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Commit bbc85f30 authored by Benjamin Peterson's avatar Benjamin Peterson
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port simplejson upgrade from the trunk #4136 

json also now works only with unicode strings

Patch by Antoine Pitrou; updated by me
parent 9d5e41f9
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Showing with 1986 additions and 934 deletions
Doc/library/json.rst
View file @ bbc85f30
......@@ -112,7 +112,7 @@ Using json.tool from the shell to validate and pretty-print::
Basic Usage
-----------
.. function:: dump(obj, fp[, skipkeys[, ensure_ascii[, check_circular[, allow_nan[, cls[, indent[, separators[, encoding[, default[, **kw]]]]]]]]]])
.. function:: dump(obj, fp[, skipkeys[, ensure_ascii[, check_circular[, allow_nan[, cls[, indent[, separators[, default[, **kw]]]]]]]]]])
Serialize *obj* as a JSON formatted stream to *fp* (a ``.write()``-supporting
file-like object).
......@@ -122,11 +122,10 @@ Basic Usage
:class:`float`, :class:`bool`, ``None``) will be skipped instead of raising a
:exc:`TypeError`.
If *ensure_ascii* is ``False`` (default: ``True``), then some chunks written
to *fp* may be :class:`unicode` instances, subject to normal Python
:class:`str` to :class:`unicode` coercion rules. Unless ``fp.write()``
explicitly understands :class:`unicode` (as in :func:`codecs.getwriter`) this
is likely to cause an error.
The :mod:`json` module always produces :class:`str` objects, not
:class:`bytes` objects. Therefore, ``fp.write()`` must support :class:`str`
input.
If *check_circular* is ``False`` (default: ``True``), then the circular
reference check for container types will be skipped and a circular reference
......@@ -146,8 +145,6 @@ Basic Usage
will be used instead of the default ``(', ', ': ')`` separators. ``(',',
':')`` is the most compact JSON representation.
*encoding* is the character encoding for str instances, default is UTF-8.
*default(obj)* is a function that should return a serializable version of
*obj* or raise :exc:`TypeError`. The default simply raises :exc:`TypeError`.
......@@ -156,26 +153,17 @@ Basic Usage
*cls* kwarg.
.. function:: dumps(obj[, skipkeys[, ensure_ascii[, check_circular[, allow_nan[, cls[, indent[, separators[, encoding[, default[, **kw]]]]]]]]]])
.. function:: dumps(obj[, skipkeys[, ensure_ascii[, check_circular[, allow_nan[, cls[, indent[, separators[, default[, **kw]]]]]]]]]])
Serialize *obj* to a JSON formatted :class:`str`.
Serialize *obj* to a JSON formatted :class:`str`. The arguments have the
same meaning as in :func:`dump`.
If *ensure_ascii* is ``False``, then the return value will be a
:class:`unicode` instance. The other arguments have the same meaning as in
:func:`dump`.
.. function:: load(fp[, encoding[, cls[, object_hook[, parse_float[, parse_int[, parse_constant[, object_pairs_hook[, **kw]]]]]]]])
.. function:: load(fp[, cls[, object_hook[, parse_float[, parse_int[, parse_constant[, object_pairs_hook[, **kw]]]]]]]])
Deserialize *fp* (a ``.read()``-supporting file-like object containing a JSON
document) to a Python object.
If the contents of *fp* are encoded with an ASCII based encoding other than
UTF-8 (e.g. latin-1), then an appropriate *encoding* name must be specified.
Encodings that are not ASCII based (such as UCS-2) are not allowed, and
should be wrapped with ``codecs.getreader(encoding)(fp)``, or simply decoded
to a :class:`unicode` object and passed to :func:`loads`.
*object_hook* is an optional function that will be called with the result of
any object literal decode (a :class:`dict`). The return value of
*object_hook* will be used instead of the :class:`dict`. This feature can be used
......@@ -241,7 +229,7 @@ Encoders and decoders
+---------------+-------------------+
| array | list |
+---------------+-------------------+
| string | unicode |
| string | str |
+---------------+-------------------+
| number (int) | int |
+---------------+-------------------+
......@@ -257,13 +245,6 @@ Encoders and decoders
It also understands ``NaN``, ``Infinity``, and ``-Infinity`` as their
corresponding ``float`` values, which is outside the JSON spec.
*encoding* determines the encoding used to interpret any :class:`str` objects
decoded by this instance (UTF-8 by default). It has no effect when decoding
:class:`unicode` objects.
Note that currently only encodings that are a superset of ASCII work, strings
of other encodings should be passed in as :class:`unicode`.
*object_hook*, if specified, will be called with the result of every JSON
object decoded and its return value will be used in place of the given
:class:`dict`. This can be used to provide custom deserializations (e.g. to
......@@ -298,20 +279,20 @@ Encoders and decoders
.. method:: decode(s)
Return the Python representation of *s* (a :class:`str` or
:class:`unicode` instance containing a JSON document)
Return the Python representation of *s* (a :class:`str` instance
containing a JSON document)
.. method:: raw_decode(s)
Decode a JSON document from *s* (a :class:`str` or :class:`unicode`
beginning with a JSON document) and return a 2-tuple of the Python
representation and the index in *s* where the document ended.
Decode a JSON document from *s* (a :class:`str` beginning with a
JSON document) and return a 2-tuple of the Python representation
and the index in *s* where the document ended.
This can be used to decode a JSON document from a string that may have
extraneous data at the end.
.. class:: JSONEncoder([skipkeys[, ensure_ascii[, check_circular[, allow_nan[, sort_keys[, indent[, separators[, encoding[, default]]]]]]]]])
.. class:: JSONEncoder([skipkeys[, ensure_ascii[, check_circular[, allow_nan[, sort_keys[, indent[, separators[, default]]]]]]]])
Extensible JSON encoder for Python data structures.
......@@ -324,7 +305,7 @@ Encoders and decoders
+-------------------+---------------+
| list, tuple | array |
+-------------------+---------------+
| str, unicode | string |
| str | string |
+-------------------+---------------+
| int, float | number |
+-------------------+---------------+
......@@ -344,9 +325,9 @@ Encoders and decoders
attempt encoding of keys that are not str, int, float or None. If
*skipkeys* is ``True``, such items are simply skipped.
If *ensure_ascii* is ``True`` (the default), the output is guaranteed to be
:class:`str` objects with all incoming unicode characters escaped. If
*ensure_ascii* is ``False``, the output will be a unicode object.
If *ensure_ascii* is ``True`` (the default), the output is guaranteed to
have all incoming non-ASCII characters escaped. If *ensure_ascii* is
``False``, these characters will be output as-is.
If *check_circular* is ``True`` (the default), then lists, dicts, and custom
encoded objects will be checked for circular references during encoding to
......@@ -376,10 +357,6 @@ Encoders and decoders
otherwise be serialized. It should return a JSON encodable version of the
object or raise a :exc:`TypeError`.
If *encoding* is not ``None``, then all input strings will be transformed
into unicode using that encoding prior to JSON-encoding. The default is
UTF-8.
.. method:: default(o)
......
Lib/json/__init__.py
View file @ bbc85f30
r"""A simple, fast, extensible JSON encoder and decoder
JSON (JavaScript Object Notation) <http://json.org> is a subset of
r"""JSON (JavaScript Object Notation) <http://json.org> is a subset of
JavaScript syntax (ECMA-262 3rd edition) used as a lightweight data
interchange format.
json exposes an API familiar to uses of the standard library
marshal and pickle modules.
:mod:`json` exposes an API familiar to users of the standard library
:mod:`marshal` and :mod:`pickle` modules. It is the externally maintained
version of the :mod:`json` library contained in Python 2.6, but maintains
compatibility with Python 2.4 and Python 2.5 and (currently) has
significant performance advantages, even without using the optional C
extension for speedups.
Encoding basic Python object hierarchies::
......@@ -32,23 +34,28 @@ Compact encoding::
>>> json.dumps([1,2,3,{'4': 5, '6': 7}], separators=(',',':'))
'[1,2,3,{"4":5,"6":7}]'
Pretty printing (using repr() because of extraneous whitespace in the output)::
Pretty printing::
>>> import json
>>> print(repr(json.dumps({'4': 5, '6': 7}, sort_keys=True, indent=4)))
'{\n "4": 5, \n "6": 7\n}'
>>> s = json.dumps({'4': 5, '6': 7}, sort_keys=True, indent=4)
>>> print('\n'.join([l.rstrip() for l in s.splitlines()]))
{
"4": 5,
"6": 7
}
Decoding JSON::
>>> import json
>>> json.loads('["foo", {"bar":["baz", null, 1.0, 2]}]')
['foo', {'bar': ['baz', None, 1.0, 2]}]
>>> json.loads('"\\"foo\\bar"')
'"foo\x08ar'
>>> obj = ['foo', {'bar': ['baz', None, 1.0, 2]}]
>>> json.loads('["foo", {"bar":["baz", null, 1.0, 2]}]') == obj
True
>>> json.loads('"\\"foo\\bar"') == '"foo\x08ar'
True
>>> from io import StringIO
>>> io = StringIO('["streaming API"]')
>>> json.load(io)
['streaming API']
>>> json.load(io)[0] == 'streaming API'
True
Specializing JSON object decoding::
......@@ -61,43 +68,36 @@ Specializing JSON object decoding::
>>> json.loads('{"__complex__": true, "real": 1, "imag": 2}',
... object_hook=as_complex)
(1+2j)
>>> import decimal
>>> json.loads('1.1', parse_float=decimal.Decimal)
Decimal('1.1')
>>> from decimal import Decimal
>>> json.loads('1.1', parse_float=Decimal) == Decimal('1.1')
True
Extending JSONEncoder::
Specializing JSON object encoding::
>>> import json
>>> class ComplexEncoder(json.JSONEncoder):
... def default(self, obj):
... if isinstance(obj, complex):
... return [obj.real, obj.imag]
... return json.JSONEncoder.default(self, obj)
>>> def encode_complex(obj):
... if isinstance(obj, complex):
... return [obj.real, obj.imag]
... raise TypeError(repr(o) + " is not JSON serializable")
...
>>> dumps(2 + 1j, cls=ComplexEncoder)
>>> json.dumps(2 + 1j, default=encode_complex)
'[2.0, 1.0]'
>>> json.JSONEncoder(default=encode_complex).encode(2 + 1j)
'[2.0, 1.0]'
>>> ComplexEncoder().encode(2 + 1j)
>>> ''.join(json.JSONEncoder(default=encode_complex).iterencode(2 + 1j))
'[2.0, 1.0]'
>>> list(ComplexEncoder().iterencode(2 + 1j))
['[', '2.0', ', ', '1.0', ']']
Using json.tool from the shell to validate and
pretty-print::
Using json.tool from the shell to validate and pretty-print::
$ echo '{"json":"obj"}' | python -mjson.tool
$ echo '{"json":"obj"}' | python -m json.tool
{
"json": "obj"
}
$ echo '{ 1.2:3.4}' | python -mjson.tool
$ echo '{ 1.2:3.4}' | python -m json.tool
Expecting property name: line 1 column 2 (char 2)
Note that the JSON produced by this module's default settings
is a subset of YAML, so it may be used as a serializer for that as well.
"""
__version__ = '1.9'
__version__ = '2.0.9'
__all__ = [
'dump', 'dumps', 'load', 'loads',
'JSONDecoder', 'JSONEncoder',
......@@ -115,45 +115,43 @@ _default_encoder = JSONEncoder(
allow_nan=True,
indent=None,
separators=None,
encoding='utf-8',
default=None,
)
def dump(obj, fp, skipkeys=False, ensure_ascii=True, check_circular=True,
allow_nan=True, cls=None, indent=None, separators=None,
encoding='utf-8', default=None, **kw):
default=None, **kw):
"""Serialize ``obj`` as a JSON formatted stream to ``fp`` (a
``.write()``-supporting file-like object).
If ``skipkeys`` is ``True`` then ``dict`` keys that are not basic types
(``str``, ``unicode``, ``int``, ``long``, ``float``, ``bool``, ``None``)
will be skipped instead of raising a ``TypeError``.
If ``skipkeys`` is true then ``dict`` keys that are not basic types
(``str``, ``unicode``, ``int``, ``float``, ``bool``, ``None``) will be
skipped instead of raising a ``TypeError``.
If ``ensure_ascii`` is ``False``, then the some chunks written to ``fp``
If ``ensure_ascii`` is false, then the some chunks written to ``fp``
may be ``unicode`` instances, subject to normal Python ``str`` to
``unicode`` coercion rules. Unless ``fp.write()`` explicitly
understands ``unicode`` (as in ``codecs.getwriter()``) this is likely
to cause an error.
If ``check_circular`` is ``False``, then the circular reference check
If ``check_circular`` is false, then the circular reference check
for container types will be skipped and a circular reference will
result in an ``OverflowError`` (or worse).
If ``allow_nan`` is ``False``, then it will be a ``ValueError`` to
If ``allow_nan`` is false, then it will be a ``ValueError`` to
serialize out of range ``float`` values (``nan``, ``inf``, ``-inf``)
in strict compliance of the JSON specification, instead of using the
JavaScript equivalents (``NaN``, ``Infinity``, ``-Infinity``).
If ``indent`` is a non-negative integer, then JSON array elements and object
members will be pretty-printed with that indent level. An indent level
of 0 will only insert newlines. ``None`` is the most compact representation.
If ``indent`` is a non-negative integer, then JSON array elements and
object members will be pretty-printed with that indent level. An indent
level of 0 will only insert newlines. ``None`` is the most compact
representation.
If ``separators`` is an ``(item_separator, dict_separator)`` tuple
then it will be used instead of the default ``(', ', ': ')`` separators.
``(',', ':')`` is the most compact JSON representation.
``encoding`` is the character encoding for str instances, default is UTF-8.
``default(obj)`` is a function that should return a serializable version
of obj or raise TypeError. The default simply raises TypeError.
......@@ -163,17 +161,17 @@ def dump(obj, fp, skipkeys=False, ensure_ascii=True, check_circular=True,
"""
# cached encoder
if (skipkeys is False and ensure_ascii is True and
check_circular is True and allow_nan is True and
if (not skipkeys and ensure_ascii and
check_circular and allow_nan and
cls is None and indent is None and separators is None and
encoding == 'utf-8' and default is None and not kw):
default is None and not kw):
iterable = _default_encoder.iterencode(obj)
else:
if cls is None:
cls = JSONEncoder
iterable = cls(skipkeys=skipkeys, ensure_ascii=ensure_ascii,
check_circular=check_circular, allow_nan=allow_nan, indent=indent,
separators=separators, encoding=encoding,
separators=separators,
default=default, **kw).iterencode(obj)
# could accelerate with writelines in some versions of Python, at
# a debuggability cost
......@@ -183,22 +181,22 @@ def dump(obj, fp, skipkeys=False, ensure_ascii=True, check_circular=True,
def dumps(obj, skipkeys=False, ensure_ascii=True, check_circular=True,
allow_nan=True, cls=None, indent=None, separators=None,
encoding='utf-8', default=None, **kw):
default=None, **kw):
"""Serialize ``obj`` to a JSON formatted ``str``.
