lbry-android-sdk/venv/lib/python3.8/site-packages/Cython/Compiler/Code.py

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2022-12-02 21:15:34 +01:00
# cython: language_level = 2
# cython: auto_pickle=False
#
# Code output module
#
from __future__ import absolute_import
import cython
cython.declare(os=object, re=object, operator=object, textwrap=object,
Template=object, Naming=object, Options=object, StringEncoding=object,
Utils=object, SourceDescriptor=object, StringIOTree=object,
DebugFlags=object, basestring=object, defaultdict=object,
closing=object, partial=object)
import os
import re
import shutil
import sys
import operator
import textwrap
from string import Template
from functools import partial
from contextlib import closing
from collections import defaultdict
try:
import hashlib
except ImportError:
import md5 as hashlib
from . import Naming
from . import Options
from . import DebugFlags
from . import StringEncoding
from . import Version
from .. import Utils
from .Scanning import SourceDescriptor
from ..StringIOTree import StringIOTree
try:
from __builtin__ import basestring
except ImportError:
from builtins import str as basestring
KEYWORDS_MUST_BE_BYTES = sys.version_info < (2, 7)
non_portable_builtins_map = {
# builtins that have different names in different Python versions
'bytes' : ('PY_MAJOR_VERSION < 3', 'str'),
'unicode' : ('PY_MAJOR_VERSION >= 3', 'str'),
'basestring' : ('PY_MAJOR_VERSION >= 3', 'str'),
'xrange' : ('PY_MAJOR_VERSION >= 3', 'range'),
'raw_input' : ('PY_MAJOR_VERSION >= 3', 'input'),
}
ctypedef_builtins_map = {
# types of builtins in "ctypedef class" statements which we don't
# import either because the names conflict with C types or because
# the type simply is not exposed.
'py_int' : '&PyInt_Type',
'py_long' : '&PyLong_Type',
'py_float' : '&PyFloat_Type',
'wrapper_descriptor' : '&PyWrapperDescr_Type',
}
basicsize_builtins_map = {
# builtins whose type has a different tp_basicsize than sizeof(...)
'PyTypeObject': 'PyHeapTypeObject',
}
uncachable_builtins = [
# Global/builtin names that cannot be cached because they may or may not
# be available at import time, for various reasons:
## - Py3.7+
'breakpoint', # might deserve an implementation in Cython
## - Py3.4+
'__loader__',
'__spec__',
## - Py3+
'BlockingIOError',
'BrokenPipeError',
'ChildProcessError',
'ConnectionAbortedError',
'ConnectionError',
'ConnectionRefusedError',
'ConnectionResetError',
'FileExistsError',
'FileNotFoundError',
'InterruptedError',
'IsADirectoryError',
'ModuleNotFoundError',
'NotADirectoryError',
'PermissionError',
'ProcessLookupError',
'RecursionError',
'ResourceWarning',
#'StopAsyncIteration', # backported
'TimeoutError',
'__build_class__',
'ascii', # might deserve an implementation in Cython
#'exec', # implemented in Cython
## - Py2.7+
'memoryview',
## - platform specific
'WindowsError',
## - others
'_', # e.g. used by gettext
]
special_py_methods = set([
'__cinit__', '__dealloc__', '__richcmp__', '__next__',
'__await__', '__aiter__', '__anext__',
'__getreadbuffer__', '__getwritebuffer__', '__getsegcount__',
'__getcharbuffer__', '__getbuffer__', '__releasebuffer__'
])
modifier_output_mapper = {
'inline': 'CYTHON_INLINE'
}.get
class IncludeCode(object):
"""
An include file and/or verbatim C code to be included in the
generated sources.
"""
# attributes:
#
# pieces {order: unicode}: pieces of C code to be generated.
# For the included file, the key "order" is zero.
# For verbatim include code, the "order" is the "order"
# attribute of the original IncludeCode where this piece
# of C code was first added. This is needed to prevent
# duplication if the same include code is found through
# multiple cimports.
# location int: where to put this include in the C sources, one
# of the constants INITIAL, EARLY, LATE
# order int: sorting order (automatically set by increasing counter)
# Constants for location. If the same include occurs with different
# locations, the earliest one takes precedense.
INITIAL = 0
EARLY = 1
LATE = 2
counter = 1 # Counter for "order"
def __init__(self, include=None, verbatim=None, late=True, initial=False):
self.order = self.counter
type(self).counter += 1
self.pieces = {}
if include:
if include[0] == '<' and include[-1] == '>':
self.pieces[0] = u'#include {0}'.format(include)
late = False # system include is never late
else:
self.pieces[0] = u'#include "{0}"'.format(include)
if verbatim:
self.pieces[self.order] = verbatim
if initial:
self.location = self.INITIAL
elif late:
self.location = self.LATE
else:
self.location = self.EARLY
def dict_update(self, d, key):
"""
Insert `self` in dict `d` with key `key`. If that key already
exists, update the attributes of the existing value with `self`.
"""
if key in d:
other = d[key]
other.location = min(self.location, other.location)
other.pieces.update(self.pieces)
else:
d[key] = self
def sortkey(self):
return self.order
def mainpiece(self):
"""
Return the main piece of C code, corresponding to the include
file. If there was no include file, return None.
"""
return self.pieces.get(0)
def write(self, code):
# Write values of self.pieces dict, sorted by the keys
for k in sorted(self.pieces):
code.putln(self.pieces[k])
def get_utility_dir():
# make this a function and not global variables:
# http://trac.cython.org/cython_trac/ticket/475
Cython_dir = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
return os.path.join(Cython_dir, "Utility")
class UtilityCodeBase(object):
"""
Support for loading utility code from a file.
Code sections in the file can be specified as follows:
##### MyUtility.proto #####
[proto declarations]
##### MyUtility.init #####
[code run at module initialization]
##### MyUtility #####
#@requires: MyOtherUtility
#@substitute: naming
[definitions]
for prototypes and implementation respectively. For non-python or
-cython files backslashes should be used instead. 5 to 30 comment
characters may be used on either side.
If the @cname decorator is not used and this is a CythonUtilityCode,
one should pass in the 'name' keyword argument to be used for name
mangling of such entries.
"""
is_cython_utility = False
_utility_cache = {}
@classmethod
def _add_utility(cls, utility, type, lines, begin_lineno, tags=None):
if utility is None:
return
code = '\n'.join(lines)
if tags and 'substitute' in tags and tags['substitute'] == set(['naming']):
del tags['substitute']
try:
code = Template(code).substitute(vars(Naming))
except (KeyError, ValueError) as e:
raise RuntimeError("Error parsing templated utility code of type '%s' at line %d: %s" % (
type, begin_lineno, e))
# remember correct line numbers at least until after templating
code = '\n' * begin_lineno + code
if type == 'proto':
utility[0] = code
elif type == 'impl':
utility[1] = code
else:
all_tags = utility[2]
if KEYWORDS_MUST_BE_BYTES:
type = type.encode('ASCII')
all_tags[type] = code
if tags:
all_tags = utility[2]
for name, values in tags.items():
if KEYWORDS_MUST_BE_BYTES:
name = name.encode('ASCII')
all_tags.setdefault(name, set()).update(values)
@classmethod
def load_utilities_from_file(cls, path):
utilities = cls._utility_cache.get(path)
if utilities:
return utilities
filename = os.path.join(get_utility_dir(), path)
_, ext = os.path.splitext(path)
if ext in ('.pyx', '.py', '.pxd', '.pxi'):
comment = '#'
strip_comments = partial(re.compile(r'^\s*#(?!\s*cython\s*:).*').sub, '')
rstrip = StringEncoding._unicode.rstrip
else:
comment = '/'
strip_comments = partial(re.compile(r'^\s*//.*|/\*[^*]*\*/').sub, '')
rstrip = partial(re.compile(r'\s+(\\?)$').sub, r'\1')
match_special = re.compile(
(r'^%(C)s{5,30}\s*(?P<name>(?:\w|\.)+)\s*%(C)s{5,30}|'
r'^%(C)s+@(?P<tag>\w+)\s*:\s*(?P<value>(?:\w|[.:])+)') %
{'C': comment}).match
match_type = re.compile(r'(.+)[.](proto(?:[.]\S+)?|impl|init|cleanup)$').match
with closing(Utils.open_source_file(filename, encoding='UTF-8')) as f:
all_lines = f.readlines()
utilities = defaultdict(lambda: [None, None, {}])
lines = []
tags = defaultdict(set)
utility = type = None
begin_lineno = 0
for lineno, line in enumerate(all_lines):
m = match_special(line)
if m:
if m.group('name'):
cls._add_utility(utility, type, lines, begin_lineno, tags)
begin_lineno = lineno + 1
del lines[:]
tags.clear()
name = m.group('name')
mtype = match_type(name)
if mtype:
name, type = mtype.groups()
else:
type = 'impl'
utility = utilities[name]
else:
tags[m.group('tag')].add(m.group('value'))
lines.append('') # keep line number correct
else:
lines.append(rstrip(strip_comments(line)))
if utility is None:
raise ValueError("Empty utility code file")
# Don't forget to add the last utility code
cls._add_utility(utility, type, lines, begin_lineno, tags)
utilities = dict(utilities) # un-defaultdict-ify
cls._utility_cache[path] = utilities
return utilities
@classmethod
def load(cls, util_code_name, from_file=None, **kwargs):
"""
Load utility code from a file specified by from_file (relative to
Cython/Utility) and name util_code_name. If from_file is not given,
load it from the file util_code_name.*. There should be only one
file matched by this pattern.
