" % p)
|
|
|
|
code.putln("*((%s *) %s) = __pyx_temp_scalar;" % (type_decl, p))
|
|
|
|
if dtype.is_pyobject:
|
|
code.putln("Py_INCREF(__pyx_temp_scalar);")
|
|
|
|
slice_iter_obj.end_loops()
|
|
code.end_block()
|
|
|
|
|
|
class SliceIndexNode(ExprNode):
|
|
# 2-element slice indexing
|
|
#
|
|
# base ExprNode
|
|
# start ExprNode or None
|
|
# stop ExprNode or None
|
|
# slice ExprNode or None constant slice object
|
|
|
|
subexprs = ['base', 'start', 'stop', 'slice']
|
|
|
|
slice = None
|
|
|
|
def infer_type(self, env):
|
|
base_type = self.base.infer_type(env)
|
|
if base_type.is_string or base_type.is_cpp_class:
|
|
return bytes_type
|
|
elif base_type.is_pyunicode_ptr:
|
|
return unicode_type
|
|
elif base_type in (bytes_type, bytearray_type, str_type, unicode_type,
|
|
basestring_type, list_type, tuple_type):
|
|
return base_type
|
|
elif base_type.is_ptr or base_type.is_array:
|
|
return PyrexTypes.c_array_type(base_type.base_type, None)
|
|
return py_object_type
|
|
|
|
def inferable_item_node(self, index=0):
|
|
# slicing shouldn't change the result type of the base, but the index might
|
|
if index is not not_a_constant and self.start:
|
|
if self.start.has_constant_result():
|
|
index += self.start.constant_result
|
|
else:
|
|
index = not_a_constant
|
|
return self.base.inferable_item_node(index)
|
|
|
|
def may_be_none(self):
|
|
base_type = self.base.type
|
|
if base_type:
|
|
if base_type.is_string:
|
|
return False
|
|
if base_type in (bytes_type, str_type, unicode_type,
|
|
basestring_type, list_type, tuple_type):
|
|
return False
|
|
return ExprNode.may_be_none(self)
|
|
|
|
def calculate_constant_result(self):
|
|
if self.start is None:
|
|
start = None
|
|
else:
|
|
start = self.start.constant_result
|
|
if self.stop is None:
|
|
stop = None
|
|
else:
|
|
stop = self.stop.constant_result
|
|
self.constant_result = self.base.constant_result[start:stop]
|
|
|
|
def compile_time_value(self, denv):
|
|
base = self.base.compile_time_value(denv)
|
|
if self.start is None:
|
|
start = 0
|
|
else:
|
|
start = self.start.compile_time_value(denv)
|
|
if self.stop is None:
|
|
stop = None
|
|
else:
|
|
stop = self.stop.compile_time_value(denv)
|
|
try:
|
|
return base[start:stop]
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def analyse_target_declaration(self, env):
|
|
pass
|
|
|
|
def analyse_target_types(self, env):
|
|
node = self.analyse_types(env, getting=False)
|
|
# when assigning, we must accept any Python type
|
|
if node.type.is_pyobject:
|
|
node.type = py_object_type
|
|
return node
|
|
|
|
def analyse_types(self, env, getting=True):
|
|
self.base = self.base.analyse_types(env)
|
|
|
|
if self.base.type.is_buffer or self.base.type.is_pythran_expr or self.base.type.is_memoryviewslice:
|
|
none_node = NoneNode(self.pos)
|
|
index = SliceNode(self.pos,
|
|
start=self.start or none_node,
|
|
stop=self.stop or none_node,
|
|
step=none_node)
|
|
index_node = IndexNode(self.pos, index=index, base=self.base)
|
|
return index_node.analyse_base_and_index_types(
|
|
env, getting=getting, setting=not getting,
|
|
analyse_base=False)
|
|
|
|
if self.start:
|
|
self.start = self.start.analyse_types(env)
|
|
if self.stop:
|
|
self.stop = self.stop.analyse_types(env)
|
|
|
|
if not env.directives['wraparound']:
|
|
check_negative_indices(self.start, self.stop)
|
|
|
|
base_type = self.base.type
|
|
if base_type.is_array and not getting:
|
|
# cannot assign directly to C array => try to assign by making a copy
|
|
if not self.start and not self.stop:
|
|
self.type = base_type
|
|
else:
|
|
self.type = PyrexTypes.CPtrType(base_type.base_type)
|
|
elif base_type.is_string or base_type.is_cpp_string:
|
|
self.type = default_str_type(env)
|
|
elif base_type.is_pyunicode_ptr:
|
|
self.type = unicode_type
|
|
elif base_type.is_ptr:
|
|
self.type = base_type
|
|
elif base_type.is_array:
|
|
# we need a ptr type here instead of an array type, as
|
|
# array types can result in invalid type casts in the C
|
|
# code
|
|
self.type = PyrexTypes.CPtrType(base_type.base_type)
|
|
else:
|
|
self.base = self.base.coerce_to_pyobject(env)
|
|
self.type = py_object_type
|
|
if base_type.is_builtin_type:
|
|
# slicing builtin types returns something of the same type
|
|
self.type = base_type
|
|
self.base = self.base.as_none_safe_node("'NoneType' object is not subscriptable")
|
|
|
|
if self.type is py_object_type:
|
|
if (not self.start or self.start.is_literal) and \
|
|
(not self.stop or self.stop.is_literal):
|
|
# cache the constant slice object, in case we need it
|
|
none_node = NoneNode(self.pos)
|
|
self.slice = SliceNode(
|
|
self.pos,
|
|
start=copy.deepcopy(self.start or none_node),
|
|
stop=copy.deepcopy(self.stop or none_node),
|
|
step=none_node
|
|
).analyse_types(env)
|
|
else:
|
|
c_int = PyrexTypes.c_py_ssize_t_type
|
|
|
|
def allow_none(node, default_value, env):
|
|
# Coerce to Py_ssize_t, but allow None as meaning the default slice bound.
|
|
from .UtilNodes import EvalWithTempExprNode, ResultRefNode
|
|
|
|
node_ref = ResultRefNode(node)
|
|
new_expr = CondExprNode(
|
|
node.pos,
|
|
true_val=IntNode(
|
|
node.pos,
|
|
type=c_int,
|
|
value=default_value,
|
|
constant_result=int(default_value) if default_value.isdigit() else not_a_constant,
|
|
),
|
|
false_val=node_ref.coerce_to(c_int, env),
|
|
test=PrimaryCmpNode(
|
|
node.pos,
|
|
operand1=node_ref,
|
|
operator='is',
|
|
operand2=NoneNode(node.pos),
|
|
).analyse_types(env)
|
|
).analyse_result_type(env)
|
|
return EvalWithTempExprNode(node_ref, new_expr)
|
|
|
|
if self.start:
|
|
if self.start.type.is_pyobject:
|
|
self.start = allow_none(self.start, '0', env)
|
|
self.start = self.start.coerce_to(c_int, env)
|
|
if self.stop:
|
|
if self.stop.type.is_pyobject:
|
|
self.stop = allow_none(self.stop, 'PY_SSIZE_T_MAX', env)
|
|
self.stop = self.stop.coerce_to(c_int, env)
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
def analyse_as_type(self, env):
|
|
base_type = self.base.analyse_as_type(env)
|
|
if base_type and not base_type.is_pyobject:
|
|
if not self.start and not self.stop:
|
|
# memory view
|
|
from . import MemoryView
|
|
env.use_utility_code(MemoryView.view_utility_code)
|
|
none_node = NoneNode(self.pos)
|
|
slice_node = SliceNode(
|
|
self.pos,
|
|
start=none_node,
|
|
stop=none_node,
|
|
step=none_node,
|
|
)
|
|
return PyrexTypes.MemoryViewSliceType(
|
|
base_type, MemoryView.get_axes_specs(env, [slice_node]))
|
|
return None
|
|
|
|
nogil_check = Node.gil_error
|
|
gil_message = "Slicing Python object"
|
|
|
|
get_slice_utility_code = TempitaUtilityCode.load(
|
|
"SliceObject", "ObjectHandling.c", context={'access': 'Get'})
|
|
|
|
set_slice_utility_code = TempitaUtilityCode.load(
|
|
"SliceObject", "ObjectHandling.c", context={'access': 'Set'})
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if ((self.base.type.is_string or self.base.type.is_cpp_string)
|
|
and dst_type in (bytes_type, bytearray_type, str_type, unicode_type)):
|
|
if (dst_type not in (bytes_type, bytearray_type)
|
|
and not env.directives['c_string_encoding']):
|
|
error(self.pos,
|
|
"default encoding required for conversion from '%s' to '%s'" %
|
|
(self.base.type, dst_type))
|
|
self.type = dst_type
|
|
if dst_type.is_array and self.base.type.is_array:
|
|
if not self.start and not self.stop:
|
|
# redundant slice building, copy C arrays directly
|
|
return self.base.coerce_to(dst_type, env)
|
|
# else: check array size if possible
|
|
return super(SliceIndexNode, self).coerce_to(dst_type, env)
|
|
|
|
def generate_result_code(self, code):
|
|
if not self.type.is_pyobject:
|
|
error(self.pos,
|
|
"Slicing is not currently supported for '%s'." % self.type)
|
|
return
|
|
|
|
base_result = self.base.result()
|
|
result = self.result()
|
|
start_code = self.start_code()
|
|
stop_code = self.stop_code()
|
|
if self.base.type.is_string:
|
|
base_result = self.base.result()
|
|
if self.base.type not in (PyrexTypes.c_char_ptr_type, PyrexTypes.c_const_char_ptr_type):
|
|
base_result = '((const char*)%s)' % base_result
|
|
if self.type is bytearray_type:
|
|
type_name = 'ByteArray'
|
|
else:
|
|
type_name = self.type.name.title()
|
|
if self.stop is None:
|
|
code.putln(
|
|
"%s = __Pyx_Py%s_FromString(%s + %s); %s" % (
|
|
result,
|
|
type_name,
|
|
base_result,
|
|
start_code,
|
|
code.error_goto_if_null(result, self.pos)))
|
|
else:
|
|
code.putln(
|
|
"%s = __Pyx_Py%s_FromStringAndSize(%s + %s, %s - %s); %s" % (
|
|
result,
|
|
type_name,
|
|
base_result,
|
|
start_code,
|
|
stop_code,
|
|
start_code,
|
|
code.error_goto_if_null(result, self.pos)))
|
|
elif self.base.type.is_pyunicode_ptr:
|
|
base_result = self.base.result()
|
|
if self.base.type != PyrexTypes.c_py_unicode_ptr_type:
|
|
base_result = '((const Py_UNICODE*)%s)' % base_result
|
|
if self.stop is None:
|
|
code.putln(
|
|
"%s = __Pyx_PyUnicode_FromUnicode(%s + %s); %s" % (
|
|
result,
|
|
base_result,
|
|
start_code,
|
|
code.error_goto_if_null(result, self.pos)))
|
|
else:
|
|
code.putln(
|
|
"%s = __Pyx_PyUnicode_FromUnicodeAndLength(%s + %s, %s - %s); %s" % (
|
|
result,
|
|
base_result,
|
|
start_code,
|
|
stop_code,
|
|
start_code,
|
|
code.error_goto_if_null(result, self.pos)))
|
|
|
|
elif self.base.type is unicode_type:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyUnicode_Substring", "StringTools.c"))
|
|
code.putln(
|
|
"%s = __Pyx_PyUnicode_Substring(%s, %s, %s); %s" % (
|
|
result,
|
|
base_result,
|
|
start_code,
|
|
stop_code,
|
|
code.error_goto_if_null(result, self.pos)))
|
|
elif self.type is py_object_type:
|
|
code.globalstate.use_utility_code(self.get_slice_utility_code)
|
|
(has_c_start, has_c_stop, c_start, c_stop,
|
|
py_start, py_stop, py_slice) = self.get_slice_config()
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_GetSlice(%s, %s, %s, %s, %s, %s, %d, %d, %d); %s" % (
|
|
result,
|
|
self.base.py_result(),
|
|
c_start, c_stop,
|
|
py_start, py_stop, py_slice,
|
|
has_c_start, has_c_stop,
|
|
bool(code.globalstate.directives['wraparound']),
|
|
code.error_goto_if_null(result, self.pos)))
|
|
else:
|
|
if self.base.type is list_type:
|
|
code.globalstate.use_utility_code(
|
|
TempitaUtilityCode.load_cached("SliceTupleAndList", "ObjectHandling.c"))
|
|
cfunc = '__Pyx_PyList_GetSlice'
|
|
elif self.base.type is tuple_type:
|
|
code.globalstate.use_utility_code(
|
|
TempitaUtilityCode.load_cached("SliceTupleAndList", "ObjectHandling.c"))
|
|
cfunc = '__Pyx_PyTuple_GetSlice'
|
|
else:
|
|
cfunc = 'PySequence_GetSlice'
|
|
code.putln(
|
|
"%s = %s(%s, %s, %s); %s" % (
|
|
result,
|
|
cfunc,
|
|
self.base.py_result(),
|
|
start_code,
|
|
stop_code,
|
|
code.error_goto_if_null(result, self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False,
|
|
exception_check=None, exception_value=None):
|
|
self.generate_subexpr_evaluation_code(code)
|
|
if self.type.is_pyobject:
|
|
code.globalstate.use_utility_code(self.set_slice_utility_code)
|
|
(has_c_start, has_c_stop, c_start, c_stop,
|
|
py_start, py_stop, py_slice) = self.get_slice_config()
|
|
code.put_error_if_neg(self.pos,
|
|
"__Pyx_PyObject_SetSlice(%s, %s, %s, %s, %s, %s, %s, %d, %d, %d)" % (
|
|
self.base.py_result(),
|
|
rhs.py_result(),
|
|
c_start, c_stop,
|
|
py_start, py_stop, py_slice,
|
|
has_c_start, has_c_stop,
|
|
bool(code.globalstate.directives['wraparound'])))
|
|
else:
|
|
start_offset = self.start_code() if self.start else '0'
|
|
if rhs.type.is_array:
|
|
array_length = rhs.type.size
|
|
self.generate_slice_guard_code(code, array_length)
|
|
else:
|
|
array_length = '%s - %s' % (self.stop_code(), start_offset)
|
|
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("IncludeStringH", "StringTools.c"))
|
|
code.putln("memcpy(&(%s[%s]), %s, sizeof(%s[0]) * (%s));" % (
|
|
self.base.result(), start_offset,
|
|
rhs.result(),
|
|
self.base.result(), array_length
|
|
))
|
|
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
|
|
def generate_deletion_code(self, code, ignore_nonexisting=False):
|
|
if not self.base.type.is_pyobject:
|
|
error(self.pos,
|
|
"Deleting slices is only supported for Python types, not '%s'." % self.type)
|
|
return
|
|
self.generate_subexpr_evaluation_code(code)
|
|
code.globalstate.use_utility_code(self.set_slice_utility_code)
|
|
(has_c_start, has_c_stop, c_start, c_stop,
|
|
py_start, py_stop, py_slice) = self.get_slice_config()
|
|
code.put_error_if_neg(self.pos,
|
|
"__Pyx_PyObject_DelSlice(%s, %s, %s, %s, %s, %s, %d, %d, %d)" % (
|
|
self.base.py_result(),
|
|
c_start, c_stop,
|
|
py_start, py_stop, py_slice,
|
|
has_c_start, has_c_stop,
|
|
bool(code.globalstate.directives['wraparound'])))
|
|
self.generate_subexpr_disposal_code(code)
|
|
self.free_subexpr_temps(code)
|
|
|
|
def get_slice_config(self):
|
|
has_c_start, c_start, py_start = False, '0', 'NULL'
|
|
if self.start:
|
|
has_c_start = not self.start.type.is_pyobject
|
|
if has_c_start:
|
|
c_start = self.start.result()
|
|
else:
|
|
py_start = '&%s' % self.start.py_result()
|
|
has_c_stop, c_stop, py_stop = False, '0', 'NULL'
|
|
if self.stop:
|
|
has_c_stop = not self.stop.type.is_pyobject
|
|
if has_c_stop:
|
|
c_stop = self.stop.result()
|
|
else:
|
|
py_stop = '&%s' % self.stop.py_result()
|
|
py_slice = self.slice and '&%s' % self.slice.py_result() or 'NULL'
|
|
return (has_c_start, has_c_stop, c_start, c_stop,
|
|
py_start, py_stop, py_slice)
|
|
|
|
def generate_slice_guard_code(self, code, target_size):
|
|
if not self.base.type.is_array:
|
|
return
|
|
slice_size = self.base.type.size
|
|
try:
|
|
total_length = slice_size = int(slice_size)
|
|
except ValueError:
|
|
total_length = None
|
|
|
|
start = stop = None
|
|
if self.stop:
|
|
stop = self.stop.result()
|
|
try:
|
|
stop = int(stop)
|
|
if stop < 0:
|
|
if total_length is None:
|
|
slice_size = '%s + %d' % (slice_size, stop)
|
|
else:
|
|
slice_size += stop
|
|
else:
|
|
slice_size = stop
|
|
stop = None
|
|
except ValueError:
|
|
pass
|
|
|
|
if self.start:
|
|
start = self.start.result()
|
|
try:
|
|
start = int(start)
|
|
if start < 0:
|
|
if total_length is None:
|
|
start = '%s + %d' % (self.base.type.size, start)
|
|
else:
|
|
start += total_length
|
|
if isinstance(slice_size, _py_int_types):
|
|
slice_size -= start
|
|
else:
|
|
slice_size = '%s - (%s)' % (slice_size, start)
|
|
start = None
|
|
except ValueError:
|
|
pass
|
|
|
|
runtime_check = None
|
|
compile_time_check = False
|
|
try:
|
|
int_target_size = int(target_size)
|
|
except ValueError:
|
|
int_target_size = None
|
|
else:
|
|
compile_time_check = isinstance(slice_size, _py_int_types)
|
|
|
|
if compile_time_check and slice_size < 0:
|
|
if int_target_size > 0:
|
|
error(self.pos, "Assignment to empty slice.")
|
|
elif compile_time_check and start is None and stop is None:
|
|
# we know the exact slice length
|
|
if int_target_size != slice_size:
|
|
error(self.pos, "Assignment to slice of wrong length, expected %s, got %s" % (
|
|
slice_size, target_size))
|
|
elif start is not None:
|
|
if stop is None:
|
|
stop = slice_size
|
|
runtime_check = "(%s)-(%s)" % (stop, start)
|
|
elif stop is not None:
|
|
runtime_check = stop
|
|
else:
|
|
runtime_check = slice_size
|
|
|
|
if runtime_check:
|
|
code.putln("if (unlikely((%s) != (%s))) {" % (runtime_check, target_size))
|
|
code.putln(
|
|
'PyErr_Format(PyExc_ValueError, "Assignment to slice of wrong length,'
|
|
' expected %%" CYTHON_FORMAT_SSIZE_T "d, got %%" CYTHON_FORMAT_SSIZE_T "d",'
|
|
' (Py_ssize_t)(%s), (Py_ssize_t)(%s));' % (
|
|
target_size, runtime_check))
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
|
|
def start_code(self):
|
|
if self.start:
|
|
return self.start.result()
|
|
else:
|
|
return "0"
|
|
|
|
def stop_code(self):
|
|
if self.stop:
|
|
return self.stop.result()
|
|
elif self.base.type.is_array:
|
|
return self.base.type.size
|
|
else:
|
|
return "PY_SSIZE_T_MAX"
|
|
|
|
def calculate_result_code(self):
|
|
# self.result() is not used, but this method must exist
|
|
return "<unused>"
|
|
|
|
|
|
class SliceNode(ExprNode):
|
|
# start:stop:step in subscript list
|
|
#
|
|
# start ExprNode
|
|
# stop ExprNode
|
|
# step ExprNode
|
|
|
|
subexprs = ['start', 'stop', 'step']
|
|
is_slice = True
|
|
type = slice_type
|
|
is_temp = 1
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = slice(
|
|
self.start.constant_result,
|
|
self.stop.constant_result,
|
|
self.step.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
start = self.start.compile_time_value(denv)
|
|
stop = self.stop.compile_time_value(denv)
|
|
step = self.step.compile_time_value(denv)
|
|
try:
|
|
return slice(start, stop, step)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def analyse_types(self, env):
|
|
start = self.start.analyse_types(env)
|
|
stop = self.stop.analyse_types(env)
|
|
step = self.step.analyse_types(env)
|
|
self.start = start.coerce_to_pyobject(env)
|
|
self.stop = stop.coerce_to_pyobject(env)
|
|
self.step = step.coerce_to_pyobject(env)
|
|
if self.start.is_literal and self.stop.is_literal and self.step.is_literal:
|
|
self.is_literal = True
|
|
self.is_temp = False
|
|
return self
|
|
|
|
gil_message = "Constructing Python slice object"
|
|
|
|
def calculate_result_code(self):
|
|
return self.result_code
|
|
|
|
def generate_result_code(self, code):
|
|
if self.is_literal:
|
|
dedup_key = make_dedup_key(self.type, (self,))
|
|
self.result_code = code.get_py_const(py_object_type, 'slice', cleanup_level=2, dedup_key=dedup_key)
|
|
code = code.get_cached_constants_writer(self.result_code)
|
|
if code is None:
|
|
return # already initialised
|
|
code.mark_pos(self.pos)
|
|
|
|
code.putln(
|
|
"%s = PySlice_New(%s, %s, %s); %s" % (
|
|
self.result(),
|
|
self.start.py_result(),
|
|
self.stop.py_result(),
|
|
self.step.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
if self.is_literal:
|
|
code.put_giveref(self.py_result())
|
|
|
|
class SliceIntNode(SliceNode):
|
|
# start:stop:step in subscript list
|
|
# This is just a node to hold start,stop and step nodes that can be
|
|
# converted to integers. This does not generate a slice python object.
|
|
#
|
|
# start ExprNode
|
|
# stop ExprNode
|
|
# step ExprNode
|
|
|
|
is_temp = 0
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = slice(
|
|
self.start.constant_result,
|
|
self.stop.constant_result,
|
|
self.step.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
start = self.start.compile_time_value(denv)
|
|
stop = self.stop.compile_time_value(denv)
|
|
step = self.step.compile_time_value(denv)
|
|
try:
|
|
return slice(start, stop, step)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def analyse_types(self, env):
|
|
self.start = self.start.analyse_types(env)
|
|
self.stop = self.stop.analyse_types(env)
|
|
self.step = self.step.analyse_types(env)
|
|
|
|
if not self.start.is_none:
|
|
self.start = self.start.coerce_to_integer(env)
|
|
if not self.stop.is_none:
|
|
self.stop = self.stop.coerce_to_integer(env)
|
|
if not self.step.is_none:
|
|
self.step = self.step.coerce_to_integer(env)
|
|
|
|
if self.start.is_literal and self.stop.is_literal and self.step.is_literal:
|
|
self.is_literal = True
|
|
self.is_temp = False
|
|
return self
|
|
|
|
def calculate_result_code(self):
|
|
pass
|
|
|
|
def generate_result_code(self, code):
|
|
for a in self.start,self.stop,self.step:
|
|
if isinstance(a, CloneNode):
|
|
a.arg.result()
|
|
|
|
|
|
class CallNode(ExprNode):
|
|
|
|
# allow overriding the default 'may_be_none' behaviour
|
|
may_return_none = None
|
|
|
|
def infer_type(self, env):
|
|
# TODO(robertwb): Reduce redundancy with analyse_types.
|
|
function = self.function
|
|
func_type = function.infer_type(env)
|
|
if isinstance(function, NewExprNode):
|
|
# note: needs call to infer_type() above
|
|
return PyrexTypes.CPtrType(function.class_type)
|
|
if func_type is py_object_type:
|
|
# function might have lied for safety => try to find better type
|
|
entry = getattr(function, 'entry', None)
|
|
if entry is not None:
|
|
func_type = entry.type or func_type
|
|
if func_type.is_ptr:
|
|
func_type = func_type.base_type
|
|
if func_type.is_cfunction:
|
|
if getattr(self.function, 'entry', None) and hasattr(self, 'args'):
|
|
alternatives = self.function.entry.all_alternatives()
|
|
arg_types = [arg.infer_type(env) for arg in self.args]
|
|
func_entry = PyrexTypes.best_match(arg_types, alternatives)
|
|
if func_entry:
|
|
func_type = func_entry.type
|
|
if func_type.is_ptr:
|
|
func_type = func_type.base_type
|
|
return func_type.return_type
|
|
return func_type.return_type
|
|
elif func_type is type_type:
|
|
if function.is_name and function.entry and function.entry.type:
|
|
result_type = function.entry.type
|
|
if result_type.is_extension_type:
|
|
return result_type
|
|
elif result_type.is_builtin_type:
|
|
if function.entry.name == 'float':
|
|
return PyrexTypes.c_double_type
|
|
elif function.entry.name in Builtin.types_that_construct_their_instance:
|
|
return result_type
|
|
return py_object_type
|
|
|
|
def type_dependencies(self, env):
|
|
# TODO: Update when Danilo's C++ code merged in to handle the
|
|
# the case of function overloading.
|
|
return self.function.type_dependencies(env)
|
|
|
|
def is_simple(self):
|
|
# C function calls could be considered simple, but they may
|
|
# have side-effects that may hit when multiple operations must
|
|
# be effected in order, e.g. when constructing the argument
|
|
# sequence for a function call or comparing values.
|
|
return False
|
|
|
|
def may_be_none(self):
|
|
if self.may_return_none is not None:
|
|
return self.may_return_none
|
|
func_type = self.function.type
|
|
if func_type is type_type and self.function.is_name:
|
|
entry = self.function.entry
|
|
if entry.type.is_extension_type:
|
|
return False
|
|
if (entry.type.is_builtin_type and
|
|
entry.name in Builtin.types_that_construct_their_instance):
|
|
return False
|
|
return ExprNode.may_be_none(self)
|
|
|
|
def set_py_result_type(self, function, func_type=None):
|
|
if func_type is None:
|
|
func_type = function.type
|
|
if func_type is Builtin.type_type and (
|
|
function.is_name and
|
|
function.entry and
|
|
function.entry.is_builtin and
|
|
function.entry.name in Builtin.types_that_construct_their_instance):
|
|
# calling a builtin type that returns a specific object type
|
|
if function.entry.name == 'float':
|
|
# the following will come true later on in a transform
|
|
self.type = PyrexTypes.c_double_type
|
|
self.result_ctype = PyrexTypes.c_double_type
|
|
else:
|
|
self.type = Builtin.builtin_types[function.entry.name]
|
|
self.result_ctype = py_object_type
|
|
self.may_return_none = False
|
|
elif function.is_name and function.type_entry:
|
|
# We are calling an extension type constructor. As long as we do not
|
|
# support __new__(), the result type is clear
|
|
self.type = function.type_entry.type
|
|
self.result_ctype = py_object_type
|
|
self.may_return_none = False
|
|
else:
|
|
self.type = py_object_type
|
|
|
|
def analyse_as_type_constructor(self, env):
|
|
type = self.function.analyse_as_type(env)
|
|
if type and type.is_struct_or_union:
|
|
args, kwds = self.explicit_args_kwds()
|
|
items = []
|
|
for arg, member in zip(args, type.scope.var_entries):
|
|
items.append(DictItemNode(pos=arg.pos, key=StringNode(pos=arg.pos, value=member.name), value=arg))
|
|
if kwds:
|
|
items += kwds.key_value_pairs
|
|
self.key_value_pairs = items
|
|
self.__class__ = DictNode
|
|
self.analyse_types(env) # FIXME
|
|
self.coerce_to(type, env)
|
|
return True
|
|
elif type and type.is_cpp_class:
|
|
self.args = [ arg.analyse_types(env) for arg in self.args ]
|
|
constructor = type.scope.lookup("<init>")
|
|
if not constructor:
|
|
error(self.function.pos, "no constructor found for C++ type '%s'" % self.function.name)
|
|
self.type = error_type
|
|
return self
|
|
self.function = RawCNameExprNode(self.function.pos, constructor.type)
|
|
self.function.entry = constructor
|
|
self.function.set_cname(type.empty_declaration_code())
|
|
self.analyse_c_function_call(env)
|
|
self.type = type
|
|
return True
|
|
|
|
def is_lvalue(self):
|
|
return self.type.is_reference
|
|
|
|
def nogil_check(self, env):
|
|
func_type = self.function_type()
|
|
if func_type.is_pyobject:
|
|
self.gil_error()
|
|
elif not getattr(func_type, 'nogil', False):
|
|
self.gil_error()
|
|
|
|
gil_message = "Calling gil-requiring function"
|
|
|
|
|
|
class SimpleCallNode(CallNode):
|
|
# Function call without keyword, * or ** args.
|
|
#
|
|
# function ExprNode
|
|
# args [ExprNode]
|
|
# arg_tuple ExprNode or None used internally
|
|
# self ExprNode or None used internally
|
|
# coerced_self ExprNode or None used internally
|
|
# wrapper_call bool used internally
|
|
# has_optional_args bool used internally
|
|
# nogil bool used internally
|
|
|
|
subexprs = ['self', 'coerced_self', 'function', 'args', 'arg_tuple']
|
|
|
|
self = None
|
|
coerced_self = None
|
|
arg_tuple = None
|
|
wrapper_call = False
|
|
has_optional_args = False
|
|
nogil = False
|
|
analysed = False
|
|
overflowcheck = False
|
|
|
|
def compile_time_value(self, denv):
|
|
function = self.function.compile_time_value(denv)
|
|
args = [arg.compile_time_value(denv) for arg in self.args]
|
|
try:
|
|
return function(*args)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def analyse_as_type(self, env):
|
|
attr = self.function.as_cython_attribute()
|
|
if attr == 'pointer':
|
|
if len(self.args) != 1:
|
|
error(self.args.pos, "only one type allowed.")
|
|
else:
|
|
type = self.args[0].analyse_as_type(env)
|
|
if not type:
|
|
error(self.args[0].pos, "Unknown type")
|
|
else:
|
|
return PyrexTypes.CPtrType(type)
|
|
elif attr == 'typeof':
|
|
if len(self.args) != 1:
|
|
error(self.args.pos, "only one type allowed.")
|
|
operand = self.args[0].analyse_types(env)
|
|
return operand.type
|
|
|
|
def explicit_args_kwds(self):
|
|
return self.args, None
|
|
|
|
def analyse_types(self, env):
|
|
if self.analyse_as_type_constructor(env):
|
|
return self
|
|
if self.analysed:
|
|
return self
|
|
self.analysed = True
|
|
self.function.is_called = 1
|
|
self.function = self.function.analyse_types(env)
|
|
function = self.function
|
|
|
|
if function.is_attribute and function.entry and function.entry.is_cmethod:
|
|
# Take ownership of the object from which the attribute
|
|
# was obtained, because we need to pass it as 'self'.
|
|
self.self = function.obj
|
|
function.obj = CloneNode(self.self)
|
|
|
|
func_type = self.function_type()
|
|
self.is_numpy_call_with_exprs = False
|
|
if (has_np_pythran(env) and function.is_numpy_attribute and
|
|
pythran_is_numpy_func_supported(function)):
|
|
has_pythran_args = True
|
|
self.arg_tuple = TupleNode(self.pos, args = self.args)
|
|
self.arg_tuple = self.arg_tuple.analyse_types(env)
|
|
for arg in self.arg_tuple.args:
|
|
has_pythran_args &= is_pythran_supported_node_or_none(arg)
|
|
self.is_numpy_call_with_exprs = bool(has_pythran_args)
|
|
if self.is_numpy_call_with_exprs:
|
|
env.add_include_file(pythran_get_func_include_file(function))
|
|
return NumPyMethodCallNode.from_node(
|
|
self,
|
|
function=function,
|
|
arg_tuple=self.arg_tuple,
|
|
type=PythranExpr(pythran_func_type(function, self.arg_tuple.args)),
|
|
)
|
|
elif func_type.is_pyobject:
|
|
self.arg_tuple = TupleNode(self.pos, args = self.args)
|
|
self.arg_tuple = self.arg_tuple.analyse_types(env).coerce_to_pyobject(env)
|
|
self.args = None
|
|
self.set_py_result_type(function, func_type)
|
|
self.is_temp = 1
|
|
else:
|
|
self.args = [ arg.analyse_types(env) for arg in self.args ]
|
|
self.analyse_c_function_call(env)
|
|
if func_type.exception_check == '+':
|
|
self.is_temp = True
|
|
return self
|
|
|
|
def function_type(self):
|
|
# Return the type of the function being called, coercing a function
|
|
# pointer to a function if necessary. If the function has fused
|
|
# arguments, return the specific type.
|
|
func_type = self.function.type
|
|
|
|
if func_type.is_ptr:
|
|
func_type = func_type.base_type
|
|
|
|
return func_type
|
|
|
|
def analyse_c_function_call(self, env):
|
|
func_type = self.function.type
|
|
if func_type is error_type:
|
|
self.type = error_type
|
|
return
|
|
|
|
if func_type.is_cfunction and func_type.is_static_method:
|
|
if self.self and self.self.type.is_extension_type:
|
|
# To support this we'd need to pass self to determine whether
|
|
# it was overloaded in Python space (possibly via a Cython
|
|
# superclass turning a cdef method into a cpdef one).
|
|
error(self.pos, "Cannot call a static method on an instance variable.")
|
|
args = self.args
|
|
elif self.self:
|
|
args = [self.self] + self.args
|
|
else:
|
|
args = self.args
|
|
|
|
if func_type.is_cpp_class:
|
|
overloaded_entry = self.function.type.scope.lookup("operator()")
|
|
if overloaded_entry is None:
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
return
|
|
elif hasattr(self.function, 'entry'):
|
|
overloaded_entry = self.function.entry
|
|
elif self.function.is_subscript and self.function.is_fused_index:
|
|
overloaded_entry = self.function.type.entry
|
|
else:
|
|
overloaded_entry = None
|
|
|
|
if overloaded_entry:
|
|
if self.function.type.is_fused:
|
|
functypes = self.function.type.get_all_specialized_function_types()
|
|
alternatives = [f.entry for f in functypes]
|
|
else:
|
|
alternatives = overloaded_entry.all_alternatives()
|
|
|
|
entry = PyrexTypes.best_match(
|
|
[arg.type for arg in args], alternatives, self.pos, env, args)
|
|
|
|
if not entry:
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
return
|
|
|
|
entry.used = True
|
|
if not func_type.is_cpp_class:
|
|
self.function.entry = entry
|
|
self.function.type = entry.type
|
|
func_type = self.function_type()
|
|
else:
|
|
entry = None
|
|
func_type = self.function_type()
|
|
if not func_type.is_cfunction:
|
|
error(self.pos, "Calling non-function type '%s'" % func_type)
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
return
|
|
|
|
# Check no. of args
|
|
max_nargs = len(func_type.args)
|
|
expected_nargs = max_nargs - func_type.optional_arg_count
|
|
actual_nargs = len(args)
|
|
if func_type.optional_arg_count and expected_nargs != actual_nargs:
|
|
self.has_optional_args = 1
|
|
self.is_temp = 1
|
|
|
|
# check 'self' argument
|
|
if entry and entry.is_cmethod and func_type.args and not func_type.is_static_method:
|
|
formal_arg = func_type.args[0]
|
|
arg = args[0]
|
|
if formal_arg.not_none:
|
|
if self.self:
|
|
self.self = self.self.as_none_safe_node(
|
|
"'NoneType' object has no attribute '%{0}s'".format('.30' if len(entry.name) <= 30 else ''),
|
|
error='PyExc_AttributeError',
|
|
format_args=[entry.name])
|
|
else:
|
|
# unbound method
|
|
arg = arg.as_none_safe_node(
|
|
"descriptor '%s' requires a '%s' object but received a 'NoneType'",
|
|
format_args=[entry.name, formal_arg.type.name])
|
|
if self.self:
|
|
if formal_arg.accept_builtin_subtypes:
|
|
arg = CMethodSelfCloneNode(self.self)
|
|
else:
|
|
arg = CloneNode(self.self)
|
|
arg = self.coerced_self = arg.coerce_to(formal_arg.type, env)
|
|
elif formal_arg.type.is_builtin_type:
|
|
# special case: unbound methods of builtins accept subtypes
|
|
arg = arg.coerce_to(formal_arg.type, env)
|
|
if arg.type.is_builtin_type and isinstance(arg, PyTypeTestNode):
|
|
arg.exact_builtin_type = False
|
|
args[0] = arg
|
|
|
|
# Coerce arguments
|
|
some_args_in_temps = False
|
|
for i in range(min(max_nargs, actual_nargs)):
|
|
formal_arg = func_type.args[i]
|
|
formal_type = formal_arg.type
|
|
arg = args[i].coerce_to(formal_type, env)
|
|
if formal_arg.not_none:
|
|
# C methods must do the None checks at *call* time
|
|
arg = arg.as_none_safe_node(
|
|
"cannot pass None into a C function argument that is declared 'not None'")
|
|
if arg.is_temp:
|
|
if i > 0:
|
|
# first argument in temp doesn't impact subsequent arguments
|
|
some_args_in_temps = True
|
|
elif arg.type.is_pyobject and not env.nogil:
|
|
if i == 0 and self.self is not None:
|
|
# a method's cloned "self" argument is ok
|
|
pass
|
|
elif arg.nonlocally_immutable():
|
|
# plain local variables are ok
|
|
pass
|
|
else:
|
|
# we do not safely own the argument's reference,
|
|
# but we must make sure it cannot be collected
|
|
# before we return from the function, so we create
|
|
# an owned temp reference to it
|
|
if i > 0: # first argument doesn't matter
|
|
some_args_in_temps = True
|
|
arg = arg.coerce_to_temp(env)
|
|
args[i] = arg
|
|
|
|
# handle additional varargs parameters
|
|
for i in range(max_nargs, actual_nargs):
|
|
arg = args[i]
|
|
if arg.type.is_pyobject:
|
|
if arg.type is str_type:
|
|
arg_ctype = PyrexTypes.c_char_ptr_type
|
|
else:
|
|
arg_ctype = arg.type.default_coerced_ctype()
|
|
if arg_ctype is None:
|
|
error(self.args[i].pos,
|
|
"Python object cannot be passed as a varargs parameter")
|
|
else:
|
|
args[i] = arg = arg.coerce_to(arg_ctype, env)
|
|
if arg.is_temp and i > 0:
|
|
some_args_in_temps = True
|
|
|
|
if some_args_in_temps:
|
|
# if some args are temps and others are not, they may get
|
|
# constructed in the wrong order (temps first) => make
|
|
# sure they are either all temps or all not temps (except
|
|
# for the last argument, which is evaluated last in any
|
|
# case)
|
|
for i in range(actual_nargs-1):
|
|
if i == 0 and self.self is not None:
|
|
continue # self is ok
|
|
arg = args[i]
|
|
if arg.nonlocally_immutable():
|
|
# locals, C functions, unassignable types are safe.
|
|
pass
|
|
elif arg.type.is_cpp_class:
|
|
# Assignment has side effects, avoid.
|
|
pass
|
|
elif env.nogil and arg.type.is_pyobject:
|
|
# can't copy a Python reference into a temp in nogil
|
|
# env (this is safe: a construction would fail in
|
|
# nogil anyway)
|
|
pass
|
|
else:
|
|
#self.args[i] = arg.coerce_to_temp(env)
|
|
# instead: issue a warning
|
|
if i > 0 or i == 1 and self.self is not None: # skip first arg
|
|
warning(arg.pos, "Argument evaluation order in C function call is undefined and may not be as expected", 0)
|
|
break
|
|
|
|
self.args[:] = args
|
|
|
|
# Calc result type and code fragment
|
|
if isinstance(self.function, NewExprNode):
|
|
self.type = PyrexTypes.CPtrType(self.function.class_type)
|
|
else:
|
|
self.type = func_type.return_type
|
|
|
|
if self.function.is_name or self.function.is_attribute:
|
|
func_entry = self.function.entry
|
|
if func_entry and (func_entry.utility_code or func_entry.utility_code_definition):
|
|
self.is_temp = 1 # currently doesn't work for self.calculate_result_code()
|
|
|
|
if self.type.is_pyobject:
|
|
self.result_ctype = py_object_type
|
|
self.is_temp = 1
|
|
elif func_type.exception_value is not None or func_type.exception_check:
|
|
self.is_temp = 1
|
|
elif self.type.is_memoryviewslice:
|
|
self.is_temp = 1
|
|
# func_type.exception_check = True
|
|
|
|
if self.is_temp and self.type.is_reference:
|
|
self.type = PyrexTypes.CFakeReferenceType(self.type.ref_base_type)
|
|
|
|
# Called in 'nogil' context?
|
|
self.nogil = env.nogil
|
|
if (self.nogil and
|
|
func_type.exception_check and
|
|
func_type.exception_check != '+'):
|
|
env.use_utility_code(pyerr_occurred_withgil_utility_code)
|
|
# C++ exception handler
|
|
if func_type.exception_check == '+':
|
|
if func_type.exception_value is None:
|
|
env.use_utility_code(UtilityCode.load_cached("CppExceptionConversion", "CppSupport.cpp"))
|
|
|
|
self.overflowcheck = env.directives['overflowcheck']
|
|
|
|
def calculate_result_code(self):
|
|
return self.c_call_code()
|
|
|
|
def c_call_code(self):
|
|
func_type = self.function_type()
|
|
if self.type is PyrexTypes.error_type or not func_type.is_cfunction:
|
|
return "<error>"
|
|
formal_args = func_type.args
|
|
arg_list_code = []
|
|
args = list(zip(formal_args, self.args))
|
|
max_nargs = len(func_type.args)
|
|
expected_nargs = max_nargs - func_type.optional_arg_count
|
|
actual_nargs = len(self.args)
|
|
for formal_arg, actual_arg in args[:expected_nargs]:
|
|
arg_code = actual_arg.result_as(formal_arg.type)
|
|
arg_list_code.append(arg_code)
|
|
|
|
if func_type.is_overridable:
|
|
arg_list_code.append(str(int(self.wrapper_call or self.function.entry.is_unbound_cmethod)))
|
|
|
|
if func_type.optional_arg_count:
|
|
if expected_nargs == actual_nargs:
|
|
optional_args = 'NULL'
|
|
else:
|
|
optional_args = "&%s" % self.opt_arg_struct
|
|
arg_list_code.append(optional_args)
|
|
|
|
for actual_arg in self.args[len(formal_args):]:
|
|
arg_list_code.append(actual_arg.result())
|
|
|
|
result = "%s(%s)" % (self.function.result(), ', '.join(arg_list_code))
|
|
return result
|
|
|
|
def is_c_result_required(self):
|
|
func_type = self.function_type()
|
|
if not func_type.exception_value or func_type.exception_check == '+':
|
|
return False # skip allocation of unused result temp
|
|
return True
|
|
|
|
def generate_evaluation_code(self, code):
|
|
function = self.function
|
|
if function.is_name or function.is_attribute:
|
|
code.globalstate.use_entry_utility_code(function.entry)
|
|
|
|
if not function.type.is_pyobject or len(self.arg_tuple.args) > 1 or (
|
|
self.arg_tuple.args and self.arg_tuple.is_literal):
|
|
super(SimpleCallNode, self).generate_evaluation_code(code)