If ``skipkeys`` is ``True`` then ``dict`` keys that are not basic types
(``str``, ``unicode``, ``int``, ``long``, ``float``, ``bool``, ``None``)
will be skipped instead of raising a ``TypeError``.
If ``skipkeys`` is false then ``dict`` keys that are not basic types
(``str``, ``unicode``, ``int``, ``float``, ``bool``, ``None``) will be
skipped instead of raising a ``TypeError``.
If ``ensure_ascii`` is ``False``, then the return value will be a
If ``ensure_ascii`` is false, then the return value will be a
``unicode`` instance subject to normal Python ``str`` to ``unicode``
coercion rules instead of being escaped to an ASCII ``str``.
If ``check_circular`` is ``False``, then the circular reference check
If ``check_circular`` is false, then the circular reference check
for container types will be skipped and a circular reference will
result in an ``OverflowError`` (or worse).
If ``allow_nan`` is ``False``, then it will be a ``ValueError`` to
If ``allow_nan`` is false, then it will be a ``ValueError`` to
serialize out of range ``float`` values (``nan``, ``inf``, ``-inf``) in
strict compliance of the JSON specification, instead of using the
JavaScript equivalents (``NaN``, ``Infinity``, ``-Infinity``).
......@@ -212,8 +210,6 @@ def dumps(obj, skipkeys=False, ensure_ascii=True, check_circular=True,
then it will be used instead of the default ``(', ', ': ')`` separators.
``(',', ':')`` is the most compact JSON representation.
``encoding`` is the character encoding for str instances, default is UTF-8.
``default(obj)`` is a function that should return a serializable version
of obj or raise TypeError. The default simply raises TypeError.
......@@ -223,35 +219,27 @@ def dumps(obj, skipkeys=False, ensure_ascii=True, check_circular=True,
"""
# cached encoder
if (skipkeys is False and ensure_ascii is True and
check_circular is True and allow_nan is True and
if (not skipkeys and ensure_ascii and
check_circular and allow_nan and
cls is None and indent is None and separators is None and
encoding == 'utf-8' and default is None and not kw):
default is None and not kw):
return _default_encoder.encode(obj)
if cls is None:
cls = JSONEncoder
return cls(
skipkeys=skipkeys, ensure_ascii=ensure_ascii,
check_circular=check_circular, allow_nan=allow_nan, indent=indent,
separators=separators, encoding=encoding, default=default,
separators=separators, default=default,
**kw).encode(obj)
_default_decoder = JSONDecoder(encoding=None, object_hook=None,
object_pairs_hook=None)
_default_decoder = JSONDecoder(object_hook=None, object_pairs_hook=None)
def load(fp, encoding=None, cls=None, object_hook=None, parse_float=None,
def load(fp, cls=None, object_hook=None, parse_float=None,
parse_int=None, parse_constant=None, object_pairs_hook=None, **kw):
"""Deserialize ``fp`` (a ``.read()``-supporting file-like object
containing a JSON document) to a Python object.
If the contents of ``fp`` is encoded with an ASCII based encoding other
than utf-8 (e.g. latin-1), then an appropriate ``encoding`` name must
be specified. Encodings that are not ASCII based (such as UCS-2) are
not allowed, and should be wrapped with
``codecs.getreader(fp)(encoding)``, or simply decoded to a ``unicode``
object and passed to ``loads()``
"""Deserialize ``fp`` (a ``.read()``-supporting file-like object containing
a JSON document) to a Python object.
``object_hook`` is an optional function that will be called with the
result of any object literal decode (a ``dict``). The return value of
......@@ -263,21 +251,16 @@ def load(fp, encoding=None, cls=None, object_hook=None, parse_float=None,
"""
return loads(fp.read(),
encoding=encoding, cls=cls, object_hook=object_hook,
cls=cls, object_hook=object_hook,
parse_float=parse_float, parse_int=parse_int,
parse_constant=parse_constant, object_pairs_hook=object_pairs_hook, **kw)
def loads(s, encoding=None, cls=None, object_hook=None, parse_float=None,
parse_int=None, parse_constant=None, object_pairs_hook=None, **kw):
"""Deserialize ``s`` (a ``str`` or ``unicode`` instance containing a JSON
"""Deserialize ``s`` (a ``str`` instance containing a JSON
document) to a Python object.
If ``s`` is a ``str`` instance and is encoded with an ASCII based encoding
other than utf-8 (e.g. latin-1) then an appropriate ``encoding`` name
must be specified. Encodings that are not ASCII based (such as UCS-2)
are not allowed and should be decoded to ``unicode`` first.
``object_hook`` is an optional function that will be called with the
result of any object literal decode (a ``dict``). The return value of
``object_hook`` will be used instead of the ``dict``. This feature
......@@ -302,7 +285,7 @@ def loads(s, encoding=None, cls=None, object_hook=None, parse_float=None,
kwarg.
"""
if (cls is None and encoding is None and object_hook is None and
if (cls is None and object_hook is None and
parse_int is None and parse_float is None and
parse_constant is None and object_pairs_hook is None and not kw):
return _default_decoder.decode(s)
......@@ -318,4 +301,4 @@ def loads(s, encoding=None, cls=None, object_hook=None, parse_float=None,
kw['parse_int'] = parse_int
if parse_constant is not None:
kw['parse_constant'] = parse_constant
return cls(encoding=encoding, **kw).decode(s)
return cls(**kw).decode(s)
Lib/json/decoder.py
View file @ bbc85f30
"""Implementation of JSONDecoder
"""
import binascii
import re
import sys
import struct
from json.scanner import Scanner, pattern
from json.scanner import make_scanner
try:
from _json import scanstring as c_scanstring
except ImportError:
......@@ -14,7 +15,14 @@ __all__ = ['JSONDecoder']
FLAGS = re.VERBOSE | re.MULTILINE | re.DOTALL
NaN, PosInf, NegInf = float('nan'), float('inf'), float('-inf')
def _floatconstants():
_BYTES = binascii.unhexlify(b'7FF80000000000007FF0000000000000')
if sys.byteorder != 'big':
_BYTES = _BYTES[:8][::-1] + _BYTES[8:][::-1]
nan, inf = struct.unpack('dd', _BYTES)
return nan, inf, -inf
NaN, PosInf, NegInf = _floatconstants()
def linecol(doc, pos):
......@@ -31,61 +39,43 @@ def linecol(doc, pos):
def errmsg(msg, doc, pos, end=None):
# Note that this function is called from _json
lineno, colno = linecol(doc, pos)
if end is None:
fmt = '{0}: line {1} column {2} (char {3})'
return fmt.format(msg, lineno, colno, pos)
#fmt = '%s: line %d column %d (char %d)'
#return fmt % (msg, lineno, colno, pos)
endlineno, endcolno = linecol(doc, end)
fmt = '{0}: line {1} column {2} - line {3} column {4} (char {5} - {6})'
return fmt.format(msg, lineno, colno, endlineno, endcolno, pos, end)
#fmt = '%s: line %d column %d - line %d column %d (char %d - %d)'
#return fmt % (msg, lineno, colno, endlineno, endcolno, pos, end)
_CONSTANTS = {
'-Infinity': NegInf,
'Infinity': PosInf,
'NaN': NaN,
'true': True,
'false': False,
'null': None,
}
def JSONConstant(match, context, c=_CONSTANTS):
s = match.group(0)
fn = getattr(context, 'parse_constant', None)
if fn is None:
rval = c[s]
else:
rval = fn(s)
return rval, None
pattern('(-?Infinity|NaN|true|false|null)')(JSONConstant)
def JSONNumber(match, context):
match = JSONNumber.regex.match(match.string, *match.span())
integer, frac, exp = match.groups()
if frac or exp:
fn = getattr(context, 'parse_float', None) or float
res = fn(integer + (frac or '') + (exp or ''))
else:
fn = getattr(context, 'parse_int', None) or int
res = fn(integer)
return res, None
pattern(r'(-?(?:0|[1-9][0-9]*))(\.[0-9]+)?([eE][-+]?[0-9]+)?')(JSONNumber)
STRINGCHUNK = re.compile(r'(.*?)(["\\\x00-\x1f])', FLAGS)
BACKSLASH = {
'"': '"', '\\': '\\', '/': '/',
'b': '\b', 'f': '\f', 'n': '\n', 'r': '\r', 't': '\t',
}
DEFAULT_ENCODING = "utf-8"
def py_scanstring(s, end, strict=True,
_b=BACKSLASH, _m=STRINGCHUNK.match):
"""Scan the string s for a JSON string. End is the index of the
character in s after the quote that started the JSON string.
Unescapes all valid JSON string escape sequences and raises ValueError
on attempt to decode an invalid string. If strict is False then literal
control characters are allowed in the string.
def py_scanstring(s, end, encoding=None, strict=True, _b=BACKSLASH, _m=STRINGCHUNK.match):
if encoding is None:
encoding = DEFAULT_ENCODING
Returns a tuple of the decoded string and the index of the character in s
after the end quote."""
chunks = []
_append = chunks.append
begin = end - 1
......@@ -96,14 +86,16 @@ def py_scanstring(s, end, encoding=None, strict=True, _b=BACKSLASH, _m=STRINGCHU
errmsg("Unterminated string starting at", s, begin))
end = chunk.end()
content, terminator = chunk.groups()
# Content is contains zero or more unescaped string characters
if content:
if not isinstance(content, str):
content = str(content, encoding)
_append(content)
# Terminator is the end of string, a literal control character,
# or a backslash denoting that an escape sequence follows
if terminator == '"':
break
elif terminator != '\\':
if strict:
#msg = "Invalid control character %r at" % (terminator,)
msg = "Invalid control character {0!r} at".format(terminator)
raise ValueError(errmsg(msg, s, end))
else:
......@@ -114,9 +106,10 @@ def py_scanstring(s, end, encoding=None, strict=True, _b=BACKSLASH, _m=STRINGCHU
except IndexError:
raise ValueError(
errmsg("Unterminated string starting at", s, begin))
# If not a unicode escape sequence, must be in the lookup table
if esc != 'u':
try:
m = _b[esc]
char = _b[esc]
except KeyError:
msg = "Invalid \\escape: {0!r}".format(esc)
raise ValueError(errmsg(msg, s, end))
......@@ -124,131 +117,138 @@ def py_scanstring(s, end, encoding=None, strict=True, _b=BACKSLASH, _m=STRINGCHU
else:
esc = s[end + 1:end + 5]
next_end = end + 5
msg = "Invalid \\uXXXX escape"
try:
if len(esc) != 4:
raise ValueError
uni = int(esc, 16)
if 0xd800 <= uni <= 0xdbff and sys.maxunicode > 65535:
msg = "Invalid \\uXXXX\\uXXXX surrogate pair"
if not s[end + 5:end + 7] == '\\u':
raise ValueError
esc2 = s[end + 7:end + 11]
if len(esc2) != 4:
raise ValueError
uni2 = int(esc2, 16)
uni = 0x10000 + (((uni - 0xd800) << 10) | (uni2 - 0xdc00))
next_end += 6
m = chr(uni)
except ValueError:
if len(esc) != 4:
msg = "Invalid \\uXXXX escape"
raise ValueError(errmsg(msg, s, end))
uni = int(esc, 16)
# Check for surrogate pair on UCS-4 systems
if 0xd800 <= uni <= 0xdbff and sys.maxunicode > 65535:
msg = "Invalid \\uXXXX\\uXXXX surrogate pair"
if not s[end + 5:end + 7] == '\\u':
raise ValueError(errmsg(msg, s, end))
esc2 = s[end + 7:end + 11]
if len(esc2) != 4:
raise ValueError(errmsg(msg, s, end))
uni2 = int(esc2, 16)
uni = 0x10000 + (((uni - 0xd800) << 10) | (uni2 - 0xdc00))
next_end += 6
char = chr(uni)
end = next_end
_append(m)
_append(char)
return ''.join(chunks), end
# Use speedup
if c_scanstring is not None:
scanstring = c_scanstring
else:
scanstring = py_scanstring
def JSONString(match, context):
encoding = getattr(context, 'encoding', None)
strict = getattr(context, 'strict', True)
return scanstring(match.string, match.end(), encoding, strict)
pattern(r'"')(JSONString)
# Use speedup if available
scanstring = c_scanstring or py_scanstring
WHITESPACE = re.compile(r'[ \t\n\r]*', FLAGS)
WHITESPACE_STR = ' \t\n\r'
WHITESPACE = re.compile(r'\s*', FLAGS)
def JSONObject(match, context, _w=WHITESPACE.match):
def JSONObject(s_and_end, strict, scan_once, object_hook, object_pairs_hook,
_w=WHITESPACE.match, _ws=WHITESPACE_STR):
s, end = s_and_end
pairs = []
pairs_append = pairs.append
s = match.string
end = _w(s, match.end()).end()
# Use a slice to prevent IndexError from being raised, the following
# check will raise a more specific ValueError if the string is empty
nextchar = s[end:end + 1]
# Trivial empty object
if nextchar == '}':
return pairs, end + 1
# Normally we expect nextchar == '"'
if nextchar != '"':
raise ValueError(errmsg("Expecting property name", s, end))
if nextchar in _ws:
end = _w(s, end).end()
nextchar = s[end:end + 1]
# Trivial empty object
if nextchar == '}':
return pairs, end + 1
elif nextchar != '"':
raise ValueError(errmsg("Expecting property name", s, end))
end += 1
encoding = getattr(context, 'encoding', None)
strict = getattr(context, 'strict', True)
iterscan = JSONScanner.iterscan
while True:
key, end = scanstring(s, end, encoding, strict)
end = _w(s, end).end()
key, end = scanstring(s, end, strict)
# To skip some function call overhead we optimize the fast paths where
# the JSON key separator is ": " or just ":".
if s[end:end + 1] != ':':
raise ValueError(errmsg("Expecting : delimiter", s, end))
end = _w(s, end + 1).end()
end = _w(s, end).end()
if s[end:end + 1] != ':':
raise ValueError(errmsg("Expecting : delimiter", s, end))
end += 1
try:
value, end = next(iterscan(s, idx=end, context=context))
if s[end] in _ws:
end += 1
if s[end] in _ws:
end = _w(s, end + 1).end()
except IndexError:
pass
try:
value, end = scan_once(s, end)
except StopIteration:
raise ValueError(errmsg("Expecting object", s, end))
pairs_append((key, value))
end = _w(s, end).end()
nextchar = s[end:end + 1]
try:
nextchar = s[end]
if nextchar in _ws:
end = _w(s, end + 1).end()
nextchar = s[end]
except IndexError:
nextchar = ''
end += 1
if nextchar == '}':
break
if nextchar != ',':
elif nextchar != ',':
raise ValueError(errmsg("Expecting , delimiter", s, end - 1))
end = _w(s, end).end()
nextchar = s[end:end + 1]
end += 1
if nextchar != '"':
raise ValueError(errmsg("Expecting property name", s, end - 1))
object_pairs_hook = getattr(context, 'object_pairs_hook', None)
if object_pairs_hook is not None:
result = object_pairs_hook(pairs)
return result, end
pairs = dict(pairs)
object_hook = getattr(context, 'object_hook', None)
if object_hook is not None:
pairs = object_hook(pairs)
return pairs, end
pattern(r'{')(JSONObject)
def JSONArray(match, context, _w=WHITESPACE.match):
def JSONArray(s_and_end, scan_once, context, _w=WHITESPACE.match):
s, end = s_and_end
values = []
s = match.string
end = _w(s, match.end()).end()
# Look-ahead for trivial empty array
nextchar = s[end:end + 1]
if nextchar in _ws:
end = _w(s, end + 1).end()
nextchar = s[end:end + 1]
# Look-ahead for trivial empty array
if nextchar == ']':
return values, end + 1
iterscan = JSONScanner.iterscan
_append = values.append
while True:
try:
value, end = next(iterscan(s, idx=end, context=context))
value, end = scan_once(s, end)
except StopIteration:
raise ValueError(errmsg("Expecting object", s, end))
values.append(value)
end = _w(s, end).end()
_append(value)
nextchar = s[end:end + 1]
if nextchar in _ws:
end = _w(s, end + 1).end()
nextchar = s[end:end + 1]
end += 1
if nextchar == ']':
break
if nextchar != ',':
elif nextchar != ',':
raise ValueError(errmsg("Expecting , delimiter", s, end))
end = _w(s, end).end()
return values, end
pattern(r'\[')(JSONArray)
ANYTHING = [
JSONObject,
JSONArray,
JSONString,
JSONConstant,
JSONNumber,
]
try:
if s[end] in _ws:
end += 1
if s[end] in _ws:
end = _w(s, end + 1).end()
except IndexError:
pass
JSONScanner = Scanner(ANYTHING)
return values, end
class JSONDecoder(object):
......@@ -278,23 +278,14 @@ class JSONDecoder(object):
It also understands ``NaN``, ``Infinity``, and ``-Infinity`` as
their corresponding ``float`` values, which is outside the JSON spec.