"""
if '::' in util_code_name:
from_file, util_code_name = util_code_name.rsplit('::', 1)
if not from_file:
utility_dir = get_utility_dir()
prefix = util_code_name + '.'
try:
listing = os.listdir(utility_dir)
except OSError:
# XXX the code below assumes as 'zipimport.zipimporter' instance
# XXX should be easy to generalize, but too lazy right now to write it
import zipfile
global __loader__
loader = __loader__
archive = loader.archive
with closing(zipfile.ZipFile(archive)) as fileobj:
listing = [os.path.basename(name)
for name in fileobj.namelist()
if os.path.join(archive, name).startswith(utility_dir)]
files = [filename for filename in listing
if filename.startswith(prefix)]
if not files:
raise ValueError("No match found for utility code " + util_code_name)
if len(files) > 1:
raise ValueError("More than one filename match found for utility code " + util_code_name)
from_file = files[0]
utilities = cls.load_utilities_from_file(from_file)
proto, impl, tags = utilities[util_code_name]
if tags:
orig_kwargs = kwargs.copy()
for name, values in tags.items():
if name in kwargs:
continue
# only pass lists when we have to: most argument expect one value or None
if name == 'requires':
if orig_kwargs:
values = [cls.load(dep, from_file, **orig_kwargs)
for dep in sorted(values)]
else:
# dependencies are rarely unique, so use load_cached() when we can
values = [cls.load_cached(dep, from_file)
for dep in sorted(values)]
elif not values:
values = None
elif len(values) == 1:
values = list(values)[0]
kwargs[name] = values
if proto is not None:
kwargs['proto'] = proto
if impl is not None:
kwargs['impl'] = impl
if 'name' not in kwargs:
kwargs['name'] = util_code_name
if 'file' not in kwargs and from_file:
kwargs['file'] = from_file
return cls(**kwargs)
@classmethod
def load_cached(cls, utility_code_name, from_file=None, __cache={}):
"""
Calls .load(), but using a per-type cache based on utility name and file name.
"""
key = (cls, from_file, utility_code_name)
try:
return __cache[key]
except KeyError:
pass
code = __cache[key] = cls.load(utility_code_name, from_file)
return code
@classmethod
def load_as_string(cls, util_code_name, from_file=None, **kwargs):
"""
Load a utility code as a string. Returns (proto, implementation)
"""
util = cls.load(util_code_name, from_file, **kwargs)
proto, impl = util.proto, util.impl
return util.format_code(proto), util.format_code(impl)
def format_code(self, code_string, replace_empty_lines=re.compile(r'\n\n+').sub):
"""
Format a code section for output.
"""
if code_string:
code_string = replace_empty_lines('\n', code_string.strip()) + '\n\n'
return code_string
def __str__(self):
return "<%s(%s)>" % (type(self).__name__, self.name)
def get_tree(self, **kwargs):
pass
def __deepcopy__(self, memodict=None):
# No need to deep-copy utility code since it's essentially immutable.
return self
class UtilityCode(UtilityCodeBase):
"""
Stores utility code to add during code generation.
See GlobalState.put_utility_code.
hashes/equals by instance
proto C prototypes
impl implementation code
init code to call on module initialization
requires utility code dependencies
proto_block the place in the resulting file where the prototype should
end up
name name of the utility code (or None)
file filename of the utility code file this utility was loaded
from (or None)
"""
def __init__(self, proto=None, impl=None, init=None, cleanup=None, requires=None,
proto_block='utility_code_proto', name=None, file=None):
# proto_block: Which code block to dump prototype in. See GlobalState.
self.proto = proto
self.impl = impl
self.init = init
self.cleanup = cleanup
self.requires = requires
self._cache = {}
self.specialize_list = []
self.proto_block = proto_block
self.name = name
self.file = file
def __hash__(self):
return hash((self.proto, self.impl))
def __eq__(self, other):
if self is other:
return True
self_type, other_type = type(self), type(other)
if self_type is not other_type and not (isinstance(other, self_type) or isinstance(self, other_type)):
return False
self_proto = getattr(self, 'proto', None)
other_proto = getattr(other, 'proto', None)
return (self_proto, self.impl) == (other_proto, other.impl)
def none_or_sub(self, s, context):
"""
Format a string in this utility code with context. If None, do nothing.
"""
if s is None:
return None
return s % context
def specialize(self, pyrex_type=None, **data):
# Dicts aren't hashable...
if pyrex_type is not None:
data['type'] = pyrex_type.empty_declaration_code()
data['type_name'] = pyrex_type.specialization_name()
key = tuple(sorted(data.items()))
try:
return self._cache[key]
except KeyError:
if self.requires is None:
requires = None
else:
requires = [r.specialize(data) for r in self.requires]
s = self._cache[key] = UtilityCode(
self.none_or_sub(self.proto, data),
self.none_or_sub(self.impl, data),
self.none_or_sub(self.init, data),
self.none_or_sub(self.cleanup, data),
requires,
self.proto_block)
self.specialize_list.append(s)
return s
def inject_string_constants(self, impl, output):
"""Replace 'PYIDENT("xyz")' by a constant Python identifier cname.
"""
if 'PYIDENT(' not in impl and 'PYUNICODE(' not in impl:
return False, impl
replacements = {}
def externalise(matchobj):
key = matchobj.groups()
try:
cname = replacements[key]
except KeyError:
str_type, name = key
cname = replacements[key] = output.get_py_string_const(
StringEncoding.EncodedString(name), identifier=str_type == 'IDENT').cname
return cname
impl = re.sub(r'PY(IDENT|UNICODE)\("([^"]+)"\)', externalise, impl)
assert 'PYIDENT(' not in impl and 'PYUNICODE(' not in impl
return bool(replacements), impl
def inject_unbound_methods(self, impl, output):
"""Replace 'UNBOUND_METHOD(type, "name")' by a constant Python identifier cname.
"""
if 'CALL_UNBOUND_METHOD(' not in impl:
return False, impl
utility_code = set()
def externalise(matchobj):
type_cname, method_name, obj_cname, args = matchobj.groups()
args = [arg.strip() for arg in args[1:].split(',')] if args else []
assert len(args) < 3, "CALL_UNBOUND_METHOD() does not support %d call arguments" % len(args)
return output.cached_unbound_method_call_code(obj_cname, type_cname, method_name, args)
impl = re.sub(
r'CALL_UNBOUND_METHOD\('
r'([a-zA-Z_]+),' # type cname
r'\s*"([^"]+)",' # method name
r'\s*([^),]+)' # object cname
r'((?:,\s*[^),]+)*)' # args*
r'\)', externalise, impl)
assert 'CALL_UNBOUND_METHOD(' not in impl
for helper in sorted(utility_code):
output.use_utility_code(UtilityCode.load_cached(helper, "ObjectHandling.c"))
return bool(utility_code), impl
def wrap_c_strings(self, impl):
"""Replace CSTRING('''xyz''') by a C compatible string
"""
if 'CSTRING(' not in impl:
return impl
def split_string(matchobj):
content = matchobj.group(1).replace('"', '\042')
return ''.join(
'"%s\\n"\n' % line if not line.endswith('\\') or line.endswith('\\\\') else '"%s"\n' % line[:-1]
for line in content.splitlines())
impl = re.sub(r'CSTRING\(\s*"""([^"]*(?:"[^"]+)*)"""\s*\)', split_string, impl)
assert 'CSTRING(' not in impl
return impl
def put_code(self, output):
if self.requires:
for dependency in self.requires:
output.use_utility_code(dependency)
if self.proto:
writer = output[self.proto_block]
writer.putln("/* %s.proto */" % self.name)
writer.put_or_include(
self.format_code(self.proto), '%s_proto' % self.name)
if self.impl:
impl = self.format_code(self.wrap_c_strings(self.impl))
is_specialised1, impl = self.inject_string_constants(impl, output)
is_specialised2, impl = self.inject_unbound_methods(impl, output)
writer = output['utility_code_def']
writer.putln("/* %s */" % self.name)
if not (is_specialised1 or is_specialised2):
# no module specific adaptations => can be reused
writer.put_or_include(impl, '%s_impl' % self.name)
else:
writer.put(impl)
if self.init:
writer = output['init_globals']
writer.putln("/* %s.init */" % self.name)
if isinstance(self.init, basestring):
writer.put(self.format_code(self.init))
else:
self.init(writer, output.module_pos)
writer.putln(writer.error_goto_if_PyErr(output.module_pos))
writer.putln()
if self.cleanup and Options.generate_cleanup_code:
writer = output['cleanup_globals']
writer.putln("/* %s.cleanup */" % self.name)
if isinstance(self.cleanup, basestring):
writer.put_or_include(
self.format_code(self.cleanup),
'%s_cleanup' % self.name)
else:
self.cleanup(writer, output.module_pos)
def sub_tempita(s, context, file=None, name=None):
"Run tempita on string s with given context."
if not s:
return None
if file:
context['__name'] = "%s:%s" % (file, name)
elif name:
context['__name'] = name
from ..Tempita import sub
return sub(s, **context)
class TempitaUtilityCode(UtilityCode):
def __init__(self, name=None, proto=None, impl=None, init=None, file=None, context=None, **kwargs):
if context is None:
context = {}
proto = sub_tempita(proto, context, file, name)
impl = sub_tempita(impl, context, file, name)
init = sub_tempita(init, context, file, name)
super(TempitaUtilityCode, self).__init__(
proto, impl, init=init, name=name, file=file, **kwargs)
@classmethod
def load_cached(cls, utility_code_name, from_file=None, context=None, __cache={}):
context_key = tuple(sorted(context.items())) if context else None
assert hash(context_key) is not None # raise TypeError if not hashable
key = (cls, from_file, utility_code_name, context_key)
try:
return __cache[key]
except KeyError:
pass
code = __cache[key] = cls.load(utility_code_name, from_file, context=context)
return code
def none_or_sub(self, s, context):
"""
Format a string in this utility code with context. If None, do nothing.
"""
if s is None:
return None
return sub_tempita(s, context, self.file, self.name)
class LazyUtilityCode(UtilityCodeBase):
"""
Utility code that calls a callback with the root code writer when
available. Useful when you only have 'env' but not 'code'.