|
|
return
|
|
|
|
# Special case 0-args and try to avoid explicit tuple creation for Python calls with 1 arg.
|
|
arg = self.arg_tuple.args[0] if self.arg_tuple.args else None
|
|
subexprs = (self.self, self.coerced_self, function, arg)
|
|
for subexpr in subexprs:
|
|
if subexpr is not None:
|
|
subexpr.generate_evaluation_code(code)
|
|
|
|
code.mark_pos(self.pos)
|
|
assert self.is_temp
|
|
self.allocate_temp_result(code)
|
|
|
|
if arg is None:
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(
|
|
"PyObjectCallNoArg", "ObjectHandling.c"))
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_CallNoArg(%s); %s" % (
|
|
self.result(),
|
|
function.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
else:
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(
|
|
"PyObjectCallOneArg", "ObjectHandling.c"))
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_CallOneArg(%s, %s); %s" % (
|
|
self.result(),
|
|
function.py_result(),
|
|
arg.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
|
|
code.put_gotref(self.py_result())
|
|
|
|
for subexpr in subexprs:
|
|
if subexpr is not None:
|
|
subexpr.generate_disposal_code(code)
|
|
subexpr.free_temps(code)
|
|
|
|
def generate_result_code(self, code):
|
|
func_type = self.function_type()
|
|
if func_type.is_pyobject:
|
|
arg_code = self.arg_tuple.py_result()
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(
|
|
"PyObjectCall", "ObjectHandling.c"))
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_Call(%s, %s, NULL); %s" % (
|
|
self.result(),
|
|
self.function.py_result(),
|
|
arg_code,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
elif func_type.is_cfunction:
|
|
if self.has_optional_args:
|
|
actual_nargs = len(self.args)
|
|
expected_nargs = len(func_type.args) - func_type.optional_arg_count
|
|
self.opt_arg_struct = code.funcstate.allocate_temp(
|
|
func_type.op_arg_struct.base_type, manage_ref=True)
|
|
code.putln("%s.%s = %s;" % (
|
|
self.opt_arg_struct,
|
|
Naming.pyrex_prefix + "n",
|
|
len(self.args) - expected_nargs))
|
|
args = list(zip(func_type.args, self.args))
|
|
for formal_arg, actual_arg in args[expected_nargs:actual_nargs]:
|
|
code.putln("%s.%s = %s;" % (
|
|
self.opt_arg_struct,
|
|
func_type.opt_arg_cname(formal_arg.name),
|
|
actual_arg.result_as(formal_arg.type)))
|
|
exc_checks = []
|
|
if self.type.is_pyobject and self.is_temp:
|
|
exc_checks.append("!%s" % self.result())
|
|
elif self.type.is_memoryviewslice:
|
|
assert self.is_temp
|
|
exc_checks.append(self.type.error_condition(self.result()))
|
|
elif func_type.exception_check != '+':
|
|
exc_val = func_type.exception_value
|
|
exc_check = func_type.exception_check
|
|
if exc_val is not None:
|
|
exc_checks.append("%s == %s" % (self.result(), func_type.return_type.cast_code(exc_val)))
|
|
if exc_check:
|
|
if self.nogil:
|
|
exc_checks.append("__Pyx_ErrOccurredWithGIL()")
|
|
else:
|
|
exc_checks.append("PyErr_Occurred()")
|
|
if self.is_temp or exc_checks:
|
|
rhs = self.c_call_code()
|
|
if self.result():
|
|
lhs = "%s = " % self.result()
|
|
if self.is_temp and self.type.is_pyobject:
|
|
#return_type = self.type # func_type.return_type
|
|
#print "SimpleCallNode.generate_result_code: casting", rhs, \
|
|
# "from", return_type, "to pyobject" ###
|
|
rhs = typecast(py_object_type, self.type, rhs)
|
|
else:
|
|
lhs = ""
|
|
if func_type.exception_check == '+':
|
|
translate_cpp_exception(code, self.pos, '%s%s;' % (lhs, rhs),
|
|
self.result() if self.type.is_pyobject else None,
|
|
func_type.exception_value, self.nogil)
|
|
else:
|
|
if (self.overflowcheck
|
|
and self.type.is_int
|
|
and self.type.signed
|
|
and self.function.result() in ('abs', 'labs', '__Pyx_abs_longlong')):
|
|
goto_error = 'if (unlikely(%s < 0)) { PyErr_SetString(PyExc_OverflowError, "value too large"); %s; }' % (
|
|
self.result(), code.error_goto(self.pos))
|
|
elif exc_checks:
|
|
goto_error = code.error_goto_if(" && ".join(exc_checks), self.pos)
|
|
else:
|
|
goto_error = ""
|
|
code.putln("%s%s; %s" % (lhs, rhs, goto_error))
|
|
if self.type.is_pyobject and self.result():
|
|
code.put_gotref(self.py_result())
|
|
if self.has_optional_args:
|
|
code.funcstate.release_temp(self.opt_arg_struct)
|
|
|
|
|
|
class NumPyMethodCallNode(SimpleCallNode):
|
|
# Pythran call to a NumPy function or method.
|
|
#
|
|
# function ExprNode the function/method to call
|
|
# arg_tuple TupleNode the arguments as an args tuple
|
|
|
|
subexprs = ['function', 'arg_tuple']
|
|
is_temp = True
|
|
may_return_none = True
|
|
|
|
def generate_evaluation_code(self, code):
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
|
|
self.function.generate_evaluation_code(code)
|
|
assert self.arg_tuple.mult_factor is None
|
|
args = self.arg_tuple.args
|
|
for arg in args:
|
|
arg.generate_evaluation_code(code)
|
|
|
|
code.putln("// function evaluation code for numpy function")
|
|
code.putln("__Pyx_call_destructor(%s);" % self.result())
|
|
code.putln("new (&%s) decltype(%s){%s{}(%s)};" % (
|
|
self.result(),
|
|
self.result(),
|
|
pythran_functor(self.function),
|
|
", ".join(a.pythran_result() for a in args)))
|
|
|
|
|
|
class PyMethodCallNode(SimpleCallNode):
|
|
# Specialised call to a (potential) PyMethodObject with non-constant argument tuple.
|
|
# Allows the self argument to be injected directly instead of repacking a tuple for it.
|
|
#
|
|
# function ExprNode the function/method object to call
|
|
# arg_tuple TupleNode the arguments for the args tuple
|
|
|
|
subexprs = ['function', 'arg_tuple']
|
|
is_temp = True
|
|
|
|
def generate_evaluation_code(self, code):
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
|
|
self.function.generate_evaluation_code(code)
|
|
assert self.arg_tuple.mult_factor is None
|
|
args = self.arg_tuple.args
|
|
for arg in args:
|
|
arg.generate_evaluation_code(code)
|
|
|
|
# make sure function is in temp so that we can replace the reference below if it's a method
|
|
reuse_function_temp = self.function.is_temp
|
|
if reuse_function_temp:
|
|
function = self.function.result()
|
|
else:
|
|
function = code.funcstate.allocate_temp(py_object_type, manage_ref=True)
|
|
self.function.make_owned_reference(code)
|
|
code.put("%s = %s; " % (function, self.function.py_result()))
|
|
self.function.generate_disposal_code(code)
|
|
self.function.free_temps(code)
|
|
|
|
self_arg = code.funcstate.allocate_temp(py_object_type, manage_ref=True)
|
|
code.putln("%s = NULL;" % self_arg)
|
|
arg_offset_cname = None
|
|
if len(args) > 1:
|
|
arg_offset_cname = code.funcstate.allocate_temp(PyrexTypes.c_int_type, manage_ref=False)
|
|
code.putln("%s = 0;" % arg_offset_cname)
|
|
|
|
def attribute_is_likely_method(attr):
|
|
obj = attr.obj
|
|
if obj.is_name and obj.entry.is_pyglobal:
|
|
return False # more likely to be a function
|
|
return True
|
|
|
|
if self.function.is_attribute:
|
|
likely_method = 'likely' if attribute_is_likely_method(self.function) else 'unlikely'
|
|
elif self.function.is_name and self.function.cf_state:
|
|
# not an attribute itself, but might have been assigned from one (e.g. bound method)
|
|
for assignment in self.function.cf_state:
|
|
value = assignment.rhs
|
|
if value and value.is_attribute and value.obj.type.is_pyobject:
|
|
if attribute_is_likely_method(value):
|
|
likely_method = 'likely'
|
|
break
|
|
else:
|
|
likely_method = 'unlikely'
|
|
else:
|
|
likely_method = 'unlikely'
|
|
|
|
code.putln("if (CYTHON_UNPACK_METHODS && %s(PyMethod_Check(%s))) {" % (likely_method, function))
|
|
code.putln("%s = PyMethod_GET_SELF(%s);" % (self_arg, function))
|
|
# the following is always true in Py3 (kept only for safety),
|
|
# but is false for unbound methods in Py2
|
|
code.putln("if (likely(%s)) {" % self_arg)
|
|
code.putln("PyObject* function = PyMethod_GET_FUNCTION(%s);" % function)
|
|
code.put_incref(self_arg, py_object_type)
|
|
code.put_incref("function", py_object_type)
|
|
# free method object as early to possible to enable reuse from CPython's freelist
|
|
code.put_decref_set(function, "function")
|
|
if len(args) > 1:
|
|
code.putln("%s = 1;" % arg_offset_cname)
|
|
code.putln("}")
|
|
code.putln("}")
|
|
|
|
if not args:
|
|
# fastest special case: try to avoid tuple creation
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectCallNoArg", "ObjectHandling.c"))
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectCallOneArg", "ObjectHandling.c"))
|
|
code.putln(
|
|
"%s = (%s) ? __Pyx_PyObject_CallOneArg(%s, %s) : __Pyx_PyObject_CallNoArg(%s);" % (
|
|
self.result(), self_arg,
|
|
function, self_arg,
|
|
function))
|
|
code.put_xdecref_clear(self_arg, py_object_type)
|
|
code.funcstate.release_temp(self_arg)
|
|
code.putln(code.error_goto_if_null(self.result(), self.pos))
|
|
code.put_gotref(self.py_result())
|
|
elif len(args) == 1:
|
|
# fastest special case: try to avoid tuple creation
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectCall2Args", "ObjectHandling.c"))
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectCallOneArg", "ObjectHandling.c"))
|
|
arg = args[0]
|
|
code.putln(
|
|
"%s = (%s) ? __Pyx_PyObject_Call2Args(%s, %s, %s) : __Pyx_PyObject_CallOneArg(%s, %s);" % (
|
|
self.result(), self_arg,
|
|
function, self_arg, arg.py_result(),
|
|
function, arg.py_result()))
|
|
code.put_xdecref_clear(self_arg, py_object_type)
|
|
code.funcstate.release_temp(self_arg)
|
|
arg.generate_disposal_code(code)
|
|
arg.free_temps(code)
|
|
code.putln(code.error_goto_if_null(self.result(), self.pos))
|
|
code.put_gotref(self.py_result())
|
|
else:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyFunctionFastCall", "ObjectHandling.c"))
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyCFunctionFastCall", "ObjectHandling.c"))
|
|
for test_func, call_prefix in [('PyFunction_Check', 'Py'), ('__Pyx_PyFastCFunction_Check', 'PyC')]:
|
|
code.putln("#if CYTHON_FAST_%sCALL" % call_prefix.upper())
|
|
code.putln("if (%s(%s)) {" % (test_func, function))
|
|
code.putln("PyObject *%s[%d] = {%s, %s};" % (
|
|
Naming.quick_temp_cname,
|
|
len(args)+1,
|
|
self_arg,
|
|
', '.join(arg.py_result() for arg in args)))
|
|
code.putln("%s = __Pyx_%sFunction_FastCall(%s, %s+1-%s, %d+%s); %s" % (
|
|
self.result(),
|
|
call_prefix,
|
|
function,
|
|
Naming.quick_temp_cname,
|
|
arg_offset_cname,
|
|
len(args),
|
|
arg_offset_cname,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_xdecref_clear(self_arg, py_object_type)
|
|
code.put_gotref(self.py_result())
|
|
for arg in args:
|
|
arg.generate_disposal_code(code)
|
|
code.putln("} else")
|
|
code.putln("#endif")
|
|
|
|
code.putln("{")
|
|
args_tuple = code.funcstate.allocate_temp(py_object_type, manage_ref=True)
|
|
code.putln("%s = PyTuple_New(%d+%s); %s" % (
|
|
args_tuple, len(args), arg_offset_cname,
|
|
code.error_goto_if_null(args_tuple, self.pos)))
|
|
code.put_gotref(args_tuple)
|
|
|
|
if len(args) > 1:
|
|
code.putln("if (%s) {" % self_arg)
|
|
code.putln("__Pyx_GIVEREF(%s); PyTuple_SET_ITEM(%s, 0, %s); %s = NULL;" % (
|
|
self_arg, args_tuple, self_arg, self_arg)) # stealing owned ref in this case
|
|
code.funcstate.release_temp(self_arg)
|
|
if len(args) > 1:
|
|
code.putln("}")
|
|
|
|
for i, arg in enumerate(args):
|
|
arg.make_owned_reference(code)
|
|
code.put_giveref(arg.py_result())
|
|
code.putln("PyTuple_SET_ITEM(%s, %d+%s, %s);" % (
|
|
args_tuple, i, arg_offset_cname, arg.py_result()))
|
|
if len(args) > 1:
|
|
code.funcstate.release_temp(arg_offset_cname)
|
|
|
|
for arg in args:
|
|
arg.generate_post_assignment_code(code)
|
|
arg.free_temps(code)
|
|
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectCall", "ObjectHandling.c"))
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_Call(%s, %s, NULL); %s" % (
|
|
self.result(),
|
|
function, args_tuple,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
code.put_decref_clear(args_tuple, py_object_type)
|
|
code.funcstate.release_temp(args_tuple)
|
|
|
|
if len(args) == 1:
|
|
code.putln("}")
|
|
code.putln("}") # !CYTHON_FAST_PYCALL
|
|
|
|
if reuse_function_temp:
|
|
self.function.generate_disposal_code(code)
|
|
self.function.free_temps(code)
|
|
else:
|
|
code.put_decref_clear(function, py_object_type)
|
|
code.funcstate.release_temp(function)
|
|
|
|
|
|
class InlinedDefNodeCallNode(CallNode):
|
|
# Inline call to defnode
|
|
#
|
|
# function PyCFunctionNode
|
|
# function_name NameNode
|
|
# args [ExprNode]
|
|
|
|
subexprs = ['args', 'function_name']
|
|
is_temp = 1
|
|
type = py_object_type
|
|
function = None
|
|
function_name = None
|
|
|
|
def can_be_inlined(self):
|
|
func_type= self.function.def_node
|
|
if func_type.star_arg or func_type.starstar_arg:
|
|
return False
|
|
if len(func_type.args) != len(self.args):
|
|
return False
|
|
if func_type.num_kwonly_args:
|
|
return False # actually wrong number of arguments
|
|
return True
|
|
|
|
def analyse_types(self, env):
|
|
self.function_name = self.function_name.analyse_types(env)
|
|
|
|
self.args = [ arg.analyse_types(env) for arg in self.args ]
|
|
func_type = self.function.def_node
|
|
actual_nargs = len(self.args)
|
|
|
|
# Coerce arguments
|
|
some_args_in_temps = False
|
|
for i in range(actual_nargs):
|
|
formal_type = func_type.args[i].type
|
|
arg = self.args[i].coerce_to(formal_type, env)
|
|
if arg.is_temp:
|
|
if i > 0:
|
|
# first argument in temp doesn't impact subsequent arguments
|
|
some_args_in_temps = True
|
|
elif arg.type.is_pyobject and not env.nogil:
|
|
if arg.nonlocally_immutable():
|
|
# plain local variables are ok
|
|
pass
|
|
else:
|
|
# we do not safely own the argument's reference,
|
|
# but we must make sure it cannot be collected
|
|
# before we return from the function, so we create
|
|
# an owned temp reference to it
|
|
if i > 0: # first argument doesn't matter
|
|
some_args_in_temps = True
|
|
arg = arg.coerce_to_temp(env)
|
|
self.args[i] = arg
|
|
|
|
if some_args_in_temps:
|
|
# if some args are temps and others are not, they may get
|
|
# constructed in the wrong order (temps first) => make
|
|
# sure they are either all temps or all not temps (except
|
|
# for the last argument, which is evaluated last in any
|
|
# case)
|
|
for i in range(actual_nargs-1):
|
|
arg = self.args[i]
|
|
if arg.nonlocally_immutable():
|
|
# locals, C functions, unassignable types are safe.
|
|
pass
|
|
elif arg.type.is_cpp_class:
|
|
# Assignment has side effects, avoid.
|
|
pass
|
|
elif env.nogil and arg.type.is_pyobject:
|
|
# can't copy a Python reference into a temp in nogil
|
|
# env (this is safe: a construction would fail in
|
|
# nogil anyway)
|
|
pass
|
|
else:
|
|
#self.args[i] = arg.coerce_to_temp(env)
|
|
# instead: issue a warning
|
|
if i > 0:
|
|
warning(arg.pos, "Argument evaluation order in C function call is undefined and may not be as expected", 0)
|
|
break
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
arg_code = [self.function_name.py_result()]
|
|
func_type = self.function.def_node
|
|
for arg, proto_arg in zip(self.args, func_type.args):
|
|
if arg.type.is_pyobject:
|
|
arg_code.append(arg.result_as(proto_arg.type))
|
|
else:
|
|
arg_code.append(arg.result())
|
|
arg_code = ', '.join(arg_code)
|
|
code.putln(
|
|
"%s = %s(%s); %s" % (
|
|
self.result(),
|
|
self.function.def_node.entry.pyfunc_cname,
|
|
arg_code,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class PythonCapiFunctionNode(ExprNode):
|
|
subexprs = []
|
|
|
|
def __init__(self, pos, py_name, cname, func_type, utility_code = None):
|
|
ExprNode.__init__(self, pos, name=py_name, cname=cname,
|
|
type=func_type, utility_code=utility_code)
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
if self.utility_code:
|
|
code.globalstate.use_utility_code(self.utility_code)
|
|
|
|
def calculate_result_code(self):
|
|
return self.cname
|
|
|
|
|
|
class PythonCapiCallNode(SimpleCallNode):
|
|
# Python C-API Function call (only created in transforms)
|
|
|
|
# By default, we assume that the call never returns None, as this
|
|
# is true for most C-API functions in CPython. If this does not
|
|
# apply to a call, set the following to True (or None to inherit
|
|
# the default behaviour).
|
|
may_return_none = False
|
|
|
|
def __init__(self, pos, function_name, func_type,
|
|
utility_code = None, py_name=None, **kwargs):
|
|
self.type = func_type.return_type
|
|
self.result_ctype = self.type
|
|
self.function = PythonCapiFunctionNode(
|
|
pos, py_name, function_name, func_type,
|
|
utility_code = utility_code)
|
|
# call this last so that we can override the constructed
|
|
# attributes above with explicit keyword arguments if required
|
|
SimpleCallNode.__init__(self, pos, **kwargs)
|
|
|
|
|
|
class CachedBuiltinMethodCallNode(CallNode):
|
|
# Python call to a method of a known Python builtin (only created in transforms)
|
|
|
|
subexprs = ['obj', 'args']
|
|
is_temp = True
|
|
|
|
def __init__(self, call_node, obj, method_name, args):
|
|
super(CachedBuiltinMethodCallNode, self).__init__(
|
|
call_node.pos,
|
|
obj=obj, method_name=method_name, args=args,
|
|
may_return_none=call_node.may_return_none,
|
|
type=call_node.type)
|
|
|
|
def may_be_none(self):
|
|
if self.may_return_none is not None:
|
|
return self.may_return_none
|
|
return ExprNode.may_be_none(self)
|
|
|
|
def generate_result_code(self, code):
|
|
type_cname = self.obj.type.cname
|
|
obj_cname = self.obj.py_result()
|
|
args = [arg.py_result() for arg in self.args]
|
|
call_code = code.globalstate.cached_unbound_method_call_code(
|
|
obj_cname, type_cname, self.method_name, args)
|
|
code.putln("%s = %s; %s" % (
|
|
self.result(), call_code,
|
|
code.error_goto_if_null(self.result(), self.pos)
|
|
))
|
|
code.put_gotref(self.result())
|
|
|
|
|
|
class GeneralCallNode(CallNode):
|
|
# General Python function call, including keyword,
|
|
# * and ** arguments.
|
|
#
|
|
# function ExprNode
|
|
# positional_args ExprNode Tuple of positional arguments
|
|
# keyword_args ExprNode or None Dict of keyword arguments
|
|
|
|
type = py_object_type
|
|
|
|
subexprs = ['function', 'positional_args', 'keyword_args']
|
|
|
|
nogil_check = Node.gil_error
|
|
|
|
def compile_time_value(self, denv):
|
|
function = self.function.compile_time_value(denv)
|
|
positional_args = self.positional_args.compile_time_value(denv)
|
|
keyword_args = self.keyword_args.compile_time_value(denv)
|
|
try:
|
|
return function(*positional_args, **keyword_args)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def explicit_args_kwds(self):
|
|
if (self.keyword_args and not self.keyword_args.is_dict_literal or
|
|
not self.positional_args.is_sequence_constructor):
|
|
raise CompileError(self.pos,
|
|
'Compile-time keyword arguments must be explicit.')
|
|
return self.positional_args.args, self.keyword_args
|
|
|
|
def analyse_types(self, env):
|
|
if self.analyse_as_type_constructor(env):
|
|
return self
|
|
self.function = self.function.analyse_types(env)
|
|
if not self.function.type.is_pyobject:
|
|
if self.function.type.is_error:
|
|
self.type = error_type
|
|
return self
|
|
if hasattr(self.function, 'entry'):
|
|
node = self.map_to_simple_call_node()
|
|
if node is not None and node is not self:
|
|
return node.analyse_types(env)
|
|
elif self.function.entry.as_variable:
|
|
self.function = self.function.coerce_to_pyobject(env)
|
|
elif node is self:
|
|
error(self.pos,
|
|
"Non-trivial keyword arguments and starred "
|
|
"arguments not allowed in cdef functions.")
|
|
else:
|
|
# error was already reported
|
|
pass
|
|
else:
|
|
self.function = self.function.coerce_to_pyobject(env)
|
|
if self.keyword_args:
|
|
self.keyword_args = self.keyword_args.analyse_types(env)
|
|
self.positional_args = self.positional_args.analyse_types(env)
|
|
self.positional_args = \
|
|
self.positional_args.coerce_to_pyobject(env)
|
|
self.set_py_result_type(self.function)
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
def map_to_simple_call_node(self):
|
|
"""
|
|
Tries to map keyword arguments to declared positional arguments.
|
|
Returns self to try a Python call, None to report an error
|
|
or a SimpleCallNode if the mapping succeeds.
|
|
"""
|
|
if not isinstance(self.positional_args, TupleNode):
|
|
# has starred argument
|
|
return self
|
|
if not self.keyword_args.is_dict_literal:
|
|
# keywords come from arbitrary expression => nothing to do here
|
|
return self
|
|
function = self.function
|
|
entry = getattr(function, 'entry', None)
|
|
if not entry:
|
|
return self
|
|
function_type = entry.type
|
|
if function_type.is_ptr:
|
|
function_type = function_type.base_type
|
|
if not function_type.is_cfunction:
|
|
return self
|
|
|
|
pos_args = self.positional_args.args
|
|
kwargs = self.keyword_args
|
|
declared_args = function_type.args
|
|
if entry.is_cmethod:
|
|
declared_args = declared_args[1:] # skip 'self'
|
|
|
|
if len(pos_args) > len(declared_args):
|
|
error(self.pos, "function call got too many positional arguments, "
|
|
"expected %d, got %s" % (len(declared_args),
|
|
len(pos_args)))
|
|
return None
|
|
|
|
matched_args = set([ arg.name for arg in declared_args[:len(pos_args)]
|
|
if arg.name ])
|
|
unmatched_args = declared_args[len(pos_args):]
|
|
matched_kwargs_count = 0
|
|
args = list(pos_args)
|
|
|
|
# check for duplicate keywords
|
|
seen = set(matched_args)
|
|
has_errors = False
|
|
for arg in kwargs.key_value_pairs:
|
|
name = arg.key.value
|
|
if name in seen:
|
|
error(arg.pos, "argument '%s' passed twice" % name)
|
|
has_errors = True
|
|
# continue to report more errors if there are any
|
|
seen.add(name)
|
|
|
|
# match keywords that are passed in order
|
|
for decl_arg, arg in zip(unmatched_args, kwargs.key_value_pairs):
|
|
name = arg.key.value
|
|
if decl_arg.name == name:
|
|
matched_args.add(name)
|
|
matched_kwargs_count += 1
|
|
args.append(arg.value)
|
|
else:
|
|
break
|
|
|
|
# match keyword arguments that are passed out-of-order, but keep
|
|
# the evaluation of non-simple arguments in order by moving them
|
|
# into temps
|
|
from .UtilNodes import EvalWithTempExprNode, LetRefNode
|
|
temps = []
|
|
if len(kwargs.key_value_pairs) > matched_kwargs_count:
|
|
unmatched_args = declared_args[len(args):]
|
|
keywords = dict([ (arg.key.value, (i+len(pos_args), arg))
|
|
for i, arg in enumerate(kwargs.key_value_pairs) ])
|
|
first_missing_keyword = None
|
|
for decl_arg in unmatched_args:
|
|
name = decl_arg.name
|
|
if name not in keywords:
|
|
# missing keyword argument => either done or error
|
|
if not first_missing_keyword:
|
|
first_missing_keyword = name
|
|
continue
|
|
elif first_missing_keyword:
|
|
if entry.as_variable:
|
|
# we might be able to convert the function to a Python
|
|
# object, which then allows full calling semantics
|
|
# with default values in gaps - currently, we only
|
|
# support optional arguments at the end
|
|
return self
|
|
# wasn't the last keyword => gaps are not supported
|
|
error(self.pos, "C function call is missing "
|
|
"argument '%s'" % first_missing_keyword)
|
|
return None
|
|
pos, arg = keywords[name]
|
|
matched_args.add(name)
|
|
matched_kwargs_count += 1
|
|
if arg.value.is_simple():
|
|
args.append(arg.value)
|
|
else:
|
|
temp = LetRefNode(arg.value)
|
|
assert temp.is_simple()
|
|
args.append(temp)
|
|
temps.append((pos, temp))
|
|
|
|
if temps:
|
|
# may have to move preceding non-simple args into temps
|
|
final_args = []
|
|
new_temps = []
|
|
first_temp_arg = temps[0][-1]
|
|
for arg_value in args:
|
|
if arg_value is first_temp_arg:
|
|
break # done
|
|
if arg_value.is_simple():
|
|
final_args.append(arg_value)
|
|
else:
|
|
temp = LetRefNode(arg_value)
|
|
new_temps.append(temp)
|
|
final_args.append(temp)
|
|
if new_temps:
|
|
args = final_args
|
|
temps = new_temps + [ arg for i,arg in sorted(temps) ]
|
|
|
|
# check for unexpected keywords
|
|
for arg in kwargs.key_value_pairs:
|
|
name = arg.key.value
|
|
if name not in matched_args:
|
|
has_errors = True
|
|
error(arg.pos,
|
|
"C function got unexpected keyword argument '%s'" %
|
|
name)
|
|
|
|
if has_errors:
|
|
# error was reported already
|
|
return None
|
|
|
|
# all keywords mapped to positional arguments
|
|
# if we are missing arguments, SimpleCallNode will figure it out
|
|
node = SimpleCallNode(self.pos, function=function, args=args)
|
|
for temp in temps[::-1]:
|
|
node = EvalWithTempExprNode(temp, node)
|
|
return node
|
|
|
|
def generate_result_code(self, code):
|
|
if self.type.is_error: return
|
|
if self.keyword_args:
|
|
kwargs = self.keyword_args.py_result()
|
|
else:
|
|
kwargs = 'NULL'
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(
|
|
"PyObjectCall", "ObjectHandling.c"))
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_Call(%s, %s, %s); %s" % (
|
|
self.result(),
|
|
self.function.py_result(),
|
|
self.positional_args.py_result(),
|
|
kwargs,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class AsTupleNode(ExprNode):
|
|
# Convert argument to tuple. Used for normalising
|
|
# the * argument of a function call.
|
|
#
|
|
# arg ExprNode
|
|
|
|
subexprs = ['arg']
|
|
is_temp = 1
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = tuple(self.arg.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
arg = self.arg.compile_time_value(denv)
|
|
try:
|
|
return tuple(arg)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def analyse_types(self, env):
|
|
self.arg = self.arg.analyse_types(env).coerce_to_pyobject(env)
|
|
if self.arg.type is tuple_type:
|
|
return self.arg.as_none_safe_node("'NoneType' object is not iterable")
|
|
self.type = tuple_type
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
nogil_check = Node.gil_error
|
|
gil_message = "Constructing Python tuple"
|
|
|
|
def generate_result_code(self, code):
|
|
cfunc = "__Pyx_PySequence_Tuple" if self.arg.type in (py_object_type, tuple_type) else "PySequence_Tuple"
|
|
code.putln(
|
|
"%s = %s(%s); %s" % (
|
|
self.result(),
|
|
cfunc, self.arg.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class MergedDictNode(ExprNode):
|
|
# Helper class for keyword arguments and other merged dicts.
|
|
#
|
|
# keyword_args [DictNode or other ExprNode]
|
|
|
|
subexprs = ['keyword_args']
|
|
is_temp = 1
|
|
type = dict_type
|
|
reject_duplicates = True
|
|
|
|
def calculate_constant_result(self):
|
|
result = {}
|
|
reject_duplicates = self.reject_duplicates
|
|
for item in self.keyword_args:
|
|
if item.is_dict_literal:
|
|
# process items in order
|
|
items = ((key.constant_result, value.constant_result)
|
|
for key, value in item.key_value_pairs)
|
|
else:
|
|
items = item.constant_result.iteritems()
|
|
|
|
for key, value in items:
|
|
if reject_duplicates and key in result:
|
|
raise ValueError("duplicate keyword argument found: %s" % key)
|
|
result[key] = value
|
|
|
|
self.constant_result = result
|
|
|
|
def compile_time_value(self, denv):
|
|
result = {}
|
|
reject_duplicates = self.reject_duplicates
|
|
for item in self.keyword_args:
|
|
if item.is_dict_literal:
|
|
# process items in order
|
|
items = [(key.compile_time_value(denv), value.compile_time_value(denv))
|
|
for key, value in item.key_value_pairs]
|
|
else:
|
|
items = item.compile_time_value(denv).iteritems()
|
|
|
|
try:
|
|
for key, value in items:
|
|
if reject_duplicates and key in result:
|
|
raise ValueError("duplicate keyword argument found: %s" % key)
|
|
result[key] = value
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
return result
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def infer_type(self, env):
|
|
return dict_type
|
|
|
|
def analyse_types(self, env):
|
|
args = [
|
|
arg.analyse_types(env).coerce_to_pyobject(env).as_none_safe_node(
|
|
# FIXME: CPython's error message starts with the runtime function name
|
|
'argument after ** must be a mapping, not NoneType')
|
|
for arg in self.keyword_args
|
|
]
|
|
|
|
if len(args) == 1 and args[0].type is dict_type:
|
|
# strip this intermediate node and use the bare dict
|
|
arg = args[0]
|
|
if arg.is_name and arg.entry.is_arg and len(arg.entry.cf_assignments) == 1:
|
|
# passing **kwargs through to function call => allow NULL
|
|
arg.allow_null = True
|
|
return arg
|
|
|
|
self.keyword_args = args
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
gil_message = "Constructing Python dict"
|
|
|
|
def generate_evaluation_code(self, code):
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
|
|
args = iter(self.keyword_args)
|
|
item = next(args)
|
|
item.generate_evaluation_code(code)
|
|
if item.type is not dict_type:
|
|
# CPython supports calling functions with non-dicts, so do we
|
|
code.putln('if (likely(PyDict_CheckExact(%s))) {' %
|
|
item.py_result())
|
|
|
|
if item.is_dict_literal:
|
|
item.make_owned_reference(code)
|
|
code.putln("%s = %s;" % (self.result(), item.py_result()))
|
|
item.generate_post_assignment_code(code)
|
|
else:
|
|
code.putln("%s = PyDict_Copy(%s); %s" % (
|
|
self.result(),
|
|
item.py_result(),
|
|
code.error_goto_if_null(self.result(), item.pos)))
|
|
code.put_gotref(self.result())
|
|
item.generate_disposal_code(code)
|
|
|
|
if item.type is not dict_type:
|
|
code.putln('} else {')
|
|
code.putln("%s = PyObject_CallFunctionObjArgs((PyObject*)&PyDict_Type, %s, NULL); %s" % (
|
|
self.result(),
|
|
item.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
item.generate_disposal_code(code)
|
|
code.putln('}')
|
|
item.free_temps(code)
|
|
|
|
helpers = set()
|
|
for item in args:
|
|
if item.is_dict_literal:
|
|
# inline update instead of creating an intermediate dict
|
|
for arg in item.key_value_pairs:
|
|
arg.generate_evaluation_code(code)
|
|
if self.reject_duplicates:
|
|
code.putln("if (unlikely(PyDict_Contains(%s, %s))) {" % (
|
|
self.result(),
|
|
arg.key.py_result()))
|
|
helpers.add("RaiseDoubleKeywords")
|
|
# FIXME: find out function name at runtime!
|
|
code.putln('__Pyx_RaiseDoubleKeywordsError("function", %s); %s' % (
|
|
arg.key.py_result(),
|
|
code.error_goto(self.pos)))
|
|
code.putln("}")
|
|
code.put_error_if_neg(arg.key.pos, "PyDict_SetItem(%s, %s, %s)" % (
|
|
self.result(),
|
|
arg.key.py_result(),
|
|
arg.value.py_result()))
|
|
arg.generate_disposal_code(code)
|
|
arg.free_temps(code)
|
|
else:
|
|
item.generate_evaluation_code(code)
|
|
if self.reject_duplicates:
|
|
# merge mapping into kwdict one by one as we need to check for duplicates
|
|
helpers.add("MergeKeywords")
|
|
code.put_error_if_neg(item.pos, "__Pyx_MergeKeywords(%s, %s)" % (
|
|
self.result(), item.py_result()))
|
|
else:
|
|
# simple case, just add all entries
|
|
helpers.add("RaiseMappingExpected")
|
|
code.putln("if (unlikely(PyDict_Update(%s, %s) < 0)) {" % (
|
|
self.result(), item.py_result()))
|
|
code.putln("if (PyErr_ExceptionMatches(PyExc_AttributeError)) "
|
|
"__Pyx_RaiseMappingExpectedError(%s);" % item.py_result())
|
|
code.putln(code.error_goto(item.pos))
|
|
code.putln("}")
|
|
item.generate_disposal_code(code)
|
|
item.free_temps(code)
|
|
|
|
for helper in sorted(helpers):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(helper, "FunctionArguments.c"))
|
|
|
|
def annotate(self, code):
|
|
for item in self.keyword_args:
|
|
item.annotate(code)
|
|
|
|
|
|
class AttributeNode(ExprNode):
|
|
# obj.attribute
|
|
#
|
|
# obj ExprNode
|
|
# attribute string
|
|
# needs_none_check boolean Used if obj is an extension type.
|
|
# If set to True, it is known that the type is not None.
|
|
#
|
|
# Used internally:
|
|
#
|
|
# is_py_attr boolean Is a Python getattr operation
|
|
# member string C name of struct member
|
|
# is_called boolean Function call is being done on result
|
|
# entry Entry Symbol table entry of attribute
|
|
|
|
is_attribute = 1
|
|
subexprs = ['obj']
|
|
|
|
type = PyrexTypes.error_type
|
|
entry = None
|
|
is_called = 0
|
|
needs_none_check = True
|
|
is_memslice_transpose = False
|
|
is_special_lookup = False
|
|
is_py_attr = 0
|
|
|
|
def as_cython_attribute(self):
|
|
if (isinstance(self.obj, NameNode) and
|
|
self.obj.is_cython_module and not
|
|
self.attribute == u"parallel"):
|
|
return self.attribute
|
|
|
|
cy = self.obj.as_cython_attribute()
|
|
if cy:
|
|
return "%s.%s" % (cy, self.attribute)
|
|
return None
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
# If coercing to a generic pyobject and this is a cpdef function
|
|
# we can create the corresponding attribute
|
|
if dst_type is py_object_type:
|
|
entry = self.entry
|
|
if entry and entry.is_cfunction and entry.as_variable:
|
|
# must be a cpdef function
|
|
self.is_temp = 1
|
|
self.entry = entry.as_variable
|
|
self.analyse_as_python_attribute(env)
|
|
return self
|
|
return ExprNode.coerce_to(self, dst_type, env)
|
|
|
|
def calculate_constant_result(self):
|
|
attr = self.attribute
|
|
if attr.startswith("__") and attr.endswith("__"):
|
|
return
|
|
self.constant_result = getattr(self.obj.constant_result, attr)
|
|
|
|
def compile_time_value(self, denv):
|
|
attr = self.attribute
|
|
if attr.startswith("__") and attr.endswith("__"):
|
|
error(self.pos,
|
|
"Invalid attribute name '%s' in compile-time expression" % attr)
|
|
return None
|
|
obj = self.obj.compile_time_value(denv)
|
|
try:
|
|
return getattr(obj, attr)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def type_dependencies(self, env):
|
|
return self.obj.type_dependencies(env)
|
|
|
|
def infer_type(self, env):
|
|
# FIXME: this is way too redundant with analyse_types()
|
|
node = self.analyse_as_cimported_attribute_node(env, target=False)
|
|
if node is not None:
|
|
return node.entry.type
|
|
node = self.analyse_as_type_attribute(env)
|
|
if node is not None:
|
|
return node.entry.type
|
|
obj_type = self.obj.infer_type(env)
|
|
self.analyse_attribute(env, obj_type=obj_type)
|
|
if obj_type.is_builtin_type and self.type.is_cfunction:
|
|
# special case: C-API replacements for C methods of
|
|
# builtin types cannot be inferred as C functions as
|
|
# that would prevent their use as bound methods
|
|
return py_object_type
|
|
elif self.entry and self.entry.is_cmethod:
|
|
# special case: bound methods should not be inferred
|
|
# as their unbound method types
|
|
return py_object_type
|
|
return self.type
|
|
|
|
def analyse_target_declaration(self, env):
|
|
pass
|
|
|
|
def analyse_target_types(self, env):
|
|
node = self.analyse_types(env, target = 1)
|
|
if node.type.is_const:
|
|
error(self.pos, "Assignment to const attribute '%s'" % self.attribute)
|
|
if not node.is_lvalue():
|
|
error(self.pos, "Assignment to non-lvalue of type '%s'" % self.type)
|
|
return node
|
|
|
|
def analyse_types(self, env, target = 0):
|
|
self.initialized_check = env.directives['initializedcheck']
|
|
node = self.analyse_as_cimported_attribute_node(env, target)
|
|
if node is None and not target:
|
|
node = self.analyse_as_type_attribute(env)
|
|
if node is None:
|
|
node = self.analyse_as_ordinary_attribute_node(env, target)
|
|
assert node is not None
|
|
if node.entry:
|
|
node.entry.used = True
|
|
if node.is_attribute:
|
|
node.wrap_obj_in_nonecheck(env)
|
|
return node
|
|
|
|
def analyse_as_cimported_attribute_node(self, env, target):
|
|
# Try to interpret this as a reference to an imported
|
|
# C const, type, var or function. If successful, mutates
|
|
# this node into a NameNode and returns 1, otherwise
|
|
# returns 0.
|
|
module_scope = self.obj.analyse_as_module(env)
|
|
if module_scope:
|
|
entry = module_scope.lookup_here(self.attribute)
|
|
if entry and (
|
|
entry.is_cglobal or entry.is_cfunction
|
|
or entry.is_type or entry.is_const):
|
|
return self.as_name_node(env, entry, target)
|
|
if self.is_cimported_module_without_shadow(env):
|
|
error(self.pos, "cimported module has no attribute '%s'" % self.attribute)
|
|
return self
|
|
return None
|
|
|
|
def analyse_as_type_attribute(self, env):
|
|
# Try to interpret this as a reference to an unbound
|
|
# C method of an extension type or builtin type. If successful,
|
|
# creates a corresponding NameNode and returns it, otherwise
|
|
# returns None.
|
|
if self.obj.is_string_literal:
|
|
return
|
|
type = self.obj.analyse_as_type(env)
|
|
if type:
|
|
if type.is_extension_type or type.is_builtin_type or type.is_cpp_class:
|
|
entry = type.scope.lookup_here(self.attribute)
|
|
if entry and (entry.is_cmethod or type.is_cpp_class and entry.type.is_cfunction):
|
|
if type.is_builtin_type:
|
|
if not self.is_called:
|
|
# must handle this as Python object
|
|
return None
|
|
ubcm_entry = entry
|
|
else:
|
|
# Create a temporary entry describing the C method
|
|
# as an ordinary function.
|
|
if entry.func_cname and not hasattr(entry.type, 'op_arg_struct'):
|
|
cname = entry.func_cname
|
|
if entry.type.is_static_method or (
|
|
env.parent_scope and env.parent_scope.is_cpp_class_scope):
|
|
ctype = entry.type
|
|
elif type.is_cpp_class:
|
|
error(self.pos, "%s not a static member of %s" % (entry.name, type))
|
|
ctype = PyrexTypes.error_type
|
|
else:
|
|
# Fix self type.
|
|
ctype = copy.copy(entry.type)
|
|
ctype.args = ctype.args[:]
|
|
ctype.args[0] = PyrexTypes.CFuncTypeArg('self', type, 'self', None)
|
|
else:
|
|
cname = "%s->%s" % (type.vtabptr_cname, entry.cname)
|
|
ctype = entry.type
|
|
ubcm_entry = Symtab.Entry(entry.name, cname, ctype)
|
|
ubcm_entry.is_cfunction = 1
|
|
ubcm_entry.func_cname = entry.func_cname
|
|
ubcm_entry.is_unbound_cmethod = 1
|
|
ubcm_entry.scope = entry.scope
|
|
return self.as_name_node(env, ubcm_entry, target=False)
|
|
elif type.is_enum:
|
|
if self.attribute in type.values:
|
|
for entry in type.entry.enum_values:
|
|
if entry.name == self.attribute:
|
|
return self.as_name_node(env, entry, target=False)
|
|
else:
|
|
error(self.pos, "%s not a known value of %s" % (self.attribute, type))
|
|
else:
|
|
error(self.pos, "%s not a known value of %s" % (self.attribute, type))
|
|
return None
|
|
|
|
def analyse_as_type(self, env):
|
|
module_scope = self.obj.analyse_as_module(env)
|
|
if module_scope:
|
|
return module_scope.lookup_type(self.attribute)
|
|
if not self.obj.is_string_literal:
|
|
base_type = self.obj.analyse_as_type(env)
|
|
if base_type and hasattr(base_type, 'scope') and base_type.scope is not None:
|
|
return base_type.scope.lookup_type(self.attribute)
|
|
return None
|
|
|
|
def analyse_as_extension_type(self, env):
|
|
# Try to interpret this as a reference to an extension type
|
|
# in a cimported module. Returns the extension type, or None.
|
|
module_scope = self.obj.analyse_as_module(env)
|
|
if module_scope:
|
|
entry = module_scope.lookup_here(self.attribute)
|
|
if entry and entry.is_type:
|
|
if entry.type.is_extension_type or entry.type.is_builtin_type:
|
|
return entry.type
|
|
return None
|
|
|
|
def analyse_as_module(self, env):
|
|
# Try to interpret this as a reference to a cimported module
|
|
# in another cimported module. Returns the module scope, or None.
|
|
module_scope = self.obj.analyse_as_module(env)
|
|
if module_scope:
|
|
entry = module_scope.lookup_here(self.attribute)
|
|
if entry and entry.as_module:
|
|
return entry.as_module
|
|
return None
|
|
|
|
def as_name_node(self, env, entry, target):
|
|
# Create a corresponding NameNode from this node and complete the
|
|
# analyse_types phase.
|
|
node = NameNode.from_node(self, name=self.attribute, entry=entry)
|
|
if target:
|
|
node = node.analyse_target_types(env)
|
|
else:
|
|
node = node.analyse_rvalue_entry(env)
|
|
node.entry.used = 1
|
|
return node
|
|
|
|
def analyse_as_ordinary_attribute_node(self, env, target):
|
|
self.obj = self.obj.analyse_types(env)
|
|
self.analyse_attribute(env)
|
|
if self.entry and self.entry.is_cmethod and not self.is_called:
|
|
# error(self.pos, "C method can only be called")
|
|
pass
|
|
## Reference to C array turns into pointer to first element.
|
|
#while self.type.is_array:
|
|
# self.type = self.type.element_ptr_type()
|
|
if self.is_py_attr:
|
|
if not target:
|
|
self.is_temp = 1
|
|
self.result_ctype = py_object_type
|
|
elif target and self.obj.type.is_builtin_type:
|
|
error(self.pos, "Assignment to an immutable object field")
|
|
#elif self.type.is_memoryviewslice and not target:
|
|
# self.is_temp = True
|
|
return self
|
|
|
|
def analyse_attribute(self, env, obj_type = None):
|
|
# Look up attribute and set self.type and self.member.
|
|
immutable_obj = obj_type is not None # used during type inference
|
|
self.is_py_attr = 0
|
|
self.member = self.attribute
|
|
if obj_type is None:
|
|
if self.obj.type.is_string or self.obj.type.is_pyunicode_ptr:
|
|
self.obj = self.obj.coerce_to_pyobject(env)
|
|
obj_type = self.obj.type
|
|
else:
|
|
if obj_type.is_string or obj_type.is_pyunicode_ptr:
|
|
obj_type = py_object_type
|
|
if obj_type.is_ptr or obj_type.is_array:
|
|
obj_type = obj_type.base_type
|
|
self.op = "->"
|
|
elif obj_type.is_extension_type or obj_type.is_builtin_type:
|
|
self.op = "->"
|
|
elif obj_type.is_reference and obj_type.is_fake_reference:
|
|
self.op = "->"
|
|
else:
|
|
self.op = "."