"""
_scanner = Scanner(ANYTHING)
__all__ = ['__init__', 'decode', 'raw_decode']
"""
def __init__(self, encoding=None, object_hook=None, parse_float=None,
def __init__(self, object_hook=None, parse_float=None,
parse_int=None, parse_constant=None, strict=True,
object_pairs_hook=None):
"""``encoding`` determines the encoding used to interpret any ``str``
objects decoded by this instance (utf-8 by default). It has no
effect when decoding ``unicode`` objects.
Note that currently only encodings that are a superset of ASCII work,
strings of other encodings should be passed in as ``unicode``.
``object_hook``, if specified, will be called with the result of
every JSON object decoded and its return value will be used in
"""``object_hook``, if specified, will be called with the result
of every JSON object decoded and its return value will be used in
place of the given ``dict``. This can be used to provide custom
deserializations (e.g. to support JSON-RPC class hinting).
......@@ -309,22 +300,25 @@ class JSONDecoder(object):
for JSON integers (e.g. float).
``parse_constant``, if specified, will be called with one of the
following strings: -Infinity, Infinity, NaN, null, true, false.
following strings: -Infinity, Infinity, NaN.
This can be used to raise an exception if invalid JSON numbers
are encountered.
"""
self.encoding = encoding
self.object_hook = object_hook
self.object_pairs_hook = object_pairs_hook
self.parse_float = parse_float
self.parse_int = parse_int
self.parse_constant = parse_constant
self.parse_float = parse_float or float
self.parse_int = parse_int or int
self.parse_constant = parse_constant or _CONSTANTS.__getitem__
self.strict = strict
self.object_pairs_hook = object_pairs_hook
self.parse_object = JSONObject
self.parse_array = JSONArray
self.parse_string = scanstring
self.scan_once = make_scanner(self)
def decode(self, s, _w=WHITESPACE.match):
"""
Return the Python representation of ``s`` (a ``str`` or ``unicode``
"""Return the Python representation of ``s`` (a ``str`` or ``unicode``
instance containing a JSON document)
"""
......@@ -334,18 +328,17 @@ class JSONDecoder(object):
raise ValueError(errmsg("Extra data", s, end, len(s)))
return obj
def raw_decode(self, s, **kw):
"""Decode a JSON document from ``s`` (a ``str`` or ``unicode`` beginning
with a JSON document) and return a 2-tuple of the Python
def raw_decode(self, s, idx=0):
"""Decode a JSON document from ``s`` (a ``str`` or ``unicode``
beginning with a JSON document) and return a 2-tuple of the Python
representation and the index in ``s`` where the document ended.
This can be used to decode a JSON document from a string that may
have extraneous data at the end.
"""
kw.setdefault('context', self)
try:
obj, end = next(self._scanner.iterscan(s, **kw))
obj, end = self.scan_once(s, idx)
except StopIteration:
raise ValueError("No JSON object could be decoded")
return obj, end
Lib/json/encoder.py
View file @ bbc85f30
"""Implementation of JSONEncoder
"""
import re
import math
try:
from _json import encode_basestring_ascii as c_encode_basestring_ascii
except ImportError:
c_encode_basestring_ascii = None
__all__ = ['JSONEncoder']
try:
from _json import make_encoder as c_make_encoder
except ImportError:
c_make_encoder = None
ESCAPE = re.compile(r'[\x00-\x1f\\"\b\f\n\r\t]')
ESCAPE_ASCII = re.compile(r'([\\"]|[^\ -~])')
HAS_UTF8 = re.compile(r'[\x80-\xff]')
HAS_UTF8 = re.compile(b'[\x80-\xff]')
ESCAPE_DCT = {
'\\': '\\\\',
'"': '\\"',
......@@ -25,30 +25,12 @@ ESCAPE_DCT = {
}
for i in range(0x20):
ESCAPE_DCT.setdefault(chr(i), '\\u{0:04x}'.format(i))
#ESCAPE_DCT.setdefault(chr(i), '\\u%04x' % (i,))
# Assume this produces an infinity on all machines (probably not guaranteed)
INFINITY = float('1e66666')
FLOAT_REPR = repr
def floatstr(o, allow_nan=True):
# Check for specials. Note that this type of test is processor- and/or
# platform-specific, so do tests which don't depend on the internals.
if math.isnan(o):
text = 'NaN'
elif math.isinf(o):
if math.copysign(1., o) == 1.:
text = 'Infinity'
else:
text = '-Infinity'
else:
return FLOAT_REPR(o)
if not allow_nan:
msg = "Out of range float values are not JSON compliant: " + repr(o)
raise ValueError(msg)
return text
def encode_basestring(s):
"""Return a JSON representation of a Python string
......@@ -59,8 +41,9 @@ def encode_basestring(s):
def py_encode_basestring_ascii(s):
if isinstance(s, bytes): # and HAS_UTF8.search(s) is not None:
s = s.decode('utf-8')
"""Return an ASCII-only JSON representation of a Python string
"""
def replace(match):
s = match.group(0)
try:
......@@ -69,20 +52,18 @@ def py_encode_basestring_ascii(s):
n = ord(s)
if n < 0x10000:
return '\\u{0:04x}'.format(n)
#return '\\u%04x' % (n,)
else:
# surrogate pair
n -= 0x10000
s1 = 0xd800 | ((n >> 10) & 0x3ff)
s2 = 0xdc00 | (n & 0x3ff)
return '\\u{0:04x}\\u{1:04x}'.format(s1, s2)
return '"' + (ESCAPE_ASCII.sub(replace, s)) + '"'
return '"' + ESCAPE_ASCII.sub(replace, s) + '"'
if c_encode_basestring_ascii is not None:
encode_basestring_ascii = c_encode_basestring_ascii
else:
encode_basestring_ascii = py_encode_basestring_ascii
encode_basestring_ascii = (
c_encode_basestring_ascii or py_encode_basestring_ascii)
class JSONEncoder(object):
"""Extensible JSON <http://json.org> encoder for Python data structures.
......@@ -113,33 +94,32 @@ class JSONEncoder(object):
implementation (to raise ``TypeError``).
"""
__all__ = ['__init__', 'default', 'encode', 'iterencode']
item_separator = ', '
key_separator = ': '
def __init__(self, skipkeys=False, ensure_ascii=True,
check_circular=True, allow_nan=True, sort_keys=False,
indent=None, separators=None, encoding='utf-8', default=None):
indent=None, separators=None, default=None):
"""Constructor for JSONEncoder, with sensible defaults.
If skipkeys is False, then it is a TypeError to attempt
If skipkeys is false, then it is a TypeError to attempt
encoding of keys that are not str, int, long, float or None. If
skipkeys is True, such items are simply skipped.
If ensure_ascii is True, the output is guaranteed to be str
If ensure_ascii is true, the output is guaranteed to be str
objects with all incoming unicode characters escaped. If
ensure_ascii is false, the output will be unicode object.
If check_circular is True, then lists, dicts, and custom encoded
If check_circular is true, then lists, dicts, and custom encoded
objects will be checked for circular references during encoding to
prevent an infinite recursion (which would cause an OverflowError).
Otherwise, no such check takes place.
If allow_nan is True, then NaN, Infinity, and -Infinity will be
If allow_nan is true, then NaN, Infinity, and -Infinity will be
encoded as such. This behavior is not JSON specification compliant,
but is consistent with most JavaScript based encoders and decoders.
Otherwise, it will be a ValueError to encode such floats.
If sort_keys is True, then the output of dictionaries will be
If sort_keys is true, then the output of dictionaries will be
sorted by key; this is useful for regression tests to ensure
that JSON serializations can be compared on a day-to-day basis.
......@@ -156,28 +136,130 @@ class JSONEncoder(object):
that can't otherwise be serialized. It should return a JSON encodable
version of the object or raise a ``TypeError``.
If encoding is not None, then all input strings will be
transformed into unicode using that encoding prior to JSON-encoding.
The default is UTF-8.
"""
self.skipkeys = skipkeys
self.ensure_ascii = ensure_ascii
self.check_circular = check_circular
self.allow_nan = allow_nan
self.sort_keys = sort_keys
self.indent = indent
self.current_indent_level = 0
if separators is not None:
self.item_separator, self.key_separator = separators
if default is not None:
self.default = default
self.encoding = encoding
def _newline_indent(self):
return '\n' + (' ' * (self.indent * self.current_indent_level))
def default(self, o):
"""Implement this method in a subclass such that it returns
a serializable object for ``o``, or calls the base implementation
(to raise a ``TypeError``).
For example, to support arbitrary iterators, you could
implement default like this::
def default(self, o):
try:
iterable = iter(o)
except TypeError:
pass
else:
return list(iterable)
return JSONEncoder.default(self, o)
"""
raise TypeError(repr(o) + " is not JSON serializable")
def encode(self, o):
"""Return a JSON string representation of a Python data structure.
>>> JSONEncoder().encode({"foo": ["bar", "baz"]})
'{"foo": ["bar", "baz"]}'
"""
# This is for extremely simple cases and benchmarks.
if isinstance(o, str):
if self.ensure_ascii:
return encode_basestring_ascii(o)
else:
return encode_basestring(o)
# This doesn't pass the iterator directly to ''.join() because the
# exceptions aren't as detailed. The list call should be roughly
# equivalent to the PySequence_Fast that ''.join() would do.
chunks = self.iterencode(o, _one_shot=True)
if not isinstance(chunks, (list, tuple)):
chunks = list(chunks)
return ''.join(chunks)
def iterencode(self, o, _one_shot=False):
"""Encode the given object and yield each string
representation as available.
For example::
for chunk in JSONEncoder().iterencode(bigobject):
mysocket.write(chunk)
"""
if self.check_circular:
markers = {}
else:
markers = None
if self.ensure_ascii:
_encoder = encode_basestring_ascii
else:
_encoder = encode_basestring
def floatstr(o, allow_nan=self.allow_nan,
_repr=FLOAT_REPR, _inf=INFINITY, _neginf=-INFINITY):
# Check for specials. Note that this type of test is processor
# and/or platform-specific, so do tests which don't depend on the
# internals.
if o != o:
text = 'NaN'
elif o == _inf:
text = 'Infinity'
elif o == _neginf:
text = '-Infinity'
else:
return _repr(o)
if not allow_nan:
raise ValueError(
"Out of range float values are not JSON compliant: " +
repr(o))
return text
def _iterencode_list(self, lst, markers=None):
if (_one_shot and c_make_encoder is not None
and not self.indent and not self.sort_keys):
_iterencode = c_make_encoder(
markers, self.default, _encoder, self.indent,
self.key_separator, self.item_separator, self.sort_keys,
self.skipkeys, self.allow_nan)
else:
_iterencode = _make_iterencode(
markers, self.default, _encoder, self.indent, floatstr,
self.key_separator, self.item_separator, self.sort_keys,
self.skipkeys, _one_shot)
return _iterencode(o, 0)
def _make_iterencode(markers, _default, _encoder, _indent, _floatstr,
_key_separator, _item_separator, _sort_keys, _skipkeys, _one_shot,
## HACK: hand-optimized bytecode; turn globals into locals
ValueError=ValueError,
dict=dict,
float=float,
id=id,
int=int,
isinstance=isinstance,
list=list,
str=str,
tuple=tuple,
):
def _iterencode_list(lst, _current_indent_level):
if not lst:
yield '[]'
return
......@@ -186,31 +268,51 @@ class JSONEncoder(object):
if markerid in markers:
raise ValueError("Circular reference detected")
markers[markerid] = lst
yield '['
if self.indent is not None:
self.current_indent_level += 1
newline_indent = self._newline_indent()
separator = self.item_separator + newline_indent
yield newline_indent
buf = '['
if _indent is not None:
_current_indent_level += 1
newline_indent = '\n' + (' ' * (_indent * _current_indent_level))
separator = _item_separator + newline_indent
buf += newline_indent
else:
newline_indent = None
separator = self.item_separator
separator = _item_separator
first = True
for value in lst:
if first:
first = False
else:
yield separator
for chunk in self._iterencode(value, markers):
yield chunk
buf = separator
if isinstance(value, str):
yield buf + _encoder(value)
elif value is None:
yield buf + 'null'
elif value is True:
yield buf + 'true'
elif value is False:
yield buf + 'false'
elif isinstance(value, int):
yield buf + str(value)
elif isinstance(value, float):
yield buf + _floatstr(value)
else:
yield buf
if isinstance(value, (list, tuple)):
chunks = _iterencode_list(value, _current_indent_level)
elif isinstance(value, dict):
chunks = _iterencode_dict(value, _current_indent_level)
else:
chunks = _iterencode(value, _current_indent_level)
for chunk in chunks:
yield chunk
if newline_indent is not None:
self.current_indent_level -= 1
yield self._newline_indent()
_current_indent_level -= 1
yield '\n' + (' ' * (_indent * _current_indent_level))
yield ']'
if markers is not None:
del markers[markerid]
def _iterencode_dict(self, dct, markers=None):
def _iterencode_dict(dct, _current_indent_level):
if not dct:
yield '{}'
return
......@@ -220,78 +322,75 @@ class JSONEncoder(object):
raise ValueError("Circular reference detected")
markers[markerid] = dct
yield '{'
key_separator = self.key_separator
if self.indent is not None:
self.current_indent_level += 1
newline_indent = self._newline_indent()
item_separator = self.item_separator + newline_indent
if _indent is not None:
_current_indent_level += 1
newline_indent = '\n' + (' ' * (_indent * _current_indent_level))
item_separator = _item_separator + newline_indent
yield newline_indent
else:
newline_indent = None
item_separator = self.item_separator
item_separator = _item_separator
first = True
if self.ensure_ascii:
encoder = encode_basestring_ascii
else:
encoder = encode_basestring
allow_nan = self.allow_nan
if self.sort_keys:
keys = list(dct.keys())
keys.sort()
items = [(k, dct[k]) for k in keys]
if _sort_keys:
items = sorted(dct.items(), key=lambda kv: kv[0])
else:
items = iter(dct.items())
_encoding = self.encoding
_do_decode = (_encoding is not None
and not (_encoding == 'utf-8'))
items = dct.items()
for key, value in items:
if isinstance(key, str):
if _do_decode:
key = key.decode(_encoding)
elif isinstance(key, str):