"""
__name__ = '<lazy>'
requires = None
def __init__(self, callback):
self.callback = callback
def put_code(self, globalstate):
utility = self.callback(globalstate.rootwriter)
globalstate.use_utility_code(utility)
class FunctionState(object):
# return_label string function return point label
# error_label string error catch point label
# continue_label string loop continue point label
# break_label string loop break point label
# return_from_error_cleanup_label string
# label_counter integer counter for naming labels
# in_try_finally boolean inside try of try...finally
# exc_vars (string * 3) exception variables for reraise, or None
# can_trace boolean line tracing is supported in the current context
# scope Scope the scope object of the current function
# Not used for now, perhaps later
def __init__(self, owner, names_taken=set(), scope=None):
self.names_taken = names_taken
self.owner = owner
self.scope = scope
self.error_label = None
self.label_counter = 0
self.labels_used = set()
self.return_label = self.new_label()
self.new_error_label()
self.continue_label = None
self.break_label = None
self.yield_labels = []
self.in_try_finally = 0
self.exc_vars = None
self.current_except = None
self.can_trace = False
self.gil_owned = True
self.temps_allocated = [] # of (name, type, manage_ref, static)
self.temps_free = {} # (type, manage_ref) -> list of free vars with same type/managed status
self.temps_used_type = {} # name -> (type, manage_ref)
self.temp_counter = 0
self.closure_temps = None
# This is used to collect temporaries, useful to find out which temps
# need to be privatized in parallel sections
self.collect_temps_stack = []
# This is used for the error indicator, which needs to be local to the
# function. It used to be global, which relies on the GIL being held.
# However, exceptions may need to be propagated through 'nogil'
# sections, in which case we introduce a race condition.
self.should_declare_error_indicator = False
self.uses_error_indicator = False
# labels
def new_label(self, name=None):
n = self.label_counter
self.label_counter = n + 1
label = "%s%d" % (Naming.label_prefix, n)
if name is not None:
label += '_' + name
return label
def new_yield_label(self, expr_type='yield'):
label = self.new_label('resume_from_%s' % expr_type)
num_and_label = (len(self.yield_labels) + 1, label)
self.yield_labels.append(num_and_label)
return num_and_label
def new_error_label(self):
old_err_lbl = self.error_label
self.error_label = self.new_label('error')
return old_err_lbl
def get_loop_labels(self):
return (
self.continue_label,
self.break_label)
def set_loop_labels(self, labels):
(self.continue_label,
self.break_label) = labels
def new_loop_labels(self):
old_labels = self.get_loop_labels()
self.set_loop_labels(
(self.new_label("continue"),
self.new_label("break")))
return old_labels
def get_all_labels(self):
return (
self.continue_label,
self.break_label,
self.return_label,
self.error_label)
def set_all_labels(self, labels):
(self.continue_label,
self.break_label,
self.return_label,
self.error_label) = labels
def all_new_labels(self):
old_labels = self.get_all_labels()
new_labels = []
for old_label, name in zip(old_labels, ['continue', 'break', 'return', 'error']):
if old_label:
new_labels.append(self.new_label(name))
else:
new_labels.append(old_label)
self.set_all_labels(new_labels)
return old_labels
def use_label(self, lbl):
self.labels_used.add(lbl)
def label_used(self, lbl):
return lbl in self.labels_used
# temp handling
def allocate_temp(self, type, manage_ref, static=False):
"""
Allocates a temporary (which may create a new one or get a previously
allocated and released one of the same type). Type is simply registered
and handed back, but will usually be a PyrexType.
If type.is_pyobject, manage_ref comes into play. If manage_ref is set to
True, the temp will be decref-ed on return statements and in exception
handling clauses. Otherwise the caller has to deal with any reference
counting of the variable.
If not type.is_pyobject, then manage_ref will be ignored, but it
still has to be passed. It is recommended to pass False by convention
if it is known that type will never be a Python object.
static=True marks the temporary declaration with "static".
This is only used when allocating backing store for a module-level
C array literals.
A C string referring to the variable is returned.
"""
if type.is_const and not type.is_reference:
type = type.const_base_type
elif type.is_reference and not type.is_fake_reference:
type = type.ref_base_type
elif type.is_cfunction:
from . import PyrexTypes
type = PyrexTypes.c_ptr_type(type) # A function itself isn't an l-value
if not type.is_pyobject and not type.is_memoryviewslice:
# Make manage_ref canonical, so that manage_ref will always mean
# a decref is needed.
manage_ref = False
freelist = self.temps_free.get((type, manage_ref))
if freelist is not None and freelist[0]:
result = freelist[0].pop()
freelist[1].remove(result)
else:
while True:
self.temp_counter += 1
result = "%s%d" % (Naming.codewriter_temp_prefix, self.temp_counter)
if result not in self.names_taken: break
self.temps_allocated.append((result, type, manage_ref, static))
self.temps_used_type[result] = (type, manage_ref)
if DebugFlags.debug_temp_code_comments:
self.owner.putln("/* %s allocated (%s) */" % (result, type))
if self.collect_temps_stack:
self.collect_temps_stack[-1].add((result, type))
return result
def release_temp(self, name):
"""
Releases a temporary so that it can be reused by other code needing
a temp of the same type.
"""
type, manage_ref = self.temps_used_type[name]
freelist = self.temps_free.get((type, manage_ref))
if freelist is None:
freelist = ([], set()) # keep order in list and make lookups in set fast
self.temps_free[(type, manage_ref)] = freelist
if name in freelist[1]:
raise RuntimeError("Temp %s freed twice!" % name)
freelist[0].append(name)
freelist[1].add(name)
if DebugFlags.debug_temp_code_comments:
self.owner.putln("/* %s released */" % name)
def temps_in_use(self):
"""Return a list of (cname,type,manage_ref) tuples of temp names and their type
that are currently in use.
"""
used = []
for name, type, manage_ref, static in self.temps_allocated:
freelist = self.temps_free.get((type, manage_ref))
if freelist is None or name not in freelist[1]:
used.append((name, type, manage_ref and type.is_pyobject))
return used
def temps_holding_reference(self):
"""Return a list of (cname,type) tuples of temp names and their type
that are currently in use. This includes only temps of a
Python object type which owns its reference.
"""
return [(name, type)
for name, type, manage_ref in self.temps_in_use()
if manage_ref and type.is_pyobject]
def all_managed_temps(self):
"""Return a list of (cname, type) tuples of refcount-managed Python objects.
"""
return [(cname, type)
for cname, type, manage_ref, static in self.temps_allocated
if manage_ref]
def all_free_managed_temps(self):
"""Return a list of (cname, type) tuples of refcount-managed Python
objects that are not currently in use. This is used by
try-except and try-finally blocks to clean up temps in the
error case.
"""
return sorted([ # Enforce deterministic order.
(cname, type)
for (type, manage_ref), freelist in self.temps_free.items() if manage_ref
for cname in freelist[0]
])
def start_collecting_temps(self):
"""
Useful to find out which temps were used in a code block
"""
self.collect_temps_stack.append(set())
def stop_collecting_temps(self):
return self.collect_temps_stack.pop()
def init_closure_temps(self, scope):
self.closure_temps = ClosureTempAllocator(scope)
class NumConst(object):
"""Global info about a Python number constant held by GlobalState.
cname string
value string
py_type string int, long, float
value_code string evaluation code if different from value
"""
def __init__(self, cname, value, py_type, value_code=None):
self.cname = cname
self.value = value
self.py_type = py_type
self.value_code = value_code or value
class PyObjectConst(object):
"""Global info about a generic constant held by GlobalState.
"""
# cname string
# type PyrexType
def __init__(self, cname, type):
self.cname = cname
self.type = type
cython.declare(possible_unicode_identifier=object, possible_bytes_identifier=object,
replace_identifier=object, find_alphanums=object)
possible_unicode_identifier = re.compile(br"(?![0-9])\w+$".decode('ascii'), re.U).match
possible_bytes_identifier = re.compile(r"(?![0-9])\w+$".encode('ASCII')).match
replace_identifier = re.compile(r'[^a-zA-Z0-9_]+').sub
find_alphanums = re.compile('([a-zA-Z0-9]+)').findall
class StringConst(object):
"""Global info about a C string constant held by GlobalState.
"""
# cname string
# text EncodedString or BytesLiteral
# py_strings {(identifier, encoding) : PyStringConst}
def __init__(self, cname, text, byte_string):
self.cname = cname
self.text = text
self.escaped_value = StringEncoding.escape_byte_string(byte_string)
self.py_strings = None
self.py_versions = []
def add_py_version(self, version):
if not version:
self.py_versions = [2, 3]
elif version not in self.py_versions:
self.py_versions.append(version)
def get_py_string_const(self, encoding, identifier=None,
is_str=False, py3str_cstring=None):
py_strings = self.py_strings
text = self.text
is_str = bool(identifier or is_str)
is_unicode = encoding is None and not is_str
if encoding is None:
# unicode string
encoding_key = None
else:
# bytes or str
encoding = encoding.lower()
if encoding in ('utf8', 'utf-8', 'ascii', 'usascii', 'us-ascii'):
encoding = None
encoding_key = None
else:
encoding_key = ''.join(find_alphanums(encoding))
key = (is_str, is_unicode, encoding_key, py3str_cstring)
if py_strings is not None:
try:
return py_strings[key]
except KeyError:
pass
else:
self.py_strings = {}
if identifier:
intern = True
elif identifier is None:
if isinstance(text, bytes):
intern = bool(possible_bytes_identifier(text))
else:
intern = bool(possible_unicode_identifier(text))
else:
intern = False
if intern:
prefix = Naming.interned_prefixes['str']
else:
prefix = Naming.py_const_prefix
if encoding_key:
encoding_prefix = '_%s' % encoding_key
else:
encoding_prefix = ''
pystring_cname = "%s%s%s_%s" % (
prefix,
(is_str and 's') or (is_unicode and 'u') or 'b',
encoding_prefix,
self.cname[len(Naming.const_prefix):])
py_string = PyStringConst(
pystring_cname, encoding, is_unicode, is_str, py3str_cstring, intern)
self.py_strings[key] = py_string
return py_string
class PyStringConst(object):
"""Global info about a Python string constant held by GlobalState.