|
|
if obj_type.has_attributes:
|
|
if obj_type.attributes_known():
|
|
entry = obj_type.scope.lookup_here(self.attribute)
|
|
if obj_type.is_memoryviewslice and not entry:
|
|
if self.attribute == 'T':
|
|
self.is_memslice_transpose = True
|
|
self.is_temp = True
|
|
self.use_managed_ref = True
|
|
self.type = self.obj.type.transpose(self.pos)
|
|
return
|
|
else:
|
|
obj_type.declare_attribute(self.attribute, env, self.pos)
|
|
entry = obj_type.scope.lookup_here(self.attribute)
|
|
if entry and entry.is_member:
|
|
entry = None
|
|
else:
|
|
error(self.pos,
|
|
"Cannot select attribute of incomplete type '%s'"
|
|
% obj_type)
|
|
self.type = PyrexTypes.error_type
|
|
return
|
|
self.entry = entry
|
|
if entry:
|
|
if obj_type.is_extension_type and entry.name == "__weakref__":
|
|
error(self.pos, "Illegal use of special attribute __weakref__")
|
|
|
|
# def methods need the normal attribute lookup
|
|
# because they do not have struct entries
|
|
# fused function go through assignment synthesis
|
|
# (foo = pycfunction(foo_func_obj)) and need to go through
|
|
# regular Python lookup as well
|
|
if (entry.is_variable and not entry.fused_cfunction) or entry.is_cmethod:
|
|
self.type = entry.type
|
|
self.member = entry.cname
|
|
return
|
|
else:
|
|
# If it's not a variable or C method, it must be a Python
|
|
# method of an extension type, so we treat it like a Python
|
|
# attribute.
|
|
pass
|
|
# If we get here, the base object is not a struct/union/extension
|
|
# type, or it is an extension type and the attribute is either not
|
|
# declared or is declared as a Python method. Treat it as a Python
|
|
# attribute reference.
|
|
self.analyse_as_python_attribute(env, obj_type, immutable_obj)
|
|
|
|
def analyse_as_python_attribute(self, env, obj_type=None, immutable_obj=False):
|
|
if obj_type is None:
|
|
obj_type = self.obj.type
|
|
# mangle private '__*' Python attributes used inside of a class
|
|
self.attribute = env.mangle_class_private_name(self.attribute)
|
|
self.member = self.attribute
|
|
self.type = py_object_type
|
|
self.is_py_attr = 1
|
|
|
|
if not obj_type.is_pyobject and not obj_type.is_error:
|
|
# Expose python methods for immutable objects.
|
|
if (obj_type.is_string or obj_type.is_cpp_string
|
|
or obj_type.is_buffer or obj_type.is_memoryviewslice
|
|
or obj_type.is_numeric
|
|
or (obj_type.is_ctuple and obj_type.can_coerce_to_pyobject(env))
|
|
or (obj_type.is_struct and obj_type.can_coerce_to_pyobject(env))):
|
|
if not immutable_obj:
|
|
self.obj = self.obj.coerce_to_pyobject(env)
|
|
elif (obj_type.is_cfunction and (self.obj.is_name or self.obj.is_attribute)
|
|
and self.obj.entry.as_variable
|
|
and self.obj.entry.as_variable.type.is_pyobject):
|
|
# might be an optimised builtin function => unpack it
|
|
if not immutable_obj:
|
|
self.obj = self.obj.coerce_to_pyobject(env)
|
|
else:
|
|
error(self.pos,
|
|
"Object of type '%s' has no attribute '%s'" %
|
|
(obj_type, self.attribute))
|
|
|
|
def wrap_obj_in_nonecheck(self, env):
|
|
if not env.directives['nonecheck']:
|
|
return
|
|
|
|
msg = None
|
|
format_args = ()
|
|
if (self.obj.type.is_extension_type and self.needs_none_check and not
|
|
self.is_py_attr):
|
|
msg = "'NoneType' object has no attribute '%{0}s'".format('.30' if len(self.attribute) <= 30 else '')
|
|
format_args = (self.attribute,)
|
|
elif self.obj.type.is_memoryviewslice:
|
|
if self.is_memslice_transpose:
|
|
msg = "Cannot transpose None memoryview slice"
|
|
else:
|
|
entry = self.obj.type.scope.lookup_here(self.attribute)
|
|
if entry:
|
|
# copy/is_c_contig/shape/strides etc
|
|
msg = "Cannot access '%s' attribute of None memoryview slice"
|
|
format_args = (entry.name,)
|
|
|
|
if msg:
|
|
self.obj = self.obj.as_none_safe_node(msg, 'PyExc_AttributeError',
|
|
format_args=format_args)
|
|
|
|
def nogil_check(self, env):
|
|
if self.is_py_attr:
|
|
self.gil_error()
|
|
|
|
gil_message = "Accessing Python attribute"
|
|
|
|
def is_cimported_module_without_shadow(self, env):
|
|
return self.obj.is_cimported_module_without_shadow(env)
|
|
|
|
def is_simple(self):
|
|
if self.obj:
|
|
return self.result_in_temp() or self.obj.is_simple()
|
|
else:
|
|
return NameNode.is_simple(self)
|
|
|
|
def is_lvalue(self):
|
|
if self.obj:
|
|
return True
|
|
else:
|
|
return NameNode.is_lvalue(self)
|
|
|
|
def is_ephemeral(self):
|
|
if self.obj:
|
|
return self.obj.is_ephemeral()
|
|
else:
|
|
return NameNode.is_ephemeral(self)
|
|
|
|
def calculate_result_code(self):
|
|
#print "AttributeNode.calculate_result_code:", self.member ###
|
|
#print "...obj node =", self.obj, "code", self.obj.result() ###
|
|
#print "...obj type", self.obj.type, "ctype", self.obj.ctype() ###
|
|
obj = self.obj
|
|
obj_code = obj.result_as(obj.type)
|
|
#print "...obj_code =", obj_code ###
|
|
if self.entry and self.entry.is_cmethod:
|
|
if obj.type.is_extension_type and not self.entry.is_builtin_cmethod:
|
|
if self.entry.final_func_cname:
|
|
return self.entry.final_func_cname
|
|
|
|
if self.type.from_fused:
|
|
# If the attribute was specialized through indexing, make
|
|
# sure to get the right fused name, as our entry was
|
|
# replaced by our parent index node
|
|
# (AnalyseExpressionsTransform)
|
|
self.member = self.entry.cname
|
|
|
|
return "((struct %s *)%s%s%s)->%s" % (
|
|
obj.type.vtabstruct_cname, obj_code, self.op,
|
|
obj.type.vtabslot_cname, self.member)
|
|
elif self.result_is_used:
|
|
return self.member
|
|
# Generating no code at all for unused access to optimised builtin
|
|
# methods fixes the problem that some optimisations only exist as
|
|
# macros, i.e. there is no function pointer to them, so we would
|
|
# generate invalid C code here.
|
|
return
|
|
elif obj.type.is_complex:
|
|
return "__Pyx_C%s(%s)" % (self.member.upper(), obj_code)
|
|
else:
|
|
if obj.type.is_builtin_type and self.entry and self.entry.is_variable:
|
|
# accessing a field of a builtin type, need to cast better than result_as() does
|
|
obj_code = obj.type.cast_code(obj.result(), to_object_struct = True)
|
|
return "%s%s%s" % (obj_code, self.op, self.member)
|
|
|
|
def generate_result_code(self, code):
|
|
if self.is_py_attr:
|
|
if self.is_special_lookup:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectLookupSpecial", "ObjectHandling.c"))
|
|
lookup_func_name = '__Pyx_PyObject_LookupSpecial'
|
|
else:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectGetAttrStr", "ObjectHandling.c"))
|
|
lookup_func_name = '__Pyx_PyObject_GetAttrStr'
|
|
code.putln(
|
|
'%s = %s(%s, %s); %s' % (
|
|
self.result(),
|
|
lookup_func_name,
|
|
self.obj.py_result(),
|
|
code.intern_identifier(self.attribute),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
elif self.type.is_memoryviewslice:
|
|
if self.is_memslice_transpose:
|
|
# transpose the slice
|
|
for access, packing in self.type.axes:
|
|
if access == 'ptr':
|
|
error(self.pos, "Transposing not supported for slices "
|
|
"with indirect dimensions")
|
|
return
|
|
|
|
code.putln("%s = %s;" % (self.result(), self.obj.result()))
|
|
code.put_incref_memoryviewslice(self.result(), have_gil=True)
|
|
|
|
T = "__pyx_memslice_transpose(&%s) == 0"
|
|
code.putln(code.error_goto_if(T % self.result(), self.pos))
|
|
elif self.initialized_check:
|
|
code.putln(
|
|
'if (unlikely(!%s.memview)) {'
|
|
'PyErr_SetString(PyExc_AttributeError,'
|
|
'"Memoryview is not initialized");'
|
|
'%s'
|
|
'}' % (self.result(), code.error_goto(self.pos)))
|
|
else:
|
|
# result_code contains what is needed, but we may need to insert
|
|
# a check and raise an exception
|
|
if self.obj.type and self.obj.type.is_extension_type:
|
|
pass
|
|
elif self.entry and self.entry.is_cmethod:
|
|
# C method implemented as function call with utility code
|
|
code.globalstate.use_entry_utility_code(self.entry)
|
|
|
|
def generate_disposal_code(self, code):
|
|
if self.is_temp and self.type.is_memoryviewslice and self.is_memslice_transpose:
|
|
# mirror condition for putting the memview incref here:
|
|
code.put_xdecref_memoryviewslice(
|
|
self.result(), have_gil=True)
|
|
code.putln("%s.memview = NULL;" % self.result())
|
|
code.putln("%s.data = NULL;" % self.result())
|
|
else:
|
|
ExprNode.generate_disposal_code(self, code)
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False,
|
|
exception_check=None, exception_value=None):
|
|
self.obj.generate_evaluation_code(code)
|
|
if self.is_py_attr:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectSetAttrStr", "ObjectHandling.c"))
|
|
code.put_error_if_neg(self.pos,
|
|
'__Pyx_PyObject_SetAttrStr(%s, %s, %s)' % (
|
|
self.obj.py_result(),
|
|
code.intern_identifier(self.attribute),
|
|
rhs.py_result()))
|
|
rhs.generate_disposal_code(code)
|
|
rhs.free_temps(code)
|
|
elif self.obj.type.is_complex:
|
|
code.putln("__Pyx_SET_C%s(%s, %s);" % (
|
|
self.member.upper(),
|
|
self.obj.result_as(self.obj.type),
|
|
rhs.result_as(self.ctype())))
|
|
else:
|
|
select_code = self.result()
|
|
if self.type.is_pyobject and self.use_managed_ref:
|
|
rhs.make_owned_reference(code)
|
|
code.put_giveref(rhs.py_result())
|
|
code.put_gotref(select_code)
|
|
code.put_decref(select_code, self.ctype())
|
|
elif self.type.is_memoryviewslice:
|
|
from . import MemoryView
|
|
MemoryView.put_assign_to_memviewslice(
|
|
select_code, rhs, rhs.result(), self.type, code)
|
|
|
|
if not self.type.is_memoryviewslice:
|
|
code.putln(
|
|
"%s = %s;" % (
|
|
select_code,
|
|
rhs.result_as(self.ctype())))
|
|
#rhs.result()))
|
|
rhs.generate_post_assignment_code(code)
|
|
rhs.free_temps(code)
|
|
self.obj.generate_disposal_code(code)
|
|
self.obj.free_temps(code)
|
|
|
|
def generate_deletion_code(self, code, ignore_nonexisting=False):
|
|
self.obj.generate_evaluation_code(code)
|
|
if self.is_py_attr or (self.entry.scope.is_property_scope
|
|
and u'__del__' in self.entry.scope.entries):
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyObjectSetAttrStr", "ObjectHandling.c"))
|
|
code.put_error_if_neg(self.pos,
|
|
'__Pyx_PyObject_DelAttrStr(%s, %s)' % (
|
|
self.obj.py_result(),
|
|
code.intern_identifier(self.attribute)))
|
|
else:
|
|
error(self.pos, "Cannot delete C attribute of extension type")
|
|
self.obj.generate_disposal_code(code)
|
|
self.obj.free_temps(code)
|
|
|
|
def annotate(self, code):
|
|
if self.is_py_attr:
|
|
style, text = 'py_attr', 'python attribute (%s)'
|
|
else:
|
|
style, text = 'c_attr', 'c attribute (%s)'
|
|
code.annotate(self.pos, AnnotationItem(style, text % self.type, size=len(self.attribute)))
|
|
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# Constructor nodes
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
class StarredUnpackingNode(ExprNode):
|
|
# A starred expression like "*a"
|
|
#
|
|
# This is only allowed in sequence assignment or construction such as
|
|
#
|
|
# a, *b = (1,2,3,4) => a = 1 ; b = [2,3,4]
|
|
#
|
|
# and will be special cased during type analysis (or generate an error
|
|
# if it's found at unexpected places).
|
|
#
|
|
# target ExprNode
|
|
|
|
subexprs = ['target']
|
|
is_starred = 1
|
|
type = py_object_type
|
|
is_temp = 1
|
|
starred_expr_allowed_here = False
|
|
|
|
def __init__(self, pos, target):
|
|
ExprNode.__init__(self, pos, target=target)
|
|
|
|
def analyse_declarations(self, env):
|
|
if not self.starred_expr_allowed_here:
|
|
error(self.pos, "starred expression is not allowed here")
|
|
self.target.analyse_declarations(env)
|
|
|
|
def infer_type(self, env):
|
|
return self.target.infer_type(env)
|
|
|
|
def analyse_types(self, env):
|
|
if not self.starred_expr_allowed_here:
|
|
error(self.pos, "starred expression is not allowed here")
|
|
self.target = self.target.analyse_types(env)
|
|
self.type = self.target.type
|
|
return self
|
|
|
|
def analyse_target_declaration(self, env):
|
|
self.target.analyse_target_declaration(env)
|
|
|
|
def analyse_target_types(self, env):
|
|
self.target = self.target.analyse_target_types(env)
|
|
self.type = self.target.type
|
|
return self
|
|
|
|
def calculate_result_code(self):
|
|
return ""
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
class SequenceNode(ExprNode):
|
|
# Base class for list and tuple constructor nodes.
|
|
# Contains common code for performing sequence unpacking.
|
|
#
|
|
# args [ExprNode]
|
|
# unpacked_items [ExprNode] or None
|
|
# coerced_unpacked_items [ExprNode] or None
|
|
# mult_factor ExprNode the integer number of content repetitions ([1,2]*3)
|
|
|
|
subexprs = ['args', 'mult_factor']
|
|
|
|
is_sequence_constructor = 1
|
|
unpacked_items = None
|
|
mult_factor = None
|
|
slow = False # trade speed for code size (e.g. use PyTuple_Pack())
|
|
|
|
def compile_time_value_list(self, denv):
|
|
return [arg.compile_time_value(denv) for arg in self.args]
|
|
|
|
def replace_starred_target_node(self):
|
|
# replace a starred node in the targets by the contained expression
|
|
self.starred_assignment = False
|
|
args = []
|
|
for arg in self.args:
|
|
if arg.is_starred:
|
|
if self.starred_assignment:
|
|
error(arg.pos, "more than 1 starred expression in assignment")
|
|
self.starred_assignment = True
|
|
arg = arg.target
|
|
arg.is_starred = True
|
|
args.append(arg)
|
|
self.args = args
|
|
|
|
def analyse_target_declaration(self, env):
|
|
self.replace_starred_target_node()
|
|
for arg in self.args:
|
|
arg.analyse_target_declaration(env)
|
|
|
|
def analyse_types(self, env, skip_children=False):
|
|
for i, arg in enumerate(self.args):
|
|
if not skip_children:
|
|
arg = arg.analyse_types(env)
|
|
self.args[i] = arg.coerce_to_pyobject(env)
|
|
if self.mult_factor:
|
|
self.mult_factor = self.mult_factor.analyse_types(env)
|
|
if not self.mult_factor.type.is_int:
|
|
self.mult_factor = self.mult_factor.coerce_to_pyobject(env)
|
|
self.is_temp = 1
|
|
# not setting self.type here, subtypes do this
|
|
return self
|
|
|
|
def coerce_to_ctuple(self, dst_type, env):
|
|
if self.type == dst_type:
|
|
return self
|
|
assert not self.mult_factor
|
|
if len(self.args) != dst_type.size:
|
|
error(self.pos, "trying to coerce sequence to ctuple of wrong length, expected %d, got %d" % (
|
|
dst_type.size, len(self.args)))
|
|
coerced_args = [arg.coerce_to(type, env) for arg, type in zip(self.args, dst_type.components)]
|
|
return TupleNode(self.pos, args=coerced_args, type=dst_type, is_temp=True)
|
|
|
|
def _create_merge_node_if_necessary(self, env):
|
|
self._flatten_starred_args()
|
|
if not any(arg.is_starred for arg in self.args):
|
|
return self
|
|
# convert into MergedSequenceNode by building partial sequences
|
|
args = []
|
|
values = []
|
|
for arg in self.args:
|
|
if arg.is_starred:
|
|
if values:
|
|
args.append(TupleNode(values[0].pos, args=values).analyse_types(env, skip_children=True))
|
|
values = []
|
|
args.append(arg.target)
|
|
else:
|
|
values.append(arg)
|
|
if values:
|
|
args.append(TupleNode(values[0].pos, args=values).analyse_types(env, skip_children=True))
|
|
node = MergedSequenceNode(self.pos, args, self.type)
|
|
if self.mult_factor:
|
|
node = binop_node(
|
|
self.pos, '*', node, self.mult_factor.coerce_to_pyobject(env),
|
|
inplace=True, type=self.type, is_temp=True)
|
|
return node
|
|
|
|
def _flatten_starred_args(self):
|
|
args = []
|
|
for arg in self.args:
|
|
if arg.is_starred and arg.target.is_sequence_constructor and not arg.target.mult_factor:
|
|
args.extend(arg.target.args)
|
|
else:
|
|
args.append(arg)
|
|
self.args[:] = args
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def analyse_target_types(self, env):
|
|
if self.mult_factor:
|
|
error(self.pos, "can't assign to multiplied sequence")
|
|
self.unpacked_items = []
|
|
self.coerced_unpacked_items = []
|
|
self.any_coerced_items = False
|
|
for i, arg in enumerate(self.args):
|
|
arg = self.args[i] = arg.analyse_target_types(env)
|
|
if arg.is_starred:
|
|
if not arg.type.assignable_from(list_type):
|
|
error(arg.pos,
|
|
"starred target must have Python object (list) type")
|
|
if arg.type is py_object_type:
|
|
arg.type = list_type
|
|
unpacked_item = PyTempNode(self.pos, env)
|
|
coerced_unpacked_item = unpacked_item.coerce_to(arg.type, env)
|
|
if unpacked_item is not coerced_unpacked_item:
|
|
self.any_coerced_items = True
|
|
self.unpacked_items.append(unpacked_item)
|
|
self.coerced_unpacked_items.append(coerced_unpacked_item)
|
|
self.type = py_object_type
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
self.generate_operation_code(code)
|
|
|
|
def generate_sequence_packing_code(self, code, target=None, plain=False):
|
|
if target is None:
|
|
target = self.result()
|
|
size_factor = c_mult = ''
|
|
mult_factor = None
|
|
|
|
if self.mult_factor and not plain:
|
|
mult_factor = self.mult_factor
|
|
if mult_factor.type.is_int:
|
|
c_mult = mult_factor.result()
|
|
if (isinstance(mult_factor.constant_result, _py_int_types) and
|
|
mult_factor.constant_result > 0):
|
|
size_factor = ' * %s' % mult_factor.constant_result
|
|
elif mult_factor.type.signed:
|
|
size_factor = ' * ((%s<0) ? 0:%s)' % (c_mult, c_mult)
|
|
else:
|
|
size_factor = ' * (%s)' % (c_mult,)
|
|
|
|
if self.type is tuple_type and (self.is_literal or self.slow) and not c_mult:
|
|
# use PyTuple_Pack() to avoid generating huge amounts of one-time code
|
|
code.putln('%s = PyTuple_Pack(%d, %s); %s' % (
|
|
target,
|
|
len(self.args),
|
|
', '.join(arg.py_result() for arg in self.args),
|
|
code.error_goto_if_null(target, self.pos)))
|
|
code.put_gotref(target)
|
|
elif self.type.is_ctuple:
|
|
for i, arg in enumerate(self.args):
|
|
code.putln("%s.f%s = %s;" % (
|
|
target, i, arg.result()))
|
|
else:
|
|
# build the tuple/list step by step, potentially multiplying it as we go
|
|
if self.type is list_type:
|
|
create_func, set_item_func = 'PyList_New', 'PyList_SET_ITEM'
|
|
elif self.type is tuple_type:
|
|
create_func, set_item_func = 'PyTuple_New', 'PyTuple_SET_ITEM'
|
|
else:
|
|
raise InternalError("sequence packing for unexpected type %s" % self.type)
|
|
arg_count = len(self.args)
|
|
code.putln("%s = %s(%s%s); %s" % (
|
|
target, create_func, arg_count, size_factor,
|
|
code.error_goto_if_null(target, self.pos)))
|
|
code.put_gotref(target)
|
|
|
|
if c_mult:
|
|
# FIXME: can't use a temp variable here as the code may
|
|
# end up in the constant building function. Temps
|
|
# currently don't work there.
|
|
|
|
#counter = code.funcstate.allocate_temp(mult_factor.type, manage_ref=False)
|
|
counter = Naming.quick_temp_cname
|
|
code.putln('{ Py_ssize_t %s;' % counter)
|
|
if arg_count == 1:
|
|
offset = counter
|
|
else:
|
|
offset = '%s * %s' % (counter, arg_count)
|
|
code.putln('for (%s=0; %s < %s; %s++) {' % (
|
|
counter, counter, c_mult, counter
|
|
))
|
|
else:
|
|
offset = ''
|
|
|
|
for i in range(arg_count):
|
|
arg = self.args[i]
|
|
if c_mult or not arg.result_in_temp():
|
|
code.put_incref(arg.result(), arg.ctype())
|
|
code.put_giveref(arg.py_result())
|
|
code.putln("%s(%s, %s, %s);" % (
|
|
set_item_func,
|
|
target,
|
|
(offset and i) and ('%s + %s' % (offset, i)) or (offset or i),
|
|
arg.py_result()))
|
|
|
|
if c_mult:
|
|
code.putln('}')
|
|
#code.funcstate.release_temp(counter)
|
|
code.putln('}')
|
|
|
|
if mult_factor is not None and mult_factor.type.is_pyobject:
|
|
code.putln('{ PyObject* %s = PyNumber_InPlaceMultiply(%s, %s); %s' % (
|
|
Naming.quick_temp_cname, target, mult_factor.py_result(),
|
|
code.error_goto_if_null(Naming.quick_temp_cname, self.pos)
|
|
))
|
|
code.put_gotref(Naming.quick_temp_cname)
|
|
code.put_decref(target, py_object_type)
|
|
code.putln('%s = %s;' % (target, Naming.quick_temp_cname))
|
|
code.putln('}')
|
|
|
|
def generate_subexpr_disposal_code(self, code):
|
|
if self.mult_factor and self.mult_factor.type.is_int:
|
|
super(SequenceNode, self).generate_subexpr_disposal_code(code)
|
|
elif self.type is tuple_type and (self.is_literal or self.slow):
|
|
super(SequenceNode, self).generate_subexpr_disposal_code(code)
|
|
else:
|
|
# We call generate_post_assignment_code here instead
|
|
# of generate_disposal_code, because values were stored
|
|
# in the tuple using a reference-stealing operation.
|
|
for arg in self.args:
|
|
arg.generate_post_assignment_code(code)
|
|
# Should NOT call free_temps -- this is invoked by the default
|
|
# generate_evaluation_code which will do that.
|
|
if self.mult_factor:
|
|
self.mult_factor.generate_disposal_code(code)
|
|
|
|
def generate_assignment_code(self, rhs, code, overloaded_assignment=False,
|
|
exception_check=None, exception_value=None):
|
|
if self.starred_assignment:
|
|
self.generate_starred_assignment_code(rhs, code)
|
|
else:
|
|
self.generate_parallel_assignment_code(rhs, code)
|
|
|
|
for item in self.unpacked_items:
|
|
item.release(code)
|
|
rhs.free_temps(code)
|
|
|
|
_func_iternext_type = PyrexTypes.CPtrType(PyrexTypes.CFuncType(
|
|
PyrexTypes.py_object_type, [
|
|
PyrexTypes.CFuncTypeArg("it", PyrexTypes.py_object_type, None),
|
|
]))
|
|
|
|
def generate_parallel_assignment_code(self, rhs, code):
|
|
# Need to work around the fact that generate_evaluation_code
|
|
# allocates the temps in a rather hacky way -- the assignment
|
|
# is evaluated twice, within each if-block.
|
|
for item in self.unpacked_items:
|
|
item.allocate(code)
|
|
special_unpack = (rhs.type is py_object_type
|
|
or rhs.type in (tuple_type, list_type)
|
|
or not rhs.type.is_builtin_type)
|
|
long_enough_for_a_loop = len(self.unpacked_items) > 3
|
|
|
|
if special_unpack:
|
|
self.generate_special_parallel_unpacking_code(
|
|
code, rhs, use_loop=long_enough_for_a_loop)
|
|
else:
|
|
code.putln("{")
|
|
self.generate_generic_parallel_unpacking_code(
|
|
code, rhs, self.unpacked_items, use_loop=long_enough_for_a_loop)
|
|
code.putln("}")
|
|
|
|
for value_node in self.coerced_unpacked_items:
|
|
value_node.generate_evaluation_code(code)
|
|
for i in range(len(self.args)):
|
|
self.args[i].generate_assignment_code(
|
|
self.coerced_unpacked_items[i], code)
|
|
|
|
def generate_special_parallel_unpacking_code(self, code, rhs, use_loop):
|
|
sequence_type_test = '1'
|
|
none_check = "likely(%s != Py_None)" % rhs.py_result()
|
|
if rhs.type is list_type:
|
|
sequence_types = ['List']
|
|
if rhs.may_be_none():
|
|
sequence_type_test = none_check
|
|
elif rhs.type is tuple_type:
|
|
sequence_types = ['Tuple']
|
|
if rhs.may_be_none():
|
|
sequence_type_test = none_check
|
|
else:
|
|
sequence_types = ['Tuple', 'List']
|
|
tuple_check = 'likely(PyTuple_CheckExact(%s))' % rhs.py_result()
|
|
list_check = 'PyList_CheckExact(%s)' % rhs.py_result()
|
|
sequence_type_test = "(%s) || (%s)" % (tuple_check, list_check)
|
|
|
|
code.putln("if (%s) {" % sequence_type_test)
|
|
code.putln("PyObject* sequence = %s;" % rhs.py_result())
|
|
|
|
# list/tuple => check size
|
|
code.putln("Py_ssize_t size = __Pyx_PySequence_SIZE(sequence);")
|
|
code.putln("if (unlikely(size != %d)) {" % len(self.args))
|
|
code.globalstate.use_utility_code(raise_too_many_values_to_unpack)
|
|
code.putln("if (size > %d) __Pyx_RaiseTooManyValuesError(%d);" % (
|
|
len(self.args), len(self.args)))
|
|
code.globalstate.use_utility_code(raise_need_more_values_to_unpack)
|
|
code.putln("else if (size >= 0) __Pyx_RaiseNeedMoreValuesError(size);")
|
|
# < 0 => exception
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
|
|
code.putln("#if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS")
|
|
# unpack items from list/tuple in unrolled loop (can't fail)
|
|
if len(sequence_types) == 2:
|
|
code.putln("if (likely(Py%s_CheckExact(sequence))) {" % sequence_types[0])
|
|
for i, item in enumerate(self.unpacked_items):
|
|
code.putln("%s = Py%s_GET_ITEM(sequence, %d); " % (
|
|
item.result(), sequence_types[0], i))
|
|
if len(sequence_types) == 2:
|
|
code.putln("} else {")
|
|
for i, item in enumerate(self.unpacked_items):
|
|
code.putln("%s = Py%s_GET_ITEM(sequence, %d); " % (
|
|
item.result(), sequence_types[1], i))
|
|
code.putln("}")
|
|
for item in self.unpacked_items:
|
|
code.put_incref(item.result(), item.ctype())
|
|
|
|
code.putln("#else")
|
|
# in non-CPython, use the PySequence protocol (which can fail)
|
|
if not use_loop:
|
|
for i, item in enumerate(self.unpacked_items):
|
|
code.putln("%s = PySequence_ITEM(sequence, %d); %s" % (
|
|
item.result(), i,
|
|
code.error_goto_if_null(item.result(), self.pos)))
|
|
code.put_gotref(item.result())
|
|
else:
|
|
code.putln("{")
|
|
code.putln("Py_ssize_t i;")
|
|
code.putln("PyObject** temps[%s] = {%s};" % (
|
|
len(self.unpacked_items),
|
|
','.join(['&%s' % item.result() for item in self.unpacked_items])))
|
|
code.putln("for (i=0; i < %s; i++) {" % len(self.unpacked_items))
|
|
code.putln("PyObject* item = PySequence_ITEM(sequence, i); %s" % (
|
|
code.error_goto_if_null('item', self.pos)))
|
|
code.put_gotref('item')
|
|
code.putln("*(temps[i]) = item;")
|
|
code.putln("}")
|
|
code.putln("}")
|
|
|
|
code.putln("#endif")
|
|
rhs.generate_disposal_code(code)
|
|
|
|
if sequence_type_test == '1':
|
|
code.putln("}") # all done
|
|
elif sequence_type_test == none_check:
|
|
# either tuple/list or None => save some code by generating the error directly
|
|
code.putln("} else {")
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("RaiseNoneIterError", "ObjectHandling.c"))
|
|
code.putln("__Pyx_RaiseNoneNotIterableError(); %s" % code.error_goto(self.pos))
|
|
code.putln("}") # all done
|
|
else:
|
|
code.putln("} else {") # needs iteration fallback code
|
|
self.generate_generic_parallel_unpacking_code(
|
|
code, rhs, self.unpacked_items, use_loop=use_loop)
|
|
code.putln("}")
|
|
|
|
def generate_generic_parallel_unpacking_code(self, code, rhs, unpacked_items, use_loop, terminate=True):
|
|
code.globalstate.use_utility_code(raise_need_more_values_to_unpack)
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("IterFinish", "ObjectHandling.c"))
|
|
code.putln("Py_ssize_t index = -1;") # must be at the start of a C block!
|
|
|
|
if use_loop:
|
|
code.putln("PyObject** temps[%s] = {%s};" % (
|
|
len(self.unpacked_items),
|
|
','.join(['&%s' % item.result() for item in unpacked_items])))
|
|
|
|
iterator_temp = code.funcstate.allocate_temp(py_object_type, manage_ref=True)
|
|
code.putln(
|
|
"%s = PyObject_GetIter(%s); %s" % (
|
|
iterator_temp,
|
|
rhs.py_result(),
|
|
code.error_goto_if_null(iterator_temp, self.pos)))
|
|
code.put_gotref(iterator_temp)
|
|
rhs.generate_disposal_code(code)
|
|
|
|
iternext_func = code.funcstate.allocate_temp(self._func_iternext_type, manage_ref=False)
|
|
code.putln("%s = Py_TYPE(%s)->tp_iternext;" % (
|
|
iternext_func, iterator_temp))
|
|
|
|
unpacking_error_label = code.new_label('unpacking_failed')
|
|
unpack_code = "%s(%s)" % (iternext_func, iterator_temp)
|
|
if use_loop:
|
|
code.putln("for (index=0; index < %s; index++) {" % len(unpacked_items))
|
|
code.put("PyObject* item = %s; if (unlikely(!item)) " % unpack_code)
|
|
code.put_goto(unpacking_error_label)
|
|
code.put_gotref("item")
|
|
code.putln("*(temps[index]) = item;")
|
|
code.putln("}")
|
|
else:
|
|
for i, item in enumerate(unpacked_items):
|
|
code.put(
|
|
"index = %d; %s = %s; if (unlikely(!%s)) " % (
|
|
i,
|
|
item.result(),
|
|
unpack_code,
|
|
item.result()))
|
|
code.put_goto(unpacking_error_label)
|
|
code.put_gotref(item.py_result())
|
|
|
|
if terminate:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("UnpackItemEndCheck", "ObjectHandling.c"))
|
|
code.put_error_if_neg(self.pos, "__Pyx_IternextUnpackEndCheck(%s, %d)" % (
|
|
unpack_code,
|
|
len(unpacked_items)))
|
|
code.putln("%s = NULL;" % iternext_func)
|
|
code.put_decref_clear(iterator_temp, py_object_type)
|
|
|
|
unpacking_done_label = code.new_label('unpacking_done')
|
|
code.put_goto(unpacking_done_label)
|
|
|
|
code.put_label(unpacking_error_label)
|
|
code.put_decref_clear(iterator_temp, py_object_type)
|
|
code.putln("%s = NULL;" % iternext_func)
|
|
code.putln("if (__Pyx_IterFinish() == 0) __Pyx_RaiseNeedMoreValuesError(index);")
|
|
code.putln(code.error_goto(self.pos))
|
|
code.put_label(unpacking_done_label)
|
|
|
|
code.funcstate.release_temp(iternext_func)
|
|
if terminate:
|
|
code.funcstate.release_temp(iterator_temp)
|
|
iterator_temp = None
|
|
|
|
return iterator_temp
|
|
|
|
def generate_starred_assignment_code(self, rhs, code):
|
|
for i, arg in enumerate(self.args):
|
|
if arg.is_starred:
|
|
starred_target = self.unpacked_items[i]
|
|
unpacked_fixed_items_left = self.unpacked_items[:i]
|
|
unpacked_fixed_items_right = self.unpacked_items[i+1:]
|
|
break
|
|
else:
|
|
assert False
|
|
|
|
iterator_temp = None
|
|
if unpacked_fixed_items_left:
|
|
for item in unpacked_fixed_items_left:
|
|
item.allocate(code)
|
|
code.putln('{')
|
|
iterator_temp = self.generate_generic_parallel_unpacking_code(
|
|
code, rhs, unpacked_fixed_items_left,
|
|
use_loop=True, terminate=False)
|
|
for i, item in enumerate(unpacked_fixed_items_left):
|
|
value_node = self.coerced_unpacked_items[i]
|
|
value_node.generate_evaluation_code(code)
|
|
code.putln('}')
|
|
|
|
starred_target.allocate(code)
|
|
target_list = starred_target.result()
|
|
code.putln("%s = PySequence_List(%s); %s" % (
|
|
target_list,
|
|
iterator_temp or rhs.py_result(),
|
|
code.error_goto_if_null(target_list, self.pos)))
|
|
code.put_gotref(target_list)
|
|
|
|
if iterator_temp:
|
|
code.put_decref_clear(iterator_temp, py_object_type)
|
|
code.funcstate.release_temp(iterator_temp)
|
|
else:
|
|
rhs.generate_disposal_code(code)
|
|
|
|
if unpacked_fixed_items_right:
|
|
code.globalstate.use_utility_code(raise_need_more_values_to_unpack)
|
|
length_temp = code.funcstate.allocate_temp(PyrexTypes.c_py_ssize_t_type, manage_ref=False)
|
|
code.putln('%s = PyList_GET_SIZE(%s);' % (length_temp, target_list))
|
|
code.putln("if (unlikely(%s < %d)) {" % (length_temp, len(unpacked_fixed_items_right)))
|
|
code.putln("__Pyx_RaiseNeedMoreValuesError(%d+%s); %s" % (
|
|
len(unpacked_fixed_items_left), length_temp,
|
|
code.error_goto(self.pos)))
|
|
code.putln('}')
|
|
|
|
for item in unpacked_fixed_items_right[::-1]:
|
|
item.allocate(code)
|
|
for i, (item, coerced_arg) in enumerate(zip(unpacked_fixed_items_right[::-1],
|
|
self.coerced_unpacked_items[::-1])):
|
|
code.putln('#if CYTHON_COMPILING_IN_CPYTHON')
|
|
code.putln("%s = PyList_GET_ITEM(%s, %s-%d); " % (
|
|
item.py_result(), target_list, length_temp, i+1))
|
|
# resize the list the hard way
|
|
code.putln("((PyVarObject*)%s)->ob_size--;" % target_list)
|
|
code.putln('#else')
|
|
code.putln("%s = PySequence_ITEM(%s, %s-%d); " % (
|
|
item.py_result(), target_list, length_temp, i+1))
|
|
code.putln('#endif')
|
|
code.put_gotref(item.py_result())
|
|
coerced_arg.generate_evaluation_code(code)
|
|
|
|
code.putln('#if !CYTHON_COMPILING_IN_CPYTHON')
|
|
sublist_temp = code.funcstate.allocate_temp(py_object_type, manage_ref=True)
|
|
code.putln('%s = PySequence_GetSlice(%s, 0, %s-%d); %s' % (
|
|
sublist_temp, target_list, length_temp, len(unpacked_fixed_items_right),
|
|
code.error_goto_if_null(sublist_temp, self.pos)))
|
|
code.put_gotref(sublist_temp)
|
|
code.funcstate.release_temp(length_temp)
|
|
code.put_decref(target_list, py_object_type)
|
|
code.putln('%s = %s; %s = NULL;' % (target_list, sublist_temp, sublist_temp))
|
|
code.putln('#else')
|
|
code.putln('(void)%s;' % sublist_temp) # avoid warning about unused variable
|
|
code.funcstate.release_temp(sublist_temp)
|
|
code.putln('#endif')
|
|
|
|
for i, arg in enumerate(self.args):
|
|
arg.generate_assignment_code(self.coerced_unpacked_items[i], code)
|
|
|
|
def annotate(self, code):
|
|
for arg in self.args:
|
|
arg.annotate(code)
|
|
if self.unpacked_items:
|
|
for arg in self.unpacked_items:
|
|
arg.annotate(code)
|
|
for arg in self.coerced_unpacked_items:
|
|
arg.annotate(code)
|
|
|
|
|
|
class TupleNode(SequenceNode):
|
|
# Tuple constructor.
|
|
|
|
type = tuple_type
|
|
is_partly_literal = False
|
|
|
|
gil_message = "Constructing Python tuple"
|
|
|
|
def infer_type(self, env):
|
|
if self.mult_factor or not self.args:
|
|
return tuple_type
|
|
arg_types = [arg.infer_type(env) for arg in self.args]
|
|
if any(type.is_pyobject or type.is_memoryviewslice or type.is_unspecified or type.is_fused
|
|
for type in arg_types):
|
|
return tuple_type
|
|
return env.declare_tuple_type(self.pos, arg_types).type
|
|
|
|
def analyse_types(self, env, skip_children=False):
|
|
if len(self.args) == 0:
|
|
self.is_temp = False
|
|
self.is_literal = True
|
|
return self
|
|
|
|
if not skip_children:
|
|
for i, arg in enumerate(self.args):
|
|
if arg.is_starred:
|
|
arg.starred_expr_allowed_here = True
|
|
self.args[i] = arg.analyse_types(env)
|
|
if (not self.mult_factor and
|
|
not any((arg.is_starred or arg.type.is_pyobject or arg.type.is_memoryviewslice or arg.type.is_fused)
|
|
for arg in self.args)):
|
|
self.type = env.declare_tuple_type(self.pos, (arg.type for arg in self.args)).type
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
node = SequenceNode.analyse_types(self, env, skip_children=True)
|
|
node = node._create_merge_node_if_necessary(env)
|
|
if not node.is_sequence_constructor:
|
|
return node
|
|
|
|
if not all(child.is_literal for child in node.args):
|
|
return node
|
|
if not node.mult_factor or (
|
|
node.mult_factor.is_literal and
|
|
isinstance(node.mult_factor.constant_result, _py_int_types)):
|
|
node.is_temp = False
|
|
node.is_literal = True
|
|
else:
|
|
if not node.mult_factor.type.is_pyobject:
|
|
node.mult_factor = node.mult_factor.coerce_to_pyobject(env)
|
|
node.is_temp = True
|
|
node.is_partly_literal = True
|
|
return node
|
|
|
|
def analyse_as_type(self, env):
|
|
# ctuple type
|
|
if not self.args:
|
|
return None
|
|
item_types = [arg.analyse_as_type(env) for arg in self.args]
|
|
if any(t is None for t in item_types):
|
|
return None
|
|
entry = env.declare_tuple_type(self.pos, item_types)
|
|
return entry.type
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if self.type.is_ctuple:
|
|
if dst_type.is_ctuple and self.type.size == dst_type.size:
|
|
return self.coerce_to_ctuple(dst_type, env)
|
|
elif dst_type is tuple_type or dst_type is py_object_type:
|
|
coerced_args = [arg.coerce_to_pyobject(env) for arg in self.args]
|
|
return TupleNode(self.pos, args=coerced_args, type=tuple_type, is_temp=1).analyse_types(env, skip_children=True)
|
|
else:
|
|
return self.coerce_to_pyobject(env).coerce_to(dst_type, env)
|
|
elif dst_type.is_ctuple and not self.mult_factor:
|
|
return self.coerce_to_ctuple(dst_type, env)
|
|
else:
|
|
return SequenceNode.coerce_to(self, dst_type, env)
|
|
|
|
def as_list(self):
|
|
t = ListNode(self.pos, args=self.args, mult_factor=self.mult_factor)
|
|
if isinstance(self.constant_result, tuple):
|
|
t.constant_result = list(self.constant_result)
|
|
return t
|
|
|
|
def is_simple(self):
|
|
# either temp or constant => always simple
|
|
return True
|
|
|
|
def nonlocally_immutable(self):
|
|
# either temp or constant => always safe
|
|
return True
|
|
|
|
def calculate_result_code(self):
|
|
if len(self.args) > 0:
|
|
return self.result_code
|
|
else:
|
|
return Naming.empty_tuple
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = tuple([
|
|
arg.constant_result for arg in self.args])
|
|
|
|
def compile_time_value(self, denv):
|
|
values = self.compile_time_value_list(denv)
|
|
try:
|
|
return tuple(values)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def generate_operation_code(self, code):
|
|
if len(self.args) == 0:
|
|
# result_code is Naming.empty_tuple
|
|
return
|
|
|
|
if self.is_literal or self.is_partly_literal:
|
|
# The "mult_factor" is part of the deduplication if it is also constant, i.e. when
|
|
# we deduplicate the multiplied result. Otherwise, only deduplicate the constant part.
|
|
dedup_key = make_dedup_key(self.type, [self.mult_factor if self.is_literal else None] + self.args)
|
|
tuple_target = code.get_py_const(py_object_type, 'tuple', cleanup_level=2, dedup_key=dedup_key)
|
|
const_code = code.get_cached_constants_writer(tuple_target)
|
|
if const_code is not None:
|
|
# constant is not yet initialised
|
|
const_code.mark_pos(self.pos)
|
|
self.generate_sequence_packing_code(const_code, tuple_target, plain=not self.is_literal)
|
|
const_code.put_giveref(tuple_target)
|
|
if self.is_literal:
|
|
self.result_code = tuple_target
|
|
else:
|
|
code.putln('%s = PyNumber_Multiply(%s, %s); %s' % (
|
|
self.result(), tuple_target, self.mult_factor.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)
|
|
))
|
|
code.put_gotref(self.py_result())
|
|
else:
|
|
self.type.entry.used = True
|
|
self.generate_sequence_packing_code(code)
|
|
|
|
|
|
class ListNode(SequenceNode):
|
|
# List constructor.
|
|
|
|
# obj_conversion_errors [PyrexError] used internally
|
|
# orignial_args [ExprNode] used internally
|
|
|
|
obj_conversion_errors = []
|
|
type = list_type
|
|
in_module_scope = False
|
|
|
|
gil_message = "Constructing Python list"
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def infer_type(self, env):
|
|
# TODO: Infer non-object list arrays.
|
|
return list_type
|
|
|
|
def analyse_expressions(self, env):
|
|
for arg in self.args:
|
|
if arg.is_starred:
|
|
arg.starred_expr_allowed_here = True
|
|
node = SequenceNode.analyse_expressions(self, env)
|
|
return node.coerce_to_pyobject(env)
|
|
|
|
def analyse_types(self, env):
|
|
with local_errors(ignore=True) as errors:
|
|
self.original_args = list(self.args)
|
|
node = SequenceNode.analyse_types(self, env)
|
|
node.obj_conversion_errors = errors
|
|
if env.is_module_scope:
|
|
self.in_module_scope = True
|
|
node = node._create_merge_node_if_necessary(env)
|
|
return node
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type.is_pyobject:
|
|
for err in self.obj_conversion_errors:
|
|
report_error(err)
|
|
self.obj_conversion_errors = []
|
|
if not self.type.subtype_of(dst_type):
|
|
error(self.pos, "Cannot coerce list to type '%s'" % dst_type)
|
|
elif (dst_type.is_array or dst_type.is_ptr) and dst_type.base_type is not PyrexTypes.c_void_type:
|
|
array_length = len(self.args)
|
|
if self.mult_factor:
|
|
if isinstance(self.mult_factor.constant_result, _py_int_types):
|
|
if self.mult_factor.constant_result <= 0:
|
|
error(self.pos, "Cannot coerce non-positively multiplied list to '%s'" % dst_type)
|
|
else:
|
|
array_length *= self.mult_factor.constant_result
|
|
else:
|
|
error(self.pos, "Cannot coerce dynamically multiplied list to '%s'" % dst_type)
|
|
base_type = dst_type.base_type
|
|
self.type = PyrexTypes.CArrayType(base_type, array_length)
|
|
for i in range(len(self.original_args)):
|
|
arg = self.args[i]
|
|
if isinstance(arg, CoerceToPyTypeNode):
|
|
arg = arg.arg
|
|
self.args[i] = arg.coerce_to(base_type, env)
|
|
elif dst_type.is_cpp_class:
|
|
# TODO(robertwb): Avoid object conversion for vector/list/set.
|
|
return TypecastNode(self.pos, operand=self, type=PyrexTypes.py_object_type).coerce_to(dst_type, env)
|
|
elif self.mult_factor:
|
|
error(self.pos, "Cannot coerce multiplied list to '%s'" % dst_type)
|
|
elif dst_type.is_struct:
|
|
if len(self.args) > len(dst_type.scope.var_entries):
|
|
error(self.pos, "Too many members for '%s'" % dst_type)
|
|
else:
|
|
if len(self.args) < len(dst_type.scope.var_entries):
|
|
warning(self.pos, "Too few members for '%s'" % dst_type, 1)
|
|
for i, (arg, member) in enumerate(zip(self.original_args, dst_type.scope.var_entries)):
|
|
if isinstance(arg, CoerceToPyTypeNode):
|
|
arg = arg.arg
|
|
self.args[i] = arg.coerce_to(member.type, env)
|
|
self.type = dst_type
|
|
elif dst_type.is_ctuple:
|
|
return self.coerce_to_ctuple(dst_type, env)
|
|
else:
|
|
self.type = error_type
|
|
error(self.pos, "Cannot coerce list to type '%s'" % dst_type)
|
|
return self
|
|
|
|
def as_list(self): # dummy for compatibility with TupleNode
|
|
return self
|
|
|
|
def as_tuple(self):
|
|
t = TupleNode(self.pos, args=self.args, mult_factor=self.mult_factor)
|
|
if isinstance(self.constant_result, list):
|
|
t.constant_result = tuple(self.constant_result)
|
|
return t
|
|
|
|
def allocate_temp_result(self, code):
|
|
if self.type.is_array and self.in_module_scope:
|
|
self.temp_code = code.funcstate.allocate_temp(
|
|
self.type, manage_ref=False, static=True)
|
|
else:
|
|
SequenceNode.allocate_temp_result(self, code)
|
|
|
|
def release_temp_result(self, env):
|
|
if self.type.is_array:
|
|
# To be valid C++, we must allocate the memory on the stack
|
|
# manually and be sure not to reuse it for something else.
|
|
# Yes, this means that we leak a temp array variable.
|
|
pass
|
|
else:
|
|
SequenceNode.release_temp_result(self, env)
|
|
|
|
def calculate_constant_result(self):
|
|
if self.mult_factor:
|
|
raise ValueError() # may exceed the compile time memory
|
|
self.constant_result = [
|
|
arg.constant_result for arg in self.args]
|
|
|
|
def compile_time_value(self, denv):
|
|
l = self.compile_time_value_list(denv)
|
|
if self.mult_factor:
|
|
l *= self.mult_factor.compile_time_value(denv)
|
|
return l
|
|
|
|
def generate_operation_code(self, code):
|
|
if self.type.is_pyobject:
|
|
for err in self.obj_conversion_errors:
|
|
report_error(err)
|
|
self.generate_sequence_packing_code(code)
|
|
elif self.type.is_array:
|
|
if self.mult_factor:
|
|
code.putln("{")
|
|
code.putln("Py_ssize_t %s;" % Naming.quick_temp_cname)
|
|
code.putln("for ({i} = 0; {i} < {count}; {i}++) {{".format(
|
|
i=Naming.quick_temp_cname, count=self.mult_factor.result()))
|
|
offset = '+ (%d * %s)' % (len(self.args), Naming.quick_temp_cname)
|
|
else:
|
|
offset = ''
|
|
for i, arg in enumerate(self.args):
|
|
if arg.type.is_array:
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("IncludeStringH", "StringTools.c"))
|
|
code.putln("memcpy(&(%s[%s%s]), %s, sizeof(%s[0]));" % (
|
|
self.result(), i, offset,
|
|
arg.result(), self.result()
|
|
))
|
|
else:
|
|
code.putln("%s[%s%s] = %s;" % (
|
|
self.result(),
|
|
i,
|
|
offset,
|
|
arg.result()))
|
|
if self.mult_factor:
|
|
code.putln("}")
|
|
code.putln("}")
|
|
elif self.type.is_struct:
|
|
for arg, member in zip(self.args, self.type.scope.var_entries):
|
|
code.putln("%s.%s = %s;" % (
|
|
self.result(),
|
|
member.cname,
|
|
arg.result()))
|
|
else:
|
|
raise InternalError("List type never specified")
|
|
|
|
|
|
class ScopedExprNode(ExprNode):
|
|
# Abstract base class for ExprNodes that have their own local
|
|
# scope, such as generator expressions.
|
|
#
|
|
# expr_scope Scope the inner scope of the expression
|
|
|
|
subexprs = []
|
|
expr_scope = None
|
|
|
|
# does this node really have a local scope, e.g. does it leak loop
|
|
# variables or not? non-leaking Py3 behaviour is default, except
|
|
# for list comprehensions where the behaviour differs in Py2 and
|
|
# Py3 (set in Parsing.py based on parser context)
|
|
has_local_scope = True
|
|
|
|
def init_scope(self, outer_scope, expr_scope=None):
|
|
if expr_scope is not None:
|
|
self.expr_scope = expr_scope
|
|
elif self.has_local_scope:
|
|
self.expr_scope = Symtab.GeneratorExpressionScope(outer_scope)
|
|
else:
|
|
self.expr_scope = None
|
|
|
|
def analyse_declarations(self, env):
|
|
self.init_scope(env)
|
|
|
|
def analyse_scoped_declarations(self, env):
|
|
# this is called with the expr_scope as env
|
|
pass
|
|
|
|
def analyse_types(self, env):
|
|
# no recursion here, the children will be analysed separately below
|
|
return self
|
|
|
|
def analyse_scoped_expressions(self, env):
|
|
# this is called with the expr_scope as env
|
|
return self
|
|
|
|
def generate_evaluation_code(self, code):
|
|
# set up local variables and free their references on exit
|
|
generate_inner_evaluation_code = super(ScopedExprNode, self).generate_evaluation_code
|
|
if not self.has_local_scope or not self.expr_scope.var_entries:
|
|
# no local variables => delegate, done
|
|
generate_inner_evaluation_code(code)
|
|
return
|
|
|
|
code.putln('{ /* enter inner scope */')
|
|
py_entries = []
|
|
for _, entry in sorted(item for item in self.expr_scope.entries.items() if item[0]):
|
|
if not entry.in_closure:
|
|
if entry.type.is_pyobject and entry.used:
|
|
py_entries.append(entry)
|
|
if not py_entries:
|
|
# no local Python references => no cleanup required
|
|
generate_inner_evaluation_code(code)
|
|
code.putln('} /* exit inner scope */')
|
|
return
|
|
|
|
# must free all local Python references at each exit point
|
|
old_loop_labels = code.new_loop_labels()
|
|
old_error_label = code.new_error_label()
|
|
|
|
generate_inner_evaluation_code(code)
|
|
|
|
# normal (non-error) exit
|
|
self._generate_vars_cleanup(code, py_entries)
|
|
|
|
# error/loop body exit points
|
|
exit_scope = code.new_label('exit_scope')
|
|
code.put_goto(exit_scope)
|
|
for label, old_label in ([(code.error_label, old_error_label)] +
|
|
list(zip(code.get_loop_labels(), old_loop_labels))):
|
|
if code.label_used(label):
|
|
code.put_label(label)
|
|
self._generate_vars_cleanup(code, py_entries)
|
|
code.put_goto(old_label)
|
|
code.put_label(exit_scope)
|
|
code.putln('} /* exit inner scope */')
|
|
|
|
code.set_loop_labels(old_loop_labels)
|
|
code.error_label = old_error_label
|
|
|
|
def _generate_vars_cleanup(self, code, py_entries):
|
|
for entry in py_entries:
|
|
if entry.is_cglobal:
|
|
code.put_var_gotref(entry)
|
|
code.put_decref_set(entry.cname, "Py_None")
|
|
else:
|
|
code.put_var_xdecref_clear(entry)
|
|
|
|
|
|
class ComprehensionNode(ScopedExprNode):
|
|
# A list/set/dict comprehension
|
|
|
|
child_attrs = ["loop"]
|
|
|
|
is_temp = True
|
|
constant_result = not_a_constant
|
|
|
|
def infer_type(self, env):
|
|
return self.type
|
|
|
|
def analyse_declarations(self, env):
|
|
self.append.target = self # this is used in the PyList_Append of the inner loop
|
|
self.init_scope(env)
|
|
|
|
def analyse_scoped_declarations(self, env):
|
|
self.loop.analyse_declarations(env)
|
|
|
|
def analyse_types(self, env):
|
|
if not self.has_local_scope:
|
|
self.loop = self.loop.analyse_expressions(env)
|
|
return self
|
|
|
|
def analyse_scoped_expressions(self, env):
|
|
if self.has_local_scope:
|
|
self.loop = self.loop.analyse_expressions(env)
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def generate_result_code(self, code):
|
|
self.generate_operation_code(code)
|
|
|
|
def generate_operation_code(self, code):
|
|
if self.type is Builtin.list_type:
|
|
create_code = 'PyList_New(0)'
|
|
elif self.type is Builtin.set_type:
|
|
create_code = 'PySet_New(NULL)'
|
|
elif self.type is Builtin.dict_type:
|
|
create_code = 'PyDict_New()'
|
|
else:
|
|
raise InternalError("illegal type for comprehension: %s" % self.type)
|
|
code.putln('%s = %s; %s' % (
|
|
self.result(), create_code,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
|
|
code.put_gotref(self.result())
|
|
self.loop.generate_execution_code(code)
|
|
|
|
def annotate(self, code):
|
|
self.loop.annotate(code)
|
|
|
|
|
|
class ComprehensionAppendNode(Node):
|
|
# Need to be careful to avoid infinite recursion:
|
|
# target must not be in child_attrs/subexprs
|
|
|
|
child_attrs = ['expr']
|
|
target = None
|
|
|
|
type = PyrexTypes.c_int_type
|
|
|
|
def analyse_expressions(self, env):
|
|
self.expr = self.expr.analyse_expressions(env)
|
|
if not self.expr.type.is_pyobject:
|
|
self.expr = self.expr.coerce_to_pyobject(env)
|
|
return self
|
|
|
|
def generate_execution_code(self, code):
|
|
if self.target.type is list_type:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("ListCompAppend", "Optimize.c"))
|
|
function = "__Pyx_ListComp_Append"
|
|
elif self.target.type is set_type:
|
|
function = "PySet_Add"
|
|
else:
|
|
raise InternalError(
|
|
"Invalid type for comprehension node: %s" % self.target.type)
|
|
|
|
self.expr.generate_evaluation_code(code)
|
|
code.putln(code.error_goto_if("%s(%s, (PyObject*)%s)" % (
|
|
function,
|
|
self.target.result(),
|
|
self.expr.result()
|
|
), self.pos))
|
|
self.expr.generate_disposal_code(code)
|
|
self.expr.free_temps(code)
|
|
|
|
def generate_function_definitions(self, env, code):
|
|
self.expr.generate_function_definitions(env, code)
|
|
|
|
def annotate(self, code):
|
|
self.expr.annotate(code)
|
|
|
|
class DictComprehensionAppendNode(ComprehensionAppendNode):
|
|
child_attrs = ['key_expr', 'value_expr']
|
|
|
|
def analyse_expressions(self, env):
|
|
self.key_expr = self.key_expr.analyse_expressions(env)
|
|
if not self.key_expr.type.is_pyobject:
|
|
self.key_expr = self.key_expr.coerce_to_pyobject(env)
|
|
self.value_expr = self.value_expr.analyse_expressions(env)
|
|
if not self.value_expr.type.is_pyobject:
|
|
self.value_expr = self.value_expr.coerce_to_pyobject(env)
|
|
return self
|
|
|
|
def generate_execution_code(self, code):
|
|
self.key_expr.generate_evaluation_code(code)
|
|
self.value_expr.generate_evaluation_code(code)
|
|
code.putln(code.error_goto_if("PyDict_SetItem(%s, (PyObject*)%s, (PyObject*)%s)" % (
|
|
self.target.result(),
|
|
self.key_expr.result(),
|
|
self.value_expr.result()
|
|
), self.pos))
|
|
self.key_expr.generate_disposal_code(code)
|
|
self.key_expr.free_temps(code)
|
|
self.value_expr.generate_disposal_code(code)
|
|
self.value_expr.free_temps(code)
|
|
|
|
def generate_function_definitions(self, env, code):
|
|
self.key_expr.generate_function_definitions(env, code)
|
|
self.value_expr.generate_function_definitions(env, code)
|
|
|
|
def annotate(self, code):
|
|
self.key_expr.annotate(code)
|
|
self.value_expr.annotate(code)
|
|
|
|
|
|
class InlinedGeneratorExpressionNode(ExprNode):
|
|
# An inlined generator expression for which the result is calculated
|
|
# inside of the loop and returned as a single, first and only Generator
|
|
# return value.
|
|
# This will only be created by transforms when replacing safe builtin
|
|
# calls on generator expressions.
|
|
#
|
|
# gen GeneratorExpressionNode the generator, not containing any YieldExprNodes
|
|
# orig_func String the name of the builtin function this node replaces
|
|
# target ExprNode or None a 'target' for a ComprehensionAppend node
|
|
|
|
subexprs = ["gen"]
|
|
orig_func = None
|
|
target = None
|
|
is_temp = True
|
|
type = py_object_type
|
|
|
|
def __init__(self, pos, gen, comprehension_type=None, **kwargs):
|
|
gbody = gen.def_node.gbody
|
|
gbody.is_inlined = True
|
|
if comprehension_type is not None:
|
|
assert comprehension_type in (list_type, set_type, dict_type), comprehension_type
|
|
gbody.inlined_comprehension_type = comprehension_type
|
|
kwargs.update(
|
|
target=RawCNameExprNode(pos, comprehension_type, Naming.retval_cname),
|
|
type=comprehension_type,
|
|
)
|
|
super(InlinedGeneratorExpressionNode, self).__init__(pos, gen=gen, **kwargs)
|
|
|
|
def may_be_none(self):
|
|
return self.orig_func not in ('any', 'all', 'sorted')
|
|
|
|
def infer_type(self, env):
|
|
return self.type
|
|
|
|
def analyse_types(self, env):
|
|
self.gen = self.gen.analyse_expressions(env)
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln("%s = __Pyx_Generator_Next(%s); %s" % (
|
|
self.result(), self.gen.result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
|
|
|
|
class MergedSequenceNode(ExprNode):
|
|
"""
|
|
Merge a sequence of iterables into a set/list/tuple.
|
|
|
|
The target collection is determined by self.type, which must be set externally.
|
|
|
|
args [ExprNode]
|
|
"""
|
|
subexprs = ['args']
|
|
is_temp = True
|
|
gil_message = "Constructing Python collection"
|
|
|
|
def __init__(self, pos, args, type):
|
|
if type in (list_type, tuple_type) and args and args[0].is_sequence_constructor:
|
|
# construct a list directly from the first argument that we can then extend
|
|
if args[0].type is not list_type:
|
|
args[0] = ListNode(args[0].pos, args=args[0].args, is_temp=True)
|
|
ExprNode.__init__(self, pos, args=args, type=type)
|
|
|
|
def calculate_constant_result(self):
|
|
result = []
|
|
for item in self.args:
|
|
if item.is_sequence_constructor and item.mult_factor:
|
|
if item.mult_factor.constant_result <= 0:
|
|
continue
|
|
# otherwise, adding each item once should be enough
|
|
if item.is_set_literal or item.is_sequence_constructor:
|
|
# process items in order
|
|
items = (arg.constant_result for arg in item.args)
|
|
else:
|
|
items = item.constant_result
|
|
result.extend(items)
|
|
if self.type is set_type:
|
|
result = set(result)
|
|
elif self.type is tuple_type:
|
|
result = tuple(result)
|
|
else:
|
|
assert self.type is list_type
|
|
self.constant_result = result
|
|
|
|
def compile_time_value(self, denv):
|
|
result = []
|
|
for item in self.args:
|
|
if item.is_sequence_constructor and item.mult_factor:
|
|
if item.mult_factor.compile_time_value(denv) <= 0:
|
|
continue
|
|
if item.is_set_literal or item.is_sequence_constructor:
|
|
# process items in order
|
|
items = (arg.compile_time_value(denv) for arg in item.args)
|
|
else:
|
|
items = item.compile_time_value(denv)
|
|
result.extend(items)
|
|
if self.type is set_type:
|
|
try:
|
|
result = set(result)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
elif self.type is tuple_type:
|
|
result = tuple(result)
|
|
else:
|
|
assert self.type is list_type
|
|
return result
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def infer_type(self, env):
|
|
return self.type
|
|
|
|
def analyse_types(self, env):
|
|
args = [
|
|
arg.analyse_types(env).coerce_to_pyobject(env).as_none_safe_node(
|
|
# FIXME: CPython's error message starts with the runtime function name
|
|
'argument after * must be an iterable, not NoneType')
|
|
for arg in self.args
|
|
]
|
|
|
|
if len(args) == 1 and args[0].type is self.type:
|
|
# strip this intermediate node and use the bare collection
|
|
return args[0]
|
|
|
|
assert self.type in (set_type, list_type, tuple_type)
|
|
|
|
self.args = args
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def generate_evaluation_code(self, code):
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
|
|
is_set = self.type is set_type
|
|
|
|
args = iter(self.args)
|
|
item = next(args)
|
|
item.generate_evaluation_code(code)
|
|
if (is_set and item.is_set_literal or
|
|
not is_set and item.is_sequence_constructor and item.type is list_type):
|
|
code.putln("%s = %s;" % (self.result(), item.py_result()))
|
|
item.generate_post_assignment_code(code)
|
|
else:
|
|
code.putln("%s = %s(%s); %s" % (
|
|
self.result(),
|
|
'PySet_New' if is_set else 'PySequence_List',
|
|
item.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
item.generate_disposal_code(code)
|
|
item.free_temps(code)
|
|
|
|
helpers = set()
|
|
if is_set:
|
|
add_func = "PySet_Add"
|
|
extend_func = "__Pyx_PySet_Update"
|
|
else:
|
|
add_func = "__Pyx_ListComp_Append"
|
|
extend_func = "__Pyx_PyList_Extend"
|
|
|
|
for item in args:
|
|
if (is_set and (item.is_set_literal or item.is_sequence_constructor) or
|
|
(item.is_sequence_constructor and not item.mult_factor)):
|
|
if not is_set and item.args:
|
|
helpers.add(("ListCompAppend", "Optimize.c"))
|
|
for arg in item.args:
|
|
arg.generate_evaluation_code(code)
|
|
code.put_error_if_neg(arg.pos, "%s(%s, %s)" % (
|
|
add_func,
|
|
self.result(),
|
|
arg.py_result()))
|
|
arg.generate_disposal_code(code)
|
|
arg.free_temps(code)
|
|
continue
|
|
|
|
if is_set:
|
|
helpers.add(("PySet_Update", "Builtins.c"))
|
|
else:
|
|
helpers.add(("ListExtend", "Optimize.c"))
|
|
|
|
item.generate_evaluation_code(code)
|
|
code.put_error_if_neg(item.pos, "%s(%s, %s)" % (
|
|
extend_func,
|
|
self.result(),
|
|
item.py_result()))
|
|
item.generate_disposal_code(code)
|
|
item.free_temps(code)
|
|
|
|
if self.type is tuple_type:
|
|
code.putln("{")
|
|
code.putln("PyObject *%s = PyList_AsTuple(%s);" % (
|
|
Naming.quick_temp_cname,
|
|
self.result()))
|
|
code.put_decref(self.result(), py_object_type)
|
|
code.putln("%s = %s; %s" % (
|
|
self.result(),
|
|
Naming.quick_temp_cname,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
code.putln("}")
|
|
|
|
for helper in sorted(helpers):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(*helper))
|
|
|
|
def annotate(self, code):
|
|
for item in self.args:
|
|
item.annotate(code)
|
|
|
|
|
|
class SetNode(ExprNode):
|
|
"""
|
|
Set constructor.
|
|
"""
|
|
subexprs = ['args']
|
|
type = set_type
|
|
is_set_literal = True
|
|
gil_message = "Constructing Python set"
|
|
|
|
def analyse_types(self, env):
|
|
for i in range(len(self.args)):
|
|
arg = self.args[i]
|
|
arg = arg.analyse_types(env)
|
|
self.args[i] = arg.coerce_to_pyobject(env)
|
|
self.type = set_type
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = set([arg.constant_result for arg in self.args])
|
|
|
|
def compile_time_value(self, denv):
|
|
values = [arg.compile_time_value(denv) for arg in self.args]
|
|
try:
|
|
return set(values)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
for arg in self.args:
|
|
arg.generate_evaluation_code(code)
|
|
self.allocate_temp_result(code)
|
|
code.putln(
|
|
"%s = PySet_New(0); %s" % (
|
|
self.result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
for arg in self.args:
|
|
code.put_error_if_neg(
|
|
self.pos,
|
|
"PySet_Add(%s, %s)" % (self.result(), arg.py_result()))
|
|
arg.generate_disposal_code(code)
|
|
arg.free_temps(code)
|
|
|
|
|
|
class DictNode(ExprNode):
|
|
# Dictionary constructor.
|
|
#
|
|
# key_value_pairs [DictItemNode]
|
|
# exclude_null_values [boolean] Do not add NULL values to dict
|
|
#
|
|
# obj_conversion_errors [PyrexError] used internally
|
|
|
|
subexprs = ['key_value_pairs']
|
|
is_temp = 1
|
|
exclude_null_values = False
|
|
type = dict_type
|
|
is_dict_literal = True
|
|
reject_duplicates = False
|
|
|
|
obj_conversion_errors = []
|
|
|
|
@classmethod
|
|
def from_pairs(cls, pos, pairs):
|
|
return cls(pos, key_value_pairs=[
|
|
DictItemNode(pos, key=k, value=v) for k, v in pairs])
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = dict([
|
|
item.constant_result for item in self.key_value_pairs])
|
|
|
|
def compile_time_value(self, denv):
|
|
pairs = [(item.key.compile_time_value(denv), item.value.compile_time_value(denv))
|
|
for item in self.key_value_pairs]
|
|
try:
|
|
return dict(pairs)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def infer_type(self, env):
|
|
# TODO: Infer struct constructors.
|
|
return dict_type
|
|
|
|
def analyse_types(self, env):
|
|
with local_errors(ignore=True) as errors:
|
|
self.key_value_pairs = [
|
|
item.analyse_types(env)
|
|
for item in self.key_value_pairs
|
|
]
|
|
self.obj_conversion_errors = errors
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type.is_pyobject:
|
|
self.release_errors()
|
|
if self.type.is_struct_or_union:
|
|
if not dict_type.subtype_of(dst_type):
|
|
error(self.pos, "Cannot interpret struct as non-dict type '%s'" % dst_type)
|
|
return DictNode(self.pos, key_value_pairs=[
|
|
DictItemNode(item.pos, key=item.key.coerce_to_pyobject(env),
|
|
value=item.value.coerce_to_pyobject(env))
|
|
for item in self.key_value_pairs])
|
|
if not self.type.subtype_of(dst_type):
|
|
error(self.pos, "Cannot interpret dict as type '%s'" % dst_type)
|
|
elif dst_type.is_struct_or_union:
|
|
self.type = dst_type
|
|
if not dst_type.is_struct and len(self.key_value_pairs) != 1:
|
|
error(self.pos, "Exactly one field must be specified to convert to union '%s'" % dst_type)
|
|
elif dst_type.is_struct and len(self.key_value_pairs) < len(dst_type.scope.var_entries):
|
|
warning(self.pos, "Not all members given for struct '%s'" % dst_type, 1)
|
|
for item in self.key_value_pairs:
|
|
if isinstance(item.key, CoerceToPyTypeNode):
|
|
item.key = item.key.arg
|
|
if not item.key.is_string_literal:
|
|
error(item.key.pos, "Invalid struct field identifier")
|
|
item.key = StringNode(item.key.pos, value="<error>")
|
|
else:
|
|
key = str(item.key.value) # converts string literals to unicode in Py3
|
|
member = dst_type.scope.lookup_here(key)
|
|
if not member:
|
|
error(item.key.pos, "struct '%s' has no field '%s'" % (dst_type, key))
|
|
else:
|
|
value = item.value
|
|
if isinstance(value, CoerceToPyTypeNode):
|
|
value = value.arg
|
|
item.value = value.coerce_to(member.type, env)
|
|
else:
|
|
self.type = error_type
|
|
error(self.pos, "Cannot interpret dict as type '%s'" % dst_type)
|
|
return self
|
|
|
|
def release_errors(self):
|
|
for err in self.obj_conversion_errors:
|
|
report_error(err)
|
|
self.obj_conversion_errors = []
|
|
|
|
gil_message = "Constructing Python dict"
|
|
|
|
def generate_evaluation_code(self, code):
|
|
# Custom method used here because key-value
|
|
# pairs are evaluated and used one at a time.
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
|
|
is_dict = self.type.is_pyobject
|
|
if is_dict:
|
|
self.release_errors()
|
|
code.putln(
|
|
"%s = __Pyx_PyDict_NewPresized(%d); %s" % (
|
|
self.result(),
|
|
len(self.key_value_pairs),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
keys_seen = set()
|
|
key_type = None
|
|
needs_error_helper = False
|
|
|
|
for item in self.key_value_pairs:
|
|
item.generate_evaluation_code(code)
|
|
if is_dict:
|
|
if self.exclude_null_values:
|
|
code.putln('if (%s) {' % item.value.py_result())
|
|
key = item.key
|
|
if self.reject_duplicates:
|
|
if keys_seen is not None:
|
|
# avoid runtime 'in' checks for literals that we can do at compile time
|
|
if not key.is_string_literal:
|
|
keys_seen = None
|
|
elif key.value in keys_seen:
|
|
# FIXME: this could be a compile time error, at least in Cython code
|
|
keys_seen = None
|
|
elif key_type is not type(key.value):
|
|
if key_type is None:
|
|
key_type = type(key.value)
|
|
keys_seen.add(key.value)
|
|
else:
|
|
# different types => may not be able to compare at compile time
|
|
keys_seen = None
|
|
else:
|
|
keys_seen.add(key.value)
|
|
|
|
if keys_seen is None:
|
|
code.putln('if (unlikely(PyDict_Contains(%s, %s))) {' % (
|
|
self.result(), key.py_result()))
|
|
# currently only used in function calls
|
|
needs_error_helper = True
|
|
code.putln('__Pyx_RaiseDoubleKeywordsError("function", %s); %s' % (
|
|
key.py_result(),
|
|
code.error_goto(item.pos)))
|
|
code.putln("} else {")
|
|
|
|
code.put_error_if_neg(self.pos, "PyDict_SetItem(%s, %s, %s)" % (
|
|
self.result(),
|
|
item.key.py_result(),
|
|
item.value.py_result()))
|
|
if self.reject_duplicates and keys_seen is None:
|
|
code.putln('}')
|
|
if self.exclude_null_values:
|
|
code.putln('}')
|
|
else:
|
|
code.putln("%s.%s = %s;" % (
|
|
self.result(),
|
|
item.key.value,
|
|
item.value.result()))
|
|
item.generate_disposal_code(code)
|
|
item.free_temps(code)
|
|
|
|
if needs_error_helper:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("RaiseDoubleKeywords", "FunctionArguments.c"))
|
|
|
|
def annotate(self, code):
|
|
for item in self.key_value_pairs:
|
|
item.annotate(code)
|
|
|
|
|
|
class DictItemNode(ExprNode):
|
|
# Represents a single item in a DictNode
|
|
#
|
|
# key ExprNode
|
|
# value ExprNode
|
|
subexprs = ['key', 'value']
|
|
|
|
nogil_check = None # Parent DictNode takes care of it
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = (
|
|
self.key.constant_result, self.value.constant_result)
|
|
|
|
def analyse_types(self, env):
|
|
self.key = self.key.analyse_types(env)
|
|
self.value = self.value.analyse_types(env)
|
|
self.key = self.key.coerce_to_pyobject(env)
|
|
self.value = self.value.coerce_to_pyobject(env)
|
|
return self
|
|
|
|
def generate_evaluation_code(self, code):
|
|
self.key.generate_evaluation_code(code)
|
|
self.value.generate_evaluation_code(code)
|
|
|
|
def generate_disposal_code(self, code):
|
|
self.key.generate_disposal_code(code)
|
|
self.value.generate_disposal_code(code)
|
|
|
|
def free_temps(self, code):
|
|
self.key.free_temps(code)
|
|
self.value.free_temps(code)
|
|
|
|
def __iter__(self):
|
|
return iter([self.key, self.value])
|
|
|
|
|
|
class SortedDictKeysNode(ExprNode):
|
|
# build sorted list of dict keys, e.g. for dir()
|
|
subexprs = ['arg']
|
|
|
|
is_temp = True
|
|
|
|
def __init__(self, arg):
|
|
ExprNode.__init__(self, arg.pos, arg=arg)
|
|
self.type = Builtin.list_type
|
|
|
|
def analyse_types(self, env):
|
|
arg = self.arg.analyse_types(env)
|
|
if arg.type is Builtin.dict_type:
|
|
arg = arg.as_none_safe_node(
|
|
"'NoneType' object is not iterable")
|
|
self.arg = arg
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def generate_result_code(self, code):
|
|
dict_result = self.arg.py_result()
|
|
if self.arg.type is Builtin.dict_type:
|
|
code.putln('%s = PyDict_Keys(%s); %s' % (
|
|
self.result(), dict_result,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
else:
|
|
# originally used PyMapping_Keys() here, but that may return a tuple
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached(
|
|
'PyObjectCallMethod0', 'ObjectHandling.c'))
|
|
keys_cname = code.intern_identifier(StringEncoding.EncodedString("keys"))
|
|
code.putln('%s = __Pyx_PyObject_CallMethod0(%s, %s); %s' % (
|
|
self.result(), dict_result, keys_cname,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
code.putln("if (unlikely(!PyList_Check(%s))) {" % self.result())
|
|
code.put_decref_set(self.result(), "PySequence_List(%s)" % self.result())
|
|
code.putln(code.error_goto_if_null(self.result(), self.pos))
|
|
code.put_gotref(self.py_result())
|
|
code.putln("}")
|
|
code.put_error_if_neg(
|
|
self.pos, 'PyList_Sort(%s)' % self.py_result())
|
|
|
|
|
|
class ModuleNameMixin(object):
|
|
def get_py_mod_name(self, code):
|
|
return code.get_py_string_const(
|
|
self.module_name, identifier=True)
|
|
|
|
def get_py_qualified_name(self, code):
|
|
return code.get_py_string_const(
|
|
self.qualname, identifier=True)
|
|
|
|
|
|
class ClassNode(ExprNode, ModuleNameMixin):
|
|
# Helper class used in the implementation of Python
|
|
# class definitions. Constructs a class object given
|
|
# a name, tuple of bases and class dictionary.
|
|
#
|
|
# name EncodedString Name of the class
|
|
# class_def_node PyClassDefNode PyClassDefNode defining this class
|
|
# doc ExprNode or None Doc string
|
|
# module_name EncodedString Name of defining module
|
|
|
|
subexprs = ['doc']
|
|
type = py_object_type
|
|
is_temp = True
|
|
|
|
def infer_type(self, env):
|
|
# TODO: could return 'type' in some cases
|
|
return py_object_type
|
|
|
|
def analyse_types(self, env):
|
|
if self.doc:
|
|
self.doc = self.doc.analyse_types(env)
|
|
self.doc = self.doc.coerce_to_pyobject(env)
|
|
env.use_utility_code(UtilityCode.load_cached("CreateClass", "ObjectHandling.c"))
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return True
|
|
|
|
gil_message = "Constructing Python class"
|
|
|
|
def generate_result_code(self, code):
|
|
class_def_node = self.class_def_node
|
|
cname = code.intern_identifier(self.name)
|
|
|
|
if self.doc:
|
|
code.put_error_if_neg(self.pos,
|
|
'PyDict_SetItem(%s, %s, %s)' % (
|
|
class_def_node.dict.py_result(),
|
|
code.intern_identifier(
|
|
StringEncoding.EncodedString("__doc__")),
|
|
self.doc.py_result()))
|
|
py_mod_name = self.get_py_mod_name(code)
|
|
qualname = self.get_py_qualified_name(code)
|
|
code.putln(
|
|
'%s = __Pyx_CreateClass(%s, %s, %s, %s, %s); %s' % (
|
|
self.result(),
|
|
class_def_node.bases.py_result(),
|
|
class_def_node.dict.py_result(),
|
|
cname,
|
|
qualname,
|
|
py_mod_name,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class Py3ClassNode(ExprNode):
|
|
# Helper class used in the implementation of Python3+
|
|
# class definitions. Constructs a class object given
|
|
# a name, tuple of bases and class dictionary.
|
|
#
|
|
# name EncodedString Name of the class
|
|
# module_name EncodedString Name of defining module
|
|
# class_def_node PyClassDefNode PyClassDefNode defining this class
|
|
# calculate_metaclass bool should call CalculateMetaclass()
|
|
# allow_py2_metaclass bool should look for Py2 metaclass
|
|
|
|
subexprs = []
|
|
type = py_object_type
|
|
is_temp = True
|
|
|
|
def infer_type(self, env):
|
|
# TODO: could return 'type' in some cases
|
|
return py_object_type
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return True
|
|
|
|
gil_message = "Constructing Python class"
|
|
|
|
def generate_result_code(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("Py3ClassCreate", "ObjectHandling.c"))
|
|
cname = code.intern_identifier(self.name)
|
|
class_def_node = self.class_def_node
|
|
mkw = class_def_node.mkw.py_result() if class_def_node.mkw else 'NULL'
|
|
if class_def_node.metaclass:
|
|
metaclass = class_def_node.metaclass.py_result()
|
|
else:
|
|
metaclass = "((PyObject*)&__Pyx_DefaultClassType)"
|
|
code.putln(
|
|
'%s = __Pyx_Py3ClassCreate(%s, %s, %s, %s, %s, %d, %d); %s' % (
|
|
self.result(),
|
|
metaclass,
|
|
cname,
|
|
class_def_node.bases.py_result(),
|
|
class_def_node.dict.py_result(),
|
|
mkw,
|
|
self.calculate_metaclass,
|
|
self.allow_py2_metaclass,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class PyClassMetaclassNode(ExprNode):
|
|
# Helper class holds Python3 metaclass object
|
|
#
|
|
# class_def_node PyClassDefNode PyClassDefNode defining this class
|
|
|
|
subexprs = []
|
|
|
|
def analyse_types(self, env):
|
|
self.type = py_object_type
|
|
self.is_temp = True
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return True
|
|
|
|
def generate_result_code(self, code):
|
|
bases = self.class_def_node.bases
|
|
mkw = self.class_def_node.mkw
|
|
if mkw:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("Py3MetaclassGet", "ObjectHandling.c"))
|
|
call = "__Pyx_Py3MetaclassGet(%s, %s)" % (
|
|
bases.result(),
|
|
mkw.result())
|
|
else:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("CalculateMetaclass", "ObjectHandling.c"))
|
|
call = "__Pyx_CalculateMetaclass(NULL, %s)" % (
|
|
bases.result())
|
|
code.putln(
|
|
"%s = %s; %s" % (
|
|
self.result(), call,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class PyClassNamespaceNode(ExprNode, ModuleNameMixin):
|
|
# Helper class holds Python3 namespace object
|
|
#
|
|
# All this are not owned by this node
|
|
# class_def_node PyClassDefNode PyClassDefNode defining this class
|
|
# doc ExprNode or None Doc string (owned)
|
|
|
|
subexprs = ['doc']
|
|
|
|
def analyse_types(self, env):
|
|
if self.doc:
|
|
self.doc = self.doc.analyse_types(env).coerce_to_pyobject(env)
|
|
self.type = py_object_type
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return True
|
|
|
|
def generate_result_code(self, code):
|
|
cname = code.intern_identifier(self.name)
|
|
py_mod_name = self.get_py_mod_name(code)
|
|
qualname = self.get_py_qualified_name(code)
|
|
class_def_node = self.class_def_node
|
|
null = "(PyObject *) NULL"
|
|
doc_code = self.doc.result() if self.doc else null
|
|
mkw = class_def_node.mkw.py_result() if class_def_node.mkw else null
|
|
metaclass = class_def_node.metaclass.py_result() if class_def_node.metaclass else null
|
|
code.putln(
|
|
"%s = __Pyx_Py3MetaclassPrepare(%s, %s, %s, %s, %s, %s, %s); %s" % (
|
|
self.result(),
|
|
metaclass,
|
|
class_def_node.bases.result(),
|
|
cname,
|
|
qualname,
|
|
mkw,
|
|
py_mod_name,
|
|
doc_code,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class ClassCellInjectorNode(ExprNode):
|
|
# Initialize CyFunction.func_classobj
|
|
is_temp = True
|
|
type = py_object_type
|
|
subexprs = []
|
|
is_active = False
|
|
|
|
def analyse_expressions(self, env):
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
assert self.is_active
|
|
code.putln(
|
|
'%s = PyList_New(0); %s' % (
|
|
self.result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
|
|
def generate_injection_code(self, code, classobj_cname):
|
|
assert self.is_active
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("CyFunctionClassCell", "CythonFunction.c"))
|
|
code.put_error_if_neg(self.pos, '__Pyx_CyFunction_InitClassCell(%s, %s)' % (
|
|
self.result(), classobj_cname))
|
|
|
|
|
|
class ClassCellNode(ExprNode):
|
|
# Class Cell for noargs super()
|
|
subexprs = []
|
|
is_temp = True
|
|
is_generator = False
|
|
type = py_object_type
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
if not self.is_generator:
|
|
code.putln('%s = __Pyx_CyFunction_GetClassObj(%s);' % (
|
|
self.result(),
|
|
Naming.self_cname))
|
|
else:
|
|
code.putln('%s = %s->classobj;' % (
|
|
self.result(), Naming.generator_cname))
|
|
code.putln(
|
|
'if (!%s) { PyErr_SetString(PyExc_SystemError, '
|
|
'"super(): empty __class__ cell"); %s }' % (
|
|
self.result(),
|
|
code.error_goto(self.pos)))
|
|
code.put_incref(self.result(), py_object_type)
|
|
|
|
|
|
class PyCFunctionNode(ExprNode, ModuleNameMixin):
|
|
# Helper class used in the implementation of Python
|
|
# functions. Constructs a PyCFunction object
|
|
# from a PyMethodDef struct.
|
|
#
|
|
# pymethdef_cname string PyMethodDef structure
|
|
# self_object ExprNode or None
|
|
# binding bool
|
|
# def_node DefNode the Python function node
|
|
# module_name EncodedString Name of defining module
|
|
# code_object CodeObjectNode the PyCodeObject creator node
|
|
|
|
subexprs = ['code_object', 'defaults_tuple', 'defaults_kwdict',
|
|
'annotations_dict']
|
|
|
|
self_object = None
|
|
code_object = None
|
|
binding = False
|
|
def_node = None
|
|
defaults = None
|
|
defaults_struct = None
|
|
defaults_pyobjects = 0
|
|
defaults_tuple = None
|
|
defaults_kwdict = None
|
|
annotations_dict = None
|
|
|
|
type = py_object_type
|
|
is_temp = 1
|
|
|
|
specialized_cpdefs = None
|
|
is_specialization = False
|
|
|
|
@classmethod
|
|
def from_defnode(cls, node, binding):
|
|
return cls(node.pos,
|
|
def_node=node,
|
|
pymethdef_cname=node.entry.pymethdef_cname,
|
|
binding=binding or node.specialized_cpdefs,
|
|
specialized_cpdefs=node.specialized_cpdefs,
|
|
code_object=CodeObjectNode(node))
|
|
|
|
def analyse_types(self, env):
|
|
if self.binding:
|
|
self.analyse_default_args(env)
|
|
return self
|
|
|
|
def analyse_default_args(self, env):
|
|
"""
|
|
Handle non-literal function's default arguments.