pass
# JavaScript is weakly typed for these, so it makes sense to
# also allow them. Many encoders seem to do something like this.
elif isinstance(key, float):
key = floatstr(key, allow_nan)
elif isinstance(key, (int, int)):
key = str(key)
key = _floatstr(key)
elif key is True:
key = 'true'
elif key is False:
key = 'false'
elif key is None:
key = 'null'
elif self.skipkeys:
elif isinstance(key, int):
key = str(key)
elif _skipkeys:
continue
else:
raise TypeError("key {0!r} is not a string".format(key))
raise TypeError("key " + repr(key) + " is not a string")
if first:
first = False
else:
yield item_separator
yield encoder(key)
yield key_separator
for chunk in self._iterencode(value, markers):
yield chunk
yield _encoder(key)
yield _key_separator
if isinstance(value, str):
yield _encoder(value)
elif value is None:
yield 'null'
elif value is True:
yield 'true'
elif value is False:
yield 'false'
elif isinstance(value, int):
yield str(value)
elif isinstance(value, float):
yield _floatstr(value)
else:
if isinstance(value, (list, tuple)):
chunks = _iterencode_list(value, _current_indent_level)
elif isinstance(value, dict):
chunks = _iterencode_dict(value, _current_indent_level)
else:
chunks = _iterencode(value, _current_indent_level)
for chunk in chunks:
yield chunk
if newline_indent is not None:
self.current_indent_level -= 1
yield self._newline_indent()
_current_indent_level -= 1
yield '\n' + (' ' * (_indent * _current_indent_level))
yield '}'
if markers is not None:
del markers[markerid]
def _iterencode(self, o, markers=None):
def _iterencode(o, _current_indent_level):
if isinstance(o, str):
if self.ensure_ascii:
encoder = encode_basestring_ascii
else:
encoder = encode_basestring
_encoding = self.encoding
if (_encoding is not None and isinstance(o, str)
and not (_encoding == 'utf-8')):
o = o.decode(_encoding)
yield encoder(o)
yield _encoder(o)
elif o is None:
yield 'null'
elif o is True:
......@@ -301,12 +400,12 @@ class JSONEncoder(object):
elif isinstance(o, (int, int)):
yield str(o)
elif isinstance(o, float):
yield floatstr(o, self.allow_nan)
yield _floatstr(o)
elif isinstance(o, (list, tuple)):
for chunk in self._iterencode_list(o, markers):
for chunk in _iterencode_list(o, _current_indent_level):
yield chunk
elif isinstance(o, dict):
for chunk in self._iterencode_dict(o, markers):
for chunk in _iterencode_dict(o, _current_indent_level):
yield chunk
else:
if markers is not None:
......@@ -314,71 +413,9 @@ class JSONEncoder(object):
if markerid in markers:
raise ValueError("Circular reference detected")
markers[markerid] = o
for chunk in self._iterencode_default(o, markers):
o = _default(o)
for chunk in _iterencode(o, _current_indent_level):
yield chunk
if markers is not None:
del markers[markerid]
def _iterencode_default(self, o, markers=None):
newobj = self.default(o)
return self._iterencode(newobj, markers)
def default(self, o):
"""Implement this method in a subclass such that it returns a serializable
object for ``o``, or calls the base implementation (to raise a
``TypeError``).
For example, to support arbitrary iterators, you could implement
default like this::
def default(self, o):
try:
iterable = iter(o)
except TypeError:
pass
else:
return list(iterable)
return JSONEncoder.default(self, o)
"""
raise TypeError(repr(o) + " is not JSON serializable")
def encode(self, o):
"""Return a JSON string representation of a Python data structure.
>>> JSONEncoder().encode({"foo": ["bar", "baz"]})
'{"foo": ["bar", "baz"]}'
"""
# This is for extremely simple cases and benchmarks.
if isinstance(o, (str, bytes)):
if isinstance(o, bytes):
_encoding = self.encoding
if (_encoding is not None
and not (_encoding == 'utf-8')):
o = o.decode(_encoding)
if self.ensure_ascii:
return encode_basestring_ascii(o)
else:
return encode_basestring(o)
# This doesn't pass the iterator directly to ''.join() because the
# exceptions aren't as detailed. The list call should be roughly
# equivalent to the PySequence_Fast that ''.join() would do.
chunks = list(self.iterencode(o))
return ''.join(chunks)
def iterencode(self, o):
"""Encode the given object and yield each string representation as
available.
For example::
for chunk in JSONEncoder().iterencode(bigobject):
mysocket.write(chunk)
"""
if self.check_circular:
markers = {}
else:
markers = None
return self._iterencode(o, markers)
return _iterencode
Lib/json/scanner.py
View file @ bbc85f30
"""Iterator based sre token scanner
"""JSON token scanner
"""
import re
import sre_parse
import sre_compile
import sre_constants
from re import VERBOSE, MULTILINE, DOTALL
from sre_constants import BRANCH, SUBPATTERN
try:
from _json import make_scanner as c_make_scanner
except ImportError:
c_make_scanner = None
__all__ = ['Scanner', 'pattern']
__all__ = ['make_scanner']
FLAGS = (VERBOSE | MULTILINE | DOTALL)
NUMBER_RE = re.compile(
r'(-?(?:0|[1-9]\d*))(\.\d+)?([eE][-+]?\d+)?',
(re.VERBOSE | re.MULTILINE | re.DOTALL))
class Scanner(object):
def __init__(self, lexicon, flags=FLAGS):
self.actions = [None]
# Combine phrases into a compound pattern
s = sre_parse.Pattern()
s.flags = flags
p = []
for idx, token in enumerate(lexicon):
phrase = token.pattern
try:
subpattern = sre_parse.SubPattern(s,
[(SUBPATTERN, (idx + 1, sre_parse.parse(phrase, flags)))])
except sre_constants.error:
raise
p.append(subpattern)
self.actions.append(token)
def py_make_scanner(context):
parse_object = context.parse_object
parse_array = context.parse_array
parse_string = context.parse_string
match_number = NUMBER_RE.match
strict = context.strict
parse_float = context.parse_float
parse_int = context.parse_int
parse_constant = context.parse_constant
object_hook = context.object_hook
s.groups = len(p) + 1 # NOTE(guido): Added to make SRE validation work
p = sre_parse.SubPattern(s, [(BRANCH, (None, p))])
self.scanner = sre_compile.compile(p)
def _scan_once(string, idx):
try:
nextchar = string[idx]
except IndexError:
raise StopIteration
def iterscan(self, string, idx=0, context=None):
"""Yield match, end_idx for each match
if nextchar == '"':
return parse_string(string, idx + 1, strict)
elif nextchar == '{':
return parse_object((string, idx + 1), strict,
_scan_once, object_hook, object_pairs_hook)
elif nextchar == '[':
return parse_array((string, idx + 1), _scan_once)
elif nextchar == 'n' and string[idx:idx + 4] == 'null':
return None, idx + 4
elif nextchar == 't' and string[idx:idx + 4] == 'true':
return True, idx + 4
elif nextchar == 'f' and string[idx:idx + 5] == 'false':
return False, idx + 5
"""
match = self.scanner.scanner(string, idx).match
actions = self.actions
lastend = idx
end = len(string)
while True:
m = match()
if m is None:
break
matchbegin, matchend = m.span()
if lastend == matchend:
break
action = actions[m.lastindex]
if action is not None:
rval, next_pos = action(m, context)
if next_pos is not None and next_pos != matchend:
# "fast forward" the scanner
matchend = next_pos
match = self.scanner.scanner(string, matchend).match
yield rval, matchend
lastend = matchend
m = match_number(string, idx)
if m is not None:
integer, frac, exp = m.groups()
if frac or exp:
res = parse_float(integer + (frac or '') + (exp or ''))
else:
res = parse_int(integer)
return res, m.end()
elif nextchar == 'N' and string[idx:idx + 3] == 'NaN':
return parse_constant('NaN'), idx + 3
elif nextchar == 'I' and string[idx:idx + 8] == 'Infinity':
return parse_constant('Infinity'), idx + 8
elif nextchar == '-' and string[idx:idx + 9] == '-Infinity':
return parse_constant('-Infinity'), idx + 9
else:
raise StopIteration
return _scan_once
def pattern(pattern, flags=FLAGS):
def decorator(fn):
fn.pattern = pattern
fn.regex = re.compile(pattern, flags)
return fn
return decorator
make_scanner = c_make_scanner or py_make_scanner
Lib/json/tests/test_decode.py
View file @ bbc85f30
......@@ -32,3 +32,10 @@ class TestDecode(TestCase):
object_pairs_hook = OrderedDict,
object_hook = lambda x: None),
OrderedDict(p))
def test_decoder_optimizations(self):
# Several optimizations were made that skip over calls to
# the whitespace regex, so this test is designed to try and
# exercise the uncommon cases. The array cases are already covered.
rval = json.loads('{ "key" : "value" , "k":"v" }')
self.assertEquals(rval, {"key":"value", "k":"v"})
Lib/json/tests/test_dump.py
View file @ bbc85f30
......@@ -11,3 +11,11 @@ class TestDump(TestCase):
def test_dumps(self):
self.assertEquals(json.dumps({}), '{}')
def test_encode_truefalse(self):
self.assertEquals(json.dumps(
{True: False, False: True}, sort_keys=True),
'{"false": true, "true": false}')
self.assertEquals(json.dumps(
{2: 3.0, 4.0: 5, False: 1, 6: True}, sort_keys=True),
'{"false": 1, "2": 3.0, "4.0": 5, "6": true}')
Lib/json/tests/test_encode_basestring_ascii.py
View file @ bbc85f30
......@@ -3,22 +3,20 @@ from unittest import TestCase
import json.encoder
CASES = [
('/\\"\ucafe\ubabe\uab98\ufcde\ubcda\uef4a\x08\x0c\n\r\t`1~!@#$%^&*()_+-=[]{}|;:\',./<>?', b'"/\\\\\\"\\ucafe\\ubabe\\uab98\\ufcde\\ubcda\\uef4a\\b\\f\\n\\r\\t`1~!@#$%^&*()_+-=[]{}|;:\',./<>?"'),
('\u0123\u4567\u89ab\ucdef\uabcd\uef4a', b'"\\u0123\\u4567\\u89ab\\ucdef\\uabcd\\uef4a"'),
('controls', b'"controls"'),
('\x08\x0c\n\r\t', b'"\\b\\f\\n\\r\\t"'),
('{"object with 1 member":["array with 1 element"]}', b'"{\\"object with 1 member\\":[\\"array with 1 element\\"]}"'),
(' s p a c e d ', b'" s p a c e d "'),
('\U0001d120', b'"\\ud834\\udd20"'),
('\u03b1\u03a9', b'"\\u03b1\\u03a9"'),
(b'\xce\xb1\xce\xa9', b'"\\u03b1\\u03a9"'),
('\u03b1\u03a9', b'"\\u03b1\\u03a9"'),
(b'\xce\xb1\xce\xa9', b'"\\u03b1\\u03a9"'),
('\u03b1\u03a9', b'"\\u03b1\\u03a9"'),
('\u03b1\u03a9', b'"\\u03b1\\u03a9"'),
("`1~!@#$%^&*()_+-={':[,]}|;.</>?", b'"`1~!@#$%^&*()_+-={\':[,]}|;.</>?"'),
('\x08\x0c\n\r\t', b'"\\b\\f\\n\\r\\t"'),
('\u0123\u4567\u89ab\ucdef\uabcd\uef4a', b'"\\u0123\\u4567\\u89ab\\ucdef\\uabcd\\uef4a"'),
('/\\"\ucafe\ubabe\uab98\ufcde\ubcda\uef4a\x08\x0c\n\r\t`1~!@#$%^&*()_+-=[]{}|;:\',./<>?', '"/\\\\\\"\\ucafe\\ubabe\\uab98\\ufcde\\ubcda\\uef4a\\b\\f\\n\\r\\t`1~!@#$%^&*()_+-=[]{}|;:\',./<>?"'),
('\u0123\u4567\u89ab\ucdef\uabcd\uef4a', '"\\u0123\\u4567\\u89ab\\ucdef\\uabcd\\uef4a"'),
('controls', '"controls"'),
('\x08\x0c\n\r\t', '"\\b\\f\\n\\r\\t"'),
('{"object with 1 member":["array with 1 element"]}', '"{\\"object with 1 member\\":[\\"array with 1 element\\"]}"'),
(' s p a c e d ', '" s p a c e d "'),
('\U0001d120', '"\\ud834\\udd20"'),
('\u03b1\u03a9', '"\\u03b1\\u03a9"'),
('\u03b1\u03a9', '"\\u03b1\\u03a9"'),
('\u03b1\u03a9', '"\\u03b1\\u03a9"'),
('\u03b1\u03a9', '"\\u03b1\\u03a9"'),
("`1~!@#$%^&*()_+-={':[,]}|;.</>?", '"`1~!@#$%^&*()_+-={\':[,]}|;.</>?"'),
('\x08\x0c\n\r\t', '"\\b\\f\\n\\r\\t"'),
('\u0123\u4567\u89ab\ucdef\uabcd\uef4a', '"\\u0123\\u4567\\u89ab\\ucdef\\uabcd\\uef4a"'),
]
class TestEncodeBaseStringAscii(TestCase):
......@@ -26,12 +24,14 @@ class TestEncodeBaseStringAscii(TestCase):
self._test_encode_basestring_ascii(json.encoder.py_encode_basestring_ascii)
def test_c_encode_basestring_ascii(self):
if json.encoder.c_encode_basestring_ascii is not None:
self._test_encode_basestring_ascii(json.encoder.c_encode_basestring_ascii)
if not json.encoder.c_encode_basestring_ascii:
return
self._test_encode_basestring_ascii(json.encoder.c_encode_basestring_ascii)
def _test_encode_basestring_ascii(self, encode_basestring_ascii):
fname = encode_basestring_ascii.__name__
for input_string, expect in CASES:
result = encode_basestring_ascii(input_string)
result = result.encode("ascii")
self.assertEquals(result, expect)
self.assertEquals(result, expect,
'{0!r} != {1!r} for {2}({3!r})'.format(
result, expect, fname, input_string))
Lib/json/tests/test_fail.py
View file @ bbc85f30
......@@ -73,4 +73,4 @@ class TestFail(TestCase):
except ValueError:
pass
else:
self.fail("Expected failure for fail%d.json: %r" % (idx, doc))