"""
# cname string
# py3str_cstring string
# encoding string
# intern boolean
# is_unicode boolean
# is_str boolean
def __init__(self, cname, encoding, is_unicode, is_str=False,
py3str_cstring=None, intern=False):
self.cname = cname
self.py3str_cstring = py3str_cstring
self.encoding = encoding
self.is_str = is_str
self.is_unicode = is_unicode
self.intern = intern
def __lt__(self, other):
return self.cname < other.cname
class GlobalState(object):
# filename_table {string : int} for finding filename table indexes
# filename_list [string] filenames in filename table order
# input_file_contents dict contents (=list of lines) of any file that was used as input
# to create this output C code. This is
# used to annotate the comments.
#
# utility_codes set IDs of used utility code (to avoid reinsertion)
#
# declared_cnames {string:Entry} used in a transition phase to merge pxd-declared
# constants etc. into the pyx-declared ones (i.e,
# check if constants are already added).
# In time, hopefully the literals etc. will be
# supplied directly instead.
#
# const_cnames_used dict global counter for unique constant identifiers
#
# parts {string:CCodeWriter}
# interned_strings
# consts
# interned_nums
# directives set Temporary variable used to track
# the current set of directives in the code generation
# process.
directives = {}
code_layout = [
'h_code',
'filename_table',
'utility_code_proto_before_types',
'numeric_typedefs', # Let these detailed individual parts stay!,
'complex_type_declarations', # as the proper solution is to make a full DAG...
'type_declarations', # More coarse-grained blocks would simply hide
'utility_code_proto', # the ugliness, not fix it
'module_declarations',
'typeinfo',
'before_global_var',
'global_var',
'string_decls',
'decls',
'late_includes',
'all_the_rest',
'pystring_table',
'cached_builtins',
'cached_constants',
'init_globals',
'init_module',
'cleanup_globals',
'cleanup_module',
'main_method',
'utility_code_def',
'end'
]
def __init__(self, writer, module_node, code_config, common_utility_include_dir=None):
self.filename_table = {}
self.filename_list = []
self.input_file_contents = {}
self.utility_codes = set()
self.declared_cnames = {}
self.in_utility_code_generation = False
self.code_config = code_config
self.common_utility_include_dir = common_utility_include_dir
self.parts = {}
self.module_node = module_node # because some utility code generation needs it
# (generating backwards-compatible Get/ReleaseBuffer
self.const_cnames_used = {}
self.string_const_index = {}
self.dedup_const_index = {}
self.pyunicode_ptr_const_index = {}
self.num_const_index = {}
self.py_constants = []
self.cached_cmethods = {}
self.initialised_constants = set()
writer.set_global_state(self)
self.rootwriter = writer
def initialize_main_c_code(self):
rootwriter = self.rootwriter
for part in self.code_layout:
self.parts[part] = rootwriter.insertion_point()
if not Options.cache_builtins:
del self.parts['cached_builtins']
else:
w = self.parts['cached_builtins']
w.enter_cfunc_scope()
w.putln("static CYTHON_SMALL_CODE int __Pyx_InitCachedBuiltins(void) {")
w = self.parts['cached_constants']
w.enter_cfunc_scope()
w.putln("")
w.putln("static CYTHON_SMALL_CODE int __Pyx_InitCachedConstants(void) {")
w.put_declare_refcount_context()
w.put_setup_refcount_context("__Pyx_InitCachedConstants")
w = self.parts['init_globals']
w.enter_cfunc_scope()
w.putln("")
w.putln("static CYTHON_SMALL_CODE int __Pyx_InitGlobals(void) {")
if not Options.generate_cleanup_code:
del self.parts['cleanup_globals']
else:
w = self.parts['cleanup_globals']
w.enter_cfunc_scope()
w.putln("")
w.putln("static CYTHON_SMALL_CODE void __Pyx_CleanupGlobals(void) {")
code = self.parts['utility_code_proto']
code.putln("")
code.putln("/* --- Runtime support code (head) --- */")
code = self.parts['utility_code_def']
if self.code_config.emit_linenums:
code.write('\n#line 1 "cython_utility"\n')
code.putln("")
code.putln("/* --- Runtime support code --- */")
def finalize_main_c_code(self):
self.close_global_decls()
#
# utility_code_def
#
code = self.parts['utility_code_def']
util = TempitaUtilityCode.load_cached("TypeConversions", "TypeConversion.c")
code.put(util.format_code(util.impl))
code.putln("")
def __getitem__(self, key):
return self.parts[key]
#
# Global constants, interned objects, etc.
#
def close_global_decls(self):
# This is called when it is known that no more global declarations will
# declared.
self.generate_const_declarations()
if Options.cache_builtins:
w = self.parts['cached_builtins']
w.putln("return 0;")
if w.label_used(w.error_label):
w.put_label(w.error_label)
w.putln("return -1;")
w.putln("}")
w.exit_cfunc_scope()
w = self.parts['cached_constants']
w.put_finish_refcount_context()
w.putln("return 0;")
if w.label_used(w.error_label):
w.put_label(w.error_label)
w.put_finish_refcount_context()
w.putln("return -1;")
w.putln("}")
w.exit_cfunc_scope()
w = self.parts['init_globals']
w.putln("return 0;")
if w.label_used(w.error_label):
w.put_label(w.error_label)
w.putln("return -1;")
w.putln("}")
w.exit_cfunc_scope()
if Options.generate_cleanup_code:
w = self.parts['cleanup_globals']
w.putln("}")
w.exit_cfunc_scope()
if Options.generate_cleanup_code:
w = self.parts['cleanup_module']
w.putln("}")
w.exit_cfunc_scope()
def put_pyobject_decl(self, entry):
self['global_var'].putln("static PyObject *%s;" % entry.cname)
# constant handling at code generation time
def get_cached_constants_writer(self, target=None):
if target is not None:
if target in self.initialised_constants:
# Return None on second/later calls to prevent duplicate creation code.
return None
self.initialised_constants.add(target)
return self.parts['cached_constants']
def get_int_const(self, str_value, longness=False):
py_type = longness and 'long' or 'int'
try:
c = self.num_const_index[(str_value, py_type)]
except KeyError:
c = self.new_num_const(str_value, py_type)
return c
def get_float_const(self, str_value, value_code):
try:
c = self.num_const_index[(str_value, 'float')]
except KeyError:
c = self.new_num_const(str_value, 'float', value_code)
return c
def get_py_const(self, type, prefix='', cleanup_level=None, dedup_key=None):
if dedup_key is not None:
const = self.dedup_const_index.get(dedup_key)
if const is not None:
return const
# create a new Python object constant
const = self.new_py_const(type, prefix)
if cleanup_level is not None \
and cleanup_level <= Options.generate_cleanup_code:
cleanup_writer = self.parts['cleanup_globals']
cleanup_writer.putln('Py_CLEAR(%s);' % const.cname)
if dedup_key is not None:
self.dedup_const_index[dedup_key] = const
return const
def get_string_const(self, text, py_version=None):
# return a C string constant, creating a new one if necessary
if text.is_unicode:
byte_string = text.utf8encode()
else:
byte_string = text.byteencode()
try:
c = self.string_const_index[byte_string]
except KeyError:
c = self.new_string_const(text, byte_string)
c.add_py_version(py_version)
return c
def get_pyunicode_ptr_const(self, text):
# return a Py_UNICODE[] constant, creating a new one if necessary
assert text.is_unicode
try:
c = self.pyunicode_ptr_const_index[text]
except KeyError:
c = self.pyunicode_ptr_const_index[text] = self.new_const_cname()
return c
def get_py_string_const(self, text, identifier=None,
is_str=False, unicode_value=None):
# return a Python string constant, creating a new one if necessary
py3str_cstring = None
if is_str and unicode_value is not None \
and unicode_value.utf8encode() != text.byteencode():
py3str_cstring = self.get_string_const(unicode_value, py_version=3)
c_string = self.get_string_const(text, py_version=2)
else:
c_string = self.get_string_const(text)
py_string = c_string.get_py_string_const(
text.encoding, identifier, is_str, py3str_cstring)
return py_string
def get_interned_identifier(self, text):
return self.get_py_string_const(text, identifier=True)
def new_string_const(self, text, byte_string):
cname = self.new_string_const_cname(byte_string)
c = StringConst(cname, text, byte_string)
self.string_const_index[byte_string] = c
return c
def new_num_const(self, value, py_type, value_code=None):
cname = self.new_num_const_cname(value, py_type)
c = NumConst(cname, value, py_type, value_code)
self.num_const_index[(value, py_type)] = c
return c
def new_py_const(self, type, prefix=''):
cname = self.new_const_cname(prefix)
c = PyObjectConst(cname, type)
self.py_constants.append(c)
return c
def new_string_const_cname(self, bytes_value):
# Create a new globally-unique nice name for a C string constant.
value = bytes_value.decode('ASCII', 'ignore')
return self.new_const_cname(value=value)
def new_num_const_cname(self, value, py_type):
if py_type == 'long':
value += 'L'
py_type = 'int'
prefix = Naming.interned_prefixes[py_type]
cname = "%s%s" % (prefix, value)
cname = cname.replace('+', '_').replace('-', 'neg_').replace('.', '_')
return cname
def new_const_cname(self, prefix='', value=''):
value = replace_identifier('_', value)[:32].strip('_')
used = self.const_cnames_used
name_suffix = value
while name_suffix in used:
counter = used[value] = used[value] + 1
name_suffix = '%s_%d' % (value, counter)
used[name_suffix] = 1
if prefix:
prefix = Naming.interned_prefixes[prefix]
else:
prefix = Naming.const_prefix
return "%s%s" % (prefix, name_suffix)
def get_cached_unbound_method(self, type_cname, method_name):
key = (type_cname, method_name)
try:
cname = self.cached_cmethods[key]
except KeyError:
cname = self.cached_cmethods[key] = self.new_const_cname(
'umethod', '%s_%s' % (type_cname, method_name))
return cname
def cached_unbound_method_call_code(self, obj_cname, type_cname, method_name, arg_cnames):