|
|
"""
|
|
nonliteral_objects = []
|
|
nonliteral_other = []
|
|
default_args = []
|
|
default_kwargs = []
|
|
annotations = []
|
|
|
|
# For global cpdef functions and def/cpdef methods in cdef classes, we must use global constants
|
|
# for default arguments to avoid the dependency on the CyFunction object as 'self' argument
|
|
# in the underlying C function. Basically, cpdef functions/methods are static C functions,
|
|
# so their optional arguments must be static, too.
|
|
# TODO: change CyFunction implementation to pass both function object and owning object for method calls
|
|
must_use_constants = env.is_c_class_scope or (self.def_node.is_wrapper and env.is_module_scope)
|
|
|
|
for arg in self.def_node.args:
|
|
if arg.default and not must_use_constants:
|
|
if not arg.default.is_literal:
|
|
arg.is_dynamic = True
|
|
if arg.type.is_pyobject:
|
|
nonliteral_objects.append(arg)
|
|
else:
|
|
nonliteral_other.append(arg)
|
|
else:
|
|
arg.default = DefaultLiteralArgNode(arg.pos, arg.default)
|
|
if arg.kw_only:
|
|
default_kwargs.append(arg)
|
|
else:
|
|
default_args.append(arg)
|
|
if arg.annotation:
|
|
arg.annotation = self.analyse_annotation(env, arg.annotation)
|
|
annotations.append((arg.pos, arg.name, arg.annotation))
|
|
|
|
for arg in (self.def_node.star_arg, self.def_node.starstar_arg):
|
|
if arg and arg.annotation:
|
|
arg.annotation = self.analyse_annotation(env, arg.annotation)
|
|
annotations.append((arg.pos, arg.name, arg.annotation))
|
|
|
|
annotation = self.def_node.return_type_annotation
|
|
if annotation:
|
|
annotation = self.analyse_annotation(env, annotation)
|
|
self.def_node.return_type_annotation = annotation
|
|
annotations.append((annotation.pos, StringEncoding.EncodedString("return"), annotation))
|
|
|
|
if nonliteral_objects or nonliteral_other:
|
|
module_scope = env.global_scope()
|
|
cname = module_scope.next_id(Naming.defaults_struct_prefix)
|
|
scope = Symtab.StructOrUnionScope(cname)
|
|
self.defaults = []
|
|
for arg in nonliteral_objects:
|
|
entry = scope.declare_var(arg.name, arg.type, None,
|
|
Naming.arg_prefix + arg.name,
|
|
allow_pyobject=True)
|
|
self.defaults.append((arg, entry))
|
|
for arg in nonliteral_other:
|
|
entry = scope.declare_var(arg.name, arg.type, None,
|
|
Naming.arg_prefix + arg.name,
|
|
allow_pyobject=False, allow_memoryview=True)
|
|
self.defaults.append((arg, entry))
|
|
entry = module_scope.declare_struct_or_union(
|
|
None, 'struct', scope, 1, None, cname=cname)
|
|
self.defaults_struct = scope
|
|
self.defaults_pyobjects = len(nonliteral_objects)
|
|
for arg, entry in self.defaults:
|
|
arg.default_value = '%s->%s' % (
|
|
Naming.dynamic_args_cname, entry.cname)
|
|
self.def_node.defaults_struct = self.defaults_struct.name
|
|
|
|
if default_args or default_kwargs:
|
|
if self.defaults_struct is None:
|
|
if default_args:
|
|
defaults_tuple = TupleNode(self.pos, args=[
|
|
arg.default for arg in default_args])
|
|
self.defaults_tuple = defaults_tuple.analyse_types(env).coerce_to_pyobject(env)
|
|
if default_kwargs:
|
|
defaults_kwdict = DictNode(self.pos, key_value_pairs=[
|
|
DictItemNode(
|
|
arg.pos,
|
|
key=IdentifierStringNode(arg.pos, value=arg.name),
|
|
value=arg.default)
|
|
for arg in default_kwargs])
|
|
self.defaults_kwdict = defaults_kwdict.analyse_types(env)
|
|
else:
|
|
if default_args:
|
|
defaults_tuple = DefaultsTupleNode(
|
|
self.pos, default_args, self.defaults_struct)
|
|
else:
|
|
defaults_tuple = NoneNode(self.pos)
|
|
if default_kwargs:
|
|
defaults_kwdict = DefaultsKwDictNode(
|
|
self.pos, default_kwargs, self.defaults_struct)
|
|
else:
|
|
defaults_kwdict = NoneNode(self.pos)
|
|
|
|
defaults_getter = Nodes.DefNode(
|
|
self.pos, args=[], star_arg=None, starstar_arg=None,
|
|
body=Nodes.ReturnStatNode(
|
|
self.pos, return_type=py_object_type,
|
|
value=TupleNode(
|
|
self.pos, args=[defaults_tuple, defaults_kwdict])),
|
|
decorators=None,
|
|
name=StringEncoding.EncodedString("__defaults__"))
|
|
# defaults getter must never live in class scopes, it's always a module function
|
|
module_scope = env.global_scope()
|
|
defaults_getter.analyse_declarations(module_scope)
|
|
defaults_getter = defaults_getter.analyse_expressions(module_scope)
|
|
defaults_getter.body = defaults_getter.body.analyse_expressions(
|
|
defaults_getter.local_scope)
|
|
defaults_getter.py_wrapper_required = False
|
|
defaults_getter.pymethdef_required = False
|
|
self.def_node.defaults_getter = defaults_getter
|
|
if annotations:
|
|
annotations_dict = DictNode(self.pos, key_value_pairs=[
|
|
DictItemNode(
|
|
pos, key=IdentifierStringNode(pos, value=name),
|
|
value=value)
|
|
for pos, name, value in annotations])
|
|
self.annotations_dict = annotations_dict.analyse_types(env)
|
|
|
|
def analyse_annotation(self, env, annotation):
|
|
if annotation is None:
|
|
return None
|
|
atype = annotation.analyse_as_type(env)
|
|
if atype is not None:
|
|
# Keep parsed types as strings as they might not be Python representable.
|
|
annotation = UnicodeNode(
|
|
annotation.pos,
|
|
value=StringEncoding.EncodedString(atype.declaration_code('', for_display=True)))
|
|
annotation = annotation.analyse_types(env)
|
|
if not annotation.type.is_pyobject:
|
|
annotation = annotation.coerce_to_pyobject(env)
|
|
return annotation
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
gil_message = "Constructing Python function"
|
|
|
|
def self_result_code(self):
|
|
if self.self_object is None:
|
|
self_result = "NULL"
|
|
else:
|
|
self_result = self.self_object.py_result()
|
|
return self_result
|
|
|
|
def generate_result_code(self, code):
|
|
if self.binding:
|
|
self.generate_cyfunction_code(code)
|
|
else:
|
|
self.generate_pycfunction_code(code)
|
|
|
|
def generate_pycfunction_code(self, code):
|
|
py_mod_name = self.get_py_mod_name(code)
|
|
code.putln(
|
|
'%s = PyCFunction_NewEx(&%s, %s, %s); %s' % (
|
|
self.result(),
|
|
self.pymethdef_cname,
|
|
self.self_result_code(),
|
|
py_mod_name,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
|
|
code.put_gotref(self.py_result())
|
|
|
|
def generate_cyfunction_code(self, code):
|
|
if self.specialized_cpdefs:
|
|
def_node = self.specialized_cpdefs[0]
|
|
else:
|
|
def_node = self.def_node
|
|
|
|
if self.specialized_cpdefs or self.is_specialization:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("FusedFunction", "CythonFunction.c"))
|
|
constructor = "__pyx_FusedFunction_New"
|
|
else:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("CythonFunction", "CythonFunction.c"))
|
|
constructor = "__Pyx_CyFunction_New"
|
|
|
|
if self.code_object:
|
|
code_object_result = self.code_object.py_result()
|
|
else:
|
|
code_object_result = 'NULL'
|
|
|
|
flags = []
|
|
if def_node.is_staticmethod:
|
|
flags.append('__Pyx_CYFUNCTION_STATICMETHOD')
|
|
elif def_node.is_classmethod:
|
|
flags.append('__Pyx_CYFUNCTION_CLASSMETHOD')
|
|
|
|
if def_node.local_scope.parent_scope.is_c_class_scope and not def_node.entry.is_anonymous:
|
|
flags.append('__Pyx_CYFUNCTION_CCLASS')
|
|
|
|
if flags:
|
|
flags = ' | '.join(flags)
|
|
else:
|
|
flags = '0'
|
|
|
|
code.putln(
|
|
'%s = %s(&%s, %s, %s, %s, %s, %s, %s); %s' % (
|
|
self.result(),
|
|
constructor,
|
|
self.pymethdef_cname,
|
|
flags,
|
|
self.get_py_qualified_name(code),
|
|
self.self_result_code(),
|
|
self.get_py_mod_name(code),
|
|
Naming.moddict_cname,
|
|
code_object_result,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
|
|
code.put_gotref(self.py_result())
|
|
|
|
if def_node.requires_classobj:
|
|
assert code.pyclass_stack, "pyclass_stack is empty"
|
|
class_node = code.pyclass_stack[-1]
|
|
code.put_incref(self.py_result(), py_object_type)
|
|
code.putln(
|
|
'PyList_Append(%s, %s);' % (
|
|
class_node.class_cell.result(),
|
|
self.result()))
|
|
code.put_giveref(self.py_result())
|
|
|
|
if self.defaults:
|
|
code.putln(
|
|
'if (!__Pyx_CyFunction_InitDefaults(%s, sizeof(%s), %d)) %s' % (
|
|
self.result(), self.defaults_struct.name,
|
|
self.defaults_pyobjects, code.error_goto(self.pos)))
|
|
defaults = '__Pyx_CyFunction_Defaults(%s, %s)' % (
|
|
self.defaults_struct.name, self.result())
|
|
for arg, entry in self.defaults:
|
|
arg.generate_assignment_code(code, target='%s->%s' % (
|
|
defaults, entry.cname))
|
|
|
|
if self.defaults_tuple:
|
|
code.putln('__Pyx_CyFunction_SetDefaultsTuple(%s, %s);' % (
|
|
self.result(), self.defaults_tuple.py_result()))
|
|
if self.defaults_kwdict:
|
|
code.putln('__Pyx_CyFunction_SetDefaultsKwDict(%s, %s);' % (
|
|
self.result(), self.defaults_kwdict.py_result()))
|
|
if def_node.defaults_getter and not self.specialized_cpdefs:
|
|
# Fused functions do not support dynamic defaults, only their specialisations can have them for now.
|
|
code.putln('__Pyx_CyFunction_SetDefaultsGetter(%s, %s);' % (
|
|
self.result(), def_node.defaults_getter.entry.pyfunc_cname))
|
|
if self.annotations_dict:
|
|
code.putln('__Pyx_CyFunction_SetAnnotationsDict(%s, %s);' % (
|
|
self.result(), self.annotations_dict.py_result()))
|
|
|
|
|
|
class InnerFunctionNode(PyCFunctionNode):
|
|
# Special PyCFunctionNode that depends on a closure class
|
|
#
|
|
|
|
binding = True
|
|
needs_self_code = True
|
|
|
|
def self_result_code(self):
|
|
if self.needs_self_code:
|
|
return "((PyObject*)%s)" % Naming.cur_scope_cname
|
|
return "NULL"
|
|
|
|
|
|
class CodeObjectNode(ExprNode):
|
|
# Create a PyCodeObject for a CyFunction instance.
|
|
#
|
|
# def_node DefNode the Python function node
|
|
# varnames TupleNode a tuple with all local variable names
|
|
|
|
subexprs = ['varnames']
|
|
is_temp = False
|
|
result_code = None
|
|
|
|
def __init__(self, def_node):
|
|
ExprNode.__init__(self, def_node.pos, def_node=def_node)
|
|
args = list(def_node.args)
|
|
# if we have args/kwargs, then the first two in var_entries are those
|
|
local_vars = [arg for arg in def_node.local_scope.var_entries if arg.name]
|
|
self.varnames = TupleNode(
|
|
def_node.pos,
|
|
args=[IdentifierStringNode(arg.pos, value=arg.name)
|
|
for arg in args + local_vars],
|
|
is_temp=0,
|
|
is_literal=1)
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def calculate_result_code(self, code=None):
|
|
if self.result_code is None:
|
|
self.result_code = code.get_py_const(py_object_type, 'codeobj', cleanup_level=2)
|
|
return self.result_code
|
|
|
|
def generate_result_code(self, code):
|
|
if self.result_code is None:
|
|
self.result_code = code.get_py_const(py_object_type, 'codeobj', cleanup_level=2)
|
|
|
|
code = code.get_cached_constants_writer(self.result_code)
|
|
if code is None:
|
|
return # already initialised
|
|
code.mark_pos(self.pos)
|
|
func = self.def_node
|
|
func_name = code.get_py_string_const(
|
|
func.name, identifier=True, is_str=False, unicode_value=func.name)
|
|
# FIXME: better way to get the module file path at module init time? Encoding to use?
|
|
file_path = StringEncoding.bytes_literal(func.pos[0].get_filenametable_entry().encode('utf8'), 'utf8')
|
|
file_path_const = code.get_py_string_const(file_path, identifier=False, is_str=True)
|
|
|
|
# This combination makes CPython create a new dict for "frame.f_locals" (see GH #1836).
|
|
flags = ['CO_OPTIMIZED', 'CO_NEWLOCALS']
|
|
|
|
if self.def_node.star_arg:
|
|
flags.append('CO_VARARGS')
|
|
if self.def_node.starstar_arg:
|
|
flags.append('CO_VARKEYWORDS')
|
|
|
|
code.putln("%s = (PyObject*)__Pyx_PyCode_New(%d, %d, %d, 0, %s, %s, %s, %s, %s, %s, %s, %s, %s, %d, %s); %s" % (
|
|
self.result_code,
|
|
len(func.args) - func.num_kwonly_args, # argcount
|
|
func.num_kwonly_args, # kwonlyargcount (Py3 only)
|
|
len(self.varnames.args), # nlocals
|
|
'|'.join(flags) or '0', # flags
|
|
Naming.empty_bytes, # code
|
|
Naming.empty_tuple, # consts
|
|
Naming.empty_tuple, # names (FIXME)
|
|
self.varnames.result(), # varnames
|
|
Naming.empty_tuple, # freevars (FIXME)
|
|
Naming.empty_tuple, # cellvars (FIXME)
|
|
file_path_const, # filename
|
|
func_name, # name
|
|
self.pos[1], # firstlineno
|
|
Naming.empty_bytes, # lnotab
|
|
code.error_goto_if_null(self.result_code, self.pos),
|
|
))
|
|
|
|
|
|
class DefaultLiteralArgNode(ExprNode):
|
|
# CyFunction's literal argument default value
|
|
#
|
|
# Evaluate literal only once.
|
|
|
|
subexprs = []
|
|
is_literal = True
|
|
is_temp = False
|
|
|
|
def __init__(self, pos, arg):
|
|
super(DefaultLiteralArgNode, self).__init__(pos)
|
|
self.arg = arg
|
|
self.type = self.arg.type
|
|
self.evaluated = False
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if not self.evaluated:
|
|
self.arg.generate_evaluation_code(code)
|
|
self.evaluated = True
|
|
|
|
def result(self):
|
|
return self.type.cast_code(self.arg.result())
|
|
|
|
|
|
class DefaultNonLiteralArgNode(ExprNode):
|
|
# CyFunction's non-literal argument default value
|
|
|
|
subexprs = []
|
|
|
|
def __init__(self, pos, arg, defaults_struct):
|
|
super(DefaultNonLiteralArgNode, self).__init__(pos)
|
|
self.arg = arg
|
|
self.defaults_struct = defaults_struct
|
|
|
|
def analyse_types(self, env):
|
|
self.type = self.arg.type
|
|
self.is_temp = False
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
def result(self):
|
|
return '__Pyx_CyFunction_Defaults(%s, %s)->%s' % (
|
|
self.defaults_struct.name, Naming.self_cname,
|
|
self.defaults_struct.lookup(self.arg.name).cname)
|
|
|
|
|
|
class DefaultsTupleNode(TupleNode):
|
|
# CyFunction's __defaults__ tuple
|
|
|
|
def __init__(self, pos, defaults, defaults_struct):
|
|
args = []
|
|
for arg in defaults:
|
|
if not arg.default.is_literal:
|
|
arg = DefaultNonLiteralArgNode(pos, arg, defaults_struct)
|
|
else:
|
|
arg = arg.default
|
|
args.append(arg)
|
|
super(DefaultsTupleNode, self).__init__(pos, args=args)
|
|
|
|
def analyse_types(self, env, skip_children=False):
|
|
return super(DefaultsTupleNode, self).analyse_types(env, skip_children).coerce_to_pyobject(env)
|
|
|
|
|
|
class DefaultsKwDictNode(DictNode):
|
|
# CyFunction's __kwdefaults__ dict
|
|
|
|
def __init__(self, pos, defaults, defaults_struct):
|
|
items = []
|
|
for arg in defaults:
|
|
name = IdentifierStringNode(arg.pos, value=arg.name)
|
|
if not arg.default.is_literal:
|
|
arg = DefaultNonLiteralArgNode(pos, arg, defaults_struct)
|
|
else:
|
|
arg = arg.default
|
|
items.append(DictItemNode(arg.pos, key=name, value=arg))
|
|
super(DefaultsKwDictNode, self).__init__(pos, key_value_pairs=items)
|
|
|
|
|
|
class LambdaNode(InnerFunctionNode):
|
|
# Lambda expression node (only used as a function reference)
|
|
#
|
|
# args [CArgDeclNode] formal arguments
|
|
# star_arg PyArgDeclNode or None * argument
|
|
# starstar_arg PyArgDeclNode or None ** argument
|
|
# lambda_name string a module-globally unique lambda name
|
|
# result_expr ExprNode
|
|
# def_node DefNode the underlying function 'def' node
|
|
|
|
child_attrs = ['def_node']
|
|
|
|
name = StringEncoding.EncodedString('<lambda>')
|
|
|
|
def analyse_declarations(self, env):
|
|
self.lambda_name = self.def_node.lambda_name = env.next_id('lambda')
|
|
self.def_node.no_assignment_synthesis = True
|
|
self.def_node.pymethdef_required = True
|
|
self.def_node.analyse_declarations(env)
|
|
self.def_node.is_cyfunction = True
|
|
self.pymethdef_cname = self.def_node.entry.pymethdef_cname
|
|
env.add_lambda_def(self.def_node)
|
|
|
|
def analyse_types(self, env):
|
|
self.def_node = self.def_node.analyse_expressions(env)
|
|
return super(LambdaNode, self).analyse_types(env)
|
|
|
|
def generate_result_code(self, code):
|
|
self.def_node.generate_execution_code(code)
|
|
super(LambdaNode, self).generate_result_code(code)
|
|
|
|
|
|
class GeneratorExpressionNode(LambdaNode):
|
|
# A generator expression, e.g. (i for i in range(10))
|
|
#
|
|
# Result is a generator.
|
|
#
|
|
# loop ForStatNode the for-loop, containing a YieldExprNode
|
|
# def_node DefNode the underlying generator 'def' node
|
|
|
|
name = StringEncoding.EncodedString('genexpr')
|
|
binding = False
|
|
|
|
def analyse_declarations(self, env):
|
|
self.genexpr_name = env.next_id('genexpr')
|
|
super(GeneratorExpressionNode, self).analyse_declarations(env)
|
|
# No pymethdef required
|
|
self.def_node.pymethdef_required = False
|
|
self.def_node.py_wrapper_required = False
|
|
self.def_node.is_cyfunction = False
|
|
# Force genexpr signature
|
|
self.def_node.entry.signature = TypeSlots.pyfunction_noargs
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln(
|
|
'%s = %s(%s); %s' % (
|
|
self.result(),
|
|
self.def_node.entry.pyfunc_cname,
|
|
self.self_result_code(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class YieldExprNode(ExprNode):
|
|
# Yield expression node
|
|
#
|
|
# arg ExprNode the value to return from the generator
|
|
# label_num integer yield label number
|
|
# is_yield_from boolean is a YieldFromExprNode to delegate to another generator
|
|
|
|
subexprs = ['arg']
|
|
type = py_object_type
|
|
label_num = 0
|
|
is_yield_from = False
|
|
is_await = False
|
|
in_async_gen = False
|
|
expr_keyword = 'yield'
|
|
|
|
def analyse_types(self, env):
|
|
if not self.label_num or (self.is_yield_from and self.in_async_gen):
|
|
error(self.pos, "'%s' not supported here" % self.expr_keyword)
|
|
self.is_temp = 1
|
|
if self.arg is not None:
|
|
self.arg = self.arg.analyse_types(env)
|
|
if not self.arg.type.is_pyobject:
|
|
self.coerce_yield_argument(env)
|
|
return self
|
|
|
|
def coerce_yield_argument(self, env):
|
|
self.arg = self.arg.coerce_to_pyobject(env)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if self.arg:
|
|
self.arg.generate_evaluation_code(code)
|
|
self.arg.make_owned_reference(code)
|
|
code.putln(
|
|
"%s = %s;" % (
|
|
Naming.retval_cname,
|
|
self.arg.result_as(py_object_type)))
|
|
self.arg.generate_post_assignment_code(code)
|
|
self.arg.free_temps(code)
|
|
else:
|
|
code.put_init_to_py_none(Naming.retval_cname, py_object_type)
|
|
self.generate_yield_code(code)
|
|
|
|
def generate_yield_code(self, code):
|
|
"""
|
|
Generate the code to return the argument in 'Naming.retval_cname'
|
|
and to continue at the yield label.
|
|
"""
|
|
label_num, label_name = code.new_yield_label(
|
|
self.expr_keyword.replace(' ', '_'))
|
|
code.use_label(label_name)
|
|
|
|
saved = []
|
|
code.funcstate.closure_temps.reset()
|
|
for cname, type, manage_ref in code.funcstate.temps_in_use():
|
|
save_cname = code.funcstate.closure_temps.allocate_temp(type)
|
|
saved.append((cname, save_cname, type))
|
|
if type.is_pyobject:
|
|
code.put_xgiveref(cname)
|
|
code.putln('%s->%s = %s;' % (Naming.cur_scope_cname, save_cname, cname))
|
|
|
|
code.put_xgiveref(Naming.retval_cname)
|
|
profile = code.globalstate.directives['profile']
|
|
linetrace = code.globalstate.directives['linetrace']
|
|
if profile or linetrace:
|
|
code.put_trace_return(Naming.retval_cname,
|
|
nogil=not code.funcstate.gil_owned)
|
|
code.put_finish_refcount_context()
|
|
|
|
if code.funcstate.current_except is not None:
|
|
# inside of an except block => save away currently handled exception
|
|
code.putln("__Pyx_Coroutine_SwapException(%s);" % Naming.generator_cname)
|
|
else:
|
|
# no exceptions being handled => restore exception state of caller
|
|
code.putln("__Pyx_Coroutine_ResetAndClearException(%s);" % Naming.generator_cname)
|
|
|
|
code.putln("/* return from %sgenerator, %sing value */" % (
|
|
'async ' if self.in_async_gen else '',
|
|
'await' if self.is_await else 'yield'))
|
|
code.putln("%s->resume_label = %d;" % (
|
|
Naming.generator_cname, label_num))
|
|
if self.in_async_gen and not self.is_await:
|
|
# __Pyx__PyAsyncGenValueWrapperNew() steals a reference to the return value
|
|
code.putln("return __Pyx__PyAsyncGenValueWrapperNew(%s);" % Naming.retval_cname)
|
|
else:
|
|
code.putln("return %s;" % Naming.retval_cname)
|
|
|
|
code.put_label(label_name)
|
|
for cname, save_cname, type in saved:
|
|
code.putln('%s = %s->%s;' % (cname, Naming.cur_scope_cname, save_cname))
|
|
if type.is_pyobject:
|
|
code.putln('%s->%s = 0;' % (Naming.cur_scope_cname, save_cname))
|
|
code.put_xgotref(cname)
|
|
self.generate_sent_value_handling_code(code, Naming.sent_value_cname)
|
|
if self.result_is_used:
|
|
self.allocate_temp_result(code)
|
|
code.put('%s = %s; ' % (self.result(), Naming.sent_value_cname))
|
|
code.put_incref(self.result(), py_object_type)
|
|
|
|
def generate_sent_value_handling_code(self, code, value_cname):
|
|
code.putln(code.error_goto_if_null(value_cname, self.pos))
|
|
|
|
|
|
class _YieldDelegationExprNode(YieldExprNode):
|
|
def yield_from_func(self, code):
|
|
raise NotImplementedError()
|
|
|
|
def generate_evaluation_code(self, code, source_cname=None, decref_source=False):
|
|
if source_cname is None:
|
|
self.arg.generate_evaluation_code(code)
|
|
code.putln("%s = %s(%s, %s);" % (
|
|
Naming.retval_cname,
|
|
self.yield_from_func(code),
|
|
Naming.generator_cname,
|
|
self.arg.py_result() if source_cname is None else source_cname))
|
|
if source_cname is None:
|
|
self.arg.generate_disposal_code(code)
|
|
self.arg.free_temps(code)
|
|
elif decref_source:
|
|
code.put_decref_clear(source_cname, py_object_type)
|
|
code.put_xgotref(Naming.retval_cname)
|
|
|
|
code.putln("if (likely(%s)) {" % Naming.retval_cname)
|
|
self.generate_yield_code(code)
|
|
code.putln("} else {")
|
|
# either error or sub-generator has normally terminated: return value => node result
|
|
if self.result_is_used:
|
|
self.fetch_iteration_result(code)
|
|
else:
|
|
self.handle_iteration_exception(code)
|
|
code.putln("}")
|
|
|
|
def fetch_iteration_result(self, code):
|
|
# YieldExprNode has allocated the result temp for us
|
|
code.putln("%s = NULL;" % self.result())
|
|
code.put_error_if_neg(self.pos, "__Pyx_PyGen_FetchStopIterationValue(&%s)" % self.result())
|
|
code.put_gotref(self.result())
|
|
|
|
def handle_iteration_exception(self, code):
|
|
code.putln("PyObject* exc_type = __Pyx_PyErr_Occurred();")
|
|
code.putln("if (exc_type) {")
|
|
code.putln("if (likely(exc_type == PyExc_StopIteration || (exc_type != PyExc_GeneratorExit &&"
|
|
" __Pyx_PyErr_GivenExceptionMatches(exc_type, PyExc_StopIteration)))) PyErr_Clear();")
|
|
code.putln("else %s" % code.error_goto(self.pos))
|
|
code.putln("}")
|
|
|
|
|
|
class YieldFromExprNode(_YieldDelegationExprNode):
|
|
# "yield from GEN" expression
|
|
is_yield_from = True
|
|
expr_keyword = 'yield from'
|
|
|
|
def coerce_yield_argument(self, env):
|
|
if not self.arg.type.is_string:
|
|
# FIXME: support C arrays and C++ iterators?
|
|
error(self.pos, "yielding from non-Python object not supported")
|
|
self.arg = self.arg.coerce_to_pyobject(env)
|
|
|
|
def yield_from_func(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("GeneratorYieldFrom", "Coroutine.c"))
|
|
return "__Pyx_Generator_Yield_From"
|
|
|
|
|
|
class AwaitExprNode(_YieldDelegationExprNode):
|
|
# 'await' expression node
|
|
#
|
|
# arg ExprNode the Awaitable value to await
|
|
# label_num integer yield label number
|
|
|
|
is_await = True
|
|
expr_keyword = 'await'
|
|
|
|
def coerce_yield_argument(self, env):
|
|
if self.arg is not None:
|
|
# FIXME: use same check as in YieldFromExprNode.coerce_yield_argument() ?
|
|
self.arg = self.arg.coerce_to_pyobject(env)
|
|
|
|
def yield_from_func(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("CoroutineYieldFrom", "Coroutine.c"))
|
|
return "__Pyx_Coroutine_Yield_From"
|
|
|
|
|
|
class AwaitIterNextExprNode(AwaitExprNode):
|
|
# 'await' expression node as part of 'async for' iteration
|
|
#
|
|
# Breaks out of loop on StopAsyncIteration exception.
|
|
|
|
def _generate_break(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("StopAsyncIteration", "Coroutine.c"))
|
|
code.putln("PyObject* exc_type = __Pyx_PyErr_Occurred();")
|
|
code.putln("if (unlikely(exc_type && (exc_type == __Pyx_PyExc_StopAsyncIteration || ("
|
|
" exc_type != PyExc_StopIteration && exc_type != PyExc_GeneratorExit &&"
|
|
" __Pyx_PyErr_GivenExceptionMatches(exc_type, __Pyx_PyExc_StopAsyncIteration))))) {")
|
|
code.putln("PyErr_Clear();")
|
|
code.putln("break;")
|
|
code.putln("}")
|
|
|
|
def fetch_iteration_result(self, code):
|
|
assert code.break_label, "AwaitIterNextExprNode outside of 'async for' loop"
|
|
self._generate_break(code)
|
|
super(AwaitIterNextExprNode, self).fetch_iteration_result(code)
|
|
|
|
def generate_sent_value_handling_code(self, code, value_cname):
|
|
assert code.break_label, "AwaitIterNextExprNode outside of 'async for' loop"
|
|
code.putln("if (unlikely(!%s)) {" % value_cname)
|
|
self._generate_break(code)
|
|
# all non-break exceptions are errors, as in parent class
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
|
|
|
|
class GlobalsExprNode(AtomicExprNode):
|
|
type = dict_type
|
|
is_temp = 1
|
|
|
|
def analyse_types(self, env):
|
|
env.use_utility_code(Builtin.globals_utility_code)
|
|
return self
|
|
|
|
gil_message = "Constructing globals dict"
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln('%s = __Pyx_Globals(); %s' % (
|
|
self.result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
|
|
|
|
class LocalsDictItemNode(DictItemNode):
|
|
def analyse_types(self, env):
|
|
self.key = self.key.analyse_types(env)
|
|
self.value = self.value.analyse_types(env)
|
|
self.key = self.key.coerce_to_pyobject(env)
|
|
if self.value.type.can_coerce_to_pyobject(env):
|
|
self.value = self.value.coerce_to_pyobject(env)
|
|
else:
|
|
self.value = None
|
|
return self
|
|
|
|
|
|
class FuncLocalsExprNode(DictNode):
|
|
def __init__(self, pos, env):
|
|
local_vars = sorted([
|
|
entry.name for entry in env.entries.values() if entry.name])
|
|
items = [LocalsDictItemNode(
|
|
pos, key=IdentifierStringNode(pos, value=var),
|
|
value=NameNode(pos, name=var, allow_null=True))
|
|
for var in local_vars]
|
|
DictNode.__init__(self, pos, key_value_pairs=items,
|
|
exclude_null_values=True)
|
|
|
|
def analyse_types(self, env):
|
|
node = super(FuncLocalsExprNode, self).analyse_types(env)
|
|
node.key_value_pairs = [ i for i in node.key_value_pairs
|
|
if i.value is not None ]
|
|
return node
|
|
|
|
|
|
class PyClassLocalsExprNode(AtomicExprNode):
|
|
def __init__(self, pos, pyclass_dict):
|
|
AtomicExprNode.__init__(self, pos)
|
|
self.pyclass_dict = pyclass_dict
|
|
|
|
def analyse_types(self, env):
|
|
self.type = self.pyclass_dict.type
|
|
self.is_temp = False
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def result(self):
|
|
return self.pyclass_dict.result()
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
def LocalsExprNode(pos, scope_node, env):
|
|
if env.is_module_scope:
|
|
return GlobalsExprNode(pos)
|
|
if env.is_py_class_scope:
|
|
return PyClassLocalsExprNode(pos, scope_node.dict)
|
|
return FuncLocalsExprNode(pos, env)
|
|
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# Unary operator nodes
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
compile_time_unary_operators = {
|
|
'not': operator.not_,
|
|
'~': operator.inv,
|
|
'-': operator.neg,
|
|
'+': operator.pos,
|
|
}
|
|
|
|
class UnopNode(ExprNode):
|
|
# operator string
|
|
# operand ExprNode
|
|
#
|
|
# Processing during analyse_expressions phase:
|
|
#
|
|
# analyse_c_operation
|
|
# Called when the operand is not a pyobject.
|
|
# - Check operand type and coerce if needed.
|
|
# - Determine result type and result code fragment.
|
|
# - Allocate temporary for result if needed.
|
|
|
|
subexprs = ['operand']
|
|
infix = True
|
|
|
|
def calculate_constant_result(self):
|
|
func = compile_time_unary_operators[self.operator]
|
|
self.constant_result = func(self.operand.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
func = compile_time_unary_operators.get(self.operator)
|
|
if not func:
|
|
error(self.pos,
|
|
"Unary '%s' not supported in compile-time expression"
|
|
% self.operator)
|
|
operand = self.operand.compile_time_value(denv)
|
|
try:
|
|
return func(operand)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def infer_type(self, env):
|
|
operand_type = self.operand.infer_type(env)
|
|
if operand_type.is_cpp_class or operand_type.is_ptr:
|
|
cpp_type = operand_type.find_cpp_operation_type(self.operator)
|
|
if cpp_type is not None:
|
|
return cpp_type
|
|
return self.infer_unop_type(env, operand_type)
|
|
|
|
def infer_unop_type(self, env, operand_type):
|
|
if operand_type.is_pyobject:
|
|
return py_object_type
|
|
else:
|
|
return operand_type
|
|
|
|
def may_be_none(self):
|
|
if self.operand.type and self.operand.type.is_builtin_type:
|
|
if self.operand.type is not type_type:
|
|
return False
|
|
return ExprNode.may_be_none(self)
|
|
|
|
def analyse_types(self, env):
|
|
self.operand = self.operand.analyse_types(env)
|
|
if self.is_pythran_operation(env):
|
|
self.type = PythranExpr(pythran_unaryop_type(self.operator, self.operand.type))
|
|
self.is_temp = 1
|
|
elif self.is_py_operation():
|
|
self.coerce_operand_to_pyobject(env)
|
|
self.type = py_object_type
|
|
self.is_temp = 1
|
|
elif self.is_cpp_operation():
|
|
self.analyse_cpp_operation(env)
|
|
else:
|
|
self.analyse_c_operation(env)
|
|
return self
|
|
|
|
def check_const(self):
|
|
return self.operand.check_const()
|
|
|
|
def is_py_operation(self):
|
|
return self.operand.type.is_pyobject or self.operand.type.is_ctuple
|
|
|
|
def is_pythran_operation(self, env):
|
|
np_pythran = has_np_pythran(env)
|
|
op_type = self.operand.type
|
|
return np_pythran and (op_type.is_buffer or op_type.is_pythran_expr)
|
|
|
|
def nogil_check(self, env):
|
|
if self.is_py_operation():
|
|
self.gil_error()
|
|
|
|
def is_cpp_operation(self):
|
|
type = self.operand.type
|
|
return type.is_cpp_class
|
|
|
|
def coerce_operand_to_pyobject(self, env):
|
|
self.operand = self.operand.coerce_to_pyobject(env)
|
|
|
|
def generate_result_code(self, code):
|
|
if self.type.is_pythran_expr:
|
|
code.putln("// Pythran unaryop")
|
|
code.putln("__Pyx_call_destructor(%s);" % self.result())
|
|
code.putln("new (&%s) decltype(%s){%s%s};" % (
|
|
self.result(),
|
|
self.result(),
|
|
self.operator,
|
|
self.operand.pythran_result()))
|
|
elif self.operand.type.is_pyobject:
|
|
self.generate_py_operation_code(code)
|
|
elif self.is_temp:
|
|
if self.is_cpp_operation() and self.exception_check == '+':
|
|
translate_cpp_exception(code, self.pos,
|
|
"%s = %s %s;" % (self.result(), self.operator, self.operand.result()),
|
|
self.result() if self.type.is_pyobject else None,
|
|
self.exception_value, self.in_nogil_context)
|
|
else:
|
|
code.putln("%s = %s %s;" % (self.result(), self.operator, self.operand.result()))
|
|
|
|
def generate_py_operation_code(self, code):
|
|
function = self.py_operation_function(code)
|
|
code.putln(
|
|
"%s = %s(%s); %s" % (
|
|
self.result(),
|
|
function,
|
|
self.operand.py_result(),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
|
|
def type_error(self):
|
|
if not self.operand.type.is_error:
|
|
error(self.pos, "Invalid operand type for '%s' (%s)" %
|
|
(self.operator, self.operand.type))
|
|
self.type = PyrexTypes.error_type
|
|
|
|
def analyse_cpp_operation(self, env, overload_check=True):
|
|
entry = env.lookup_operator(self.operator, [self.operand])
|
|
if overload_check and not entry:
|
|
self.type_error()
|
|
return
|
|
if entry:
|
|
self.exception_check = entry.type.exception_check
|
|
self.exception_value = entry.type.exception_value
|
|
if self.exception_check == '+':
|
|
self.is_temp = True
|
|
if self.exception_value is None:
|
|
env.use_utility_code(UtilityCode.load_cached("CppExceptionConversion", "CppSupport.cpp"))
|
|
else:
|
|
self.exception_check = ''
|
|
self.exception_value = ''
|
|
cpp_type = self.operand.type.find_cpp_operation_type(self.operator)
|
|
if overload_check and cpp_type is None:
|
|
error(self.pos, "'%s' operator not defined for %s" % (
|
|
self.operator, type))
|
|
self.type_error()
|
|
return
|
|
self.type = cpp_type
|
|
|
|
|
|
class NotNode(UnopNode):
|
|
# 'not' operator
|
|
#
|
|
# operand ExprNode
|
|
operator = '!'
|
|
|
|
type = PyrexTypes.c_bint_type
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = not self.operand.constant_result
|
|
|
|
def compile_time_value(self, denv):
|
|
operand = self.operand.compile_time_value(denv)
|
|
try:
|
|
return not operand
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def infer_unop_type(self, env, operand_type):
|
|
return PyrexTypes.c_bint_type
|
|
|
|
def analyse_types(self, env):
|
|
self.operand = self.operand.analyse_types(env)
|
|
operand_type = self.operand.type
|
|
if operand_type.is_cpp_class:
|
|
self.analyse_cpp_operation(env)
|
|
else:
|
|
self.operand = self.operand.coerce_to_boolean(env)
|
|
return self
|
|
|
|
def calculate_result_code(self):
|
|
return "(!%s)" % self.operand.result()
|
|
|
|
|
|
class UnaryPlusNode(UnopNode):
|
|
# unary '+' operator
|
|
|
|
operator = '+'
|
|
|
|
def analyse_c_operation(self, env):
|
|
self.type = PyrexTypes.widest_numeric_type(
|
|
self.operand.type, PyrexTypes.c_int_type)
|
|
|
|
def py_operation_function(self, code):
|
|
return "PyNumber_Positive"
|
|
|
|
def calculate_result_code(self):
|
|
if self.is_cpp_operation():
|
|
return "(+%s)" % self.operand.result()
|
|
else:
|
|
return self.operand.result()
|
|
|
|
|
|
class UnaryMinusNode(UnopNode):
|
|
# unary '-' operator
|
|
|
|
operator = '-'
|
|
|
|
def analyse_c_operation(self, env):
|
|
if self.operand.type.is_numeric:
|
|
self.type = PyrexTypes.widest_numeric_type(
|
|
self.operand.type, PyrexTypes.c_int_type)
|
|
elif self.operand.type.is_enum:
|
|
self.type = PyrexTypes.c_int_type
|
|
else:
|
|
self.type_error()
|
|
if self.type.is_complex:
|
|
self.infix = False
|
|
|
|
def py_operation_function(self, code):
|
|
return "PyNumber_Negative"
|
|
|
|
def calculate_result_code(self):
|
|
if self.infix:
|
|
return "(-%s)" % self.operand.result()
|
|
else:
|
|
return "%s(%s)" % (self.operand.type.unary_op('-'), self.operand.result())
|
|
|
|
def get_constant_c_result_code(self):
|
|
value = self.operand.get_constant_c_result_code()
|
|
if value:
|
|
return "(-%s)" % value
|
|
|
|
class TildeNode(UnopNode):
|
|
# unary '~' operator
|
|
|
|
def analyse_c_operation(self, env):
|
|
if self.operand.type.is_int:
|
|
self.type = PyrexTypes.widest_numeric_type(
|
|
self.operand.type, PyrexTypes.c_int_type)
|
|
elif self.operand.type.is_enum:
|
|
self.type = PyrexTypes.c_int_type
|
|
else:
|
|
self.type_error()
|
|
|
|
def py_operation_function(self, code):
|
|
return "PyNumber_Invert"
|
|
|
|
def calculate_result_code(self):
|
|
return "(~%s)" % self.operand.result()
|
|
|
|
|
|
class CUnopNode(UnopNode):
|
|
|
|
def is_py_operation(self):
|
|
return False
|
|
|
|
class DereferenceNode(CUnopNode):
|
|
# unary * operator
|
|
|
|
operator = '*'
|
|
|
|
def infer_unop_type(self, env, operand_type):
|
|
if operand_type.is_ptr:
|
|
return operand_type.base_type
|
|
else:
|
|
return PyrexTypes.error_type
|
|
|
|
def analyse_c_operation(self, env):
|
|
if self.operand.type.is_ptr:
|
|
self.type = self.operand.type.base_type
|
|
else:
|
|
self.type_error()
|
|
|
|
def calculate_result_code(self):
|
|
return "(*%s)" % self.operand.result()
|
|
|
|
|
|
class DecrementIncrementNode(CUnopNode):
|
|
# unary ++/-- operator
|
|
|
|
def analyse_c_operation(self, env):
|
|
if self.operand.type.is_numeric:
|
|
self.type = PyrexTypes.widest_numeric_type(
|
|
self.operand.type, PyrexTypes.c_int_type)
|
|
elif self.operand.type.is_ptr:
|
|
self.type = self.operand.type
|
|
else:
|
|
self.type_error()
|
|
|
|
def calculate_result_code(self):
|
|
if self.is_prefix:
|
|
return "(%s%s)" % (self.operator, self.operand.result())
|
|
else:
|
|
return "(%s%s)" % (self.operand.result(), self.operator)
|
|
|
|
def inc_dec_constructor(is_prefix, operator):
|
|
return lambda pos, **kwds: DecrementIncrementNode(pos, is_prefix=is_prefix, operator=operator, **kwds)
|
|
|
|
|
|
class AmpersandNode(CUnopNode):
|
|
# The C address-of operator.
|
|
#
|
|
# operand ExprNode
|
|
operator = '&'
|
|
|
|
def infer_unop_type(self, env, operand_type):
|
|
return PyrexTypes.c_ptr_type(operand_type)
|
|
|
|
def analyse_types(self, env):
|
|
self.operand = self.operand.analyse_types(env)
|
|
argtype = self.operand.type
|
|
if argtype.is_cpp_class:
|
|
self.analyse_cpp_operation(env, overload_check=False)
|
|
if not (argtype.is_cfunction or argtype.is_reference or self.operand.is_addressable()):
|
|
if argtype.is_memoryviewslice:
|
|
self.error("Cannot take address of memoryview slice")
|
|
else:
|
|
self.error("Taking address of non-lvalue (type %s)" % argtype)
|
|
return self
|
|
if argtype.is_pyobject:
|
|
self.error("Cannot take address of Python %s" % (
|
|
"variable '%s'" % self.operand.name if self.operand.is_name else
|
|
"object attribute '%s'" % self.operand.attribute if self.operand.is_attribute else
|
|
"object"))
|
|
return self
|
|
if not argtype.is_cpp_class or not self.type:
|
|
self.type = PyrexTypes.c_ptr_type(argtype)
|
|
return self
|
|
|
|
def check_const(self):
|
|
return self.operand.check_const_addr()
|
|
|
|
def error(self, mess):
|
|
error(self.pos, mess)
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
|
|
def calculate_result_code(self):
|
|
return "(&%s)" % self.operand.result()
|
|
|
|
def generate_result_code(self, code):
|
|
if (self.operand.type.is_cpp_class and self.exception_check == '+'):
|
|
translate_cpp_exception(code, self.pos,
|
|
"%s = %s %s;" % (self.result(), self.operator, self.operand.result()),
|
|
self.result() if self.type.is_pyobject else None,
|
|
self.exception_value, self.in_nogil_context)
|
|
|
|
|
|
unop_node_classes = {
|
|
"+": UnaryPlusNode,
|
|
"-": UnaryMinusNode,
|
|
"~": TildeNode,
|
|
}
|
|
|
|
def unop_node(pos, operator, operand):