self.fail("Expected failure for fail{0}.json: {1!r}".format(idx, doc))
Lib/json/tests/test_float.py
View file @ bbc85f30
......@@ -5,5 +5,11 @@ import json
class TestFloat(TestCase):
def test_floats(self):
for num in [1617161771.7650001, math.pi, math.pi**100, math.pi**-100]:
for num in [1617161771.7650001, math.pi, math.pi**100, math.pi**-100, 3.1]:
self.assertEquals(float(json.dumps(num)), num)
self.assertEquals(json.loads(json.dumps(num)), num)
def test_ints(self):
for num in [1, 1<<32, 1<<64]:
self.assertEquals(json.dumps(num), str(num))
self.assertEquals(int(json.dumps(num)), num)
Lib/json/tests/test_scanstring.py
View file @ bbc85f30
......@@ -15,96 +15,90 @@ class TestScanString(TestCase):
def _test_scanstring(self, scanstring):
self.assertEquals(
scanstring('"z\\ud834\\udd20x"', 1, None, True),
scanstring('"z\\ud834\\udd20x"', 1, True),
('z\U0001d120x', 16))
if sys.maxunicode == 65535:
self.assertEquals(
scanstring('"z\U0001d120x"', 1, None, True),
scanstring('"z\U0001d120x"', 1, True),
('z\U0001d120x', 6))
else:
self.assertEquals(
scanstring('"z\U0001d120x"', 1, None, True),
scanstring('"z\U0001d120x"', 1, True),
('z\U0001d120x', 5))
self.assertEquals(
scanstring('"\\u007b"', 1, None, True),
scanstring('"\\u007b"', 1, True),
('{', 8))
self.assertEquals(
scanstring('"A JSON payload should be an object or array, not a string."', 1, None, True),
scanstring('"A JSON payload should be an object or array, not a string."', 1, True),
('A JSON payload should be an object or array, not a string.', 60))
self.assertEquals(
scanstring('["Unclosed array"', 2, None, True),
scanstring('["Unclosed array"', 2, True),
('Unclosed array', 17))
self.assertEquals(
scanstring('["extra comma",]', 2, None, True),
scanstring('["extra comma",]', 2, True),
('extra comma', 14))
self.assertEquals(
scanstring('["double extra comma",,]', 2, None, True),
scanstring('["double extra comma",,]', 2, True),
('double extra comma', 21))
self.assertEquals(
scanstring('["Comma after the close"],', 2, None, True),
scanstring('["Comma after the close"],', 2, True),
('Comma after the close', 24))
self.assertEquals(
scanstring('["Extra close"]]', 2, None, True),
scanstring('["Extra close"]]', 2, True),
('Extra close', 14))
self.assertEquals(
scanstring('{"Extra comma": true,}', 2, None, True),
scanstring('{"Extra comma": true,}', 2, True),
('Extra comma', 14))
self.assertEquals(
scanstring('{"Extra value after close": true} "misplaced quoted value"', 2, None, True),
scanstring('{"Extra value after close": true} "misplaced quoted value"', 2, True),
('Extra value after close', 26))
self.assertEquals(
scanstring('{"Illegal expression": 1 + 2}', 2, None, True),
scanstring('{"Illegal expression": 1 + 2}', 2, True),
('Illegal expression', 21))
self.assertEquals(
scanstring('{"Illegal invocation": alert()}', 2, None, True),
scanstring('{"Illegal invocation": alert()}', 2, True),
('Illegal invocation', 21))
self.assertEquals(
scanstring('{"Numbers cannot have leading zeroes": 013}', 2, None, True),
scanstring('{"Numbers cannot have leading zeroes": 013}', 2, True),
('Numbers cannot have leading zeroes', 37))
self.assertEquals(
scanstring('{"Numbers cannot be hex": 0x14}', 2, None, True),
scanstring('{"Numbers cannot be hex": 0x14}', 2, True),
('Numbers cannot be hex', 24))
self.assertEquals(
scanstring('[[[[[[[[[[[[[[[[[[[["Too deep"]]]]]]]]]]]]]]]]]]]]', 21, None, True),
scanstring('[[[[[[[[[[[[[[[[[[[["Too deep"]]]]]]]]]]]]]]]]]]]]', 21, True),
('Too deep', 30))
self.assertEquals(
scanstring('{"Missing colon" null}', 2, None, True),
scanstring('{"Missing colon" null}', 2, True),
('Missing colon', 16))
self.assertEquals(
scanstring('{"Double colon":: null}', 2, None, True),
scanstring('{"Double colon":: null}', 2, True),
('Double colon', 15))
self.assertEquals(
scanstring('{"Comma instead of colon", null}', 2, None, True),
scanstring('{"Comma instead of colon", null}', 2, True),
('Comma instead of colon', 25))
self.assertEquals(
scanstring('["Colon instead of comma": false]', 2, None, True),
scanstring('["Colon instead of comma": false]', 2, True),
('Colon instead of comma', 25))
self.assertEquals(
scanstring('["Bad value", truth]', 2, None, True),
scanstring('["Bad value", truth]', 2, True),
('Bad value', 12))
def test_issue3623(self):
self.assertRaises(ValueError, json.decoder.scanstring, b"xxx", 1,
"xxx")
self.assertRaises(UnicodeDecodeError,
json.encoder.encode_basestring_ascii, b"xx\xff")
Lib/json/tests/test_unicode.py
View file @ bbc85f30
......@@ -4,20 +4,8 @@ import json
from collections import OrderedDict
class TestUnicode(TestCase):
def test_encoding1(self):
encoder = json.JSONEncoder(encoding='utf-8')
u = '\N{GREEK SMALL LETTER ALPHA}\N{GREEK CAPITAL LETTER OMEGA}'
s = u.encode('utf-8')
ju = encoder.encode(u)
js = encoder.encode(s)
self.assertEquals(ju, js)
def test_encoding2(self):
u = '\N{GREEK SMALL LETTER ALPHA}\N{GREEK CAPITAL LETTER OMEGA}'
s = u.encode('utf-8')
ju = json.dumps(u, encoding='utf-8')
js = json.dumps(s, encoding='utf-8')
self.assertEquals(ju, js)
# test_encoding1 and test_encoding2 from 2.x are irrelevant (only str
# is supported as input, not bytes).
def test_encoding3(self):
u = '\N{GREEK SMALL LETTER ALPHA}\N{GREEK CAPITAL LETTER OMEGA}'
......@@ -52,8 +40,22 @@ class TestUnicode(TestCase):
def test_unicode_decode(self):
for i in range(0, 0xd7ff):
u = chr(i)
js = '"\\u{0:04x}"'.format(i)
self.assertEquals(json.loads(js), u)
s = '"\\u{0:04x}"'.format(i)
self.assertEquals(json.loads(s), u)
def test_unicode_preservation(self):
self.assertEquals(type(json.loads('""')), str)
self.assertEquals(type(json.loads('"a"')), str)
self.assertEquals(type(json.loads('["a"]')[0]), str)
def test_bytes_encode(self):
self.assertRaises(TypeError, json.dumps, b"hi")
self.assertRaises(TypeError, json.dumps, [b"hi"])
def test_bytes_decode(self):
self.assertRaises(TypeError, json.loads, b'"hi"')
self.assertRaises(TypeError, json.loads, b'["hi"]')
def test_object_pairs_hook_with_unicode(self):
s = '{"xkd":1, "kcw":2, "art":3, "hxm":4, "qrt":5, "pad":6, "hoy":7}'
......
Lib/json/tool.py
View file @ bbc85f30
......@@ -2,11 +2,11 @@ r"""Command-line tool to validate and pretty-print JSON
Usage::
$ echo '{"json":"obj"}' | python -mjson.tool
$ echo '{"json":"obj"}' | python -m json.tool
{
"json": "obj"
}
$ echo '{ 1.2:3.4}' | python -mjson.tool
$ echo '{ 1.2:3.4}' | python -m json.tool
Expecting property name: line 1 column 2 (char 2)
"""
......@@ -24,7 +24,7 @@ def main():
infile = open(sys.argv[1], 'rb')
outfile = open(sys.argv[2], 'wb')
else:
raise SystemExit("{0} [infile [outfile]]".format(sys.argv[0]))
raise SystemExit(sys.argv[0] + " [infile [outfile]]")
try:
obj = json.load(infile)
except ValueError as e:
......
Misc/NEWS
View file @ bbc85f30
......@@ -107,6 +107,8 @@ Installation
Library
-------
- The json module now works exclusively with str and not bytes.
- Issue #3959: The ipaddr module has been added to the standard library.
Contributed by Google.
......
Modules/_json.c
View file @ bbc85f30
#include "Python.h"
#include "structmember.h"
#if PY_VERSION_HEX < 0x02060000 && !defined(Py_TYPE)
#define Py_TYPE(ob) (((PyObject*)(ob))->ob_type)
#endif
#if PY_VERSION_HEX < 0x02050000 && !defined(PY_SSIZE_T_MIN)
typedef int Py_ssize_t;
#define PY_SSIZE_T_MAX INT_MAX
#define PY_SSIZE_T_MIN INT_MIN
#define PyInt_FromSsize_t PyInt_FromLong
#define PyInt_AsSsize_t PyInt_AsLong
#endif
#ifndef Py_IS_FINITE
#define Py_IS_FINITE(X) (!Py_IS_INFINITY(X) && !Py_IS_NAN(X))
#endif
#ifdef __GNUC__
#define UNUSED __attribute__((__unused__))
#else
#define UNUSED
#endif
#define PyScanner_Check(op) PyObject_TypeCheck(op, &PyScannerType)
#define PyScanner_CheckExact(op) (Py_TYPE(op) == &PyScannerType)
#define PyEncoder_Check(op) PyObject_TypeCheck(op, &PyEncoderType)
#define PyEncoder_CheckExact(op) (Py_TYPE(op) == &PyEncoderType)
static PyTypeObject PyScannerType;
static PyTypeObject PyEncoderType;
typedef struct _PyScannerObject {
PyObject_HEAD
PyObject *strict;
PyObject *object_hook;
PyObject *object_pairs_hook;
PyObject *parse_float;
PyObject *parse_int;
PyObject *parse_constant;
} PyScannerObject;
static PyMemberDef scanner_members[] = {
{"strict", T_OBJECT, offsetof(PyScannerObject, strict), READONLY, "strict"},
{"object_hook", T_OBJECT, offsetof(PyScannerObject, object_hook), READONLY, "object_hook"},
{"object_pairs_hook", T_OBJECT, offsetof(PyScannerObject, object_pairs_hook), READONLY},
{"parse_float", T_OBJECT, offsetof(PyScannerObject, parse_float), READONLY, "parse_float"},
{"parse_int", T_OBJECT, offsetof(PyScannerObject, parse_int), READONLY, "parse_int"},
{"parse_constant", T_OBJECT, offsetof(PyScannerObject, parse_constant), READONLY, "parse_constant"},
{NULL}
};
typedef struct _PyEncoderObject {
PyObject_HEAD
PyObject *markers;
PyObject *defaultfn;
PyObject *encoder;
PyObject *indent;
PyObject *key_separator;
PyObject *item_separator;
PyObject *sort_keys;
PyObject *skipkeys;
int fast_encode;
int allow_nan;
} PyEncoderObject;
static PyMemberDef encoder_members[] = {
{"markers", T_OBJECT, offsetof(PyEncoderObject, markers), READONLY, "markers"},
{"default", T_OBJECT, offsetof(PyEncoderObject, defaultfn), READONLY, "default"},
{"encoder", T_OBJECT, offsetof(PyEncoderObject, encoder), READONLY, "encoder"},
{"indent", T_OBJECT, offsetof(PyEncoderObject, indent), READONLY, "indent"},
{"key_separator", T_OBJECT, offsetof(PyEncoderObject, key_separator), READONLY, "key_separator"},
{"item_separator", T_OBJECT, offsetof(PyEncoderObject, item_separator), READONLY, "item_separator"},
{"sort_keys", T_OBJECT, offsetof(PyEncoderObject, sort_keys), READONLY, "sort_keys"},
{"skipkeys", T_OBJECT, offsetof(PyEncoderObject, skipkeys), READONLY, "skipkeys"},
{NULL}
};
static PyObject *
ascii_escape_unicode(PyObject *pystr);
static PyObject *
py_encode_basestring_ascii(PyObject* self UNUSED, PyObject *pystr);
void init_json(void);
static PyObject *
scan_once_unicode(PyScannerObject *s, PyObject *pystr, Py_ssize_t idx, Py_ssize_t *next_idx_ptr);
static PyObject *
_build_rval_index_tuple(PyObject *rval, Py_ssize_t idx);
static PyObject *
scanner_new(PyTypeObject *type, PyObject *args, PyObject *kwds);
static int
scanner_init(PyObject *self, PyObject *args, PyObject *kwds);
static void
scanner_dealloc(PyObject *self);
static int
scanner_clear(PyObject *self);
static PyObject *
encoder_new(PyTypeObject *type, PyObject *args, PyObject *kwds);
static int
encoder_init(PyObject *self, PyObject *args, PyObject *kwds);
static void
encoder_dealloc(PyObject *self);
static int
encoder_clear(PyObject *self);
static int
encoder_listencode_list(PyEncoderObject *s, PyObject *rval, PyObject *seq, Py_ssize_t indent_level);
static int
encoder_listencode_obj(PyEncoderObject *s, PyObject *rval, PyObject *obj, Py_ssize_t indent_level);
static int
encoder_listencode_dict(PyEncoderObject *s, PyObject *rval, PyObject *dct, Py_ssize_t indent_level);
static PyObject *
_encoded_const(PyObject *const);
static void
raise_errmsg(char *msg, PyObject *s, Py_ssize_t end);
static PyObject *
encoder_encode_string(PyEncoderObject *s, PyObject *obj);
static int
_convertPyInt_AsSsize_t(PyObject *o, Py_ssize_t *size_ptr);
static PyObject *
_convertPyInt_FromSsize_t(Py_ssize_t *size_ptr);
static PyObject *
encoder_encode_float(PyEncoderObject *s, PyObject *obj);
#define DEFAULT_ENCODING "utf-8"
#define S_CHAR(c) (c >= ' ' && c <= '~' && c != '\\' && c != '"')
#define MIN_EXPANSION 6
#define IS_WHITESPACE(c) (((c) == ' ') || ((c) == '\t') || ((c) == '\n') || ((c) == '\r'))
#define MIN_EXPANSION 6
#ifdef Py_UNICODE_WIDE
#define MAX_EXPANSION (2 * MIN_EXPANSION)
#else
#define MAX_EXPANSION MIN_EXPANSION
#endif
static int
_convertPyInt_AsSsize_t(PyObject *o, Py_ssize_t *size_ptr)
{
/* PyObject to Py_ssize_t converter */
*size_ptr = PyLong_AsSsize_t(o);
if (*size_ptr == -1 && PyErr_Occurred());