# admittedly, not the best place to put this method, but it is reused by UtilityCode and ExprNodes ...
utility_code_name = "CallUnboundCMethod%d" % len(arg_cnames)
self.use_utility_code(UtilityCode.load_cached(utility_code_name, "ObjectHandling.c"))
cache_cname = self.get_cached_unbound_method(type_cname, method_name)
args = [obj_cname] + arg_cnames
return "__Pyx_%s(&%s, %s)" % (
utility_code_name,
cache_cname,
', '.join(args),
)
def add_cached_builtin_decl(self, entry):
if entry.is_builtin and entry.is_const:
if self.should_declare(entry.cname, entry):
self.put_pyobject_decl(entry)
w = self.parts['cached_builtins']
condition = None
if entry.name in non_portable_builtins_map:
condition, replacement = non_portable_builtins_map[entry.name]
w.putln('#if %s' % condition)
self.put_cached_builtin_init(
entry.pos, StringEncoding.EncodedString(replacement),
entry.cname)
w.putln('#else')
self.put_cached_builtin_init(
entry.pos, StringEncoding.EncodedString(entry.name),
entry.cname)
if condition:
w.putln('#endif')
def put_cached_builtin_init(self, pos, name, cname):
w = self.parts['cached_builtins']
interned_cname = self.get_interned_identifier(name).cname
self.use_utility_code(
UtilityCode.load_cached("GetBuiltinName", "ObjectHandling.c"))
w.putln('%s = __Pyx_GetBuiltinName(%s); if (!%s) %s' % (
cname,
interned_cname,
cname,
w.error_goto(pos)))
def generate_const_declarations(self):
self.generate_cached_methods_decls()
self.generate_string_constants()
self.generate_num_constants()
self.generate_object_constant_decls()
def generate_object_constant_decls(self):
consts = [(len(c.cname), c.cname, c)
for c in self.py_constants]
consts.sort()
decls_writer = self.parts['decls']
for _, cname, c in consts:
decls_writer.putln(
"static %s;" % c.type.declaration_code(cname))
def generate_cached_methods_decls(self):
if not self.cached_cmethods:
return
decl = self.parts['decls']
init = self.parts['init_globals']
cnames = []
for (type_cname, method_name), cname in sorted(self.cached_cmethods.items()):
cnames.append(cname)
method_name_cname = self.get_interned_identifier(StringEncoding.EncodedString(method_name)).cname
decl.putln('static __Pyx_CachedCFunction %s = {0, &%s, 0, 0, 0};' % (
cname, method_name_cname))
# split type reference storage as it might not be static
init.putln('%s.type = (PyObject*)&%s;' % (
cname, type_cname))
if Options.generate_cleanup_code:
cleanup = self.parts['cleanup_globals']
for cname in cnames:
cleanup.putln("Py_CLEAR(%s.method);" % cname)
def generate_string_constants(self):
c_consts = [(len(c.cname), c.cname, c) for c in self.string_const_index.values()]
c_consts.sort()
py_strings = []
decls_writer = self.parts['string_decls']
for _, cname, c in c_consts:
conditional = False
if c.py_versions and (2 not in c.py_versions or 3 not in c.py_versions):
conditional = True
decls_writer.putln("#if PY_MAJOR_VERSION %s 3" % (
(2 in c.py_versions) and '<' or '>='))
decls_writer.putln('static const char %s[] = "%s";' % (
cname, StringEncoding.split_string_literal(c.escaped_value)))
if conditional:
decls_writer.putln("#endif")
if c.py_strings is not None:
for py_string in c.py_strings.values():
py_strings.append((c.cname, len(py_string.cname), py_string))
for c, cname in sorted(self.pyunicode_ptr_const_index.items()):
utf16_array, utf32_array = StringEncoding.encode_pyunicode_string(c)
if utf16_array:
# Narrow and wide representations differ
decls_writer.putln("#ifdef Py_UNICODE_WIDE")
decls_writer.putln("static Py_UNICODE %s[] = { %s };" % (cname, utf32_array))
if utf16_array:
decls_writer.putln("#else")
decls_writer.putln("static Py_UNICODE %s[] = { %s };" % (cname, utf16_array))
decls_writer.putln("#endif")
if py_strings:
self.use_utility_code(UtilityCode.load_cached("InitStrings", "StringTools.c"))
py_strings.sort()
w = self.parts['pystring_table']
w.putln("")
w.putln("static __Pyx_StringTabEntry %s[] = {" % Naming.stringtab_cname)
for c_cname, _, py_string in py_strings:
if not py_string.is_str or not py_string.encoding or \
py_string.encoding in ('ASCII', 'USASCII', 'US-ASCII',
'UTF8', 'UTF-8'):
encoding = '0'
else:
encoding = '"%s"' % py_string.encoding.lower()
decls_writer.putln(
"static PyObject *%s;" % py_string.cname)
if py_string.py3str_cstring:
w.putln("#if PY_MAJOR_VERSION >= 3")
w.putln("{&%s, %s, sizeof(%s), %s, %d, %d, %d}," % (
py_string.cname,
py_string.py3str_cstring.cname,
py_string.py3str_cstring.cname,
'0', 1, 0,
py_string.intern
))
w.putln("#else")
w.putln("{&%s, %s, sizeof(%s), %s, %d, %d, %d}," % (
py_string.cname,
c_cname,
c_cname,
encoding,
py_string.is_unicode,
py_string.is_str,
py_string.intern
))
if py_string.py3str_cstring:
w.putln("#endif")
w.putln("{0, 0, 0, 0, 0, 0, 0}")
w.putln("};")
init_globals = self.parts['init_globals']
init_globals.putln(
"if (__Pyx_InitStrings(%s) < 0) %s;" % (
Naming.stringtab_cname,
init_globals.error_goto(self.module_pos)))
def generate_num_constants(self):
consts = [(c.py_type, c.value[0] == '-', len(c.value), c.value, c.value_code, c)
for c in self.num_const_index.values()]
consts.sort()
decls_writer = self.parts['decls']
init_globals = self.parts['init_globals']
for py_type, _, _, value, value_code, c in consts:
cname = c.cname
decls_writer.putln("static PyObject *%s;" % cname)
if py_type == 'float':
function = 'PyFloat_FromDouble(%s)'
elif py_type == 'long':
function = 'PyLong_FromString((char *)"%s", 0, 0)'
elif Utils.long_literal(value):
function = 'PyInt_FromString((char *)"%s", 0, 0)'
elif len(value.lstrip('-')) > 4:
function = "PyInt_FromLong(%sL)"
else:
function = "PyInt_FromLong(%s)"
init_globals.putln('%s = %s; %s' % (
cname, function % value_code,
init_globals.error_goto_if_null(cname, self.module_pos)))
# The functions below are there in a transition phase only
# and will be deprecated. They are called from Nodes.BlockNode.
# The copy&paste duplication is intentional in order to be able
# to see quickly how BlockNode worked, until this is replaced.
def should_declare(self, cname, entry):
if cname in self.declared_cnames:
other = self.declared_cnames[cname]
assert str(entry.type) == str(other.type)
assert entry.init == other.init
return False
else:
self.declared_cnames[cname] = entry
return True
#
# File name state
#
def lookup_filename(self, source_desc):
entry = source_desc.get_filenametable_entry()
try:
index = self.filename_table[entry]
except KeyError:
index = len(self.filename_list)
self.filename_list.append(source_desc)
self.filename_table[entry] = index
return index
def commented_file_contents(self, source_desc):
try:
return self.input_file_contents[source_desc]
except KeyError:
pass
source_file = source_desc.get_lines(encoding='ASCII',
error_handling='ignore')
try:
F = [u' * ' + line.rstrip().replace(
u'*/', u'*[inserted by cython to avoid comment closer]/'
).replace(
u'/*', u'/[inserted by cython to avoid comment start]*'
)
for line in source_file]
finally:
if hasattr(source_file, 'close'):
source_file.close()
if not F: F.append(u'')
self.input_file_contents[source_desc] = F
return F
#
# Utility code state
#
def use_utility_code(self, utility_code):
"""
Adds code to the C file. utility_code should
a) implement __eq__/__hash__ for the purpose of knowing whether the same
code has already been included
b) implement put_code, which takes a globalstate instance
See UtilityCode.
"""
if utility_code and utility_code not in self.utility_codes:
self.utility_codes.add(utility_code)
utility_code.put_code(self)
def use_entry_utility_code(self, entry):
if entry is None:
return
if entry.utility_code:
self.use_utility_code(entry.utility_code)
if entry.utility_code_definition:
self.use_utility_code(entry.utility_code_definition)
def funccontext_property(func):
name = func.__name__
attribute_of = operator.attrgetter(name)
def get(self):
return attribute_of(self.funcstate)
def set(self, value):
setattr(self.funcstate, name, value)
return property(get, set)
class CCodeConfig(object):
# emit_linenums boolean write #line pragmas?
# emit_code_comments boolean copy the original code into C comments?
# c_line_in_traceback boolean append the c file and line number to the traceback for exceptions?
def __init__(self, emit_linenums=True, emit_code_comments=True, c_line_in_traceback=True):
self.emit_code_comments = emit_code_comments
self.emit_linenums = emit_linenums
self.c_line_in_traceback = c_line_in_traceback
class CCodeWriter(object):
"""
Utility class to output C code.
When creating an insertion point one must care about the state that is
kept:
- formatting state (level, bol) is cloned and used in insertion points
as well
- labels, temps, exc_vars: One must construct a scope in which these can
exist by calling enter_cfunc_scope/exit_cfunc_scope (these are for
sanity checking and forward compatibility). Created insertion points
looses this scope and cannot access it.
- marker: Not copied to insertion point
- filename_table, filename_list, input_file_contents: All codewriters
coming from the same root share the same instances simultaneously.