|
|
# Construct unnop node of appropriate class for
|
|
# given operator.
|
|
if isinstance(operand, IntNode) and operator == '-':
|
|
return IntNode(pos = operand.pos, value = str(-Utils.str_to_number(operand.value)),
|
|
longness=operand.longness, unsigned=operand.unsigned)
|
|
elif isinstance(operand, UnopNode) and operand.operator == operator in '+-':
|
|
warning(pos, "Python has no increment/decrement operator: %s%sx == %s(%sx) == x" % ((operator,)*4), 5)
|
|
return unop_node_classes[operator](pos,
|
|
operator = operator,
|
|
operand = operand)
|
|
|
|
|
|
class TypecastNode(ExprNode):
|
|
# C type cast
|
|
#
|
|
# operand ExprNode
|
|
# base_type CBaseTypeNode
|
|
# declarator CDeclaratorNode
|
|
# typecheck boolean
|
|
#
|
|
# If used from a transform, one can if wanted specify the attribute
|
|
# "type" directly and leave base_type and declarator to None
|
|
|
|
subexprs = ['operand']
|
|
base_type = declarator = type = None
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def infer_type(self, env):
|
|
if self.type is None:
|
|
base_type = self.base_type.analyse(env)
|
|
_, self.type = self.declarator.analyse(base_type, env)
|
|
return self.type
|
|
|
|
def analyse_types(self, env):
|
|
if self.type is None:
|
|
base_type = self.base_type.analyse(env)
|
|
_, self.type = self.declarator.analyse(base_type, env)
|
|
if self.operand.has_constant_result():
|
|
# Must be done after self.type is resolved.
|
|
self.calculate_constant_result()
|
|
if self.type.is_cfunction:
|
|
error(self.pos,
|
|
"Cannot cast to a function type")
|
|
self.type = PyrexTypes.error_type
|
|
self.operand = self.operand.analyse_types(env)
|
|
if self.type is PyrexTypes.c_bint_type:
|
|
# short circuit this to a coercion
|
|
return self.operand.coerce_to_boolean(env)
|
|
to_py = self.type.is_pyobject
|
|
from_py = self.operand.type.is_pyobject
|
|
if from_py and not to_py and self.operand.is_ephemeral():
|
|
if not self.type.is_numeric and not self.type.is_cpp_class:
|
|
error(self.pos, "Casting temporary Python object to non-numeric non-Python type")
|
|
if to_py and not from_py:
|
|
if self.type is bytes_type and self.operand.type.is_int:
|
|
return CoerceIntToBytesNode(self.operand, env)
|
|
elif self.operand.type.can_coerce_to_pyobject(env):
|
|
self.result_ctype = py_object_type
|
|
self.operand = self.operand.coerce_to(self.type, env)
|
|
else:
|
|
if self.operand.type.is_ptr:
|
|
if not (self.operand.type.base_type.is_void or self.operand.type.base_type.is_struct):
|
|
error(self.pos, "Python objects cannot be cast from pointers of primitive types")
|
|
else:
|
|
# Should this be an error?
|
|
warning(self.pos, "No conversion from %s to %s, python object pointer used." % (
|
|
self.operand.type, self.type))
|
|
self.operand = self.operand.coerce_to_simple(env)
|
|
elif from_py and not to_py:
|
|
if self.type.create_from_py_utility_code(env):
|
|
self.operand = self.operand.coerce_to(self.type, env)
|
|
elif self.type.is_ptr:
|
|
if not (self.type.base_type.is_void or self.type.base_type.is_struct):
|
|
error(self.pos, "Python objects cannot be cast to pointers of primitive types")
|
|
else:
|
|
warning(self.pos, "No conversion from %s to %s, python object pointer used." % (
|
|
self.type, self.operand.type))
|
|
elif from_py and to_py:
|
|
if self.typecheck:
|
|
self.operand = PyTypeTestNode(self.operand, self.type, env, notnone=True)
|
|
elif isinstance(self.operand, SliceIndexNode):
|
|
# This cast can influence the created type of string slices.
|
|
self.operand = self.operand.coerce_to(self.type, env)
|
|
elif self.type.is_complex and self.operand.type.is_complex:
|
|
self.operand = self.operand.coerce_to_simple(env)
|
|
elif self.operand.type.is_fused:
|
|
self.operand = self.operand.coerce_to(self.type, env)
|
|
#self.type = self.operand.type
|
|
if self.type.is_ptr and self.type.base_type.is_cfunction and self.type.base_type.nogil:
|
|
op_type = self.operand.type
|
|
if op_type.is_ptr:
|
|
op_type = op_type.base_type
|
|
if op_type.is_cfunction and not op_type.nogil:
|
|
warning(self.pos,
|
|
"Casting a GIL-requiring function into a nogil function circumvents GIL validation", 1)
|
|
return self
|
|
|
|
def is_simple(self):
|
|
# either temp or a C cast => no side effects other than the operand's
|
|
return self.operand.is_simple()
|
|
|
|
def is_ephemeral(self):
|
|
# either temp or a C cast => no side effects other than the operand's
|
|
return self.operand.is_ephemeral()
|
|
|
|
def nonlocally_immutable(self):
|
|
return self.is_temp or self.operand.nonlocally_immutable()
|
|
|
|
def nogil_check(self, env):
|
|
if self.type and self.type.is_pyobject and self.is_temp:
|
|
self.gil_error()
|
|
|
|
def check_const(self):
|
|
return self.operand.check_const()
|
|
|
|
def calculate_constant_result(self):
|
|
self.constant_result = self.calculate_result_code(self.operand.constant_result)
|
|
|
|
def calculate_result_code(self, operand_result = None):
|
|
if operand_result is None:
|
|
operand_result = self.operand.result()
|
|
if self.type.is_complex:
|
|
operand_result = self.operand.result()
|
|
if self.operand.type.is_complex:
|
|
real_part = self.type.real_type.cast_code("__Pyx_CREAL(%s)" % operand_result)
|
|
imag_part = self.type.real_type.cast_code("__Pyx_CIMAG(%s)" % operand_result)
|
|
else:
|
|
real_part = self.type.real_type.cast_code(operand_result)
|
|
imag_part = "0"
|
|
return "%s(%s, %s)" % (
|
|
self.type.from_parts,
|
|
real_part,
|
|
imag_part)
|
|
else:
|
|
return self.type.cast_code(operand_result)
|
|
|
|
def get_constant_c_result_code(self):
|
|
operand_result = self.operand.get_constant_c_result_code()
|
|
if operand_result:
|
|
return self.type.cast_code(operand_result)
|
|
|
|
def result_as(self, type):
|
|
if self.type.is_pyobject and not self.is_temp:
|
|
# Optimise away some unnecessary casting
|
|
return self.operand.result_as(type)
|
|
else:
|
|
return ExprNode.result_as(self, type)
|
|
|
|
def generate_result_code(self, code):
|
|
if self.is_temp:
|
|
code.putln(
|
|
"%s = (PyObject *)%s;" % (
|
|
self.result(),
|
|
self.operand.result()))
|
|
code.put_incref(self.result(), self.ctype())
|
|
|
|
|
|
ERR_START = "Start may not be given"
|
|
ERR_NOT_STOP = "Stop must be provided to indicate shape"
|
|
ERR_STEPS = ("Strides may only be given to indicate contiguity. "
|
|
"Consider slicing it after conversion")
|
|
ERR_NOT_POINTER = "Can only create cython.array from pointer or array"
|
|
ERR_BASE_TYPE = "Pointer base type does not match cython.array base type"
|
|
|
|
|
|
class CythonArrayNode(ExprNode):
|
|
"""
|
|
Used when a pointer of base_type is cast to a memoryviewslice with that
|
|
base type. i.e.
|
|
|
|
<int[:M:1, :N]> p
|
|
|
|
creates a fortran-contiguous cython.array.
|
|
|
|
We leave the type set to object so coercions to object are more efficient
|
|
and less work. Acquiring a memoryviewslice from this will be just as
|
|
efficient. ExprNode.coerce_to() will do the additional typecheck on
|
|
self.compile_time_type
|
|
|
|
This also handles <int[:, :]> my_c_array
|
|
|
|
|
|
operand ExprNode the thing we're casting
|
|
base_type_node MemoryViewSliceTypeNode the cast expression node
|
|
"""
|
|
|
|
subexprs = ['operand', 'shapes']
|
|
|
|
shapes = None
|
|
is_temp = True
|
|
mode = "c"
|
|
array_dtype = None
|
|
|
|
shape_type = PyrexTypes.c_py_ssize_t_type
|
|
|
|
def analyse_types(self, env):
|
|
from . import MemoryView
|
|
|
|
self.operand = self.operand.analyse_types(env)
|
|
if self.array_dtype:
|
|
array_dtype = self.array_dtype
|
|
else:
|
|
array_dtype = self.base_type_node.base_type_node.analyse(env)
|
|
axes = self.base_type_node.axes
|
|
|
|
self.type = error_type
|
|
self.shapes = []
|
|
ndim = len(axes)
|
|
|
|
# Base type of the pointer or C array we are converting
|
|
base_type = self.operand.type
|
|
|
|
if not self.operand.type.is_ptr and not self.operand.type.is_array:
|
|
error(self.operand.pos, ERR_NOT_POINTER)
|
|
return self
|
|
|
|
# Dimension sizes of C array
|
|
array_dimension_sizes = []
|
|
if base_type.is_array:
|
|
while base_type.is_array:
|
|
array_dimension_sizes.append(base_type.size)
|
|
base_type = base_type.base_type
|
|
elif base_type.is_ptr:
|
|
base_type = base_type.base_type
|
|
else:
|
|
error(self.pos, "unexpected base type %s found" % base_type)
|
|
return self
|
|
|
|
if not (base_type.same_as(array_dtype) or base_type.is_void):
|
|
error(self.operand.pos, ERR_BASE_TYPE)
|
|
return self
|
|
elif self.operand.type.is_array and len(array_dimension_sizes) != ndim:
|
|
error(self.operand.pos,
|
|
"Expected %d dimensions, array has %d dimensions" %
|
|
(ndim, len(array_dimension_sizes)))
|
|
return self
|
|
|
|
# Verify the start, stop and step values
|
|
# In case of a C array, use the size of C array in each dimension to
|
|
# get an automatic cast
|
|
for axis_no, axis in enumerate(axes):
|
|
if not axis.start.is_none:
|
|
error(axis.start.pos, ERR_START)
|
|
return self
|
|
|
|
if axis.stop.is_none:
|
|
if array_dimension_sizes:
|
|
dimsize = array_dimension_sizes[axis_no]
|
|
axis.stop = IntNode(self.pos, value=str(dimsize),
|
|
constant_result=dimsize,
|
|
type=PyrexTypes.c_int_type)
|
|
else:
|
|
error(axis.pos, ERR_NOT_STOP)
|
|
return self
|
|
|
|
axis.stop = axis.stop.analyse_types(env)
|
|
shape = axis.stop.coerce_to(self.shape_type, env)
|
|
if not shape.is_literal:
|
|
shape.coerce_to_temp(env)
|
|
|
|
self.shapes.append(shape)
|
|
|
|
first_or_last = axis_no in (0, ndim - 1)
|
|
if not axis.step.is_none and first_or_last:
|
|
# '1' in the first or last dimension denotes F or C contiguity
|
|
axis.step = axis.step.analyse_types(env)
|
|
if (not axis.step.type.is_int and axis.step.is_literal and not
|
|
axis.step.type.is_error):
|
|
error(axis.step.pos, "Expected an integer literal")
|
|
return self
|
|
|
|
if axis.step.compile_time_value(env) != 1:
|
|
error(axis.step.pos, ERR_STEPS)
|
|
return self
|
|
|
|
if axis_no == 0:
|
|
self.mode = "fortran"
|
|
|
|
elif not axis.step.is_none and not first_or_last:
|
|
# step provided in some other dimension
|
|
error(axis.step.pos, ERR_STEPS)
|
|
return self
|
|
|
|
if not self.operand.is_name:
|
|
self.operand = self.operand.coerce_to_temp(env)
|
|
|
|
axes = [('direct', 'follow')] * len(axes)
|
|
if self.mode == "fortran":
|
|
axes[0] = ('direct', 'contig')
|
|
else:
|
|
axes[-1] = ('direct', 'contig')
|
|
|
|
self.coercion_type = PyrexTypes.MemoryViewSliceType(array_dtype, axes)
|
|
self.coercion_type.validate_memslice_dtype(self.pos)
|
|
self.type = self.get_cython_array_type(env)
|
|
MemoryView.use_cython_array_utility_code(env)
|
|
env.use_utility_code(MemoryView.typeinfo_to_format_code)
|
|
return self
|
|
|
|
def allocate_temp_result(self, code):
|
|
if self.temp_code:
|
|
raise RuntimeError("temp allocated multiple times")
|
|
|
|
self.temp_code = code.funcstate.allocate_temp(self.type, True)
|
|
|
|
def infer_type(self, env):
|
|
return self.get_cython_array_type(env)
|
|
|
|
def get_cython_array_type(self, env):
|
|
cython_scope = env.global_scope().context.cython_scope
|
|
cython_scope.load_cythonscope()
|
|
return cython_scope.viewscope.lookup("array").type
|
|
|
|
def generate_result_code(self, code):
|
|
from . import Buffer
|
|
|
|
shapes = [self.shape_type.cast_code(shape.result())
|
|
for shape in self.shapes]
|
|
dtype = self.coercion_type.dtype
|
|
|
|
shapes_temp = code.funcstate.allocate_temp(py_object_type, True)
|
|
format_temp = code.funcstate.allocate_temp(py_object_type, True)
|
|
|
|
itemsize = "sizeof(%s)" % dtype.empty_declaration_code()
|
|
type_info = Buffer.get_type_information_cname(code, dtype)
|
|
|
|
if self.operand.type.is_ptr:
|
|
code.putln("if (!%s) {" % self.operand.result())
|
|
code.putln( 'PyErr_SetString(PyExc_ValueError,'
|
|
'"Cannot create cython.array from NULL pointer");')
|
|
code.putln(code.error_goto(self.operand.pos))
|
|
code.putln("}")
|
|
|
|
code.putln("%s = __pyx_format_from_typeinfo(&%s); %s" % (
|
|
format_temp,
|
|
type_info,
|
|
code.error_goto_if_null(format_temp, self.pos),
|
|
))
|
|
code.put_gotref(format_temp)
|
|
|
|
buildvalue_fmt = " __PYX_BUILD_PY_SSIZE_T " * len(shapes)
|
|
code.putln('%s = Py_BuildValue((char*) "(" %s ")", %s); %s' % (
|
|
shapes_temp,
|
|
buildvalue_fmt,
|
|
", ".join(shapes),
|
|
code.error_goto_if_null(shapes_temp, self.pos),
|
|
))
|
|
code.put_gotref(shapes_temp)
|
|
|
|
tup = (self.result(), shapes_temp, itemsize, format_temp,
|
|
self.mode, self.operand.result())
|
|
code.putln('%s = __pyx_array_new('
|
|
'%s, %s, PyBytes_AS_STRING(%s), '
|
|
'(char *) "%s", (char *) %s);' % tup)
|
|
code.putln(code.error_goto_if_null(self.result(), self.pos))
|
|
code.put_gotref(self.result())
|
|
|
|
def dispose(temp):
|
|
code.put_decref_clear(temp, py_object_type)
|
|
code.funcstate.release_temp(temp)
|
|
|
|
dispose(shapes_temp)
|
|
dispose(format_temp)
|
|
|
|
@classmethod
|
|
def from_carray(cls, src_node, env):
|
|
"""
|
|
Given a C array type, return a CythonArrayNode
|
|
"""
|
|
pos = src_node.pos
|
|
base_type = src_node.type
|
|
|
|
none_node = NoneNode(pos)
|
|
axes = []
|
|
|
|
while base_type.is_array:
|
|
axes.append(SliceNode(pos, start=none_node, stop=none_node,
|
|
step=none_node))
|
|
base_type = base_type.base_type
|
|
axes[-1].step = IntNode(pos, value="1", is_c_literal=True)
|
|
|
|
memslicenode = Nodes.MemoryViewSliceTypeNode(pos, axes=axes,
|
|
base_type_node=base_type)
|
|
result = CythonArrayNode(pos, base_type_node=memslicenode,
|
|
operand=src_node, array_dtype=base_type)
|
|
result = result.analyse_types(env)
|
|
return result
|
|
|
|
class SizeofNode(ExprNode):
|
|
# Abstract base class for sizeof(x) expression nodes.
|
|
|
|
type = PyrexTypes.c_size_t_type
|
|
|
|
def check_const(self):
|
|
return True
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
class SizeofTypeNode(SizeofNode):
|
|
# C sizeof function applied to a type
|
|
#
|
|
# base_type CBaseTypeNode
|
|
# declarator CDeclaratorNode
|
|
|
|
subexprs = []
|
|
arg_type = None
|
|
|
|
def analyse_types(self, env):
|
|
# we may have incorrectly interpreted a dotted name as a type rather than an attribute
|
|
# this could be better handled by more uniformly treating types as runtime-available objects
|
|
if 0 and self.base_type.module_path:
|
|
path = self.base_type.module_path
|
|
obj = env.lookup(path[0])
|
|
if obj.as_module is None:
|
|
operand = NameNode(pos=self.pos, name=path[0])
|
|
for attr in path[1:]:
|
|
operand = AttributeNode(pos=self.pos, obj=operand, attribute=attr)
|
|
operand = AttributeNode(pos=self.pos, obj=operand, attribute=self.base_type.name)
|
|
node = SizeofVarNode(self.pos, operand=operand).analyse_types(env)
|
|
return node
|
|
if self.arg_type is None:
|
|
base_type = self.base_type.analyse(env)
|
|
_, arg_type = self.declarator.analyse(base_type, env)
|
|
self.arg_type = arg_type
|
|
self.check_type()
|
|
return self
|
|
|
|
def check_type(self):
|
|
arg_type = self.arg_type
|
|
if not arg_type:
|
|
return
|
|
if arg_type.is_pyobject and not arg_type.is_extension_type:
|
|
error(self.pos, "Cannot take sizeof Python object")
|
|
elif arg_type.is_void:
|
|
error(self.pos, "Cannot take sizeof void")
|
|
elif not arg_type.is_complete():
|
|
error(self.pos, "Cannot take sizeof incomplete type '%s'" % arg_type)
|
|
|
|
def calculate_result_code(self):
|
|
if self.arg_type.is_extension_type:
|
|
# the size of the pointer is boring
|
|
# we want the size of the actual struct
|
|
arg_code = self.arg_type.declaration_code("", deref=1)
|
|
else:
|
|
arg_code = self.arg_type.empty_declaration_code()
|
|
return "(sizeof(%s))" % arg_code
|
|
|
|
|
|
class SizeofVarNode(SizeofNode):
|
|
# C sizeof function applied to a variable
|
|
#
|
|
# operand ExprNode
|
|
|
|
subexprs = ['operand']
|
|
|
|
def analyse_types(self, env):
|
|
# We may actually be looking at a type rather than a variable...
|
|
# If we are, traditional analysis would fail...
|
|
operand_as_type = self.operand.analyse_as_type(env)
|
|
if operand_as_type:
|
|
self.arg_type = operand_as_type
|
|
if self.arg_type.is_fused:
|
|
self.arg_type = self.arg_type.specialize(env.fused_to_specific)
|
|
self.__class__ = SizeofTypeNode
|
|
self.check_type()
|
|
else:
|
|
self.operand = self.operand.analyse_types(env)
|
|
return self
|
|
|
|
def calculate_result_code(self):
|
|
return "(sizeof(%s))" % self.operand.result()
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
|
|
class TypeidNode(ExprNode):
|
|
# C++ typeid operator applied to a type or variable
|
|
#
|
|
# operand ExprNode
|
|
# arg_type ExprNode
|
|
# is_variable boolean
|
|
|
|
type = PyrexTypes.error_type
|
|
|
|
subexprs = ['operand']
|
|
|
|
arg_type = None
|
|
is_variable = None
|
|
is_temp = 1
|
|
|
|
def get_type_info_type(self, env):
|
|
env_module = env
|
|
while not env_module.is_module_scope:
|
|
env_module = env_module.outer_scope
|
|
typeinfo_module = env_module.find_module('libcpp.typeinfo', self.pos)
|
|
typeinfo_entry = typeinfo_module.lookup('type_info')
|
|
return PyrexTypes.CFakeReferenceType(PyrexTypes.c_const_type(typeinfo_entry.type))
|
|
|
|
def analyse_types(self, env):
|
|
type_info = self.get_type_info_type(env)
|
|
if not type_info:
|
|
self.error("The 'libcpp.typeinfo' module must be cimported to use the typeid() operator")
|
|
return self
|
|
self.type = type_info
|
|
as_type = self.operand.analyse_as_type(env)
|
|
if as_type:
|
|
self.arg_type = as_type
|
|
self.is_type = True
|
|
else:
|
|
self.arg_type = self.operand.analyse_types(env)
|
|
self.is_type = False
|
|
if self.arg_type.type.is_pyobject:
|
|
self.error("Cannot use typeid on a Python object")
|
|
return self
|
|
elif self.arg_type.type.is_void:
|
|
self.error("Cannot use typeid on void")
|
|
return self
|
|
elif not self.arg_type.type.is_complete():
|
|
self.error("Cannot use typeid on incomplete type '%s'" % self.arg_type.type)
|
|
return self
|
|
env.use_utility_code(UtilityCode.load_cached("CppExceptionConversion", "CppSupport.cpp"))
|
|
return self
|
|
|
|
def error(self, mess):
|
|
error(self.pos, mess)
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
|
|
def check_const(self):
|
|
return True
|
|
|
|
def calculate_result_code(self):
|
|
return self.temp_code
|
|
|
|
def generate_result_code(self, code):
|
|
if self.is_type:
|
|
arg_code = self.arg_type.empty_declaration_code()
|
|
else:
|
|
arg_code = self.arg_type.result()
|
|
translate_cpp_exception(code, self.pos,
|
|
"%s = typeid(%s);" % (self.temp_code, arg_code),
|
|
None, None, self.in_nogil_context)
|
|
|
|
class TypeofNode(ExprNode):
|
|
# Compile-time type of an expression, as a string.
|
|
#
|
|
# operand ExprNode
|
|
# literal StringNode # internal
|
|
|
|
literal = None
|
|
type = py_object_type
|
|
|
|
subexprs = ['literal'] # 'operand' will be ignored after type analysis!
|
|
|
|
def analyse_types(self, env):
|
|
self.operand = self.operand.analyse_types(env)
|
|
value = StringEncoding.EncodedString(str(self.operand.type)) #self.operand.type.typeof_name())
|
|
literal = StringNode(self.pos, value=value)
|
|
literal = literal.analyse_types(env)
|
|
self.literal = literal.coerce_to_pyobject(env)
|
|
return self
|
|
|
|
def analyse_as_type(self, env):
|
|
self.operand = self.operand.analyse_types(env)
|
|
return self.operand.type
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def generate_evaluation_code(self, code):
|
|
self.literal.generate_evaluation_code(code)
|
|
|
|
def calculate_result_code(self):
|
|
return self.literal.calculate_result_code()
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# Binary operator nodes
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
try:
|
|
matmul_operator = operator.matmul
|
|
except AttributeError:
|
|
def matmul_operator(a, b):
|
|
try:
|
|
func = a.__matmul__
|
|
except AttributeError:
|
|
func = b.__rmatmul__
|
|
return func(a, b)
|
|
|
|
compile_time_binary_operators = {
|
|
'<': operator.lt,
|
|
'<=': operator.le,
|
|
'==': operator.eq,
|
|
'!=': operator.ne,
|
|
'>=': operator.ge,
|
|
'>': operator.gt,
|
|
'is': operator.is_,
|
|
'is_not': operator.is_not,
|
|
'+': operator.add,
|
|
'&': operator.and_,
|
|
'/': operator.truediv,
|
|
'//': operator.floordiv,
|
|
'<<': operator.lshift,
|
|
'%': operator.mod,
|
|
'*': operator.mul,
|
|
'|': operator.or_,
|
|
'**': operator.pow,
|
|
'>>': operator.rshift,
|
|
'-': operator.sub,
|
|
'^': operator.xor,
|
|
'@': matmul_operator,
|
|
'in': lambda x, seq: x in seq,
|
|
'not_in': lambda x, seq: x not in seq,
|
|
}
|
|
|
|
def get_compile_time_binop(node):
|
|
func = compile_time_binary_operators.get(node.operator)
|
|
if not func:
|
|
error(node.pos,
|
|
"Binary '%s' not supported in compile-time expression"
|
|
% node.operator)
|
|
return func
|
|
|
|
|
|
class BinopNode(ExprNode):
|
|
# operator string
|
|
# operand1 ExprNode
|
|
# operand2 ExprNode
|
|
#
|
|
# Processing during analyse_expressions phase:
|
|
#
|
|
# analyse_c_operation
|
|
# Called when neither operand is a pyobject.
|
|
# - Check operand types and coerce if needed.
|
|
# - Determine result type and result code fragment.
|
|
# - Allocate temporary for result if needed.
|
|
|
|
subexprs = ['operand1', 'operand2']
|
|
inplace = False
|
|
|
|
def calculate_constant_result(self):
|
|
func = compile_time_binary_operators[self.operator]
|
|
self.constant_result = func(
|
|
self.operand1.constant_result,
|
|
self.operand2.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
func = get_compile_time_binop(self)
|
|
operand1 = self.operand1.compile_time_value(denv)
|
|
operand2 = self.operand2.compile_time_value(denv)
|
|
try:
|
|
return func(operand1, operand2)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def infer_type(self, env):
|
|
return self.result_type(self.operand1.infer_type(env),
|
|
self.operand2.infer_type(env), env)
|
|
|
|
def analyse_types(self, env):
|
|
self.operand1 = self.operand1.analyse_types(env)
|
|
self.operand2 = self.operand2.analyse_types(env)
|
|
self.analyse_operation(env)
|
|
return self
|
|
|
|
def analyse_operation(self, env):
|
|
if self.is_pythran_operation(env):
|
|
self.type = self.result_type(self.operand1.type,
|
|
self.operand2.type, env)
|
|
assert self.type.is_pythran_expr
|
|
self.is_temp = 1
|
|
elif self.is_py_operation():
|
|
self.coerce_operands_to_pyobjects(env)
|
|
self.type = self.result_type(self.operand1.type,
|
|
self.operand2.type, env)
|
|
assert self.type.is_pyobject
|
|
self.is_temp = 1
|
|
elif self.is_cpp_operation():
|
|
self.analyse_cpp_operation(env)
|
|
else:
|
|
self.analyse_c_operation(env)
|
|
|
|
def is_py_operation(self):
|
|
return self.is_py_operation_types(self.operand1.type, self.operand2.type)
|
|
|
|
def is_py_operation_types(self, type1, type2):
|
|
return type1.is_pyobject or type2.is_pyobject or type1.is_ctuple or type2.is_ctuple
|
|
|
|
def is_pythran_operation(self, env):
|
|
return self.is_pythran_operation_types(self.operand1.type, self.operand2.type, env)
|
|
|
|
def is_pythran_operation_types(self, type1, type2, env):
|
|
# Support only expr op supported_type, or supported_type op expr
|
|
return has_np_pythran(env) and \
|
|
(is_pythran_supported_operation_type(type1) and is_pythran_supported_operation_type(type2)) and \
|
|
(is_pythran_expr(type1) or is_pythran_expr(type2))
|
|
|
|
def is_cpp_operation(self):
|
|
return (self.operand1.type.is_cpp_class
|
|
or self.operand2.type.is_cpp_class)
|
|
|
|
def analyse_cpp_operation(self, env):
|
|
entry = env.lookup_operator(self.operator, [self.operand1, self.operand2])
|
|
if not entry:
|
|
self.type_error()
|
|
return
|
|
func_type = entry.type
|
|
self.exception_check = func_type.exception_check
|
|
self.exception_value = func_type.exception_value
|
|
if self.exception_check == '+':
|
|
# Used by NumBinopNodes to break up expressions involving multiple
|
|
# operators so that exceptions can be handled properly.
|
|
self.is_temp = 1
|
|
if self.exception_value is None:
|
|
env.use_utility_code(UtilityCode.load_cached("CppExceptionConversion", "CppSupport.cpp"))
|
|
if func_type.is_ptr:
|
|
func_type = func_type.base_type
|
|
if len(func_type.args) == 1:
|
|
self.operand2 = self.operand2.coerce_to(func_type.args[0].type, env)
|
|
else:
|
|
self.operand1 = self.operand1.coerce_to(func_type.args[0].type, env)
|
|
self.operand2 = self.operand2.coerce_to(func_type.args[1].type, env)
|
|
self.type = func_type.return_type
|
|
|
|
def result_type(self, type1, type2, env):
|
|
if self.is_pythran_operation_types(type1, type2, env):
|
|
return PythranExpr(pythran_binop_type(self.operator, type1, type2))
|
|
if self.is_py_operation_types(type1, type2):
|
|
if type2.is_string:
|
|
type2 = Builtin.bytes_type
|
|
elif type2.is_pyunicode_ptr:
|
|
type2 = Builtin.unicode_type
|
|
if type1.is_string:
|
|
type1 = Builtin.bytes_type
|
|
elif type1.is_pyunicode_ptr:
|
|
type1 = Builtin.unicode_type
|
|
if type1.is_builtin_type or type2.is_builtin_type:
|
|
if type1 is type2 and self.operator in '**%+|&^':
|
|
# FIXME: at least these operators should be safe - others?
|
|
return type1
|
|
result_type = self.infer_builtin_types_operation(type1, type2)
|
|
if result_type is not None:
|
|
return result_type
|
|
return py_object_type
|
|
elif type1.is_error or type2.is_error:
|
|
return PyrexTypes.error_type
|
|
else:
|
|
return self.compute_c_result_type(type1, type2)
|
|
|
|
def infer_builtin_types_operation(self, type1, type2):
|
|
return None
|
|
|
|
def nogil_check(self, env):
|
|
if self.is_py_operation():
|
|
self.gil_error()
|
|
|
|
def coerce_operands_to_pyobjects(self, env):
|
|
self.operand1 = self.operand1.coerce_to_pyobject(env)
|
|
self.operand2 = self.operand2.coerce_to_pyobject(env)
|
|
|
|
def check_const(self):
|
|
return self.operand1.check_const() and self.operand2.check_const()
|
|
|
|
def is_ephemeral(self):
|
|
return (super(BinopNode, self).is_ephemeral() or
|
|
self.operand1.is_ephemeral() or self.operand2.is_ephemeral())
|
|
|
|
def generate_result_code(self, code):
|
|
if self.type.is_pythran_expr:
|
|
code.putln("// Pythran binop")
|
|
code.putln("__Pyx_call_destructor(%s);" % self.result())
|
|
if self.operator == '**':
|
|
code.putln("new (&%s) decltype(%s){pythonic::numpy::functor::power{}(%s, %s)};" % (
|
|
self.result(),
|
|
self.result(),
|
|
self.operand1.pythran_result(),
|
|
self.operand2.pythran_result()))
|
|
else:
|
|
code.putln("new (&%s) decltype(%s){%s %s %s};" % (
|
|
self.result(),
|
|
self.result(),
|
|
self.operand1.pythran_result(),
|
|
self.operator,
|
|
self.operand2.pythran_result()))
|
|
elif self.operand1.type.is_pyobject:
|
|
function = self.py_operation_function(code)
|
|
if self.operator == '**':
|
|
extra_args = ", Py_None"
|
|
else:
|
|
extra_args = ""
|
|
code.putln(
|
|
"%s = %s(%s, %s%s); %s" % (
|
|
self.result(),
|
|
function,
|
|
self.operand1.py_result(),
|
|
self.operand2.py_result(),
|
|
extra_args,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.py_result())
|
|
elif self.is_temp:
|
|
# C++ overloaded operators with exception values are currently all
|
|
# handled through temporaries.
|
|
if self.is_cpp_operation() and self.exception_check == '+':
|
|
translate_cpp_exception(code, self.pos,
|
|
"%s = %s;" % (self.result(), self.calculate_result_code()),
|
|
self.result() if self.type.is_pyobject else None,
|
|
self.exception_value, self.in_nogil_context)
|
|
else:
|
|
code.putln("%s = %s;" % (self.result(), self.calculate_result_code()))
|
|
|
|
def type_error(self):
|
|
if not (self.operand1.type.is_error
|
|
or self.operand2.type.is_error):
|
|
error(self.pos, "Invalid operand types for '%s' (%s; %s)" %
|
|
(self.operator, self.operand1.type,
|
|
self.operand2.type))
|
|
self.type = PyrexTypes.error_type
|
|
|
|
|
|
class CBinopNode(BinopNode):
|
|
|
|
def analyse_types(self, env):
|
|
node = BinopNode.analyse_types(self, env)
|
|
if node.is_py_operation():
|
|
node.type = PyrexTypes.error_type
|
|
return node
|
|
|
|
def py_operation_function(self, code):
|
|
return ""
|
|
|
|
def calculate_result_code(self):
|
|
return "(%s %s %s)" % (
|
|
self.operand1.result(),
|
|
self.operator,
|
|
self.operand2.result())
|
|
|
|
def compute_c_result_type(self, type1, type2):
|
|
cpp_type = None
|
|
if type1.is_cpp_class or type1.is_ptr:
|
|
cpp_type = type1.find_cpp_operation_type(self.operator, type2)
|
|
if cpp_type is None and (type2.is_cpp_class or type2.is_ptr):
|
|
cpp_type = type2.find_cpp_operation_type(self.operator, type1)
|
|
# FIXME: do we need to handle other cases here?
|
|
return cpp_type
|
|
|
|
|
|
def c_binop_constructor(operator):
|
|
def make_binop_node(pos, **operands):
|
|
return CBinopNode(pos, operator=operator, **operands)
|
|
return make_binop_node
|
|
|
|
class NumBinopNode(BinopNode):
|
|
# Binary operation taking numeric arguments.
|
|
|
|
infix = True
|
|
overflow_check = False
|
|
overflow_bit_node = None
|
|
|
|
def analyse_c_operation(self, env):
|
|
type1 = self.operand1.type
|
|
type2 = self.operand2.type
|
|
self.type = self.compute_c_result_type(type1, type2)
|
|
if not self.type:
|
|
self.type_error()
|
|
return
|
|
if self.type.is_complex:
|
|
self.infix = False
|
|
if (self.type.is_int
|
|
and env.directives['overflowcheck']
|
|
and self.operator in self.overflow_op_names):
|
|
if (self.operator in ('+', '*')
|
|
and self.operand1.has_constant_result()
|
|
and not self.operand2.has_constant_result()):
|
|
self.operand1, self.operand2 = self.operand2, self.operand1
|
|
self.overflow_check = True
|
|
self.overflow_fold = env.directives['overflowcheck.fold']
|
|
self.func = self.type.overflow_check_binop(
|
|
self.overflow_op_names[self.operator],
|
|
env,
|
|
const_rhs = self.operand2.has_constant_result())
|
|
self.is_temp = True
|
|
if not self.infix or (type1.is_numeric and type2.is_numeric):
|
|
self.operand1 = self.operand1.coerce_to(self.type, env)
|
|
self.operand2 = self.operand2.coerce_to(self.type, env)
|
|
|
|
def compute_c_result_type(self, type1, type2):
|
|
if self.c_types_okay(type1, type2):
|
|
widest_type = PyrexTypes.widest_numeric_type(type1, type2)
|
|
if widest_type is PyrexTypes.c_bint_type:
|
|
if self.operator not in '|^&':
|
|
# False + False == 0 # not False!
|
|
widest_type = PyrexTypes.c_int_type
|
|
else:
|
|
widest_type = PyrexTypes.widest_numeric_type(
|
|
widest_type, PyrexTypes.c_int_type)
|
|
return widest_type
|
|
else:
|
|
return None
|
|
|
|
def may_be_none(self):
|
|
if self.type and self.type.is_builtin_type:
|
|
# if we know the result type, we know the operation, so it can't be None
|
|
return False
|
|
type1 = self.operand1.type
|
|
type2 = self.operand2.type
|
|
if type1 and type1.is_builtin_type and type2 and type2.is_builtin_type:
|
|
# XXX: I can't think of any case where a binary operation
|
|
# on builtin types evaluates to None - add a special case
|
|
# here if there is one.
|
|
return False
|
|
return super(NumBinopNode, self).may_be_none()
|
|
|
|
def get_constant_c_result_code(self):
|
|
value1 = self.operand1.get_constant_c_result_code()
|
|
value2 = self.operand2.get_constant_c_result_code()
|
|
if value1 and value2:
|
|
return "(%s %s %s)" % (value1, self.operator, value2)
|
|
else:
|
|
return None
|
|
|
|
def c_types_okay(self, type1, type2):
|
|
#print "NumBinopNode.c_types_okay:", type1, type2 ###
|
|
return (type1.is_numeric or type1.is_enum) \
|
|
and (type2.is_numeric or type2.is_enum)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if self.overflow_check:
|
|
self.overflow_bit_node = self
|
|
self.overflow_bit = code.funcstate.allocate_temp(PyrexTypes.c_int_type, manage_ref=False)
|
|
code.putln("%s = 0;" % self.overflow_bit)
|
|
super(NumBinopNode, self).generate_evaluation_code(code)
|
|
if self.overflow_check:
|
|
code.putln("if (unlikely(%s)) {" % self.overflow_bit)
|
|
code.putln('PyErr_SetString(PyExc_OverflowError, "value too large");')
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
code.funcstate.release_temp(self.overflow_bit)
|
|
|
|
def calculate_result_code(self):
|
|
if self.overflow_bit_node is not None:
|
|
return "%s(%s, %s, &%s)" % (
|
|
self.func,
|
|
self.operand1.result(),
|
|
self.operand2.result(),
|
|
self.overflow_bit_node.overflow_bit)
|
|
elif self.type.is_cpp_class or self.infix:
|
|
if is_pythran_expr(self.type):
|
|
result1, result2 = self.operand1.pythran_result(), self.operand2.pythran_result()
|
|
else:
|
|
result1, result2 = self.operand1.result(), self.operand2.result()
|
|
return "(%s %s %s)" % (result1, self.operator, result2)
|
|
else:
|
|
func = self.type.binary_op(self.operator)
|
|
if func is None:
|
|
error(self.pos, "binary operator %s not supported for %s" % (self.operator, self.type))
|
|
return "%s(%s, %s)" % (
|
|
func,
|
|
self.operand1.result(),
|
|
self.operand2.result())
|
|
|
|
def is_py_operation_types(self, type1, type2):
|
|
return (type1.is_unicode_char or
|
|
type2.is_unicode_char or
|
|
BinopNode.is_py_operation_types(self, type1, type2))
|
|
|
|
def py_operation_function(self, code):
|
|
function_name = self.py_functions[self.operator]
|
|
if self.inplace:
|
|
function_name = function_name.replace('PyNumber_', 'PyNumber_InPlace')
|
|
return function_name
|
|
|
|
py_functions = {
|
|
"|": "PyNumber_Or",
|
|
"^": "PyNumber_Xor",
|
|
"&": "PyNumber_And",
|
|
"<<": "PyNumber_Lshift",
|
|
">>": "PyNumber_Rshift",
|
|
"+": "PyNumber_Add",
|
|
"-": "PyNumber_Subtract",
|
|
"*": "PyNumber_Multiply",
|
|
"@": "__Pyx_PyNumber_MatrixMultiply",
|
|
"/": "__Pyx_PyNumber_Divide",
|
|
"//": "PyNumber_FloorDivide",
|
|
"%": "PyNumber_Remainder",
|
|
"**": "PyNumber_Power",
|
|
}
|
|
|
|
overflow_op_names = {
|
|
"+": "add",
|
|
"-": "sub",
|
|
"*": "mul",
|
|
"<<": "lshift",
|
|
}
|
|
|
|
|
|
class IntBinopNode(NumBinopNode):
|
|
# Binary operation taking integer arguments.
|
|
|
|
def c_types_okay(self, type1, type2):
|
|
#print "IntBinopNode.c_types_okay:", type1, type2 ###
|
|
return (type1.is_int or type1.is_enum) \
|
|
and (type2.is_int or type2.is_enum)
|
|
|
|
|
|
class AddNode(NumBinopNode):
|
|
# '+' operator.
|
|
|
|
def is_py_operation_types(self, type1, type2):
|
|
if type1.is_string and type2.is_string or type1.is_pyunicode_ptr and type2.is_pyunicode_ptr:
|
|
return 1
|
|
else:
|
|
return NumBinopNode.is_py_operation_types(self, type1, type2)
|
|
|
|
def infer_builtin_types_operation(self, type1, type2):
|
|
# b'abc' + 'abc' raises an exception in Py3,
|
|
# so we can safely infer the Py2 type for bytes here
|
|
string_types = (bytes_type, bytearray_type, str_type, basestring_type, unicode_type)
|
|
if type1 in string_types and type2 in string_types:
|
|
return string_types[max(string_types.index(type1),
|
|
string_types.index(type2))]
|
|
return None
|
|
|
|
def compute_c_result_type(self, type1, type2):
|
|
#print "AddNode.compute_c_result_type:", type1, self.operator, type2 ###
|
|
if (type1.is_ptr or type1.is_array) and (type2.is_int or type2.is_enum):
|
|
return type1
|
|
elif (type2.is_ptr or type2.is_array) and (type1.is_int or type1.is_enum):
|
|
return type2
|
|
else:
|
|
return NumBinopNode.compute_c_result_type(
|
|
self, type1, type2)
|
|
|
|
def py_operation_function(self, code):
|
|
type1, type2 = self.operand1.type, self.operand2.type
|
|
|
|
if type1 is unicode_type or type2 is unicode_type:
|
|
if type1 in (unicode_type, str_type) and type2 in (unicode_type, str_type):
|
|
is_unicode_concat = True
|
|
elif isinstance(self.operand1, FormattedValueNode) or isinstance(self.operand2, FormattedValueNode):
|
|
# Assume that even if we don't know the second type, it's going to be a string.
|
|
is_unicode_concat = True
|
|
else:
|
|
# Operation depends on the second type.
|
|
is_unicode_concat = False
|
|
|
|
if is_unicode_concat:
|
|
if self.operand1.may_be_none() or self.operand2.may_be_none():
|
|
return '__Pyx_PyUnicode_ConcatSafe'
|
|
else:
|
|
return '__Pyx_PyUnicode_Concat'
|
|
|
|
return super(AddNode, self).py_operation_function(code)
|
|
|
|
|
|
class SubNode(NumBinopNode):
|
|
# '-' operator.
|
|
|
|
def compute_c_result_type(self, type1, type2):
|
|
if (type1.is_ptr or type1.is_array) and (type2.is_int or type2.is_enum):
|
|
return type1
|
|
elif (type1.is_ptr or type1.is_array) and (type2.is_ptr or type2.is_array):
|
|
return PyrexTypes.c_ptrdiff_t_type
|
|
else:
|
|
return NumBinopNode.compute_c_result_type(
|
|
self, type1, type2)
|
|
|
|
|
|
class MulNode(NumBinopNode):
|
|
# '*' operator.
|
|
|
|
def is_py_operation_types(self, type1, type2):
|
|
if ((type1.is_string and type2.is_int) or
|
|
(type2.is_string and type1.is_int)):
|
|
return 1
|
|
else:
|
|
return NumBinopNode.is_py_operation_types(self, type1, type2)
|
|
|
|
def infer_builtin_types_operation(self, type1, type2):
|
|
# let's assume that whatever builtin type you multiply a string with
|
|
# will either return a string of the same type or fail with an exception
|
|
string_types = (bytes_type, bytearray_type, str_type, basestring_type, unicode_type)
|
|
if type1 in string_types and type2.is_builtin_type:
|
|
return type1
|
|
if type2 in string_types and type1.is_builtin_type:
|
|
return type2
|
|
# multiplication of containers/numbers with an integer value
|
|
# always (?) returns the same type
|
|
if type1.is_int:
|
|
return type2
|
|
if type2.is_int:
|
|
return type1
|
|
return None
|
|
|
|
|
|
class MatMultNode(NumBinopNode):
|
|
# '@' operator.
|
|
|
|
def is_py_operation_types(self, type1, type2):
|
|
return True
|
|
|
|
def generate_evaluation_code(self, code):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("MatrixMultiply", "ObjectHandling.c"))
|
|
super(MatMultNode, self).generate_evaluation_code(code)
|
|
|
|
|
|
class DivNode(NumBinopNode):