return 1;
return 0;
}
static PyObject *
_convertPyInt_FromSsize_t(Py_ssize_t *size_ptr)
{
/* Py_ssize_t to PyObject converter */
return PyLong_FromSsize_t(*size_ptr);
}
static Py_ssize_t
ascii_escape_char(Py_UNICODE c, char *output, Py_ssize_t chars)
ascii_escape_unichar(Py_UNICODE c, Py_UNICODE *output, Py_ssize_t chars)
{
Py_UNICODE x;
/* Escape unicode code point c to ASCII escape sequences
in char *output. output must have at least 12 bytes unused to
accommodate an escaped surrogate pair "\uXXXX\uXXXX" */
output[chars++] = '\\';
switch (c) {
case '\\': output[chars++] = (char)c; break;
case '"': output[chars++] = (char)c; break;
case '\\': output[chars++] = c; break;
case '"': output[chars++] = c; break;
case '\b': output[chars++] = 'b'; break;
case '\f': output[chars++] = 'f'; break;
case '\n': output[chars++] = 'n'; break;
......@@ -30,27 +167,19 @@ ascii_escape_char(Py_UNICODE c, char *output, Py_ssize_t chars)
Py_UNICODE v = c - 0x10000;
c = 0xd800 | ((v >> 10) & 0x3ff);
output[chars++] = 'u';
x = (c & 0xf000) >> 12;
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
x = (c & 0x0f00) >> 8;
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
x = (c & 0x00f0) >> 4;
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
x = (c & 0x000f);
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
output[chars++] = "0123456789abcdef"[(c >> 12) & 0xf];
output[chars++] = "0123456789abcdef"[(c >> 8) & 0xf];
output[chars++] = "0123456789abcdef"[(c >> 4) & 0xf];
output[chars++] = "0123456789abcdef"[(c ) & 0xf];
c = 0xdc00 | (v & 0x3ff);
output[chars++] = '\\';
}
#endif
output[chars++] = 'u';
x = (c & 0xf000) >> 12;
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
x = (c & 0x0f00) >> 8;
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
x = (c & 0x00f0) >> 4;
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
x = (c & 0x000f);
output[chars++] = (x < 10) ? '0' + x : 'a' + (x - 10);
output[chars++] = "0123456789abcdef"[(c >> 12) & 0xf];
output[chars++] = "0123456789abcdef"[(c >> 8) & 0xf];
output[chars++] = "0123456789abcdef"[(c >> 4) & 0xf];
output[chars++] = "0123456789abcdef"[(c ) & 0xf];
}
return chars;
}
......@@ -58,118 +187,66 @@ ascii_escape_char(Py_UNICODE c, char *output, Py_ssize_t chars)
static PyObject *
ascii_escape_unicode(PyObject *pystr)
{
/* Take a PyUnicode pystr and return a new ASCII-only escaped PyUnicode */
Py_ssize_t i;
Py_ssize_t input_chars;
Py_ssize_t output_size;
Py_ssize_t max_output_size;
Py_ssize_t chars;
PyObject *rval;
char *output;
Py_UNICODE *output;
Py_UNICODE *input_unicode;
input_chars = PyUnicode_GET_SIZE(pystr);
input_unicode = PyUnicode_AS_UNICODE(pystr);
/* One char input can be up to 6 chars output, estimate 4 of these */
output_size = 2 + (MIN_EXPANSION * 4) + input_chars;
rval = PyBytes_FromStringAndSize(NULL, output_size);
max_output_size = 2 + (input_chars * MAX_EXPANSION);
rval = PyUnicode_FromStringAndSize(NULL, output_size);
if (rval == NULL) {
return NULL;
}
output = PyBytes_AS_STRING(rval);
output = PyUnicode_AS_UNICODE(rval);
chars = 0;
output[chars++] = '"';
for (i = 0; i < input_chars; i++) {
Py_UNICODE c = input_unicode[i];
if (S_CHAR(c)) {
output[chars++] = (char)c;
output[chars++] = c;
}
else {
chars = ascii_escape_char(c, output, chars);
else {
chars = ascii_escape_unichar(c, output, chars);
}
if (output_size - chars < (1 + MAX_EXPANSION)) {
/* There's more than four, so let's resize by a lot */
output_size *= 2;
Py_ssize_t new_output_size = output_size * 2;
/* This is an upper bound */
if (output_size > 2 + (input_chars * MAX_EXPANSION)) {
output_size = 2 + (input_chars * MAX_EXPANSION);
}
if (_PyBytes_Resize(&rval, output_size) == -1) {
return NULL;
}
output = PyBytes_AS_STRING(rval);
}
}
output[chars++] = '"';
if (_PyBytes_Resize(&rval, chars) == -1) {
return NULL;
}
return rval;
}
static PyObject *
ascii_escape_str(PyObject *pystr)
{
Py_ssize_t i;
Py_ssize_t input_chars;
Py_ssize_t output_size;
Py_ssize_t chars;
PyObject *rval;
char *output;
char *input_str;
input_chars = PyBytes_GET_SIZE(pystr);
input_str = PyBytes_AS_STRING(pystr);
/* One char input can be up to 6 chars output, estimate 4 of these */
output_size = 2 + (MIN_EXPANSION * 4) + input_chars;
rval = PyBytes_FromStringAndSize(NULL, output_size);
if (rval == NULL) {
return NULL;
}
output = PyBytes_AS_STRING(rval);
chars = 0;
output[chars++] = '"';
for (i = 0; i < input_chars; i++) {
Py_UNICODE c = (Py_UNICODE)input_str[i];
if (S_CHAR(c)) {
output[chars++] = (char)c;
}
else if (c > 0x7F) {
/* We hit a non-ASCII character, bail to unicode mode */
PyObject *uni;
Py_DECREF(rval);
uni = PyUnicode_DecodeUTF8(input_str, input_chars, "strict");
if (uni == NULL) {
return NULL;
}
rval = ascii_escape_unicode(uni);
Py_DECREF(uni);
return rval;
}
else {
chars = ascii_escape_char(c, output, chars);
}
/* An ASCII char can't possibly expand to a surrogate! */
if (output_size - chars < (1 + MIN_EXPANSION)) {
/* There's more than four, so let's resize by a lot */
output_size *= 2;
if (output_size > 2 + (input_chars * MIN_EXPANSION)) {
output_size = 2 + (input_chars * MIN_EXPANSION);
if (new_output_size > max_output_size) {
new_output_size = max_output_size;
}
if (_PyBytes_Resize(&rval, output_size) == -1) {
return NULL;
/* Make sure that the output size changed before resizing */
if (new_output_size != output_size) {
output_size = new_output_size;
if (PyUnicode_Resize(&rval, output_size) == -1) {
return NULL;
}
output = PyUnicode_AS_UNICODE(rval);
}
output = PyBytes_AS_STRING(rval);
}
}
output[chars++] = '"';
if (_PyBytes_Resize(&rval, chars) == -1) {
if (PyUnicode_Resize(&rval, chars) == -1) {
return NULL;
}
return rval;
}
void
static void
raise_errmsg(char *msg, PyObject *s, Py_ssize_t end)
{
/* Use the Python function json.decoder.errmsg to raise a nice
looking ValueError exception */
static PyObject *errmsg_fn = NULL;
PyObject *pymsg;
if (errmsg_fn == NULL) {
......@@ -177,228 +254,68 @@ raise_errmsg(char *msg, PyObject *s, Py_ssize_t end)
if (decoder == NULL)
return;
errmsg_fn = PyObject_GetAttrString(decoder, "errmsg");
Py_DECREF(decoder);
if (errmsg_fn == NULL)
return;
Py_DECREF(decoder);
}
pymsg = PyObject_CallFunction(errmsg_fn, "(zOn)", msg, s, end);
pymsg = PyObject_CallFunction(errmsg_fn, "(zOO&)", msg, s, _convertPyInt_FromSsize_t, &end);
if (pymsg) {
PyErr_SetObject(PyExc_ValueError, pymsg);
Py_DECREF(pymsg);
}
/*
def linecol(doc, pos):
lineno = doc.count('\n', 0, pos) + 1
if lineno == 1:
colno = pos
else:
colno = pos - doc.rindex('\n', 0, pos)
return lineno, colno
def errmsg(msg, doc, pos, end=None):
lineno, colno = linecol(doc, pos)
if end is None:
return '%s: line %d column %d (char %d)' % (msg, lineno, colno, pos)
endlineno, endcolno = linecol(doc, end)
return '%s: line %d column %d - line %d column %d (char %d - %d)' % (
msg, lineno, colno, endlineno, endcolno, pos, end)
*/
}
static PyObject *
join_list_unicode(PyObject *lst)
{
static PyObject *ustr = NULL;
static PyObject *joinstr = NULL;
if (ustr == NULL) {
Py_UNICODE c = 0;
ustr = PyUnicode_FromUnicode(&c, 0);
}
if (joinstr == NULL) {
joinstr = PyUnicode_InternFromString("join");
}
if (joinstr == NULL || ustr == NULL) {
return NULL;
/* return u''.join(lst) */
static PyObject *sep = NULL;
if (sep == NULL) {
sep = PyUnicode_FromStringAndSize("", 0);
if (sep == NULL)
return NULL;
}
return PyObject_CallMethodObjArgs(ustr, joinstr, lst, NULL);
return PyUnicode_Join(sep, lst);
}
static PyObject *
scanstring_str(PyObject *pystr, Py_ssize_t end, char *encoding, int strict)
{
PyObject *rval;
Py_ssize_t len = PyBytes_GET_SIZE(pystr);
Py_ssize_t begin = end - 1;
Py_ssize_t next = begin;
char *buf = PyBytes_AS_STRING(pystr);
Py_buffer info;
PyObject *chunks = PyList_New(0);
if (chunks == NULL) {
goto bail;
}
if (end < 0 || len <= end) {
PyErr_SetString(PyExc_ValueError, "end is out of bounds");
goto bail;
_build_rval_index_tuple(PyObject *rval, Py_ssize_t idx) {
/* return (rval, idx) tuple, stealing reference to rval */
PyObject *tpl;
PyObject *pyidx;
/*
steal a reference to rval, returns (rval, idx)
*/
if (rval == NULL) {
return NULL;
}
while (1) {
/* Find the end of the string or the next escape */
Py_UNICODE c = 0;
PyObject *chunk = NULL;
for (next = end; next < len; next++) {
c = buf[next];
if (c == '"' || c == '\\') {
break;
}
else if (strict && c <= 0x1f) {
raise_errmsg("Invalid control character at", pystr, next);
goto bail;
}
}
if (!(c == '"' || c == '\\')) {
raise_errmsg("Unterminated string starting at", pystr, begin);
goto bail;
}
/* Pick up this chunk if it's not zero length */
if (next != end) {
PyObject *strchunk;
if (PyBuffer_FillInfo(&info, NULL, &buf[end], next - end, 1, 0) < 0) {
goto bail;
}
strchunk = PyMemoryView_FromBuffer(&info);
if (strchunk == NULL) {
goto bail;
}
chunk = PyUnicode_FromEncodedObject(strchunk, encoding, NULL);
Py_DECREF(strchunk);
if (chunk == NULL) {
goto bail;
}
if (PyList_Append(chunks, chunk)) {
Py_DECREF(chunk);
goto bail;
}
Py_DECREF(chunk);
}
next++;
if (c == '"') {
end = next;
break;
}
if (next == len) {
raise_errmsg("Unterminated string starting at", pystr, begin);
goto bail;
}
c = buf[next];
if (c != 'u') {
/* Non-unicode backslash escapes */
end = next + 1;
switch (c) {
case '"': break;
case '\\': break;
case '/': break;
case 'b': c = '\b'; break;
case 'f': c = '\f'; break;
case 'n': c = '\n'; break;
case 'r': c = '\r'; break;
case 't': c = '\t'; break;
default: c = 0;
}
if (c == 0) {
raise_errmsg("Invalid \\escape", pystr, end - 2);
goto bail;
}
}
else {
c = 0;
next++;
end = next + 4;
if (end >= len) {
raise_errmsg("Invalid \\uXXXX escape", pystr, next - 1);
goto bail;
}
/* Decode 4 hex digits */
for (; next < end; next++) {
Py_ssize_t shl = (end - next - 1) << 2;
Py_UNICODE digit = buf[next];
switch (digit) {
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
c |= (digit - '0') << shl; break;
case 'a': case 'b': case 'c': case 'd': case 'e':
case 'f':
c |= (digit - 'a' + 10) << shl; break;
case 'A': case 'B': case 'C': case 'D': case 'E':
case 'F':
c |= (digit - 'A' + 10) << shl; break;
default:
raise_errmsg("Invalid \\uXXXX escape", pystr, end - 5);
goto bail;
}
}
#ifdef Py_UNICODE_WIDE
/* Surrogate pair */
if (c >= 0xd800 && c <= 0xdbff) {
Py_UNICODE c2 = 0;
if (end + 6 >= len) {
raise_errmsg("Invalid \\uXXXX\\uXXXX surrogate pair", pystr,
end - 5);
}
if (buf[next++] != '\\' || buf[next++] != 'u') {
raise_errmsg("Invalid \\uXXXX\\uXXXX surrogate pair", pystr,
end - 5);
}
end += 6;
/* Decode 4 hex digits */
for (; next < end; next++) {
Py_ssize_t shl = (end - next - 1) << 2;
Py_UNICODE digit = buf[next];
switch (digit) {
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
c2 |= (digit - '0') << shl; break;
case 'a': case 'b': case 'c': case 'd': case 'e':
case 'f':
c2 |= (digit - 'a' + 10) << shl; break;
case 'A': case 'B': case 'C': case 'D': case 'E':
case 'F':
c2 |= (digit - 'A' + 10) << shl; break;
default:
raise_errmsg("Invalid \\uXXXX escape", pystr, end - 5);
goto bail;
}
}
c = 0x10000 + (((c - 0xd800) << 10) | (c2 - 0xdc00));
}
#endif
}
chunk = PyUnicode_FromUnicode(&c, 1);
if (chunk == NULL) {
goto bail;
}
if (PyList_Append(chunks, chunk)) {
Py_DECREF(chunk);
goto bail;
}
Py_DECREF(chunk);
pyidx = PyLong_FromSsize_t(idx);
if (pyidx == NULL) {
Py_DECREF(rval);
return NULL;
}
rval = join_list_unicode(chunks);
if (rval == NULL) {
goto bail;
tpl = PyTuple_New(2);
if (tpl == NULL) {
Py_DECREF(pyidx);
Py_DECREF(rval);
return NULL;
}
Py_CLEAR(chunks);
return Py_BuildValue("(Nn)", rval, end);
bail:
Py_XDECREF(chunks);
return NULL;
PyTuple_SET_ITEM(tpl, 0, rval);
PyTuple_SET_ITEM(tpl, 1, pyidx);
return tpl;
}
static PyObject *
scanstring_unicode(PyObject *pystr, Py_ssize_t end, int strict)
scanstring_unicode(PyObject *pystr, Py_ssize_t end, int strict, Py_ssize_t *next_end_ptr)
{
/* Read the JSON string from PyUnicode pystr.