"""
# f file output file
# buffer StringIOTree
# level int indentation level
# bol bool beginning of line?
# marker string comment to emit before next line
# funcstate FunctionState contains state local to a C function used for code
# generation (labels and temps state etc.)
# globalstate GlobalState contains state global for a C file (input file info,
# utility code, declared constants etc.)
# pyclass_stack list used during recursive code generation to pass information
# about the current class one is in
# code_config CCodeConfig configuration options for the C code writer
@cython.locals(create_from='CCodeWriter')
def __init__(self, create_from=None, buffer=None, copy_formatting=False):
if buffer is None: buffer = StringIOTree()
self.buffer = buffer
self.last_pos = None
self.last_marked_pos = None
self.pyclass_stack = []
self.funcstate = None
self.globalstate = None
self.code_config = None
self.level = 0
self.call_level = 0
self.bol = 1
if create_from is not None:
# Use same global state
self.set_global_state(create_from.globalstate)
self.funcstate = create_from.funcstate
# Clone formatting state
if copy_formatting:
self.level = create_from.level
self.bol = create_from.bol
self.call_level = create_from.call_level
self.last_pos = create_from.last_pos
self.last_marked_pos = create_from.last_marked_pos
def create_new(self, create_from, buffer, copy_formatting):
# polymorphic constructor -- very slightly more versatile
# than using __class__
result = CCodeWriter(create_from, buffer, copy_formatting)
return result
def set_global_state(self, global_state):
assert self.globalstate is None # prevent overwriting once it's set
self.globalstate = global_state
self.code_config = global_state.code_config
def copyto(self, f):
self.buffer.copyto(f)
def getvalue(self):
return self.buffer.getvalue()
def write(self, s):
# also put invalid markers (lineno 0), to indicate that those lines
# have no Cython source code correspondence
cython_lineno = self.last_marked_pos[1] if self.last_marked_pos else 0
self.buffer.markers.extend([cython_lineno] * s.count('\n'))
self.buffer.write(s)
def insertion_point(self):
other = self.create_new(create_from=self, buffer=self.buffer.insertion_point(), copy_formatting=True)
return other
def new_writer(self):
"""
Creates a new CCodeWriter connected to the same global state, which
can later be inserted using insert.
"""
return CCodeWriter(create_from=self)
def insert(self, writer):
"""
Inserts the contents of another code writer (created with
the same global state) in the current location.
It is ok to write to the inserted writer also after insertion.
"""
assert writer.globalstate is self.globalstate
self.buffer.insert(writer.buffer)
# Properties delegated to function scope
@funccontext_property
def label_counter(self): pass
@funccontext_property
def return_label(self): pass
@funccontext_property
def error_label(self): pass
@funccontext_property
def labels_used(self): pass
@funccontext_property
def continue_label(self): pass
@funccontext_property
def break_label(self): pass
@funccontext_property
def return_from_error_cleanup_label(self): pass
@funccontext_property
def yield_labels(self): pass
# Functions delegated to function scope
def new_label(self, name=None): return self.funcstate.new_label(name)
def new_error_label(self): return self.funcstate.new_error_label()
def new_yield_label(self, *args): return self.funcstate.new_yield_label(*args)
def get_loop_labels(self): return self.funcstate.get_loop_labels()
def set_loop_labels(self, labels): return self.funcstate.set_loop_labels(labels)
def new_loop_labels(self): return self.funcstate.new_loop_labels()
def get_all_labels(self): return self.funcstate.get_all_labels()
def set_all_labels(self, labels): return self.funcstate.set_all_labels(labels)
def all_new_labels(self): return self.funcstate.all_new_labels()
def use_label(self, lbl): return self.funcstate.use_label(lbl)
def label_used(self, lbl): return self.funcstate.label_used(lbl)
def enter_cfunc_scope(self, scope=None):
self.funcstate = FunctionState(self, scope=scope)
def exit_cfunc_scope(self):
self.funcstate = None
# constant handling
def get_py_int(self, str_value, longness):
return self.globalstate.get_int_const(str_value, longness).cname
def get_py_float(self, str_value, value_code):
return self.globalstate.get_float_const(str_value, value_code).cname
def get_py_const(self, type, prefix='', cleanup_level=None, dedup_key=None):
return self.globalstate.get_py_const(type, prefix, cleanup_level, dedup_key).cname
def get_string_const(self, text):
return self.globalstate.get_string_const(text).cname
def get_pyunicode_ptr_const(self, text):
return self.globalstate.get_pyunicode_ptr_const(text)
def get_py_string_const(self, text, identifier=None,
is_str=False, unicode_value=None):
return self.globalstate.get_py_string_const(
text, identifier, is_str, unicode_value).cname
def get_argument_default_const(self, type):
return self.globalstate.get_py_const(type).cname
def intern(self, text):
return self.get_py_string_const(text)
def intern_identifier(self, text):
return self.get_py_string_const(text, identifier=True)
def get_cached_constants_writer(self, target=None):
return self.globalstate.get_cached_constants_writer(target)
# code generation
def putln(self, code="", safe=False):
if self.last_pos and self.bol:
self.emit_marker()
if self.code_config.emit_linenums and self.last_marked_pos:
source_desc, line, _ = self.last_marked_pos
self.write('\n#line %s "%s"\n' % (line, source_desc.get_escaped_description()))
if code:
if safe:
self.put_safe(code)
else:
self.put(code)
self.write("\n")
self.bol = 1
def mark_pos(self, pos, trace=True):
if pos is None:
return
if self.last_marked_pos and self.last_marked_pos[:2] == pos[:2]:
return
self.last_pos = (pos, trace)
def emit_marker(self):
pos, trace = self.last_pos
self.last_marked_pos = pos
self.last_pos = None
self.write("\n")
if self.code_config.emit_code_comments:
self.indent()
self.write("/* %s */\n" % self._build_marker(pos))
if trace and self.funcstate and self.funcstate.can_trace and self.globalstate.directives['linetrace']:
self.indent()
self.write('__Pyx_TraceLine(%d,%d,%s)\n' % (
pos[1], not self.funcstate.gil_owned, self.error_goto(pos)))
def _build_marker(self, pos):
source_desc, line, col = pos
assert isinstance(source_desc, SourceDescriptor)
contents = self.globalstate.commented_file_contents(source_desc)
lines = contents[max(0, line-3):line] # line numbers start at 1
lines[-1] += u' # <<<<<<<<<<<<<<'
lines += contents[line:line+2]
return u'"%s":%d\n%s\n' % (source_desc.get_escaped_description(), line, u'\n'.join(lines))
def put_safe(self, code):
# put code, but ignore {}
self.write(code)
self.bol = 0
def put_or_include(self, code, name):
include_dir = self.globalstate.common_utility_include_dir
if include_dir and len(code) > 1024:
include_file = "%s_%s.h" % (
name, hashlib.md5(code.encode('utf8')).hexdigest())
path = os.path.join(include_dir, include_file)
if not os.path.exists(path):
tmp_path = '%s.tmp%s' % (path, os.getpid())
with closing(Utils.open_new_file(tmp_path)) as f:
f.write(code)
shutil.move(tmp_path, path)
code = '#include "%s"\n' % path
self.put(code)
def put(self, code):
fix_indent = False
if "{" in code:
dl = code.count("{")
else:
dl = 0
if "}" in code:
dl -= code.count("}")
if dl < 0:
self.level += dl
elif dl == 0 and code[0] == "}":
# special cases like "} else {" need a temporary dedent
fix_indent = True
self.level -= 1
if self.bol:
self.indent()
self.write(code)
self.bol = 0
if dl > 0:
self.level += dl
elif fix_indent:
self.level += 1
def putln_tempita(self, code, **context):
from ..Tempita import sub
self.putln(sub(code, **context))
def put_tempita(self, code, **context):
from ..Tempita import sub
self.put(sub(code, **context))
def increase_indent(self):
self.level += 1
def decrease_indent(self):
self.level -= 1
def begin_block(self):
self.putln("{")
self.increase_indent()
def end_block(self):
self.decrease_indent()
self.putln("}")
def indent(self):
self.write(" " * self.level)
def get_py_version_hex(self, pyversion):
return "0x%02X%02X%02X%02X" % (tuple(pyversion) + (0,0,0,0))[:4]
def put_label(self, lbl):
if lbl in self.funcstate.labels_used:
self.putln("%s:;" % lbl)
def put_goto(self, lbl):
self.funcstate.use_label(lbl)
self.putln("goto %s;" % lbl)
def put_var_declaration(self, entry, storage_class="",
dll_linkage=None, definition=True):
#print "Code.put_var_declaration:", entry.name, "definition =", definition ###
if entry.visibility == 'private' and not (definition or entry.defined_in_pxd):
#print "...private and not definition, skipping", entry.cname ###
return
if entry.visibility == "private" and not entry.used:
#print "...private and not used, skipping", entry.cname ###
return
if storage_class:
self.put("%s " % storage_class)
if not entry.cf_used:
self.put('CYTHON_UNUSED ')
self.put(entry.type.declaration_code(
entry.cname, dll_linkage=dll_linkage))
if entry.init is not None:
self.put_safe(" = %s" % entry.type.literal_code(entry.init))
elif entry.type.is_pyobject:
self.put(" = NULL")
self.putln(";")
def put_temp_declarations(self, func_context):
for name, type, manage_ref, static in func_context.temps_allocated:
decl = type.declaration_code(name)
if type.is_pyobject:
self.putln("%s = NULL;" % decl)
elif type.is_memoryviewslice:
from . import MemoryView
self.putln("%s = %s;" % (decl, MemoryView.memslice_entry_init))
else:
self.putln("%s%s;" % (static and "static " or "", decl))
if func_context.should_declare_error_indicator:
if self.funcstate.uses_error_indicator:
unused = ''
else:
unused = 'CYTHON_UNUSED '
# Initialize these variables to silence compiler warnings
self.putln("%sint %s = 0;" % (unused, Naming.lineno_cname))
self.putln("%sconst char *%s = NULL;" % (unused, Naming.filename_cname))
self.putln("%sint %s = 0;" % (unused, Naming.clineno_cname))
def put_generated_by(self):
self.putln("/* Generated by Cython %s */" % Version.watermark)
self.putln("")
def put_h_guard(self, guard):
self.putln("#ifndef %s" % guard)
self.putln("#define %s" % guard)
def unlikely(self, cond):
if Options.gcc_branch_hints:
return 'unlikely(%s)' % cond
else:
return cond
def build_function_modifiers(self, modifiers, mapper=modifier_output_mapper):
if not modifiers:
return ''
return '%s ' % ' '.join([mapper(m,m) for m in modifiers])
# Python objects and reference counting
def entry_as_pyobject(self, entry):
type = entry.type
if (not entry.is_self_arg and not entry.type.is_complete()
or entry.type.is_extension_type):
return "(PyObject *)" + entry.cname
else:
return entry.cname
def as_pyobject(self, cname, type):
from .PyrexTypes import py_object_type, typecast
return typecast(py_object_type, type, cname)
def put_gotref(self, cname):
self.putln("__Pyx_GOTREF(%s);" % cname)
def put_giveref(self, cname):
self.putln("__Pyx_GIVEREF(%s);" % cname)
def put_xgiveref(self, cname):
self.putln("__Pyx_XGIVEREF(%s);" % cname)
def put_xgotref(self, cname):
self.putln("__Pyx_XGOTREF(%s);" % cname)
def put_incref(self, cname, type, nanny=True):
if nanny:
self.putln("__Pyx_INCREF(%s);" % self.as_pyobject(cname, type))
else:
self.putln("Py_INCREF(%s);" % self.as_pyobject(cname, type))
def put_decref(self, cname, type, nanny=True):
self._put_decref(cname, type, nanny, null_check=False, clear=False)
def put_var_gotref(self, entry):
if entry.type.is_pyobject:
self.putln("__Pyx_GOTREF(%s);" % self.entry_as_pyobject(entry))
def put_var_giveref(self, entry):
if entry.type.is_pyobject:
self.putln("__Pyx_GIVEREF(%s);" % self.entry_as_pyobject(entry))
def put_var_xgotref(self, entry):
if entry.type.is_pyobject:
self.putln("__Pyx_XGOTREF(%s);" % self.entry_as_pyobject(entry))
def put_var_xgiveref(self, entry):
if entry.type.is_pyobject:
self.putln("__Pyx_XGIVEREF(%s);" % self.entry_as_pyobject(entry))
def put_var_incref(self, entry, nanny=True):
if entry.type.is_pyobject:
if nanny:
self.putln("__Pyx_INCREF(%s);" % self.entry_as_pyobject(entry))
else:
self.putln("Py_INCREF(%s);" % self.entry_as_pyobject(entry))
def put_var_xincref(self, entry):
if entry.type.is_pyobject:
self.putln("__Pyx_XINCREF(%s);" % self.entry_as_pyobject(entry))
def put_decref_clear(self, cname, type, nanny=True, clear_before_decref=False):
self._put_decref(cname, type, nanny, null_check=False,
clear=True, clear_before_decref=clear_before_decref)
def put_xdecref(self, cname, type, nanny=True, have_gil=True):
self._put_decref(cname, type, nanny, null_check=True,
have_gil=have_gil, clear=False)
def put_xdecref_clear(self, cname, type, nanny=True, clear_before_decref=False):
self._put_decref(cname, type, nanny, null_check=True,
clear=True, clear_before_decref=clear_before_decref)
def _put_decref(self, cname, type, nanny=True, null_check=False,
have_gil=True, clear=False, clear_before_decref=False):
if type.is_memoryviewslice:
self.put_xdecref_memoryviewslice(cname, have_gil=have_gil)
return
prefix = '__Pyx' if nanny else 'Py'
X = 'X' if null_check else ''
if clear:
if clear_before_decref:
if not nanny:
X = '' # CPython doesn't have a Py_XCLEAR()
self.putln("%s_%sCLEAR(%s);" % (prefix, X, cname))
else:
self.putln("%s_%sDECREF(%s); %s = 0;" % (
prefix, X, self.as_pyobject(cname, type), cname))
else:
self.putln("%s_%sDECREF(%s);" % (
prefix, X, self.as_pyobject(cname, type)))
def put_decref_set(self, cname, rhs_cname):
self.putln("__Pyx_DECREF_SET(%s, %s);" % (cname, rhs_cname))
def put_xdecref_set(self, cname, rhs_cname):
self.putln("__Pyx_XDECREF_SET(%s, %s);" % (cname, rhs_cname))
def put_var_decref(self, entry):
if entry.type.is_pyobject:
self.putln("__Pyx_XDECREF(%s);" % self.entry_as_pyobject(entry))
def put_var_xdecref(self, entry, nanny=True):
if entry.type.is_pyobject:
if nanny:
self.putln("__Pyx_XDECREF(%s);" % self.entry_as_pyobject(entry))
else:
self.putln("Py_XDECREF(%s);" % self.entry_as_pyobject(entry))
def put_var_decref_clear(self, entry):
self._put_var_decref_clear(entry, null_check=False)
def put_var_xdecref_clear(self, entry):
self._put_var_decref_clear(entry, null_check=True)
def _put_var_decref_clear(self, entry, null_check):
if entry.type.is_pyobject:
if entry.in_closure:
# reset before DECREF to make sure closure state is
# consistent during call to DECREF()
self.putln("__Pyx_%sCLEAR(%s);" % (
null_check and 'X' or '',
entry.cname))
else:
self.putln("__Pyx_%sDECREF(%s); %s = 0;" % (
null_check and 'X' or '',
self.entry_as_pyobject(entry),
entry.cname))
def put_var_decrefs(self, entries, used_only = 0):
for entry in entries:
if not used_only or entry.used:
if entry.xdecref_cleanup:
self.put_var_xdecref(entry)
else:
self.put_var_decref(entry)
def put_var_xdecrefs(self, entries):
for entry in entries:
self.put_var_xdecref(entry)
def put_var_xdecrefs_clear(self, entries):
for entry in entries:
self.put_var_xdecref_clear(entry)
def put_incref_memoryviewslice(self, slice_cname, have_gil=False):
from . import MemoryView
self.globalstate.use_utility_code(MemoryView.memviewslice_init_code)
self.putln("__PYX_INC_MEMVIEW(&%s, %d);" % (slice_cname, int(have_gil)))
def put_xdecref_memoryviewslice(self, slice_cname, have_gil=False):
from . import MemoryView
self.globalstate.use_utility_code(MemoryView.memviewslice_init_code)
self.putln("__PYX_XDEC_MEMVIEW(&%s, %d);" % (slice_cname, int(have_gil)))
def put_xgiveref_memoryviewslice(self, slice_cname):
self.put_xgiveref("%s.memview" % slice_cname)
def put_init_to_py_none(self, cname, type, nanny=True):
from .PyrexTypes import py_object_type, typecast
py_none = typecast(type, py_object_type, "Py_None")
if nanny:
self.putln("%s = %s; __Pyx_INCREF(Py_None);" % (cname, py_none))
else:
self.putln("%s = %s; Py_INCREF(Py_None);" % (cname, py_none))
def put_init_var_to_py_none(self, entry, template = "%s", nanny=True):
code = template % entry.cname
#if entry.type.is_extension_type:
# code = "((PyObject*)%s)" % code
self.put_init_to_py_none(code, entry.type, nanny)
if entry.in_closure:
self.put_giveref('Py_None')
def put_pymethoddef(self, entry, term, allow_skip=True, wrapper_code_writer=None):
if entry.is_special or entry.name == '__getattribute__':
if entry.name not in special_py_methods:
if entry.name == '__getattr__' and not self.globalstate.directives['fast_getattr']:
pass
# Python's typeobject.c will automatically fill in our slot
# in add_operators() (called by PyType_Ready) with a value
# that's better than ours.
elif allow_skip:
return
method_flags = entry.signature.method_flags()
if not method_flags:
return
if entry.is_special:
from . import TypeSlots
method_flags += [TypeSlots.method_coexist]
func_ptr = wrapper_code_writer.put_pymethoddef_wrapper(entry) if wrapper_code_writer else entry.func_cname
# Add required casts, but try not to shadow real warnings.
cast = '__Pyx_PyCFunctionFast' if 'METH_FASTCALL' in method_flags else 'PyCFunction'
if 'METH_KEYWORDS' in method_flags:
cast += 'WithKeywords'
if cast != 'PyCFunction':
func_ptr = '(void*)(%s)%s' % (cast, func_ptr)
self.putln(
'{"%s", (PyCFunction)%s, %s, %s}%s' % (
entry.name,
func_ptr,
"|".join(method_flags),
entry.doc_cname if entry.doc else '0',
term))
def put_pymethoddef_wrapper(self, entry):
func_cname = entry.func_cname
if entry.is_special:
method_flags = entry.signature.method_flags()
if method_flags and 'METH_NOARGS' in method_flags:
# Special NOARGS methods really take no arguments besides 'self', but PyCFunction expects one.
func_cname = Naming.method_wrapper_prefix + func_cname
self.putln("static PyObject *%s(PyObject *self, CYTHON_UNUSED PyObject *arg) {return %s(self);}" % (
func_cname, entry.func_cname))
return func_cname
# GIL methods
def put_ensure_gil(self, declare_gilstate=True, variable=None):
"""
Acquire the GIL. The generated code is safe even when no PyThreadState
has been allocated for this thread (for threads not initialized by
using the Python API). Additionally, the code generated by this method
may be called recursively.
"""
self.globalstate.use_utility_code(
UtilityCode.load_cached("ForceInitThreads", "ModuleSetupCode.c"))
if self.globalstate.directives['fast_gil']:
self.globalstate.use_utility_code(UtilityCode.load_cached("FastGil", "ModuleSetupCode.c"))
else:
self.globalstate.use_utility_code(UtilityCode.load_cached("NoFastGil", "ModuleSetupCode.c"))
self.putln("#ifdef WITH_THREAD")
if not variable:
variable = '__pyx_gilstate_save'
if declare_gilstate:
self.put("PyGILState_STATE ")
self.putln("%s = __Pyx_PyGILState_Ensure();" % variable)
self.putln("#endif")
def put_release_ensured_gil(self, variable=None):
"""
Releases the GIL, corresponds to `put_ensure_gil`.