|
|
# '/' or '//' operator.
|
|
|
|
cdivision = None
|
|
truedivision = None # == "unknown" if operator == '/'
|
|
ctruedivision = False
|
|
cdivision_warnings = False
|
|
zerodivision_check = None
|
|
|
|
def find_compile_time_binary_operator(self, op1, op2):
|
|
func = compile_time_binary_operators[self.operator]
|
|
if self.operator == '/' and self.truedivision is None:
|
|
# => true div for floats, floor div for integers
|
|
if isinstance(op1, _py_int_types) and isinstance(op2, _py_int_types):
|
|
func = compile_time_binary_operators['//']
|
|
return func
|
|
|
|
def calculate_constant_result(self):
|
|
op1 = self.operand1.constant_result
|
|
op2 = self.operand2.constant_result
|
|
func = self.find_compile_time_binary_operator(op1, op2)
|
|
self.constant_result = func(
|
|
self.operand1.constant_result,
|
|
self.operand2.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
operand1 = self.operand1.compile_time_value(denv)
|
|
operand2 = self.operand2.compile_time_value(denv)
|
|
try:
|
|
func = self.find_compile_time_binary_operator(
|
|
operand1, operand2)
|
|
return func(operand1, operand2)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
|
|
def _check_truedivision(self, env):
|
|
if self.cdivision or env.directives['cdivision']:
|
|
self.ctruedivision = False
|
|
else:
|
|
self.ctruedivision = self.truedivision
|
|
|
|
def infer_type(self, env):
|
|
self._check_truedivision(env)
|
|
return self.result_type(
|
|
self.operand1.infer_type(env),
|
|
self.operand2.infer_type(env), env)
|
|
|
|
def analyse_operation(self, env):
|
|
self._check_truedivision(env)
|
|
NumBinopNode.analyse_operation(self, env)
|
|
if self.is_cpp_operation():
|
|
self.cdivision = True
|
|
if not self.type.is_pyobject:
|
|
self.zerodivision_check = (
|
|
self.cdivision is None and not env.directives['cdivision']
|
|
and (not self.operand2.has_constant_result() or
|
|
self.operand2.constant_result == 0))
|
|
if self.zerodivision_check or env.directives['cdivision_warnings']:
|
|
# Need to check ahead of time to warn or raise zero division error
|
|
self.operand1 = self.operand1.coerce_to_simple(env)
|
|
self.operand2 = self.operand2.coerce_to_simple(env)
|
|
|
|
def compute_c_result_type(self, type1, type2):
|
|
if self.operator == '/' and self.ctruedivision and not type1.is_cpp_class and not type2.is_cpp_class:
|
|
if not type1.is_float and not type2.is_float:
|
|
widest_type = PyrexTypes.widest_numeric_type(type1, PyrexTypes.c_double_type)
|
|
widest_type = PyrexTypes.widest_numeric_type(type2, widest_type)
|
|
return widest_type
|
|
return NumBinopNode.compute_c_result_type(self, type1, type2)
|
|
|
|
def zero_division_message(self):
|
|
if self.type.is_int:
|
|
return "integer division or modulo by zero"
|
|
else:
|
|
return "float division"
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if not self.type.is_pyobject and not self.type.is_complex:
|
|
if self.cdivision is None:
|
|
self.cdivision = (
|
|
code.globalstate.directives['cdivision']
|
|
or self.type.is_float
|
|
or ((self.type.is_numeric or self.type.is_enum) and not self.type.signed)
|
|
)
|
|
if not self.cdivision:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("DivInt", "CMath.c").specialize(self.type))
|
|
NumBinopNode.generate_evaluation_code(self, code)
|
|
self.generate_div_warning_code(code)
|
|
|
|
def generate_div_warning_code(self, code):
|
|
in_nogil = self.in_nogil_context
|
|
if not self.type.is_pyobject:
|
|
if self.zerodivision_check:
|
|
if not self.infix:
|
|
zero_test = "%s(%s)" % (self.type.unary_op('zero'), self.operand2.result())
|
|
else:
|
|
zero_test = "%s == 0" % self.operand2.result()
|
|
code.putln("if (unlikely(%s)) {" % zero_test)
|
|
if in_nogil:
|
|
code.put_ensure_gil()
|
|
code.putln('PyErr_SetString(PyExc_ZeroDivisionError, "%s");' % self.zero_division_message())
|
|
if in_nogil:
|
|
code.put_release_ensured_gil()
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
if self.type.is_int and self.type.signed and self.operator != '%':
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached("UnaryNegOverflows", "Overflow.c"))
|
|
if self.operand2.type.signed == 2:
|
|
# explicitly signed, no runtime check needed
|
|
minus1_check = 'unlikely(%s == -1)' % self.operand2.result()
|
|
else:
|
|
type_of_op2 = self.operand2.type.empty_declaration_code()
|
|
minus1_check = '(!(((%s)-1) > 0)) && unlikely(%s == (%s)-1)' % (
|
|
type_of_op2, self.operand2.result(), type_of_op2)
|
|
code.putln("else if (sizeof(%s) == sizeof(long) && %s "
|
|
" && unlikely(UNARY_NEG_WOULD_OVERFLOW(%s))) {" % (
|
|
self.type.empty_declaration_code(),
|
|
minus1_check,
|
|
self.operand1.result()))
|
|
if in_nogil:
|
|
code.put_ensure_gil()
|
|
code.putln('PyErr_SetString(PyExc_OverflowError, "value too large to perform division");')
|
|
if in_nogil:
|
|
code.put_release_ensured_gil()
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
if code.globalstate.directives['cdivision_warnings'] and self.operator != '/':
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("CDivisionWarning", "CMath.c"))
|
|
code.putln("if (unlikely((%s < 0) ^ (%s < 0))) {" % (
|
|
self.operand1.result(),
|
|
self.operand2.result()))
|
|
warning_code = "__Pyx_cdivision_warning(%(FILENAME)s, %(LINENO)s)" % {
|
|
'FILENAME': Naming.filename_cname,
|
|
'LINENO': Naming.lineno_cname,
|
|
}
|
|
|
|
if in_nogil:
|
|
result_code = 'result'
|
|
code.putln("int %s;" % result_code)
|
|
code.put_ensure_gil()
|
|
code.putln(code.set_error_info(self.pos, used=True))
|
|
code.putln("%s = %s;" % (result_code, warning_code))
|
|
code.put_release_ensured_gil()
|
|
else:
|
|
result_code = warning_code
|
|
code.putln(code.set_error_info(self.pos, used=True))
|
|
|
|
code.put("if (unlikely(%s)) " % result_code)
|
|
code.put_goto(code.error_label)
|
|
code.putln("}")
|
|
|
|
def calculate_result_code(self):
|
|
if self.type.is_complex or self.is_cpp_operation():
|
|
return NumBinopNode.calculate_result_code(self)
|
|
elif self.type.is_float and self.operator == '//':
|
|
return "floor(%s / %s)" % (
|
|
self.operand1.result(),
|
|
self.operand2.result())
|
|
elif self.truedivision or self.cdivision:
|
|
op1 = self.operand1.result()
|
|
op2 = self.operand2.result()
|
|
if self.truedivision:
|
|
if self.type != self.operand1.type:
|
|
op1 = self.type.cast_code(op1)
|
|
if self.type != self.operand2.type:
|
|
op2 = self.type.cast_code(op2)
|
|
return "(%s / %s)" % (op1, op2)
|
|
else:
|
|
return "__Pyx_div_%s(%s, %s)" % (
|
|
self.type.specialization_name(),
|
|
self.operand1.result(),
|
|
self.operand2.result())
|
|
|
|
|
|
_find_formatting_types = re.compile(
|
|
br"%"
|
|
br"(?:%|" # %%
|
|
br"(?:\([^)]+\))?" # %(name)
|
|
br"[-+#,0-9 ]*([a-z])" # %.2f etc.
|
|
br")").findall
|
|
|
|
# These format conversion types can never trigger a Unicode string conversion in Py2.
|
|
_safe_bytes_formats = set([
|
|
# Excludes 's' and 'r', which can generate non-bytes strings.
|
|
b'd', b'i', b'o', b'u', b'x', b'X', b'e', b'E', b'f', b'F', b'g', b'G', b'c', b'b', b'a',
|
|
])
|
|
|
|
|
|
class ModNode(DivNode):
|
|
# '%' operator.
|
|
|
|
def is_py_operation_types(self, type1, type2):
|
|
return (type1.is_string
|
|
or type2.is_string
|
|
or NumBinopNode.is_py_operation_types(self, type1, type2))
|
|
|
|
def infer_builtin_types_operation(self, type1, type2):
|
|
# b'%s' % xyz raises an exception in Py3<3.5, so it's safe to infer the type for Py2 and later Py3's.
|
|
if type1 is unicode_type:
|
|
# None + xyz may be implemented by RHS
|
|
if type2.is_builtin_type or not self.operand1.may_be_none():
|
|
return type1
|
|
elif type1 in (bytes_type, str_type, basestring_type):
|
|
if type2 is unicode_type:
|
|
return type2
|
|
elif type2.is_numeric:
|
|
return type1
|
|
elif self.operand1.is_string_literal:
|
|
if type1 is str_type or type1 is bytes_type:
|
|
if set(_find_formatting_types(self.operand1.value)) <= _safe_bytes_formats:
|
|
return type1
|
|
return basestring_type
|
|
elif type1 is bytes_type and not type2.is_builtin_type:
|
|
return None # RHS might implement '% operator differently in Py3
|
|
else:
|
|
return basestring_type # either str or unicode, can't tell
|
|
return None
|
|
|
|
def zero_division_message(self):
|
|
if self.type.is_int:
|
|
return "integer division or modulo by zero"
|
|
else:
|
|
return "float divmod()"
|
|
|
|
def analyse_operation(self, env):
|
|
DivNode.analyse_operation(self, env)
|
|
if not self.type.is_pyobject:
|
|
if self.cdivision is None:
|
|
self.cdivision = env.directives['cdivision'] or not self.type.signed
|
|
if not self.cdivision and not self.type.is_int and not self.type.is_float:
|
|
error(self.pos, "mod operator not supported for type '%s'" % self.type)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
if not self.type.is_pyobject and not self.cdivision:
|
|
if self.type.is_int:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("ModInt", "CMath.c").specialize(self.type))
|
|
else: # float
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("ModFloat", "CMath.c").specialize(
|
|
self.type, math_h_modifier=self.type.math_h_modifier))
|
|
# NOTE: skipping over DivNode here
|
|
NumBinopNode.generate_evaluation_code(self, code)
|
|
self.generate_div_warning_code(code)
|
|
|
|
def calculate_result_code(self):
|
|
if self.cdivision:
|
|
if self.type.is_float:
|
|
return "fmod%s(%s, %s)" % (
|
|
self.type.math_h_modifier,
|
|
self.operand1.result(),
|
|
self.operand2.result())
|
|
else:
|
|
return "(%s %% %s)" % (
|
|
self.operand1.result(),
|
|
self.operand2.result())
|
|
else:
|
|
return "__Pyx_mod_%s(%s, %s)" % (
|
|
self.type.specialization_name(),
|
|
self.operand1.result(),
|
|
self.operand2.result())
|
|
|
|
def py_operation_function(self, code):
|
|
type1, type2 = self.operand1.type, self.operand2.type
|
|
# ("..." % x) must call "x.__rmod__()" for string subtypes.
|
|
if type1 is unicode_type:
|
|
if self.operand1.may_be_none() or (
|
|
type2.is_extension_type and type2.subtype_of(type1) or
|
|
type2 is py_object_type and not isinstance(self.operand2, CoerceToPyTypeNode)):
|
|
return '__Pyx_PyUnicode_FormatSafe'
|
|
else:
|
|
return 'PyUnicode_Format'
|
|
elif type1 is str_type:
|
|
if self.operand1.may_be_none() or (
|
|
type2.is_extension_type and type2.subtype_of(type1) or
|
|
type2 is py_object_type and not isinstance(self.operand2, CoerceToPyTypeNode)):
|
|
return '__Pyx_PyString_FormatSafe'
|
|
else:
|
|
return '__Pyx_PyString_Format'
|
|
return super(ModNode, self).py_operation_function(code)
|
|
|
|
|
|
class PowNode(NumBinopNode):
|
|
# '**' operator.
|
|
|
|
def analyse_c_operation(self, env):
|
|
NumBinopNode.analyse_c_operation(self, env)
|
|
if self.type.is_complex:
|
|
if self.type.real_type.is_float:
|
|
self.operand1 = self.operand1.coerce_to(self.type, env)
|
|
self.operand2 = self.operand2.coerce_to(self.type, env)
|
|
self.pow_func = self.type.binary_op('**')
|
|
else:
|
|
error(self.pos, "complex int powers not supported")
|
|
self.pow_func = "<error>"
|
|
elif self.type.is_float:
|
|
self.pow_func = "pow" + self.type.math_h_modifier
|
|
elif self.type.is_int:
|
|
self.pow_func = "__Pyx_pow_%s" % self.type.empty_declaration_code().replace(' ', '_')
|
|
env.use_utility_code(
|
|
UtilityCode.load_cached("IntPow", "CMath.c").specialize(
|
|
func_name=self.pow_func,
|
|
type=self.type.empty_declaration_code(),
|
|
signed=self.type.signed and 1 or 0))
|
|
elif not self.type.is_error:
|
|
error(self.pos, "got unexpected types for C power operator: %s, %s" %
|
|
(self.operand1.type, self.operand2.type))
|
|
|
|
def calculate_result_code(self):
|
|
# Work around MSVC overloading ambiguity.
|
|
def typecast(operand):
|
|
if self.type == operand.type:
|
|
return operand.result()
|
|
else:
|
|
return self.type.cast_code(operand.result())
|
|
return "%s(%s, %s)" % (
|
|
self.pow_func,
|
|
typecast(self.operand1),
|
|
typecast(self.operand2))
|
|
|
|
def py_operation_function(self, code):
|
|
if (self.type.is_pyobject and
|
|
self.operand1.constant_result == 2 and
|
|
isinstance(self.operand1.constant_result, _py_int_types) and
|
|
self.operand2.type is py_object_type):
|
|
code.globalstate.use_utility_code(UtilityCode.load_cached('PyNumberPow2', 'Optimize.c'))
|
|
if self.inplace:
|
|
return '__Pyx_PyNumber_InPlacePowerOf2'
|
|
else:
|
|
return '__Pyx_PyNumber_PowerOf2'
|
|
return super(PowNode, self).py_operation_function(code)
|
|
|
|
|
|
class BoolBinopNode(ExprNode):
|
|
"""
|
|
Short-circuiting boolean operation.
|
|
|
|
Note that this node provides the same code generation method as
|
|
BoolBinopResultNode to simplify expression nesting.
|
|
|
|
operator string "and"/"or"
|
|
operand1 BoolBinopNode/BoolBinopResultNode left operand
|
|
operand2 BoolBinopNode/BoolBinopResultNode right operand
|
|
"""
|
|
subexprs = ['operand1', 'operand2']
|
|
is_temp = True
|
|
operator = None
|
|
operand1 = None
|
|
operand2 = None
|
|
|
|
def infer_type(self, env):
|
|
type1 = self.operand1.infer_type(env)
|
|
type2 = self.operand2.infer_type(env)
|
|
return PyrexTypes.independent_spanning_type(type1, type2)
|
|
|
|
def may_be_none(self):
|
|
if self.operator == 'or':
|
|
return self.operand2.may_be_none()
|
|
else:
|
|
return self.operand1.may_be_none() or self.operand2.may_be_none()
|
|
|
|
def calculate_constant_result(self):
|
|
operand1 = self.operand1.constant_result
|
|
operand2 = self.operand2.constant_result
|
|
if self.operator == 'and':
|
|
self.constant_result = operand1 and operand2
|
|
else:
|
|
self.constant_result = operand1 or operand2
|
|
|
|
def compile_time_value(self, denv):
|
|
operand1 = self.operand1.compile_time_value(denv)
|
|
operand2 = self.operand2.compile_time_value(denv)
|
|
if self.operator == 'and':
|
|
return operand1 and operand2
|
|
else:
|
|
return operand1 or operand2
|
|
|
|
def is_ephemeral(self):
|
|
return self.operand1.is_ephemeral() or self.operand2.is_ephemeral()
|
|
|
|
def analyse_types(self, env):
|
|
# Note: we do not do any coercion here as we most likely do not know the final type anyway.
|
|
# We even accept to set self.type to ErrorType if both operands do not have a spanning type.
|
|
# The coercion to the final type and to a "simple" value is left to coerce_to().
|
|
operand1 = self.operand1.analyse_types(env)
|
|
operand2 = self.operand2.analyse_types(env)
|
|
self.type = PyrexTypes.independent_spanning_type(
|
|
operand1.type, operand2.type)
|
|
self.operand1 = self._wrap_operand(operand1, env)
|
|
self.operand2 = self._wrap_operand(operand2, env)
|
|
return self
|
|
|
|
def _wrap_operand(self, operand, env):
|
|
if not isinstance(operand, (BoolBinopNode, BoolBinopResultNode)):
|
|
operand = BoolBinopResultNode(operand, self.type, env)
|
|
return operand
|
|
|
|
def wrap_operands(self, env):
|
|
"""
|
|
Must get called by transforms that want to create a correct BoolBinopNode
|
|
after the type analysis phase.
|
|
"""
|
|
self.operand1 = self._wrap_operand(self.operand1, env)
|
|
self.operand2 = self._wrap_operand(self.operand2, env)
|
|
|
|
def coerce_to_boolean(self, env):
|
|
return self.coerce_to(PyrexTypes.c_bint_type, env)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
operand1 = self.operand1.coerce_to(dst_type, env)
|
|
operand2 = self.operand2.coerce_to(dst_type, env)
|
|
return BoolBinopNode.from_node(
|
|
self, type=dst_type,
|
|
operator=self.operator,
|
|
operand1=operand1, operand2=operand2)
|
|
|
|
def generate_bool_evaluation_code(self, code, final_result_temp, final_result_type, and_label, or_label, end_label, fall_through):
|
|
code.mark_pos(self.pos)
|
|
|
|
outer_labels = (and_label, or_label)
|
|
if self.operator == 'and':
|
|
my_label = and_label = code.new_label('next_and')
|
|
else:
|
|
my_label = or_label = code.new_label('next_or')
|
|
self.operand1.generate_bool_evaluation_code(
|
|
code, final_result_temp, final_result_type, and_label, or_label, end_label, my_label)
|
|
|
|
and_label, or_label = outer_labels
|
|
|
|
code.put_label(my_label)
|
|
self.operand2.generate_bool_evaluation_code(
|
|
code, final_result_temp, final_result_type, and_label, or_label, end_label, fall_through)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
self.allocate_temp_result(code)
|
|
result_type = PyrexTypes.py_object_type if self.type.is_pyobject else self.type
|
|
or_label = and_label = None
|
|
end_label = code.new_label('bool_binop_done')
|
|
self.generate_bool_evaluation_code(code, self.result(), result_type, and_label, or_label, end_label, end_label)
|
|
code.put_label(end_label)
|
|
|
|
gil_message = "Truth-testing Python object"
|
|
|
|
def check_const(self):
|
|
return self.operand1.check_const() and self.operand2.check_const()
|
|
|
|
def generate_subexpr_disposal_code(self, code):
|
|
pass # nothing to do here, all done in generate_evaluation_code()
|
|
|
|
def free_subexpr_temps(self, code):
|
|
pass # nothing to do here, all done in generate_evaluation_code()
|
|
|
|
def generate_operand1_test(self, code):
|
|
# Generate code to test the truth of the first operand.
|
|
if self.type.is_pyobject:
|
|
test_result = code.funcstate.allocate_temp(
|
|
PyrexTypes.c_bint_type, manage_ref=False)
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_IsTrue(%s); %s" % (
|
|
test_result,
|
|
self.operand1.py_result(),
|
|
code.error_goto_if_neg(test_result, self.pos)))
|
|
else:
|
|
test_result = self.operand1.result()
|
|
return (test_result, self.type.is_pyobject)
|
|
|
|
|
|
class BoolBinopResultNode(ExprNode):
|
|
"""
|
|
Intermediate result of a short-circuiting and/or expression.
|
|
Tests the result for 'truthiness' and takes care of coercing the final result
|
|
of the overall expression to the target type.
|
|
|
|
Note that this node provides the same code generation method as
|
|
BoolBinopNode to simplify expression nesting.
|
|
|
|
arg ExprNode the argument to test
|
|
value ExprNode the coerced result value node
|
|
"""
|
|
|
|
subexprs = ['arg', 'value']
|
|
is_temp = True
|
|
arg = None
|
|
value = None
|
|
|
|
def __init__(self, arg, result_type, env):
|
|
# using 'arg' multiple times, so it must be a simple/temp value
|
|
arg = arg.coerce_to_simple(env)
|
|
# wrap in ProxyNode, in case a transform wants to replace self.arg later
|
|
arg = ProxyNode(arg)
|
|
super(BoolBinopResultNode, self).__init__(
|
|
arg.pos, arg=arg, type=result_type,
|
|
value=CloneNode(arg).coerce_to(result_type, env))
|
|
|
|
def coerce_to_boolean(self, env):
|
|
return self.coerce_to(PyrexTypes.c_bint_type, env)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
# unwrap, coerce, rewrap
|
|
arg = self.arg.arg
|
|
if dst_type is PyrexTypes.c_bint_type:
|
|
arg = arg.coerce_to_boolean(env)
|
|
# TODO: unwrap more coercion nodes?
|
|
return BoolBinopResultNode(arg, dst_type, env)
|
|
|
|
def nogil_check(self, env):
|
|
# let's leave all errors to BoolBinopNode
|
|
pass
|
|
|
|
def generate_operand_test(self, code):
|
|
# Generate code to test the truth of the first operand.
|
|
if self.arg.type.is_pyobject:
|
|
test_result = code.funcstate.allocate_temp(
|
|
PyrexTypes.c_bint_type, manage_ref=False)
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_IsTrue(%s); %s" % (
|
|
test_result,
|
|
self.arg.py_result(),
|
|
code.error_goto_if_neg(test_result, self.pos)))
|
|
else:
|
|
test_result = self.arg.result()
|
|
return (test_result, self.arg.type.is_pyobject)
|
|
|
|
def generate_bool_evaluation_code(self, code, final_result_temp, final_result_type, and_label, or_label, end_label, fall_through):
|
|
code.mark_pos(self.pos)
|
|
|
|
# x => x
|
|
# x and ... or ... => next 'and' / 'or'
|
|
# False ... or x => next 'or'
|
|
# True and x => next 'and'
|
|
# True or x => True (operand)
|
|
|
|
self.arg.generate_evaluation_code(code)
|
|
if and_label or or_label:
|
|
test_result, uses_temp = self.generate_operand_test(code)
|
|
if uses_temp and (and_label and or_label):
|
|
# cannot become final result => free early
|
|
# disposal: uses_temp and (and_label and or_label)
|
|
self.arg.generate_disposal_code(code)
|
|
sense = '!' if or_label else ''
|
|
code.putln("if (%s%s) {" % (sense, test_result))
|
|
if uses_temp:
|
|
code.funcstate.release_temp(test_result)
|
|
if not uses_temp or not (and_label and or_label):
|
|
# disposal: (not uses_temp) or {not (and_label and or_label) [if]}
|
|
self.arg.generate_disposal_code(code)
|
|
|
|
if or_label and or_label != fall_through:
|
|
# value is false => short-circuit to next 'or'
|
|
code.put_goto(or_label)
|
|
if and_label:
|
|
# value is true => go to next 'and'
|
|
if or_label:
|
|
code.putln("} else {")
|
|
if not uses_temp:
|
|
# disposal: (not uses_temp) and {(and_label and or_label) [else]}
|
|
self.arg.generate_disposal_code(code)
|
|
if and_label != fall_through:
|
|
code.put_goto(and_label)
|
|
|
|
if not and_label or not or_label:
|
|
# if no next 'and' or 'or', we provide the result
|
|
if and_label or or_label:
|
|
code.putln("} else {")
|
|
self.value.generate_evaluation_code(code)
|
|
self.value.make_owned_reference(code)
|
|
code.putln("%s = %s;" % (final_result_temp, self.value.result_as(final_result_type)))
|
|
self.value.generate_post_assignment_code(code)
|
|
# disposal: {not (and_label and or_label) [else]}
|
|
self.arg.generate_disposal_code(code)
|
|
self.value.free_temps(code)
|
|
if end_label != fall_through:
|
|
code.put_goto(end_label)
|
|
|
|
if and_label or or_label:
|
|
code.putln("}")
|
|
self.arg.free_temps(code)
|
|
|
|
|
|
class CondExprNode(ExprNode):
|
|
# Short-circuiting conditional expression.
|
|
#
|
|
# test ExprNode
|
|
# true_val ExprNode
|
|
# false_val ExprNode
|
|
|
|
true_val = None
|
|
false_val = None
|
|
is_temp = True
|
|
|
|
subexprs = ['test', 'true_val', 'false_val']
|
|
|
|
def type_dependencies(self, env):
|
|
return self.true_val.type_dependencies(env) + self.false_val.type_dependencies(env)
|
|
|
|
def infer_type(self, env):
|
|
return PyrexTypes.independent_spanning_type(
|
|
self.true_val.infer_type(env),
|
|
self.false_val.infer_type(env))
|
|
|
|
def calculate_constant_result(self):
|
|
if self.test.constant_result:
|
|
self.constant_result = self.true_val.constant_result
|
|
else:
|
|
self.constant_result = self.false_val.constant_result
|
|
|
|
def is_ephemeral(self):
|
|
return self.true_val.is_ephemeral() or self.false_val.is_ephemeral()
|
|
|
|
def analyse_types(self, env):
|
|
self.test = self.test.analyse_types(env).coerce_to_boolean(env)
|
|
self.true_val = self.true_val.analyse_types(env)
|
|
self.false_val = self.false_val.analyse_types(env)
|
|
return self.analyse_result_type(env)
|
|
|
|
def analyse_result_type(self, env):
|
|
self.type = PyrexTypes.independent_spanning_type(
|
|
self.true_val.type, self.false_val.type)
|
|
if self.type.is_reference:
|
|
self.type = PyrexTypes.CFakeReferenceType(self.type.ref_base_type)
|
|
if self.type.is_pyobject:
|
|
self.result_ctype = py_object_type
|
|
elif self.true_val.is_ephemeral() or self.false_val.is_ephemeral():
|
|
error(self.pos, "Unsafe C derivative of temporary Python reference used in conditional expression")
|
|
if self.true_val.type.is_pyobject or self.false_val.type.is_pyobject:
|
|
self.true_val = self.true_val.coerce_to(self.type, env)
|
|
self.false_val = self.false_val.coerce_to(self.type, env)
|
|
if self.type.is_error:
|
|
self.type_error()
|
|
return self
|
|
|
|
def coerce_to_integer(self, env):
|
|
self.true_val = self.true_val.coerce_to_integer(env)
|
|
self.false_val = self.false_val.coerce_to_integer(env)
|
|
self.result_ctype = None
|
|
return self.analyse_result_type(env)
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
self.true_val = self.true_val.coerce_to(dst_type, env)
|
|
self.false_val = self.false_val.coerce_to(dst_type, env)
|
|
self.result_ctype = None
|
|
return self.analyse_result_type(env)
|
|
|
|
def type_error(self):
|
|
if not (self.true_val.type.is_error or self.false_val.type.is_error):
|
|
error(self.pos, "Incompatible types in conditional expression (%s; %s)" %
|
|
(self.true_val.type, self.false_val.type))
|
|
self.type = PyrexTypes.error_type
|
|
|
|
def check_const(self):
|
|
return (self.test.check_const()
|
|
and self.true_val.check_const()
|
|
and self.false_val.check_const())
|
|
|
|
def generate_evaluation_code(self, code):
|
|
# Because subexprs may not be evaluated we can use a more optimal
|
|
# subexpr allocation strategy than the default, so override evaluation_code.
|
|
|
|
code.mark_pos(self.pos)
|
|
self.allocate_temp_result(code)
|
|
self.test.generate_evaluation_code(code)
|
|
code.putln("if (%s) {" % self.test.result())
|
|
self.eval_and_get(code, self.true_val)
|
|
code.putln("} else {")
|
|
self.eval_and_get(code, self.false_val)
|
|
code.putln("}")
|
|
self.test.generate_disposal_code(code)
|
|
self.test.free_temps(code)
|
|
|
|
def eval_and_get(self, code, expr):
|
|
expr.generate_evaluation_code(code)
|
|
if self.type.is_memoryviewslice:
|
|
expr.make_owned_memoryviewslice(code)
|
|
else:
|
|
expr.make_owned_reference(code)
|
|
code.putln('%s = %s;' % (self.result(), expr.result_as(self.ctype())))
|
|
expr.generate_post_assignment_code(code)
|
|
expr.free_temps(code)
|
|
|
|
def generate_subexpr_disposal_code(self, code):
|
|
pass # done explicitly above (cleanup must separately happen within the if/else blocks)
|
|
|
|
def free_subexpr_temps(self, code):
|
|
pass # done explicitly above (cleanup must separately happen within the if/else blocks)
|
|
|
|
|
|
richcmp_constants = {
|
|
"<" : "Py_LT",
|
|
"<=": "Py_LE",
|
|
"==": "Py_EQ",
|
|
"!=": "Py_NE",
|
|
"<>": "Py_NE",
|
|
">" : "Py_GT",
|
|
">=": "Py_GE",
|
|
# the following are faked by special compare functions
|
|
"in" : "Py_EQ",
|
|
"not_in": "Py_NE",
|
|
}
|
|
|
|
class CmpNode(object):
|
|
# Mixin class containing code common to PrimaryCmpNodes
|
|
# and CascadedCmpNodes.
|
|
|
|
special_bool_cmp_function = None
|
|
special_bool_cmp_utility_code = None
|
|
|
|
def infer_type(self, env):
|
|
# TODO: Actually implement this (after merging with -unstable).
|
|
return py_object_type
|
|
|
|
def calculate_cascaded_constant_result(self, operand1_result):
|
|
func = compile_time_binary_operators[self.operator]
|
|
operand2_result = self.operand2.constant_result
|
|
if (isinstance(operand1_result, any_string_type) and
|
|
isinstance(operand2_result, any_string_type) and
|
|
type(operand1_result) != type(operand2_result)):
|
|
# string comparison of different types isn't portable
|
|
return
|
|
|
|
if self.operator in ('in', 'not_in'):
|
|
if isinstance(self.operand2, (ListNode, TupleNode, SetNode)):
|
|
if not self.operand2.args:
|
|
self.constant_result = self.operator == 'not_in'
|
|
return
|
|
elif isinstance(self.operand2, ListNode) and not self.cascade:
|
|
# tuples are more efficient to store than lists
|
|
self.operand2 = self.operand2.as_tuple()
|
|
elif isinstance(self.operand2, DictNode):
|
|
if not self.operand2.key_value_pairs:
|
|
self.constant_result = self.operator == 'not_in'
|
|
return
|
|
|
|
self.constant_result = func(operand1_result, operand2_result)
|
|
|
|
def cascaded_compile_time_value(self, operand1, denv):
|
|
func = get_compile_time_binop(self)
|
|
operand2 = self.operand2.compile_time_value(denv)
|
|
try:
|
|
result = func(operand1, operand2)
|
|
except Exception as e:
|
|
self.compile_time_value_error(e)
|
|
result = None
|
|
if result:
|
|
cascade = self.cascade
|
|
if cascade:
|
|
result = result and cascade.cascaded_compile_time_value(operand2, denv)
|
|
return result
|
|
|
|
def is_cpp_comparison(self):
|
|
return self.operand1.type.is_cpp_class or self.operand2.type.is_cpp_class
|
|
|
|
def find_common_int_type(self, env, op, operand1, operand2):
|
|
# type1 != type2 and at least one of the types is not a C int
|
|
type1 = operand1.type
|
|
type2 = operand2.type
|
|
type1_can_be_int = False
|
|
type2_can_be_int = False
|
|
|
|
if operand1.is_string_literal and operand1.can_coerce_to_char_literal():
|
|
type1_can_be_int = True
|
|
if operand2.is_string_literal and operand2.can_coerce_to_char_literal():
|
|
type2_can_be_int = True
|
|
|
|
if type1.is_int:
|
|
if type2_can_be_int:
|
|
return type1
|
|
elif type2.is_int:
|
|
if type1_can_be_int:
|
|
return type2
|
|
elif type1_can_be_int:
|
|
if type2_can_be_int:
|
|
if Builtin.unicode_type in (type1, type2):
|
|
return PyrexTypes.c_py_ucs4_type
|
|
else:
|
|
return PyrexTypes.c_uchar_type
|
|
|
|
return None
|
|
|
|
def find_common_type(self, env, op, operand1, common_type=None):
|
|
operand2 = self.operand2
|
|
type1 = operand1.type
|
|
type2 = operand2.type
|
|
|
|
new_common_type = None
|
|
|
|
# catch general errors
|
|
if (type1 == str_type and (type2.is_string or type2 in (bytes_type, unicode_type)) or
|
|
type2 == str_type and (type1.is_string or type1 in (bytes_type, unicode_type))):
|
|
error(self.pos, "Comparisons between bytes/unicode and str are not portable to Python 3")
|
|
new_common_type = error_type
|
|
|
|
# try to use numeric comparisons where possible
|
|
elif type1.is_complex or type2.is_complex:
|
|
if (op not in ('==', '!=')
|
|
and (type1.is_complex or type1.is_numeric)
|
|
and (type2.is_complex or type2.is_numeric)):
|
|
error(self.pos, "complex types are unordered")
|
|
new_common_type = error_type
|
|
elif type1.is_pyobject:
|
|
new_common_type = Builtin.complex_type if type1.subtype_of(Builtin.complex_type) else py_object_type
|
|
elif type2.is_pyobject:
|
|
new_common_type = Builtin.complex_type if type2.subtype_of(Builtin.complex_type) else py_object_type
|
|
else:
|
|
new_common_type = PyrexTypes.widest_numeric_type(type1, type2)
|
|
elif type1.is_numeric and type2.is_numeric:
|
|
new_common_type = PyrexTypes.widest_numeric_type(type1, type2)
|
|
elif common_type is None or not common_type.is_pyobject:
|
|
new_common_type = self.find_common_int_type(env, op, operand1, operand2)
|
|
|
|
if new_common_type is None:
|
|
# fall back to generic type compatibility tests
|
|
if type1.is_ctuple or type2.is_ctuple:
|
|
new_common_type = py_object_type
|
|
elif type1 == type2:
|
|
new_common_type = type1
|
|
elif type1.is_pyobject or type2.is_pyobject:
|
|
if type2.is_numeric or type2.is_string:
|
|
if operand2.check_for_coercion_error(type1, env):
|
|
new_common_type = error_type
|
|
else:
|
|
new_common_type = py_object_type
|
|
elif type1.is_numeric or type1.is_string:
|
|
if operand1.check_for_coercion_error(type2, env):
|
|
new_common_type = error_type
|
|
else:
|
|
new_common_type = py_object_type
|
|
elif py_object_type.assignable_from(type1) and py_object_type.assignable_from(type2):
|
|
new_common_type = py_object_type
|
|
else:
|
|
# one Python type and one non-Python type, not assignable
|
|
self.invalid_types_error(operand1, op, operand2)
|
|
new_common_type = error_type
|
|
elif type1.assignable_from(type2):
|
|
new_common_type = type1
|
|
elif type2.assignable_from(type1):
|
|
new_common_type = type2
|
|
else:
|
|
# C types that we couldn't handle up to here are an error
|
|
self.invalid_types_error(operand1, op, operand2)
|
|
new_common_type = error_type
|
|
|
|
if new_common_type.is_string and (isinstance(operand1, BytesNode) or
|
|
isinstance(operand2, BytesNode)):
|
|
# special case when comparing char* to bytes literal: must
|
|
# compare string values!
|
|
new_common_type = bytes_type
|
|
|
|
# recursively merge types
|
|
if common_type is None or new_common_type.is_error:
|
|
common_type = new_common_type
|
|
else:
|
|
# we could do a lot better by splitting the comparison
|
|
# into a non-Python part and a Python part, but this is
|
|
# safer for now
|
|
common_type = PyrexTypes.spanning_type(common_type, new_common_type)
|
|
|
|
if self.cascade:
|
|
common_type = self.cascade.find_common_type(env, self.operator, operand2, common_type)
|
|
|
|
return common_type
|
|
|
|
def invalid_types_error(self, operand1, op, operand2):
|
|
error(self.pos, "Invalid types for '%s' (%s, %s)" %
|
|
(op, operand1.type, operand2.type))
|
|
|
|
def is_python_comparison(self):
|
|
return (not self.is_ptr_contains()
|
|
and not self.is_c_string_contains()
|
|
and (self.has_python_operands()
|
|
or (self.cascade and self.cascade.is_python_comparison())
|
|
or self.operator in ('in', 'not_in')))
|
|
|
|
def coerce_operands_to(self, dst_type, env):
|
|
operand2 = self.operand2
|
|
if operand2.type != dst_type:
|
|
self.operand2 = operand2.coerce_to(dst_type, env)
|
|
if self.cascade:
|
|
self.cascade.coerce_operands_to(dst_type, env)
|
|
|
|
def is_python_result(self):
|
|
return ((self.has_python_operands() and
|
|
self.special_bool_cmp_function is None and
|
|
self.operator not in ('is', 'is_not', 'in', 'not_in') and
|
|
not self.is_c_string_contains() and
|
|
not self.is_ptr_contains())
|
|
or (self.cascade and self.cascade.is_python_result()))
|
|
|
|
def is_c_string_contains(self):
|
|
return self.operator in ('in', 'not_in') and \
|
|
((self.operand1.type.is_int
|
|
and (self.operand2.type.is_string or self.operand2.type is bytes_type)) or
|
|
(self.operand1.type.is_unicode_char
|
|
and self.operand2.type is unicode_type))
|
|
|
|
def is_ptr_contains(self):
|
|
if self.operator in ('in', 'not_in'):
|
|
container_type = self.operand2.type
|
|
return (container_type.is_ptr or container_type.is_array) \
|
|
and not container_type.is_string
|
|
|
|
def find_special_bool_compare_function(self, env, operand1, result_is_bool=False):
|
|
# note: currently operand1 must get coerced to a Python object if we succeed here!
|
|
if self.operator in ('==', '!='):
|
|
type1, type2 = operand1.type, self.operand2.type
|
|
if result_is_bool or (type1.is_builtin_type and type2.is_builtin_type):
|
|
if type1 is Builtin.unicode_type or type2 is Builtin.unicode_type:
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("UnicodeEquals", "StringTools.c")
|
|
self.special_bool_cmp_function = "__Pyx_PyUnicode_Equals"
|
|
return True
|
|
elif type1 is Builtin.bytes_type or type2 is Builtin.bytes_type:
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("BytesEquals", "StringTools.c")
|
|
self.special_bool_cmp_function = "__Pyx_PyBytes_Equals"
|
|
return True
|
|
elif type1 is Builtin.basestring_type or type2 is Builtin.basestring_type:
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("UnicodeEquals", "StringTools.c")
|
|
self.special_bool_cmp_function = "__Pyx_PyUnicode_Equals"
|
|
return True
|
|
elif type1 is Builtin.str_type or type2 is Builtin.str_type:
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("StrEquals", "StringTools.c")
|
|
self.special_bool_cmp_function = "__Pyx_PyString_Equals"
|
|
return True
|
|
elif self.operator in ('in', 'not_in'):
|
|
if self.operand2.type is Builtin.dict_type:
|
|
self.operand2 = self.operand2.as_none_safe_node("'NoneType' object is not iterable")
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("PyDictContains", "ObjectHandling.c")
|
|
self.special_bool_cmp_function = "__Pyx_PyDict_ContainsTF"
|
|
return True
|
|
elif self.operand2.type is Builtin.set_type:
|
|
self.operand2 = self.operand2.as_none_safe_node("'NoneType' object is not iterable")
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("PySetContains", "ObjectHandling.c")
|
|
self.special_bool_cmp_function = "__Pyx_PySet_ContainsTF"
|
|
return True
|
|
elif self.operand2.type is Builtin.unicode_type:
|
|
self.operand2 = self.operand2.as_none_safe_node("'NoneType' object is not iterable")
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("PyUnicodeContains", "StringTools.c")
|
|
self.special_bool_cmp_function = "__Pyx_PyUnicode_ContainsTF"
|
|
return True
|
|
else:
|
|
if not self.operand2.type.is_pyobject:
|
|
self.operand2 = self.operand2.coerce_to_pyobject(env)
|
|
self.special_bool_cmp_utility_code = UtilityCode.load_cached("PySequenceContains", "ObjectHandling.c")
|
|
self.special_bool_cmp_function = "__Pyx_PySequence_ContainsTF"
|
|
return True
|
|
return False
|
|
|
|
def generate_operation_code(self, code, result_code,
|
|
operand1, op , operand2):
|
|
if self.type.is_pyobject:
|
|
error_clause = code.error_goto_if_null
|
|
got_ref = "__Pyx_XGOTREF(%s); " % result_code
|
|
if self.special_bool_cmp_function:
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("PyBoolOrNullFromLong", "ObjectHandling.c"))
|
|
coerce_result = "__Pyx_PyBoolOrNull_FromLong"
|
|
else:
|
|
coerce_result = "__Pyx_PyBool_FromLong"
|
|
else:
|
|
error_clause = code.error_goto_if_neg
|
|
got_ref = ""
|
|
coerce_result = ""
|
|
|
|
if self.special_bool_cmp_function:
|
|
if operand1.type.is_pyobject:
|
|
result1 = operand1.py_result()
|
|
else:
|
|
result1 = operand1.result()
|
|
if operand2.type.is_pyobject:
|
|
result2 = operand2.py_result()
|
|
else:
|
|
result2 = operand2.result()
|
|
if self.special_bool_cmp_utility_code:
|
|
code.globalstate.use_utility_code(self.special_bool_cmp_utility_code)
|
|
code.putln(
|
|
"%s = %s(%s(%s, %s, %s)); %s%s" % (
|
|
result_code,
|
|
coerce_result,
|
|
self.special_bool_cmp_function,
|
|
result1, result2, richcmp_constants[op],
|
|
got_ref,
|
|
error_clause(result_code, self.pos)))
|
|
|
|
elif operand1.type.is_pyobject and op not in ('is', 'is_not'):
|
|
assert op not in ('in', 'not_in'), op
|
|
code.putln("%s = PyObject_RichCompare(%s, %s, %s); %s%s" % (
|
|
result_code,
|
|
operand1.py_result(),
|
|
operand2.py_result(),
|
|
richcmp_constants[op],
|
|
got_ref,
|
|
error_clause(result_code, self.pos)))
|
|
|
|
elif operand1.type.is_complex:
|
|
code.putln("%s = %s(%s%s(%s, %s));" % (
|
|
result_code,
|
|
coerce_result,
|
|
op == "!=" and "!" or "",
|
|
operand1.type.unary_op('eq'),
|
|
operand1.result(),
|
|
operand2.result()))
|
|
|
|
else:
|
|
type1 = operand1.type
|
|
type2 = operand2.type
|
|
if (type1.is_extension_type or type2.is_extension_type) \
|
|
and not type1.same_as(type2):
|
|
common_type = py_object_type
|
|
elif type1.is_numeric:
|
|
common_type = PyrexTypes.widest_numeric_type(type1, type2)
|
|
else:
|
|
common_type = type1
|
|
code1 = operand1.result_as(common_type)
|
|
code2 = operand2.result_as(common_type)
|
|
statement = "%s = %s(%s %s %s);" % (
|
|
result_code,
|
|
coerce_result,
|
|
code1,
|
|
self.c_operator(op),
|
|
code2)
|
|
if self.is_cpp_comparison() and self.exception_check == '+':
|
|
translate_cpp_exception(
|
|
code,
|
|
self.pos,
|
|
statement,
|
|
result_code if self.type.is_pyobject else None,
|
|
self.exception_value,
|
|
self.in_nogil_context)
|
|
else:
|
|
code.putln(statement)
|
|
|
|
def c_operator(self, op):
|
|
if op == 'is':
|
|
return "=="
|
|
elif op == 'is_not':
|
|
return "!="
|
|
else:
|
|
return op
|
|
|
|
class PrimaryCmpNode(ExprNode, CmpNode):
|
|
# Non-cascaded comparison or first comparison of
|
|
# a cascaded sequence.
|
|
#
|
|
# operator string
|
|
# operand1 ExprNode
|
|
# operand2 ExprNode
|
|
# cascade CascadedCmpNode
|
|
|
|
# We don't use the subexprs mechanism, because
|
|
# things here are too complicated for it to handle.
|
|
# Instead, we override all the framework methods
|
|
# which use it.
|
|
|
|
child_attrs = ['operand1', 'operand2', 'coerced_operand2', 'cascade']
|
|
|
|
cascade = None
|
|
coerced_operand2 = None
|
|
is_memslice_nonecheck = False
|
|
|
|
def infer_type(self, env):
|
|
type1 = self.operand1.infer_type(env)
|
|
type2 = self.operand2.infer_type(env)
|
|
|
|
if is_pythran_expr(type1) or is_pythran_expr(type2):
|
|
if is_pythran_supported_type(type1) and is_pythran_supported_type(type2):
|
|
return PythranExpr(pythran_binop_type(self.operator, type1, type2))
|
|
|
|
# TODO: implement this for other types.
|
|
return py_object_type
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def calculate_constant_result(self):
|
|
assert not self.cascade
|
|
self.calculate_cascaded_constant_result(self.operand1.constant_result)
|
|
|
|
def compile_time_value(self, denv):
|
|
operand1 = self.operand1.compile_time_value(denv)
|
|
return self.cascaded_compile_time_value(operand1, denv)
|
|
|
|
def analyse_types(self, env):
|
|
self.operand1 = self.operand1.analyse_types(env)
|
|
self.operand2 = self.operand2.analyse_types(env)
|
|
if self.is_cpp_comparison():
|
|
self.analyse_cpp_comparison(env)
|
|
if self.cascade:
|
|
error(self.pos, "Cascading comparison not yet supported for cpp types.")