end is the index of the first character after the quote.
if strict is zero then literal control characters are allowed
*next_end_ptr is a return-by-reference index of the character
after the end quote
Return value is a new PyUnicode
*/
PyObject *rval;
Py_ssize_t len = PyUnicode_GET_SIZE(pystr);
Py_ssize_t begin = end - 1;
......@@ -481,18 +398,18 @@ scanstring_unicode(PyObject *pystr, Py_ssize_t end, int strict)
}
/* Decode 4 hex digits */
for (; next < end; next++) {
Py_ssize_t shl = (end - next - 1) << 2;
Py_UNICODE digit = buf[next];
c <<= 4;
switch (digit) {
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
c |= (digit - '0') << shl; break;
c |= (digit - '0'); break;
case 'a': case 'b': case 'c': case 'd': case 'e':
case 'f':
c |= (digit - 'a' + 10) << shl; break;
c |= (digit - 'a' + 10); break;
case 'A': case 'B': case 'C': case 'D': case 'E':
case 'F':
c |= (digit - 'A' + 10) << shl; break;
c |= (digit - 'A' + 10); break;
default:
raise_errmsg("Invalid \\uXXXX escape", pystr, end - 5);
goto bail;
......@@ -500,38 +417,46 @@ scanstring_unicode(PyObject *pystr, Py_ssize_t end, int strict)
}
#ifdef Py_UNICODE_WIDE
/* Surrogate pair */
if (c >= 0xd800 && c <= 0xdbff) {
if ((c & 0xfc00) == 0xd800) {
Py_UNICODE c2 = 0;
if (end + 6 >= len) {
raise_errmsg("Invalid \\uXXXX\\uXXXX surrogate pair", pystr,
end - 5);
raise_errmsg("Unpaired high surrogate", pystr, end - 5);
goto bail;
}
if (buf[next++] != '\\' || buf[next++] != 'u') {
raise_errmsg("Invalid \\uXXXX\\uXXXX surrogate pair", pystr,
end - 5);
raise_errmsg("Unpaired high surrogate", pystr, end - 5);
goto bail;
}
end += 6;
/* Decode 4 hex digits */
for (; next < end; next++) {
Py_ssize_t shl = (end - next - 1) << 2;
c2 <<= 4;
Py_UNICODE digit = buf[next];
switch (digit) {
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
c2 |= (digit - '0') << shl; break;
c2 |= (digit - '0'); break;
case 'a': case 'b': case 'c': case 'd': case 'e':
case 'f':
c2 |= (digit - 'a' + 10) << shl; break;
c2 |= (digit - 'a' + 10); break;
case 'A': case 'B': case 'C': case 'D': case 'E':
case 'F':
c2 |= (digit - 'A' + 10) << shl; break;
c2 |= (digit - 'A' + 10); break;
default:
raise_errmsg("Invalid \\uXXXX escape", pystr, end - 5);
goto bail;
}
}
if ((c2 & 0xfc00) != 0xdc00) {
raise_errmsg("Unpaired high surrogate", pystr, end - 5);
goto bail;
}
c = 0x10000 + (((c - 0xd800) << 10) | (c2 - 0xdc00));
}
else if ((c & 0xfc00) == 0xdc00) {
raise_errmsg("Unpaired low surrogate", pystr, end - 5);
goto bail;
}
#endif
}
chunk = PyUnicode_FromUnicode(&c, 1);
......@@ -549,34 +474,41 @@ scanstring_unicode(PyObject *pystr, Py_ssize_t end, int strict)
if (rval == NULL) {
goto bail;
}
Py_CLEAR(chunks);
return Py_BuildValue("(Nn)", rval, end);
Py_DECREF(chunks);
*next_end_ptr = end;
return rval;
bail:
*next_end_ptr = -1;
Py_XDECREF(chunks);
return NULL;
}
PyDoc_STRVAR(pydoc_scanstring,
"scanstring(str_or_bytes, end, encoding) -> (bytes, end)\n");
"scanstring(basestring, end, strict=True) -> (bytes, end)\n"
"\n"
"Scan the string s for a JSON string. End is the index of the\n"
"character in s after the quote that started the JSON string.\n"
"Unescapes all valid JSON string escape sequences and raises ValueError\n"
"on attempt to decode an invalid string. If strict is False then literal\n"
"control characters are allowed in the string.\n"
"\n"
"Returns a tuple of the decoded string and the index of the character in s\n"
"after the end quote."
);
static PyObject *
py_scanstring(PyObject* self, PyObject *args)
py_scanstring(PyObject* self UNUSED, PyObject *args)
{
PyObject *pystr;
PyObject *rval;
Py_ssize_t end;
char *encoding = NULL;
int strict = 0;
if (!PyArg_ParseTuple(args, "On|zi:scanstring", &pystr, &end, &encoding, &strict)) {
Py_ssize_t next_end = -1;
int strict = 1;
if (!PyArg_ParseTuple(args, "OO&|i:scanstring", &pystr, _convertPyInt_AsSsize_t, &end, &strict)) {
return NULL;
}
if (encoding == NULL) {
encoding = DEFAULT_ENCODING;
}
if (PyBytes_Check(pystr)) {
return scanstring_str(pystr, end, encoding, strict);
}
else if (PyUnicode_Check(pystr)) {
return scanstring_unicode(pystr, end, strict);
if (PyUnicode_Check(pystr)) {
rval = scanstring_unicode(pystr, end, strict, &next_end);
}
else {
PyErr_Format(PyExc_TypeError,
......@@ -584,61 +516,1176 @@ py_scanstring(PyObject* self, PyObject *args)
Py_TYPE(pystr)->tp_name);
return NULL;
}
return _build_rval_index_tuple(rval, next_end);
}
PyDoc_STRVAR(pydoc_encode_basestring_ascii,
"encode_basestring_ascii(str_or_bytes) -> bytes\n");
"encode_basestring_ascii(basestring) -> bytes\n"
"\n"
"Return an ASCII-only JSON representation of a Python string"
);
static PyObject *
py_encode_basestring_ascii(PyObject* self, PyObject *pystr)
py_encode_basestring_ascii(PyObject* self UNUSED, PyObject *pystr)
{
PyObject *rval;
/* Return an ASCII-only JSON representation of a Python string */
/* METH_O */
if (PyBytes_Check(pystr)) {
rval = ascii_escape_str(pystr);
}
else if (PyUnicode_Check(pystr)) {
if (PyUnicode_Check(pystr)) {
rval = ascii_escape_unicode(pystr);
}
else {
PyErr_Format(PyExc_TypeError,
"first argument must be a string or unicode, not %.80s",
PyErr_Format(PyExc_TypeError,
"first argument must be a string, not %.80s",
Py_TYPE(pystr)->tp_name);
return NULL;
}
if (rval != NULL && PyBytes_Check(rval)) {
PyObject *urval = PyUnicode_DecodeASCII(PyBytes_AS_STRING(rval), PyBytes_GET_SIZE(rval), NULL);
Py_DECREF(rval);
return urval;
}
return rval;
}
static PyMethodDef json_methods[] = {
{"encode_basestring_ascii", (PyCFunction)py_encode_basestring_ascii,
METH_O, pydoc_encode_basestring_ascii},
{"scanstring", (PyCFunction)py_scanstring, METH_VARARGS,
pydoc_scanstring},
{NULL, NULL, 0, NULL}
};
PyDoc_STRVAR(module_doc,
"json speedups\n");
static void
scanner_dealloc(PyObject *self)
{
/* Deallocate scanner object */
scanner_clear(self);
Py_TYPE(self)->tp_free(self);
}
static struct PyModuleDef jsonmodule = {
PyModuleDef_HEAD_INIT,
"_json",
module_doc,
-1,
json_methods,
NULL,
NULL,
NULL,
NULL
};
static int
scanner_traverse(PyObject *self, visitproc visit, void *arg)
{
PyScannerObject *s;
assert(PyScanner_Check(self));
s = (PyScannerObject *)self;
Py_VISIT(s->strict);
Py_VISIT(s->object_hook);
Py_VISIT(s->object_pairs_hook);
Py_VISIT(s->parse_float);
Py_VISIT(s->parse_int);
Py_VISIT(s->parse_constant);
return 0;
}
PyObject*
PyInit__json(void)
static int
scanner_clear(PyObject *self)
{
return PyModule_Create(&jsonmodule);
PyScannerObject *s;
assert(PyScanner_Check(self));
s = (PyScannerObject *)self;
Py_CLEAR(s->strict);
Py_CLEAR(s->object_hook);
Py_CLEAR(s->object_pairs_hook);
Py_CLEAR(s->parse_float);
Py_CLEAR(s->parse_int);
Py_CLEAR(s->parse_constant);
return 0;
}
static PyObject *
_parse_object_unicode(PyScannerObject *s, PyObject *pystr, Py_ssize_t idx, Py_ssize_t *next_idx_ptr) {
/* Read a JSON object from PyUnicode pystr.
idx is the index of the first character after the opening curly brace.
*next_idx_ptr is a return-by-reference index to the first character after
the closing curly brace.
Returns a new PyObject (usually a dict, but object_hook can change that)
*/
Py_UNICODE *str = PyUnicode_AS_UNICODE(pystr);
Py_ssize_t end_idx = PyUnicode_GET_SIZE(pystr) - 1;
PyObject *val = NULL;
PyObject *rval = PyList_New(0);
PyObject *key = NULL;
int strict = PyObject_IsTrue(s->strict);
Py_ssize_t next_idx;
if (rval == NULL)
return NULL;
/* skip whitespace after { */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
/* only loop if the object is non-empty */
if (idx <= end_idx && str[idx] != '}') {
while (idx <= end_idx) {
/* read key */
if (str[idx] != '"') {
raise_errmsg("Expecting property name", pystr, idx);
goto bail;
}
key = scanstring_unicode(pystr, idx + 1, strict, &next_idx);
if (key == NULL)
goto bail;
idx = next_idx;
/* skip whitespace between key and : delimiter, read :, skip whitespace */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
if (idx > end_idx || str[idx] != ':') {
raise_errmsg("Expecting : delimiter", pystr, idx);
goto bail;
}
idx++;
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
/* read any JSON term */
val = scan_once_unicode(s, pystr, idx, &next_idx);
if (val == NULL)
goto bail;
{
PyObject *tuple = PyTuple_Pack(2, key, val);
if (tuple == NULL)
goto bail;
if (PyList_Append(rval, tuple) == -1) {
Py_DECREF(tuple);
goto bail;
}
Py_DECREF(tuple);
}
Py_CLEAR(key);
Py_CLEAR(val);
idx = next_idx;
/* skip whitespace before } or , */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
/* bail if the object is closed or we didn't get the , delimiter */
if (idx > end_idx) break;
if (str[idx] == '}') {
break;
}
else if (str[idx] != ',') {
raise_errmsg("Expecting , delimiter", pystr, idx);
goto bail;
}
idx++;
/* skip whitespace after , delimiter */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
}
}
/* verify that idx < end_idx, str[idx] should be '}' */
if (idx > end_idx || str[idx] != '}') {
raise_errmsg("Expecting object", pystr, end_idx);
goto bail;
}
*next_idx_ptr = idx + 1;
if (s->object_pairs_hook != Py_None) {
val = PyObject_CallFunctionObjArgs(s->object_pairs_hook, rval, NULL);
if (val == NULL)
goto bail;
Py_DECREF(rval);
return val;
}
val = PyDict_New();
if (val == NULL)
goto bail;
if (PyDict_MergeFromSeq2(val, rval, 1) == -1)
goto bail;
Py_DECREF(rval);
rval = val;
/* if object_hook is not None: rval = object_hook(rval) */
if (s->object_hook != Py_None) {
val = PyObject_CallFunctionObjArgs(s->object_hook, rval, NULL);
if (val == NULL)
goto bail;
Py_DECREF(rval);
rval = val;
val = NULL;
}
return rval;
bail:
Py_XDECREF(key);
Py_XDECREF(val);
Py_DECREF(rval);
return NULL;
}
static PyObject *
_parse_array_unicode(PyScannerObject *s, PyObject *pystr, Py_ssize_t idx, Py_ssize_t *next_idx_ptr) {
/* Read a JSON array from PyString pystr.
idx is the index of the first character after the opening brace.
*next_idx_ptr is a return-by-reference index to the first character after
the closing brace.
Returns a new PyList
*/
Py_UNICODE *str = PyUnicode_AS_UNICODE(pystr);
Py_ssize_t end_idx = PyUnicode_GET_SIZE(pystr) - 1;
PyObject *val = NULL;
PyObject *rval = PyList_New(0);
Py_ssize_t next_idx;
if (rval == NULL)
return NULL;
/* skip whitespace after [ */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
/* only loop if the array is non-empty */
if (idx <= end_idx && str[idx] != ']') {
while (idx <= end_idx) {
/* read any JSON term */
val = scan_once_unicode(s, pystr, idx, &next_idx);
if (val == NULL)
goto bail;
if (PyList_Append(rval, val) == -1)
goto bail;
Py_CLEAR(val);
idx = next_idx;
/* skip whitespace between term and , */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
/* bail if the array is closed or we didn't get the , delimiter */
if (idx > end_idx) break;
if (str[idx] == ']') {
break;
}
else if (str[idx] != ',') {
raise_errmsg("Expecting , delimiter", pystr, idx);
goto bail;
}
idx++;
/* skip whitespace after , */
while (idx <= end_idx && IS_WHITESPACE(str[idx])) idx++;
}
}
/* verify that idx < end_idx, str[idx] should be ']' */
if (idx > end_idx || str[idx] != ']') {
raise_errmsg("Expecting object", pystr, end_idx);
goto bail;
}
*next_idx_ptr = idx + 1;
return rval;
bail:
Py_XDECREF(val);
Py_DECREF(rval);
return NULL;
}
static PyObject *
_parse_constant(PyScannerObject *s, char *constant, Py_ssize_t idx, Py_ssize_t *next_idx_ptr) {
/* Read a JSON constant from PyString pystr.
constant is the constant string that was found
("NaN", "Infinity", "-Infinity").
idx is the index of the first character of the constant
*next_idx_ptr is a return-by-reference index to the first character after
the constant.
Returns the result of parse_constant
*/
PyObject *cstr;
PyObject *rval;
/* constant is "NaN", "Infinity", or "-Infinity" */
cstr = PyUnicode_InternFromString(constant);
if (cstr == NULL)
return NULL;
/* rval = parse_constant(constant) */
rval = PyObject_CallFunctionObjArgs(s->parse_constant, cstr, NULL);
idx += PyUnicode_GET_SIZE(cstr);
Py_DECREF(cstr);
*next_idx_ptr = idx;
return rval;
}
static PyObject *
_match_number_unicode(PyScannerObject *s, PyObject *pystr, Py_ssize_t start, Py_ssize_t *next_idx_ptr) {
/* Read a JSON number from PyUnicode pystr.
idx is the index of the first character of the number
*next_idx_ptr is a return-by-reference index to the first character after
the number.