"""
if self.globalstate.directives['fast_gil']:
self.globalstate.use_utility_code(UtilityCode.load_cached("FastGil", "ModuleSetupCode.c"))
else:
self.globalstate.use_utility_code(UtilityCode.load_cached("NoFastGil", "ModuleSetupCode.c"))
if not variable:
variable = '__pyx_gilstate_save'
self.putln("#ifdef WITH_THREAD")
self.putln("__Pyx_PyGILState_Release(%s);" % variable)
self.putln("#endif")
def put_acquire_gil(self, variable=None):
"""
Acquire the GIL. The thread's thread state must have been initialized
by a previous `put_release_gil`
"""
if self.globalstate.directives['fast_gil']:
self.globalstate.use_utility_code(UtilityCode.load_cached("FastGil", "ModuleSetupCode.c"))
else:
self.globalstate.use_utility_code(UtilityCode.load_cached("NoFastGil", "ModuleSetupCode.c"))
self.putln("#ifdef WITH_THREAD")
self.putln("__Pyx_FastGIL_Forget();")
if variable:
self.putln('_save = %s;' % variable)
self.putln("Py_BLOCK_THREADS")
self.putln("#endif")
def put_release_gil(self, variable=None):
"Release the GIL, corresponds to `put_acquire_gil`."
if self.globalstate.directives['fast_gil']:
self.globalstate.use_utility_code(UtilityCode.load_cached("FastGil", "ModuleSetupCode.c"))
else:
self.globalstate.use_utility_code(UtilityCode.load_cached("NoFastGil", "ModuleSetupCode.c"))
self.putln("#ifdef WITH_THREAD")
self.putln("PyThreadState *_save;")
self.putln("Py_UNBLOCK_THREADS")
if variable:
self.putln('%s = _save;' % variable)
self.putln("__Pyx_FastGIL_Remember();")
self.putln("#endif")
def declare_gilstate(self):
self.putln("#ifdef WITH_THREAD")
self.putln("PyGILState_STATE __pyx_gilstate_save;")
self.putln("#endif")
# error handling
def put_error_if_neg(self, pos, value):
# TODO this path is almost _never_ taken, yet this macro makes is slower!
# return self.putln("if (unlikely(%s < 0)) %s" % (value, self.error_goto(pos)))
return self.putln("if (%s < 0) %s" % (value, self.error_goto(pos)))
def put_error_if_unbound(self, pos, entry, in_nogil_context=False):
from . import ExprNodes
if entry.from_closure:
func = '__Pyx_RaiseClosureNameError'
self.globalstate.use_utility_code(
ExprNodes.raise_closure_name_error_utility_code)
elif entry.type.is_memoryviewslice and in_nogil_context:
func = '__Pyx_RaiseUnboundMemoryviewSliceNogil'
self.globalstate.use_utility_code(
ExprNodes.raise_unbound_memoryview_utility_code_nogil)
else:
func = '__Pyx_RaiseUnboundLocalError'
self.globalstate.use_utility_code(
ExprNodes.raise_unbound_local_error_utility_code)
self.putln('if (unlikely(!%s)) { %s("%s"); %s }' % (
entry.type.check_for_null_code(entry.cname),
func,
entry.name,
self.error_goto(pos)))
def set_error_info(self, pos, used=False):
self.funcstate.should_declare_error_indicator = True
if used:
self.funcstate.uses_error_indicator = True
return "__PYX_MARK_ERR_POS(%s, %s)" % (
self.lookup_filename(pos[0]),
pos[1])
def error_goto(self, pos, used=True):
lbl = self.funcstate.error_label
self.funcstate.use_label(lbl)
if pos is None:
return 'goto %s;' % lbl
self.funcstate.should_declare_error_indicator = True
if used:
self.funcstate.uses_error_indicator = True
return "__PYX_ERR(%s, %s, %s)" % (
self.lookup_filename(pos[0]),
pos[1],
lbl)
def error_goto_if(self, cond, pos):
return "if (%s) %s" % (self.unlikely(cond), self.error_goto(pos))
def error_goto_if_null(self, cname, pos):
return self.error_goto_if("!%s" % cname, pos)
def error_goto_if_neg(self, cname, pos):
return self.error_goto_if("%s < 0" % cname, pos)
def error_goto_if_PyErr(self, pos):
return self.error_goto_if("PyErr_Occurred()", pos)
def lookup_filename(self, filename):
return self.globalstate.lookup_filename(filename)
def put_declare_refcount_context(self):
self.putln('__Pyx_RefNannyDeclarations')
def put_setup_refcount_context(self, name, acquire_gil=False):
if acquire_gil:
self.globalstate.use_utility_code(
UtilityCode.load_cached("ForceInitThreads", "ModuleSetupCode.c"))
self.putln('__Pyx_RefNannySetupContext("%s", %d);' % (name, acquire_gil and 1 or 0))
def put_finish_refcount_context(self):
self.putln("__Pyx_RefNannyFinishContext();")
def put_add_traceback(self, qualified_name, include_cline=True):
"""
Build a Python traceback for propagating exceptions.
qualified_name should be the qualified name of the function.
"""
format_tuple = (
qualified_name,
Naming.clineno_cname if include_cline else 0,
Naming.lineno_cname,
Naming.filename_cname,
)
self.funcstate.uses_error_indicator = True
self.putln('__Pyx_AddTraceback("%s", %s, %s, %s);' % format_tuple)
def put_unraisable(self, qualified_name, nogil=False):
"""
Generate code to print a Python warning for an unraisable exception.
qualified_name should be the qualified name of the function.
"""
format_tuple = (
qualified_name,
Naming.clineno_cname,
Naming.lineno_cname,
Naming.filename_cname,
self.globalstate.directives['unraisable_tracebacks'],
nogil,
)
self.funcstate.uses_error_indicator = True
self.putln('__Pyx_WriteUnraisable("%s", %s, %s, %s, %d, %d);' % format_tuple)
self.globalstate.use_utility_code(
UtilityCode.load_cached("WriteUnraisableException", "Exceptions.c"))
def put_trace_declarations(self):
self.putln('__Pyx_TraceDeclarations')
def put_trace_frame_init(self, codeobj=None):
if codeobj:
self.putln('__Pyx_TraceFrameInit(%s)' % codeobj)
def put_trace_call(self, name, pos, nogil=False):
self.putln('__Pyx_TraceCall("%s", %s[%s], %s, %d, %s);' % (
name, Naming.filetable_cname, self.lookup_filename(pos[0]), pos[1], nogil, self.error_goto(pos)))
def put_trace_exception(self):
self.putln("__Pyx_TraceException();")
def put_trace_return(self, retvalue_cname, nogil=False):
self.putln("__Pyx_TraceReturn(%s, %d);" % (retvalue_cname, nogil))
def putln_openmp(self, string):
self.putln("#ifdef _OPENMP")
self.putln(string)
self.putln("#endif /* _OPENMP */")
def undef_builtin_expect(self, cond):
"""
Redefine the macros likely() and unlikely to no-ops, depending on
condition 'cond'
"""
self.putln("#if %s" % cond)
self.putln(" #undef likely")
self.putln(" #undef unlikely")
self.putln(" #define likely(x) (x)")
self.putln(" #define unlikely(x) (x)")
self.putln("#endif")
def redef_builtin_expect(self, cond):
self.putln("#if %s" % cond)
self.putln(" #undef likely")
self.putln(" #undef unlikely")
self.putln(" #define likely(x) __builtin_expect(!!(x), 1)")
self.putln(" #define unlikely(x) __builtin_expect(!!(x), 0)")
self.putln("#endif")
class PyrexCodeWriter(object):
# f file output file
# level int indentation level
def __init__(self, outfile_name):
self.f = Utils.open_new_file(outfile_name)
self.level = 0
def putln(self, code):
self.f.write("%s%s\n" % (" " * self.level, code))
def indent(self):
self.level += 1
def dedent(self):
self.level -= 1
class PyxCodeWriter(object):
"""
Can be used for writing out some Cython code. To use the indenter
functionality, the Cython.Compiler.Importer module will have to be used
to load the code to support python 2.4
"""
def __init__(self, buffer=None, indent_level=0, context=None, encoding='ascii'):
self.buffer = buffer or StringIOTree()
self.level = indent_level
self.context = context
self.encoding = encoding
def indent(self, levels=1):
self.level += levels
return True
def dedent(self, levels=1):
self.level -= levels
def indenter(self, line):
"""
Instead of
with pyx_code.indenter("for i in range(10):"):
pyx_code.putln("print i")
write
if pyx_code.indenter("for i in range(10);"):
pyx_code.putln("print i")
pyx_code.dedent()
"""
self.putln(line)
self.indent()
return True
def getvalue(self):
result = self.buffer.getvalue()
if isinstance(result, bytes):
result = result.decode(self.encoding)
return result
def putln(self, line, context=None):
context = context or self.context
if context:
line = sub_tempita(line, context)
self._putln(line)
def _putln(self, line):
self.buffer.write("%s%s\n" % (self.level * " ", line))
def put_chunk(self, chunk, context=None):
context = context or self.context
if context:
chunk = sub_tempita(chunk, context)
chunk = textwrap.dedent(chunk)
for line in chunk.splitlines():
self._putln(line)
def insertion_point(self):
return PyxCodeWriter(self.buffer.insertion_point(), self.level,
self.context)
def named_insertion_point(self, name):
setattr(self, name, self.insertion_point())
class ClosureTempAllocator(object):
def __init__(self, klass):
self.klass = klass
self.temps_allocated = {}
self.temps_free = {}
self.temps_count = 0
def reset(self):
for type, cnames in self.temps_allocated.items():
self.temps_free[type] = list(cnames)
def allocate_temp(self, type):
if type not in self.temps_allocated:
self.temps_allocated[type] = []
self.temps_free[type] = []
elif self.temps_free[type]:
return self.temps_free[type].pop(0)
cname = '%s%d' % (Naming.codewriter_temp_prefix, self.temps_count)
self.klass.declare_var(pos=None, name=cname, cname=cname, type=type, is_cdef=True)
self.temps_allocated[type].append(cname)
self.temps_count += 1
return cname