|
|
return self
|
|
|
|
type1 = self.operand1.type
|
|
type2 = self.operand2.type
|
|
if is_pythran_expr(type1) or is_pythran_expr(type2):
|
|
if is_pythran_supported_type(type1) and is_pythran_supported_type(type2):
|
|
self.type = PythranExpr(pythran_binop_type(self.operator, type1, type2))
|
|
self.is_pycmp = False
|
|
return self
|
|
|
|
if self.analyse_memoryviewslice_comparison(env):
|
|
return self
|
|
|
|
if self.cascade:
|
|
self.cascade = self.cascade.analyse_types(env)
|
|
|
|
if self.operator in ('in', 'not_in'):
|
|
if self.is_c_string_contains():
|
|
self.is_pycmp = False
|
|
common_type = None
|
|
if self.cascade:
|
|
error(self.pos, "Cascading comparison not yet supported for 'int_val in string'.")
|
|
return self
|
|
if self.operand2.type is unicode_type:
|
|
env.use_utility_code(UtilityCode.load_cached("PyUCS4InUnicode", "StringTools.c"))
|
|
else:
|
|
if self.operand1.type is PyrexTypes.c_uchar_type:
|
|
self.operand1 = self.operand1.coerce_to(PyrexTypes.c_char_type, env)
|
|
if self.operand2.type is not bytes_type:
|
|
self.operand2 = self.operand2.coerce_to(bytes_type, env)
|
|
env.use_utility_code(UtilityCode.load_cached("BytesContains", "StringTools.c"))
|
|
self.operand2 = self.operand2.as_none_safe_node(
|
|
"argument of type 'NoneType' is not iterable")
|
|
elif self.is_ptr_contains():
|
|
if self.cascade:
|
|
error(self.pos, "Cascading comparison not supported for 'val in sliced pointer'.")
|
|
self.type = PyrexTypes.c_bint_type
|
|
# Will be transformed by IterationTransform
|
|
return self
|
|
elif self.find_special_bool_compare_function(env, self.operand1):
|
|
if not self.operand1.type.is_pyobject:
|
|
self.operand1 = self.operand1.coerce_to_pyobject(env)
|
|
common_type = None # if coercion needed, the method call above has already done it
|
|
self.is_pycmp = False # result is bint
|
|
else:
|
|
common_type = py_object_type
|
|
self.is_pycmp = True
|
|
elif self.find_special_bool_compare_function(env, self.operand1):
|
|
if not self.operand1.type.is_pyobject:
|
|
self.operand1 = self.operand1.coerce_to_pyobject(env)
|
|
common_type = None # if coercion needed, the method call above has already done it
|
|
self.is_pycmp = False # result is bint
|
|
else:
|
|
common_type = self.find_common_type(env, self.operator, self.operand1)
|
|
self.is_pycmp = common_type.is_pyobject
|
|
|
|
if common_type is not None and not common_type.is_error:
|
|
if self.operand1.type != common_type:
|
|
self.operand1 = self.operand1.coerce_to(common_type, env)
|
|
self.coerce_operands_to(common_type, env)
|
|
|
|
if self.cascade:
|
|
self.operand2 = self.operand2.coerce_to_simple(env)
|
|
self.cascade.coerce_cascaded_operands_to_temp(env)
|
|
operand2 = self.cascade.optimise_comparison(self.operand2, env)
|
|
if operand2 is not self.operand2:
|
|
self.coerced_operand2 = operand2
|
|
if self.is_python_result():
|
|
self.type = PyrexTypes.py_object_type
|
|
else:
|
|
self.type = PyrexTypes.c_bint_type
|
|
cdr = self.cascade
|
|
while cdr:
|
|
cdr.type = self.type
|
|
cdr = cdr.cascade
|
|
if self.is_pycmp or self.cascade or self.special_bool_cmp_function:
|
|
# 1) owned reference, 2) reused value, 3) potential function error return value
|
|
self.is_temp = 1
|
|
return self
|
|
|
|
def analyse_cpp_comparison(self, env):
|
|
type1 = self.operand1.type
|
|
type2 = self.operand2.type
|
|
self.is_pycmp = False
|
|
entry = env.lookup_operator(self.operator, [self.operand1, self.operand2])
|
|
if entry is None:
|
|
error(self.pos, "Invalid types for '%s' (%s, %s)" %
|
|
(self.operator, type1, type2))
|
|
self.type = PyrexTypes.error_type
|
|
self.result_code = "<error>"
|
|
return
|
|
func_type = entry.type
|
|
if func_type.is_ptr:
|
|
func_type = func_type.base_type
|
|
self.exception_check = func_type.exception_check
|
|
self.exception_value = func_type.exception_value
|
|
if self.exception_check == '+':
|
|
self.is_temp = True
|
|
if self.exception_value is None:
|
|
env.use_utility_code(UtilityCode.load_cached("CppExceptionConversion", "CppSupport.cpp"))
|
|
if len(func_type.args) == 1:
|
|
self.operand2 = self.operand2.coerce_to(func_type.args[0].type, env)
|
|
else:
|
|
self.operand1 = self.operand1.coerce_to(func_type.args[0].type, env)
|
|
self.operand2 = self.operand2.coerce_to(func_type.args[1].type, env)
|
|
self.type = func_type.return_type
|
|
|
|
def analyse_memoryviewslice_comparison(self, env):
|
|
have_none = self.operand1.is_none or self.operand2.is_none
|
|
have_slice = (self.operand1.type.is_memoryviewslice or
|
|
self.operand2.type.is_memoryviewslice)
|
|
ops = ('==', '!=', 'is', 'is_not')
|
|
if have_slice and have_none and self.operator in ops:
|
|
self.is_pycmp = False
|
|
self.type = PyrexTypes.c_bint_type
|
|
self.is_memslice_nonecheck = True
|
|
return True
|
|
|
|
return False
|
|
|
|
def coerce_to_boolean(self, env):
|
|
if self.is_pycmp:
|
|
# coercing to bool => may allow for more efficient comparison code
|
|
if self.find_special_bool_compare_function(
|
|
env, self.operand1, result_is_bool=True):
|
|
self.is_pycmp = False
|
|
self.type = PyrexTypes.c_bint_type
|
|
self.is_temp = 1
|
|
if self.cascade:
|
|
operand2 = self.cascade.optimise_comparison(
|
|
self.operand2, env, result_is_bool=True)
|
|
if operand2 is not self.operand2:
|
|
self.coerced_operand2 = operand2
|
|
return self
|
|
# TODO: check if we can optimise parts of the cascade here
|
|
return ExprNode.coerce_to_boolean(self, env)
|
|
|
|
def has_python_operands(self):
|
|
return (self.operand1.type.is_pyobject
|
|
or self.operand2.type.is_pyobject)
|
|
|
|
def check_const(self):
|
|
if self.cascade:
|
|
self.not_const()
|
|
return False
|
|
else:
|
|
return self.operand1.check_const() and self.operand2.check_const()
|
|
|
|
def calculate_result_code(self):
|
|
operand1, operand2 = self.operand1, self.operand2
|
|
if operand1.type.is_complex:
|
|
if self.operator == "!=":
|
|
negation = "!"
|
|
else:
|
|
negation = ""
|
|
return "(%s%s(%s, %s))" % (
|
|
negation,
|
|
operand1.type.binary_op('=='),
|
|
operand1.result(),
|
|
operand2.result())
|
|
elif self.is_c_string_contains():
|
|
if operand2.type is unicode_type:
|
|
method = "__Pyx_UnicodeContainsUCS4"
|
|
else:
|
|
method = "__Pyx_BytesContains"
|
|
if self.operator == "not_in":
|
|
negation = "!"
|
|
else:
|
|
negation = ""
|
|
return "(%s%s(%s, %s))" % (
|
|
negation,
|
|
method,
|
|
operand2.result(),
|
|
operand1.result())
|
|
else:
|
|
if is_pythran_expr(self.type):
|
|
result1, result2 = operand1.pythran_result(), operand2.pythran_result()
|
|
else:
|
|
result1, result2 = operand1.result(), operand2.result()
|
|
if self.is_memslice_nonecheck:
|
|
if operand1.type.is_memoryviewslice:
|
|
result1 = "((PyObject *) %s.memview)" % result1
|
|
else:
|
|
result2 = "((PyObject *) %s.memview)" % result2
|
|
|
|
return "(%s %s %s)" % (
|
|
result1,
|
|
self.c_operator(self.operator),
|
|
result2)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
self.operand1.generate_evaluation_code(code)
|
|
self.operand2.generate_evaluation_code(code)
|
|
if self.is_temp:
|
|
self.allocate_temp_result(code)
|
|
self.generate_operation_code(code, self.result(),
|
|
self.operand1, self.operator, self.operand2)
|
|
if self.cascade:
|
|
self.cascade.generate_evaluation_code(
|
|
code, self.result(), self.coerced_operand2 or self.operand2,
|
|
needs_evaluation=self.coerced_operand2 is not None)
|
|
self.operand1.generate_disposal_code(code)
|
|
self.operand1.free_temps(code)
|
|
self.operand2.generate_disposal_code(code)
|
|
self.operand2.free_temps(code)
|
|
|
|
def generate_subexpr_disposal_code(self, code):
|
|
# If this is called, it is a non-cascaded cmp,
|
|
# so only need to dispose of the two main operands.
|
|
self.operand1.generate_disposal_code(code)
|
|
self.operand2.generate_disposal_code(code)
|
|
|
|
def free_subexpr_temps(self, code):
|
|
# If this is called, it is a non-cascaded cmp,
|
|
# so only need to dispose of the two main operands.
|
|
self.operand1.free_temps(code)
|
|
self.operand2.free_temps(code)
|
|
|
|
def annotate(self, code):
|
|
self.operand1.annotate(code)
|
|
self.operand2.annotate(code)
|
|
if self.cascade:
|
|
self.cascade.annotate(code)
|
|
|
|
|
|
class CascadedCmpNode(Node, CmpNode):
|
|
# A CascadedCmpNode is not a complete expression node. It
|
|
# hangs off the side of another comparison node, shares
|
|
# its left operand with that node, and shares its result
|
|
# with the PrimaryCmpNode at the head of the chain.
|
|
#
|
|
# operator string
|
|
# operand2 ExprNode
|
|
# cascade CascadedCmpNode
|
|
|
|
child_attrs = ['operand2', 'coerced_operand2', 'cascade']
|
|
|
|
cascade = None
|
|
coerced_operand2 = None
|
|
constant_result = constant_value_not_set # FIXME: where to calculate this?
|
|
|
|
def infer_type(self, env):
|
|
# TODO: Actually implement this (after merging with -unstable).
|
|
return py_object_type
|
|
|
|
def type_dependencies(self, env):
|
|
return ()
|
|
|
|
def has_constant_result(self):
|
|
return self.constant_result is not constant_value_not_set and \
|
|
self.constant_result is not not_a_constant
|
|
|
|
def analyse_types(self, env):
|
|
self.operand2 = self.operand2.analyse_types(env)
|
|
if self.cascade:
|
|
self.cascade = self.cascade.analyse_types(env)
|
|
return self
|
|
|
|
def has_python_operands(self):
|
|
return self.operand2.type.is_pyobject
|
|
|
|
def is_cpp_comparison(self):
|
|
# cascaded comparisons aren't currently implemented for c++ classes.
|
|
return False
|
|
|
|
def optimise_comparison(self, operand1, env, result_is_bool=False):
|
|
if self.find_special_bool_compare_function(env, operand1, result_is_bool):
|
|
self.is_pycmp = False
|
|
self.type = PyrexTypes.c_bint_type
|
|
if not operand1.type.is_pyobject:
|
|
operand1 = operand1.coerce_to_pyobject(env)
|
|
if self.cascade:
|
|
operand2 = self.cascade.optimise_comparison(self.operand2, env, result_is_bool)
|
|
if operand2 is not self.operand2:
|
|
self.coerced_operand2 = operand2
|
|
return operand1
|
|
|
|
def coerce_operands_to_pyobjects(self, env):
|
|
self.operand2 = self.operand2.coerce_to_pyobject(env)
|
|
if self.operand2.type is dict_type and self.operator in ('in', 'not_in'):
|
|
self.operand2 = self.operand2.as_none_safe_node("'NoneType' object is not iterable")
|
|
if self.cascade:
|
|
self.cascade.coerce_operands_to_pyobjects(env)
|
|
|
|
def coerce_cascaded_operands_to_temp(self, env):
|
|
if self.cascade:
|
|
#self.operand2 = self.operand2.coerce_to_temp(env) #CTT
|
|
self.operand2 = self.operand2.coerce_to_simple(env)
|
|
self.cascade.coerce_cascaded_operands_to_temp(env)
|
|
|
|
def generate_evaluation_code(self, code, result, operand1, needs_evaluation=False):
|
|
if self.type.is_pyobject:
|
|
code.putln("if (__Pyx_PyObject_IsTrue(%s)) {" % result)
|
|
code.put_decref(result, self.type)
|
|
else:
|
|
code.putln("if (%s) {" % result)
|
|
if needs_evaluation:
|
|
operand1.generate_evaluation_code(code)
|
|
self.operand2.generate_evaluation_code(code)
|
|
self.generate_operation_code(code, result,
|
|
operand1, self.operator, self.operand2)
|
|
if self.cascade:
|
|
self.cascade.generate_evaluation_code(
|
|
code, result, self.coerced_operand2 or self.operand2,
|
|
needs_evaluation=self.coerced_operand2 is not None)
|
|
if needs_evaluation:
|
|
operand1.generate_disposal_code(code)
|
|
operand1.free_temps(code)
|
|
# Cascaded cmp result is always temp
|
|
self.operand2.generate_disposal_code(code)
|
|
self.operand2.free_temps(code)
|
|
code.putln("}")
|
|
|
|
def annotate(self, code):
|
|
self.operand2.annotate(code)
|
|
if self.cascade:
|
|
self.cascade.annotate(code)
|
|
|
|
|
|
binop_node_classes = {
|
|
"or": BoolBinopNode,
|
|
"and": BoolBinopNode,
|
|
"|": IntBinopNode,
|
|
"^": IntBinopNode,
|
|
"&": IntBinopNode,
|
|
"<<": IntBinopNode,
|
|
">>": IntBinopNode,
|
|
"+": AddNode,
|
|
"-": SubNode,
|
|
"*": MulNode,
|
|
"@": MatMultNode,
|
|
"/": DivNode,
|
|
"//": DivNode,
|
|
"%": ModNode,
|
|
"**": PowNode,
|
|
}
|
|
|
|
|
|
def binop_node(pos, operator, operand1, operand2, inplace=False, **kwargs):
|
|
# Construct binop node of appropriate class for
|
|
# given operator.
|
|
return binop_node_classes[operator](
|
|
pos,
|
|
operator=operator,
|
|
operand1=operand1,
|
|
operand2=operand2,
|
|
inplace=inplace,
|
|
**kwargs)
|
|
|
|
|
|
#-------------------------------------------------------------------
|
|
#
|
|
# Coercion nodes
|
|
#
|
|
# Coercion nodes are special in that they are created during
|
|
# the analyse_types phase of parse tree processing.
|
|
# Their __init__ methods consequently incorporate some aspects
|
|
# of that phase.
|
|
#
|
|
#-------------------------------------------------------------------
|
|
|
|
class CoercionNode(ExprNode):
|
|
# Abstract base class for coercion nodes.
|
|
#
|
|
# arg ExprNode node being coerced
|
|
|
|
subexprs = ['arg']
|
|
constant_result = not_a_constant
|
|
|
|
def __init__(self, arg):
|
|
super(CoercionNode, self).__init__(arg.pos)
|
|
self.arg = arg
|
|
if debug_coercion:
|
|
print("%s Coercing %s" % (self, self.arg))
|
|
|
|
def calculate_constant_result(self):
|
|
# constant folding can break type coercion, so this is disabled
|
|
pass
|
|
|
|
def annotate(self, code):
|
|
self.arg.annotate(code)
|
|
if self.arg.type != self.type:
|
|
file, line, col = self.pos
|
|
code.annotate((file, line, col-1), AnnotationItem(
|
|
style='coerce', tag='coerce', text='[%s] to [%s]' % (self.arg.type, self.type)))
|
|
|
|
|
|
class CoerceToMemViewSliceNode(CoercionNode):
|
|
"""
|
|
Coerce an object to a memoryview slice. This holds a new reference in
|
|
a managed temp.
|
|
"""
|
|
|
|
def __init__(self, arg, dst_type, env):
|
|
assert dst_type.is_memoryviewslice
|
|
assert not arg.type.is_memoryviewslice
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = dst_type
|
|
self.is_temp = 1
|
|
self.env = env
|
|
self.use_managed_ref = True
|
|
self.arg = arg
|
|
|
|
def generate_result_code(self, code):
|
|
self.type.create_from_py_utility_code(self.env)
|
|
code.putln(self.type.from_py_call_code(
|
|
self.arg.py_result(),
|
|
self.result(),
|
|
self.pos,
|
|
code
|
|
))
|
|
|
|
|
|
class CastNode(CoercionNode):
|
|
# Wrap a node in a C type cast.
|
|
|
|
def __init__(self, arg, new_type):
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = new_type
|
|
|
|
def may_be_none(self):
|
|
return self.arg.may_be_none()
|
|
|
|
def calculate_result_code(self):
|
|
return self.arg.result_as(self.type)
|
|
|
|
def generate_result_code(self, code):
|
|
self.arg.generate_result_code(code)
|
|
|
|
|
|
class PyTypeTestNode(CoercionNode):
|
|
# This node is used to check that a generic Python
|
|
# object is an instance of a particular extension type.
|
|
# This node borrows the result of its argument node.
|
|
|
|
exact_builtin_type = True
|
|
|
|
def __init__(self, arg, dst_type, env, notnone=False):
|
|
# The arg is know to be a Python object, and
|
|
# the dst_type is known to be an extension type.
|
|
assert dst_type.is_extension_type or dst_type.is_builtin_type, "PyTypeTest on non extension type"
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = dst_type
|
|
self.result_ctype = arg.ctype()
|
|
self.notnone = notnone
|
|
|
|
nogil_check = Node.gil_error
|
|
gil_message = "Python type test"
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
if self.notnone:
|
|
return False
|
|
return self.arg.may_be_none()
|
|
|
|
def is_simple(self):
|
|
return self.arg.is_simple()
|
|
|
|
def result_in_temp(self):
|
|
return self.arg.result_in_temp()
|
|
|
|
def is_ephemeral(self):
|
|
return self.arg.is_ephemeral()
|
|
|
|
def nonlocally_immutable(self):
|
|
return self.arg.nonlocally_immutable()
|
|
|
|
def reanalyse(self):
|
|
if self.type != self.arg.type or not self.arg.is_temp:
|
|
return self
|
|
if not self.type.typeobj_is_available():
|
|
return self
|
|
if self.arg.may_be_none() and self.notnone:
|
|
return self.arg.as_none_safe_node("Cannot convert NoneType to %.200s" % self.type.name)
|
|
return self.arg
|
|
|
|
def calculate_constant_result(self):
|
|
# FIXME
|
|
pass
|
|
|
|
def calculate_result_code(self):
|
|
return self.arg.result()
|
|
|
|
def generate_result_code(self, code):
|
|
if self.type.typeobj_is_available():
|
|
if self.type.is_builtin_type:
|
|
type_test = self.type.type_test_code(
|
|
self.arg.py_result(),
|
|
self.notnone, exact=self.exact_builtin_type)
|
|
else:
|
|
type_test = self.type.type_test_code(
|
|
self.arg.py_result(), self.notnone)
|
|
code.globalstate.use_utility_code(
|
|
UtilityCode.load_cached("ExtTypeTest", "ObjectHandling.c"))
|
|
code.putln("if (!(%s)) %s" % (
|
|
type_test, code.error_goto(self.pos)))
|
|
else:
|
|
error(self.pos, "Cannot test type of extern C class "
|
|
"without type object name specification")
|
|
|
|
def generate_post_assignment_code(self, code):
|
|
self.arg.generate_post_assignment_code(code)
|
|
|
|
def free_temps(self, code):
|
|
self.arg.free_temps(code)
|
|
|
|
|
|
class NoneCheckNode(CoercionNode):
|
|
# This node is used to check that a Python object is not None and
|
|
# raises an appropriate exception (as specified by the creating
|
|
# transform).
|
|
|
|
is_nonecheck = True
|
|
|
|
def __init__(self, arg, exception_type_cname, exception_message,
|
|
exception_format_args=()):
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = arg.type
|
|
self.result_ctype = arg.ctype()
|
|
self.exception_type_cname = exception_type_cname
|
|
self.exception_message = exception_message
|
|
self.exception_format_args = tuple(exception_format_args or ())
|
|
|
|
nogil_check = None # this node only guards an operation that would fail already
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def is_simple(self):
|
|
return self.arg.is_simple()
|
|
|
|
def result_in_temp(self):
|
|
return self.arg.result_in_temp()
|
|
|
|
def nonlocally_immutable(self):
|
|
return self.arg.nonlocally_immutable()
|
|
|
|
def calculate_result_code(self):
|
|
return self.arg.result()
|
|
|
|
def condition(self):
|
|
if self.type.is_pyobject:
|
|
return self.arg.py_result()
|
|
elif self.type.is_memoryviewslice:
|
|
return "((PyObject *) %s.memview)" % self.arg.result()
|
|
else:
|
|
raise Exception("unsupported type")
|
|
|
|
@classmethod
|
|
def generate(cls, arg, code, exception_message,
|
|
exception_type_cname="PyExc_TypeError", exception_format_args=(), in_nogil_context=False):
|
|
node = cls(arg, exception_type_cname, exception_message, exception_format_args)
|
|
node.in_nogil_context = in_nogil_context
|
|
node.put_nonecheck(code)
|
|
|
|
@classmethod
|
|
def generate_if_needed(cls, arg, code, exception_message,
|
|
exception_type_cname="PyExc_TypeError", exception_format_args=(), in_nogil_context=False):
|
|
if arg.may_be_none():
|
|
cls.generate(arg, code, exception_message, exception_type_cname, exception_format_args, in_nogil_context)
|
|
|
|
def put_nonecheck(self, code):
|
|
code.putln(
|
|
"if (unlikely(%s == Py_None)) {" % self.condition())
|
|
|
|
if self.in_nogil_context:
|
|
code.put_ensure_gil()
|
|
|
|
escape = StringEncoding.escape_byte_string
|
|
if self.exception_format_args:
|
|
code.putln('PyErr_Format(%s, "%s", %s);' % (
|
|
self.exception_type_cname,
|
|
StringEncoding.escape_byte_string(
|
|
self.exception_message.encode('UTF-8')),
|
|
', '.join([ '"%s"' % escape(str(arg).encode('UTF-8'))
|
|
for arg in self.exception_format_args ])))
|
|
else:
|
|
code.putln('PyErr_SetString(%s, "%s");' % (
|
|
self.exception_type_cname,
|
|
escape(self.exception_message.encode('UTF-8'))))
|
|
|
|
if self.in_nogil_context:
|
|
code.put_release_ensured_gil()
|
|
|
|
code.putln(code.error_goto(self.pos))
|
|
code.putln("}")
|
|
|
|
def generate_result_code(self, code):
|
|
self.put_nonecheck(code)
|
|
|
|
def generate_post_assignment_code(self, code):
|
|
self.arg.generate_post_assignment_code(code)
|
|
|
|
def free_temps(self, code):
|
|
self.arg.free_temps(code)
|
|
|
|
|
|
class CoerceToPyTypeNode(CoercionNode):
|
|
# This node is used to convert a C data type
|
|
# to a Python object.
|
|
|
|
type = py_object_type
|
|
target_type = py_object_type
|
|
is_temp = 1
|
|
|
|
def __init__(self, arg, env, type=py_object_type):
|
|
if not arg.type.create_to_py_utility_code(env):
|
|
error(arg.pos, "Cannot convert '%s' to Python object" % arg.type)
|
|
elif arg.type.is_complex:
|
|
# special case: complex coercion is so complex that it
|
|
# uses a macro ("__pyx_PyComplex_FromComplex()"), for
|
|
# which the argument must be simple
|
|
arg = arg.coerce_to_simple(env)
|
|
CoercionNode.__init__(self, arg)
|
|
if type is py_object_type:
|
|
# be specific about some known types
|
|
if arg.type.is_string or arg.type.is_cpp_string:
|
|
self.type = default_str_type(env)
|
|
elif arg.type.is_pyunicode_ptr or arg.type.is_unicode_char:
|
|
self.type = unicode_type
|
|
elif arg.type.is_complex:
|
|
self.type = Builtin.complex_type
|
|
self.target_type = self.type
|
|
elif arg.type.is_string or arg.type.is_cpp_string:
|
|
if (type not in (bytes_type, bytearray_type)
|
|
and not env.directives['c_string_encoding']):
|
|
error(arg.pos,
|
|
"default encoding required for conversion from '%s' to '%s'" %
|
|
(arg.type, type))
|
|
self.type = self.target_type = type
|
|
else:
|
|
# FIXME: check that the target type and the resulting type are compatible
|
|
self.target_type = type
|
|
|
|
gil_message = "Converting to Python object"
|
|
|
|
def may_be_none(self):
|
|
# FIXME: is this always safe?
|
|
return False
|
|
|
|
def coerce_to_boolean(self, env):
|
|
arg_type = self.arg.type
|
|
if (arg_type == PyrexTypes.c_bint_type or
|
|
(arg_type.is_pyobject and arg_type.name == 'bool')):
|
|
return self.arg.coerce_to_temp(env)
|
|
else:
|
|
return CoerceToBooleanNode(self, env)
|
|
|
|
def coerce_to_integer(self, env):
|
|
# If not already some C integer type, coerce to longint.
|
|
if self.arg.type.is_int:
|
|
return self.arg
|
|
else:
|
|
return self.arg.coerce_to(PyrexTypes.c_long_type, env)
|
|
|
|
def analyse_types(self, env):
|
|
# The arg is always already analysed
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln('%s; %s' % (
|
|
self.arg.type.to_py_call_code(
|
|
self.arg.result(),
|
|
self.result(),
|
|
self.target_type),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class CoerceIntToBytesNode(CoerceToPyTypeNode):
|
|
# This node is used to convert a C int type to a Python bytes
|
|
# object.
|
|
|
|
is_temp = 1
|
|
|
|
def __init__(self, arg, env):
|
|
arg = arg.coerce_to_simple(env)
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = Builtin.bytes_type
|
|
|
|
def generate_result_code(self, code):
|
|
arg = self.arg
|
|
arg_result = arg.result()
|
|
if arg.type not in (PyrexTypes.c_char_type,
|
|
PyrexTypes.c_uchar_type,
|
|
PyrexTypes.c_schar_type):
|
|
if arg.type.signed:
|
|
code.putln("if ((%s < 0) || (%s > 255)) {" % (
|
|
arg_result, arg_result))
|
|
else:
|
|
code.putln("if (%s > 255) {" % arg_result)
|
|
code.putln('PyErr_SetString(PyExc_OverflowError, '
|
|
'"value too large to pack into a byte"); %s' % (
|
|
code.error_goto(self.pos)))
|
|
code.putln('}')
|
|
temp = None
|
|
if arg.type is not PyrexTypes.c_char_type:
|
|
temp = code.funcstate.allocate_temp(PyrexTypes.c_char_type, manage_ref=False)
|
|
code.putln("%s = (char)%s;" % (temp, arg_result))
|
|
arg_result = temp
|
|
code.putln('%s = PyBytes_FromStringAndSize(&%s, 1); %s' % (
|
|
self.result(),
|
|
arg_result,
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
if temp is not None:
|
|
code.funcstate.release_temp(temp)
|
|
code.put_gotref(self.py_result())
|
|
|
|
|
|
class CoerceFromPyTypeNode(CoercionNode):
|
|
# This node is used to convert a Python object
|
|
# to a C data type.
|
|
|
|
def __init__(self, result_type, arg, env):
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = result_type
|
|
self.is_temp = 1
|
|
if not result_type.create_from_py_utility_code(env):
|
|
error(arg.pos,
|
|
"Cannot convert Python object to '%s'" % result_type)
|
|
if self.type.is_string or self.type.is_pyunicode_ptr:
|
|
if self.arg.is_name and self.arg.entry and self.arg.entry.is_pyglobal:
|
|
warning(arg.pos,
|
|
"Obtaining '%s' from externally modifiable global Python value" % result_type,
|
|
level=1)
|
|
|
|
def analyse_types(self, env):
|
|
# The arg is always already analysed
|
|
return self
|
|
|
|
def is_ephemeral(self):
|
|
return (self.type.is_ptr and not self.type.is_array) and self.arg.is_ephemeral()
|
|
|
|
def generate_result_code(self, code):
|
|
from_py_function = None
|
|
# for certain source types, we can do better than the generic coercion
|
|
if self.type.is_string and self.arg.type is bytes_type:
|
|
if self.type.from_py_function.startswith('__Pyx_PyObject_As'):
|
|
from_py_function = '__Pyx_PyBytes' + self.type.from_py_function[len('__Pyx_PyObject'):]
|
|
NoneCheckNode.generate_if_needed(self.arg, code, "expected bytes, NoneType found")
|
|
|
|
code.putln(self.type.from_py_call_code(
|
|
self.arg.py_result(), self.result(), self.pos, code, from_py_function=from_py_function))
|
|
if self.type.is_pyobject:
|
|
code.put_gotref(self.py_result())
|
|
|
|
def nogil_check(self, env):
|
|
error(self.pos, "Coercion from Python not allowed without the GIL")
|
|
|
|
|
|
class CoerceToBooleanNode(CoercionNode):
|
|
# This node is used when a result needs to be used
|
|
# in a boolean context.
|
|
|
|
type = PyrexTypes.c_bint_type
|
|
|
|
_special_builtins = {
|
|
Builtin.list_type: 'PyList_GET_SIZE',
|
|
Builtin.tuple_type: 'PyTuple_GET_SIZE',
|
|
Builtin.set_type: 'PySet_GET_SIZE',
|
|
Builtin.frozenset_type: 'PySet_GET_SIZE',
|
|
Builtin.bytes_type: 'PyBytes_GET_SIZE',
|
|
Builtin.bytearray_type: 'PyByteArray_GET_SIZE',
|
|
Builtin.unicode_type: '__Pyx_PyUnicode_IS_TRUE',
|
|
}
|
|
|
|
def __init__(self, arg, env):
|
|
CoercionNode.__init__(self, arg)
|
|
if arg.type.is_pyobject:
|
|
self.is_temp = 1
|
|
|
|
def nogil_check(self, env):
|
|
if self.arg.type.is_pyobject and self._special_builtins.get(self.arg.type) is None:
|
|
self.gil_error()
|
|
|
|
gil_message = "Truth-testing Python object"
|
|
|
|
def check_const(self):
|
|
if self.is_temp:
|
|
self.not_const()
|
|
return False
|
|
return self.arg.check_const()
|
|
|
|
def calculate_result_code(self):
|
|
return "(%s != 0)" % self.arg.result()
|
|
|
|
def generate_result_code(self, code):
|
|
if not self.is_temp:
|
|
return
|
|
test_func = self._special_builtins.get(self.arg.type)
|
|
if test_func is not None:
|
|
checks = ["(%s != Py_None)" % self.arg.py_result()] if self.arg.may_be_none() else []
|
|
checks.append("(%s(%s) != 0)" % (test_func, self.arg.py_result()))
|
|
code.putln("%s = %s;" % (self.result(), '&&'.join(checks)))
|
|
else:
|
|
code.putln(
|
|
"%s = __Pyx_PyObject_IsTrue(%s); %s" % (
|
|
self.result(),
|
|
self.arg.py_result(),
|
|
code.error_goto_if_neg(self.result(), self.pos)))
|
|
|
|
|
|
class CoerceToComplexNode(CoercionNode):
|
|
|
|
def __init__(self, arg, dst_type, env):
|
|
if arg.type.is_complex:
|
|
arg = arg.coerce_to_simple(env)
|
|
self.type = dst_type
|
|
CoercionNode.__init__(self, arg)
|
|
dst_type.create_declaration_utility_code(env)
|
|
|
|
def calculate_result_code(self):
|
|
if self.arg.type.is_complex:
|
|
real_part = "__Pyx_CREAL(%s)" % self.arg.result()
|
|
imag_part = "__Pyx_CIMAG(%s)" % self.arg.result()
|
|
else:
|
|
real_part = self.arg.result()
|
|
imag_part = "0"
|
|
return "%s(%s, %s)" % (
|
|
self.type.from_parts,
|
|
real_part,
|
|
imag_part)
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
class CoerceToTempNode(CoercionNode):
|
|
# This node is used to force the result of another node
|
|
# to be stored in a temporary. It is only used if the
|
|
# argument node's result is not already in a temporary.
|
|
|
|
def __init__(self, arg, env):
|
|
CoercionNode.__init__(self, arg)
|
|
self.type = self.arg.type.as_argument_type()
|
|
self.constant_result = self.arg.constant_result
|
|
self.is_temp = 1
|
|
if self.type.is_pyobject:
|
|
self.result_ctype = py_object_type
|
|
|
|
gil_message = "Creating temporary Python reference"
|
|
|
|
def analyse_types(self, env):
|
|
# The arg is always already analysed
|
|
return self
|
|
|
|
def coerce_to_boolean(self, env):
|
|
self.arg = self.arg.coerce_to_boolean(env)
|
|
if self.arg.is_simple():
|
|
return self.arg
|
|
self.type = self.arg.type
|
|
self.result_ctype = self.type
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
#self.arg.generate_evaluation_code(code) # Already done
|
|
# by generic generate_subexpr_evaluation_code!
|
|
code.putln("%s = %s;" % (
|
|
self.result(), self.arg.result_as(self.ctype())))
|
|
if self.use_managed_ref:
|
|
if self.type.is_pyobject:
|
|
code.put_incref(self.result(), self.ctype())
|
|
elif self.type.is_memoryviewslice:
|
|
code.put_incref_memoryviewslice(self.result(),
|
|
not self.in_nogil_context)
|
|
|
|
class ProxyNode(CoercionNode):
|
|
"""
|
|
A node that should not be replaced by transforms or other means,
|
|
and hence can be useful to wrap the argument to a clone node
|
|
|
|
MyNode -> ProxyNode -> ArgNode
|
|
CloneNode -^
|
|
"""
|
|
|
|
nogil_check = None
|
|
|
|
def __init__(self, arg):
|
|
super(ProxyNode, self).__init__(arg)
|
|
self.constant_result = arg.constant_result
|
|
self._proxy_type()
|
|
|
|
def analyse_types(self, env):
|
|
self.arg = self.arg.analyse_expressions(env)
|
|
self._proxy_type()
|
|
return self
|
|
|
|
def infer_type(self, env):
|
|
return self.arg.infer_type(env)
|
|
|
|
def _proxy_type(self):
|
|
if hasattr(self.arg, 'type'):
|
|
self.type = self.arg.type
|
|
self.result_ctype = self.arg.result_ctype
|
|
if hasattr(self.arg, 'entry'):
|
|
self.entry = self.arg.entry
|
|
|
|
def generate_result_code(self, code):
|
|
self.arg.generate_result_code(code)
|
|
|
|
def result(self):
|
|
return self.arg.result()
|
|
|
|
def is_simple(self):
|
|
return self.arg.is_simple()
|
|
|
|
def may_be_none(self):
|
|
return self.arg.may_be_none()
|
|
|
|
def generate_evaluation_code(self, code):
|
|
self.arg.generate_evaluation_code(code)
|
|
|
|
def generate_disposal_code(self, code):
|
|
self.arg.generate_disposal_code(code)
|
|
|
|
def free_temps(self, code):
|
|
self.arg.free_temps(code)
|
|
|
|
class CloneNode(CoercionNode):
|
|
# This node is employed when the result of another node needs
|
|
# to be used multiple times. The argument node's result must
|
|
# be in a temporary. This node "borrows" the result from the
|
|
# argument node, and does not generate any evaluation or
|
|
# disposal code for it. The original owner of the argument
|
|
# node is responsible for doing those things.
|
|
|
|
subexprs = [] # Arg is not considered a subexpr
|
|
nogil_check = None
|
|
|
|
def __init__(self, arg):
|
|
CoercionNode.__init__(self, arg)
|
|
self.constant_result = arg.constant_result
|
|
if hasattr(arg, 'type'):
|
|
self.type = arg.type
|
|
self.result_ctype = arg.result_ctype
|
|
if hasattr(arg, 'entry'):
|
|
self.entry = arg.entry
|
|
|
|
def result(self):
|
|
return self.arg.result()
|
|
|
|
def may_be_none(self):
|
|
return self.arg.may_be_none()
|
|
|
|
def type_dependencies(self, env):
|
|
return self.arg.type_dependencies(env)
|
|
|
|
def infer_type(self, env):
|
|
return self.arg.infer_type(env)
|
|
|
|
def analyse_types(self, env):
|
|
self.type = self.arg.type
|
|
self.result_ctype = self.arg.result_ctype
|
|
self.is_temp = 1
|
|
if hasattr(self.arg, 'entry'):
|
|
self.entry = self.arg.entry
|
|
return self
|
|
|
|
def coerce_to(self, dest_type, env):
|
|
if self.arg.is_literal:
|
|
return self.arg.coerce_to(dest_type, env)
|
|
return super(CloneNode, self).coerce_to(dest_type, env)
|
|
|
|
def is_simple(self):
|
|
return True # result is always in a temp (or a name)
|
|
|
|
def generate_evaluation_code(self, code):
|
|
pass
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
def generate_disposal_code(self, code):
|
|
pass
|
|
|
|
def free_temps(self, code):
|
|
pass
|
|
|
|
|
|
class CMethodSelfCloneNode(CloneNode):
|
|
# Special CloneNode for the self argument of builtin C methods
|
|
# that accepts subtypes of the builtin type. This is safe only
|
|
# for 'final' subtypes, as subtypes of the declared type may
|
|
# override the C method.
|
|
|
|
def coerce_to(self, dst_type, env):
|
|
if dst_type.is_builtin_type and self.type.subtype_of(dst_type):
|
|
return self
|
|
return CloneNode.coerce_to(self, dst_type, env)
|
|
|
|
|
|
class ModuleRefNode(ExprNode):
|
|
# Simple returns the module object
|
|
|
|
type = py_object_type
|
|
is_temp = False
|
|
subexprs = []
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def may_be_none(self):
|
|
return False
|
|
|
|
def calculate_result_code(self):
|
|
return Naming.module_cname
|
|
|
|
def generate_result_code(self, code):
|
|
pass
|
|
|
|
class DocstringRefNode(ExprNode):
|
|
# Extracts the docstring of the body element
|
|
|
|
subexprs = ['body']
|
|
type = py_object_type
|
|
is_temp = True
|
|
|
|
def __init__(self, pos, body):
|
|
ExprNode.__init__(self, pos)
|
|
assert body.type.is_pyobject
|
|
self.body = body
|
|
|
|
def analyse_types(self, env):
|
|
return self
|
|
|
|
def generate_result_code(self, code):
|
|
code.putln('%s = __Pyx_GetAttr(%s, %s); %s' % (
|
|
self.result(), self.body.result(),
|
|
code.intern_identifier(StringEncoding.EncodedString("__doc__")),
|
|
code.error_goto_if_null(self.result(), self.pos)))
|
|
code.put_gotref(self.result())
|
|
|
|
|
|
|
|
#------------------------------------------------------------------------------------
|
|
#
|
|
# Runtime support code
|
|
#
|
|
#------------------------------------------------------------------------------------
|
|
|
|
pyerr_occurred_withgil_utility_code= UtilityCode(
|
|
proto = """
|
|
static CYTHON_INLINE int __Pyx_ErrOccurredWithGIL(void); /* proto */
|
|
""",
|
|
impl = """
|
|
static CYTHON_INLINE int __Pyx_ErrOccurredWithGIL(void) {
|
|
int err;
|
|
#ifdef WITH_THREAD
|
|
PyGILState_STATE _save = PyGILState_Ensure();
|
|
#endif
|
|
err = !!PyErr_Occurred();
|
|
#ifdef WITH_THREAD
|
|
PyGILState_Release(_save);
|
|
#endif
|
|
return err;
|
|
}
|
|
"""
|
|
)
|
|
|
|
#------------------------------------------------------------------------------------
|
|
|
|
raise_unbound_local_error_utility_code = UtilityCode(
|
|
proto = """
|
|
static CYTHON_INLINE void __Pyx_RaiseUnboundLocalError(const char *varname);
|
|
""",
|
|
impl = """
|
|
static CYTHON_INLINE void __Pyx_RaiseUnboundLocalError(const char *varname) {
|
|
PyErr_Format(PyExc_UnboundLocalError, "local variable '%s' referenced before assignment", varname);
|
|
}
|
|
""")
|
|
|
|
raise_closure_name_error_utility_code = UtilityCode(
|
|
proto = """
|
|
static CYTHON_INLINE void __Pyx_RaiseClosureNameError(const char *varname);
|
|
""",
|
|
impl = """
|
|
static CYTHON_INLINE void __Pyx_RaiseClosureNameError(const char *varname) {
|
|
PyErr_Format(PyExc_NameError, "free variable '%s' referenced before assignment in enclosing scope", varname);
|
|
}
|
|
""")
|
|
|
|
# Don't inline the function, it should really never be called in production
|
|
raise_unbound_memoryview_utility_code_nogil = UtilityCode(
|
|
proto = """
|
|
static void __Pyx_RaiseUnboundMemoryviewSliceNogil(const char *varname);
|
|
""",
|
|
impl = """
|
|
static void __Pyx_RaiseUnboundMemoryviewSliceNogil(const char *varname) {
|
|
#ifdef WITH_THREAD
|
|
PyGILState_STATE gilstate = PyGILState_Ensure();
|
|
#endif
|
|
__Pyx_RaiseUnboundLocalError(varname);
|
|
#ifdef WITH_THREAD
|
|
PyGILState_Release(gilstate);
|
|
#endif
|
|
}
|
|
""",
|
|
requires = [raise_unbound_local_error_utility_code])
|
|
|
|
#------------------------------------------------------------------------------------
|
|
|
|
raise_too_many_values_to_unpack = UtilityCode.load_cached("RaiseTooManyValuesToUnpack", "ObjectHandling.c")
|
|
raise_need_more_values_to_unpack = UtilityCode.load_cached("RaiseNeedMoreValuesToUnpack", "ObjectHandling.c")
|
|
tuple_unpacking_error_code = UtilityCode.load_cached("UnpackTupleError", "ObjectHandling.c")
|