Returns a new PyObject representation of that number:
PyInt, PyLong, or PyFloat.
May return other types if parse_int or parse_float are set
*/
Py_UNICODE *str = PyUnicode_AS_UNICODE(pystr);
Py_ssize_t end_idx = PyUnicode_GET_SIZE(pystr) - 1;
Py_ssize_t idx = start;
int is_float = 0;
PyObject *rval;
PyObject *numstr;
/* read a sign if it's there, make sure it's not the end of the string */
if (str[idx] == '-') {
idx++;
if (idx > end_idx) {
PyErr_SetNone(PyExc_StopIteration);
return NULL;
}
}
/* read as many integer digits as we find as long as it doesn't start with 0 */
if (str[idx] >= '1' && str[idx] <= '9') {
idx++;
while (idx <= end_idx && str[idx] >= '0' && str[idx] <= '9') idx++;
}
/* if it starts with 0 we only expect one integer digit */
else if (str[idx] == '0') {
idx++;
}
/* no integer digits, error */
else {
PyErr_SetNone(PyExc_StopIteration);
return NULL;
}
/* if the next char is '.' followed by a digit then read all float digits */
if (idx < end_idx && str[idx] == '.' && str[idx + 1] >= '0' && str[idx + 1] <= '9') {
is_float = 1;
idx += 2;
while (idx <= end_idx && str[idx] >= '0' && str[idx] <= '9') idx++;
}
/* if the next char is 'e' or 'E' then maybe read the exponent (or backtrack) */
if (idx < end_idx && (str[idx] == 'e' || str[idx] == 'E')) {
Py_ssize_t e_start = idx;
idx++;
/* read an exponent sign if present */
if (idx < end_idx && (str[idx] == '-' || str[idx] == '+')) idx++;
/* read all digits */
while (idx <= end_idx && str[idx] >= '0' && str[idx] <= '9') idx++;
/* if we got a digit, then parse as float. if not, backtrack */
if (str[idx - 1] >= '0' && str[idx - 1] <= '9') {
is_float = 1;
}
else {
idx = e_start;
}
}
/* copy the section we determined to be a number */
numstr = PyUnicode_FromUnicode(&str[start], idx - start);
if (numstr == NULL)
return NULL;
if (is_float) {
/* parse as a float using a fast path if available, otherwise call user defined method */
if (s->parse_float != (PyObject *)&PyFloat_Type) {
rval = PyObject_CallFunctionObjArgs(s->parse_float, numstr, NULL);
}
else {
rval = PyFloat_FromString(numstr);
}
}
else {
/* no fast path for unicode -> int, just call */
rval = PyObject_CallFunctionObjArgs(s->parse_int, numstr, NULL);
}
Py_DECREF(numstr);
*next_idx_ptr = idx;
return rval;
}
static PyObject *
scan_once_unicode(PyScannerObject *s, PyObject *pystr, Py_ssize_t idx, Py_ssize_t *next_idx_ptr)
{
/* Read one JSON term (of any kind) from PyUnicode pystr.
idx is the index of the first character of the term
*next_idx_ptr is a return-by-reference index to the first character after
the number.
Returns a new PyObject representation of the term.
*/
Py_UNICODE *str = PyUnicode_AS_UNICODE(pystr);
Py_ssize_t length = PyUnicode_GET_SIZE(pystr);
if (idx >= length) {
PyErr_SetNone(PyExc_StopIteration);
return NULL;
}
switch (str[idx]) {
case '"':
/* string */
return scanstring_unicode(pystr, idx + 1,
PyObject_IsTrue(s->strict),
next_idx_ptr);
case '{':
/* object */
return _parse_object_unicode(s, pystr, idx + 1, next_idx_ptr);
case '[':
/* array */
return _parse_array_unicode(s, pystr, idx + 1, next_idx_ptr);
case 'n':
/* null */
if ((idx + 3 < length) && str[idx + 1] == 'u' && str[idx + 2] == 'l' && str[idx + 3] == 'l') {
Py_INCREF(Py_None);
*next_idx_ptr = idx + 4;
return Py_None;
}
break;
case 't':
/* true */
if ((idx + 3 < length) && str[idx + 1] == 'r' && str[idx + 2] == 'u' && str[idx + 3] == 'e') {
Py_INCREF(Py_True);
*next_idx_ptr = idx + 4;
return Py_True;
}
break;
case 'f':
/* false */
if ((idx + 4 < length) && str[idx + 1] == 'a' && str[idx + 2] == 'l' && str[idx + 3] == 's' && str[idx + 4] == 'e') {
Py_INCREF(Py_False);
*next_idx_ptr = idx + 5;
return Py_False;
}
break;
case 'N':
/* NaN */
if ((idx + 2 < length) && str[idx + 1] == 'a' && str[idx + 2] == 'N') {
return _parse_constant(s, "NaN", idx, next_idx_ptr);
}
break;
case 'I':
/* Infinity */
if ((idx + 7 < length) && str[idx + 1] == 'n' && str[idx + 2] == 'f' && str[idx + 3] == 'i' && str[idx + 4] == 'n' && str[idx + 5] == 'i' && str[idx + 6] == 't' && str[idx + 7] == 'y') {
return _parse_constant(s, "Infinity", idx, next_idx_ptr);
}
break;
case '-':
/* -Infinity */
if ((idx + 8 < length) && str[idx + 1] == 'I' && str[idx + 2] == 'n' && str[idx + 3] == 'f' && str[idx + 4] == 'i' && str[idx + 5] == 'n' && str[idx + 6] == 'i' && str[idx + 7] == 't' && str[idx + 8] == 'y') {
return _parse_constant(s, "-Infinity", idx, next_idx_ptr);
}
break;
}
/* Didn't find a string, object, array, or named constant. Look for a number. */
return _match_number_unicode(s, pystr, idx, next_idx_ptr);
}
static PyObject *
scanner_call(PyObject *self, PyObject *args, PyObject *kwds)
{
/* Python callable interface to scan_once_{str,unicode} */
PyObject *pystr;
PyObject *rval;
Py_ssize_t idx;
Py_ssize_t next_idx = -1;
static char *kwlist[] = {"string", "idx", NULL};
PyScannerObject *s;
assert(PyScanner_Check(self));
s = (PyScannerObject *)self;
if (!PyArg_ParseTupleAndKeywords(args, kwds, "OO&:scan_once", kwlist, &pystr, _convertPyInt_AsSsize_t, &idx))
return NULL;
if (PyUnicode_Check(pystr)) {
rval = scan_once_unicode(s, pystr, idx, &next_idx);
}
else {
PyErr_Format(PyExc_TypeError,
"first argument must be a string, not %.80s",
Py_TYPE(pystr)->tp_name);
return NULL;
}
return _build_rval_index_tuple(rval, next_idx);
}
static PyObject *
scanner_new(PyTypeObject *type, PyObject *args, PyObject *kwds)
{
PyScannerObject *s;
s = (PyScannerObject *)type->tp_alloc(type, 0);
if (s != NULL) {
s->strict = NULL;
s->object_hook = NULL;
s->object_pairs_hook = NULL;
s->parse_float = NULL;
s->parse_int = NULL;
s->parse_constant = NULL;
}
return (PyObject *)s;
}
static int
scanner_init(PyObject *self, PyObject *args, PyObject *kwds)
{
/* Initialize Scanner object */
PyObject *ctx;
static char *kwlist[] = {"context", NULL};
PyScannerObject *s;
assert(PyScanner_Check(self));
s = (PyScannerObject *)self;
if (!PyArg_ParseTupleAndKeywords(args, kwds, "O:make_scanner", kwlist, &ctx))
return -1;
/* All of these will fail "gracefully" so we don't need to verify them */
s->strict = PyObject_GetAttrString(ctx, "strict");
if (s->strict == NULL)
goto bail;
s->object_hook = PyObject_GetAttrString(ctx, "object_hook");
if (s->object_hook == NULL)
goto bail;
s->object_pairs_hook = PyObject_GetAttrString(ctx, "object_pairs_hook");
if (s->object_pairs_hook == NULL)
goto bail;
s->parse_float = PyObject_GetAttrString(ctx, "parse_float");
if (s->parse_float == NULL)
goto bail;
s->parse_int = PyObject_GetAttrString(ctx, "parse_int");
if (s->parse_int == NULL)
goto bail;
s->parse_constant = PyObject_GetAttrString(ctx, "parse_constant");
if (s->parse_constant == NULL)
goto bail;
return 0;
bail:
Py_CLEAR(s->strict);
Py_CLEAR(s->object_hook);
Py_CLEAR(s->object_pairs_hook);
Py_CLEAR(s->parse_float);
Py_CLEAR(s->parse_int);
Py_CLEAR(s->parse_constant);
return -1;
}
PyDoc_STRVAR(scanner_doc, "JSON scanner object");
static
PyTypeObject PyScannerType = {
PyVarObject_HEAD_INIT(NULL, 0)
"_json.Scanner", /* tp_name */
sizeof(PyScannerObject), /* tp_basicsize */
0, /* tp_itemsize */
scanner_dealloc, /* tp_dealloc */
0, /* tp_print */
0, /* tp_getattr */
0, /* tp_setattr */
0, /* tp_compare */
0, /* tp_repr */
0, /* tp_as_number */
0, /* tp_as_sequence */
0, /* tp_as_mapping */
0, /* tp_hash */
scanner_call, /* tp_call */
0, /* tp_str */
0,/* PyObject_GenericGetAttr, */ /* tp_getattro */
0,/* PyObject_GenericSetAttr, */ /* tp_setattro */
0, /* tp_as_buffer */
Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC, /* tp_flags */
scanner_doc, /* tp_doc */
scanner_traverse, /* tp_traverse */
scanner_clear, /* tp_clear */
0, /* tp_richcompare */
0, /* tp_weaklistoffset */
0, /* tp_iter */
0, /* tp_iternext */
0, /* tp_methods */
scanner_members, /* tp_members */
0, /* tp_getset */
0, /* tp_base */
0, /* tp_dict */
0, /* tp_descr_get */
0, /* tp_descr_set */
0, /* tp_dictoffset */
scanner_init, /* tp_init */
0,/* PyType_GenericAlloc, */ /* tp_alloc */
scanner_new, /* tp_new */
0,/* PyObject_GC_Del, */ /* tp_free */
};
static PyObject *
encoder_new(PyTypeObject *type, PyObject *args, PyObject *kwds)
{
PyEncoderObject *s;
s = (PyEncoderObject *)type->tp_alloc(type, 0);
if (s != NULL) {
s->markers = NULL;
s->defaultfn = NULL;
s->encoder = NULL;
s->indent = NULL;
s->key_separator = NULL;
s->item_separator = NULL;
s->sort_keys = NULL;
s->skipkeys = NULL;
}
return (PyObject *)s;
}
static int
encoder_init(PyObject *self, PyObject *args, PyObject *kwds)
{
/* initialize Encoder object */
static char *kwlist[] = {"markers", "default", "encoder", "indent", "key_separator", "item_separator", "sort_keys", "skipkeys", "allow_nan", NULL};
PyEncoderObject *s;
PyObject *allow_nan;
assert(PyEncoder_Check(self));
s = (PyEncoderObject *)self;
if (!PyArg_ParseTupleAndKeywords(args, kwds, "OOOOOOOOO:make_encoder", kwlist,
&s->markers, &s->defaultfn, &s->encoder, &s->indent, &s->key_separator, &s->item_separator, &s->sort_keys, &s->skipkeys, &allow_nan))
return -1;
Py_INCREF(s->markers);
Py_INCREF(s->defaultfn);
Py_INCREF(s->encoder);
Py_INCREF(s->indent);
Py_INCREF(s->key_separator);
Py_INCREF(s->item_separator);
Py_INCREF(s->sort_keys);
Py_INCREF(s->skipkeys);
s->fast_encode = (PyCFunction_Check(s->encoder) && PyCFunction_GetFunction(s->encoder) == (PyCFunction)py_encode_basestring_ascii);
s->allow_nan = PyObject_IsTrue(allow_nan);
return 0;
}
static PyObject *
encoder_call(PyObject *self, PyObject *args, PyObject *kwds)
{
/* Python callable interface to encode_listencode_obj */
static char *kwlist[] = {"obj", "_current_indent_level", NULL};
PyObject *obj;
PyObject *rval;
Py_ssize_t indent_level;
PyEncoderObject *s;
assert(PyEncoder_Check(self));
s = (PyEncoderObject *)self;
if (!PyArg_ParseTupleAndKeywords(args, kwds, "OO&:_iterencode", kwlist,
&obj, _convertPyInt_AsSsize_t, &indent_level))
return NULL;
rval = PyList_New(0);
if (rval == NULL)
return NULL;
if (encoder_listencode_obj(s, rval, obj, indent_level)) {
Py_DECREF(rval);
return NULL;
}
return rval;
}
static PyObject *
_encoded_const(PyObject *obj)
{
/* Return the JSON string representation of None, True, False */
if (obj == Py_None) {
static PyObject *s_null = NULL;
if (s_null == NULL) {
s_null = PyUnicode_InternFromString("null");
}
Py_INCREF(s_null);
return s_null;
}
else if (obj == Py_True) {
static PyObject *s_true = NULL;
if (s_true == NULL) {
s_true = PyUnicode_InternFromString("true");
}
Py_INCREF(s_true);
return s_true;
}
else if (obj == Py_False) {
static PyObject *s_false = NULL;
if (s_false == NULL) {
s_false = PyUnicode_InternFromString("false");
}
Py_INCREF(s_false);
return s_false;
}
else {
PyErr_SetString(PyExc_ValueError, "not a const");
return NULL;
}
}
static PyObject *
encoder_encode_float(PyEncoderObject *s, PyObject *obj)
{
/* Return the JSON representation of a PyFloat */
double i = PyFloat_AS_DOUBLE(obj);
if (!Py_IS_FINITE(i)) {
if (!s->allow_nan) {
PyErr_SetString(PyExc_ValueError, "Out of range float values are not JSON compliant");
return NULL;
}
if (i > 0) {
return PyUnicode_FromString("Infinity");
}
else if (i < 0) {
return PyUnicode_FromString("-Infinity");
}
else {
return PyUnicode_FromString("NaN");
}
}
/* Use a better float format here? */
return PyObject_Repr(obj);
}
static PyObject *
encoder_encode_string(PyEncoderObject *s, PyObject *obj)
{
/* Return the JSON representation of a string */
if (s->fast_encode)
return py_encode_basestring_ascii(NULL, obj);
else
return PyObject_CallFunctionObjArgs(s->encoder, obj, NULL);
}
static int
_steal_list_append(PyObject *lst, PyObject *stolen)
{
/* Append stolen and then decrement its reference count */
int rval = PyList_Append(lst, stolen);
Py_DECREF(stolen);
return rval;
}
static int
encoder_listencode_obj(PyEncoderObject *s, PyObject *rval, PyObject *obj, Py_ssize_t indent_level)
{
/* Encode Python object obj to a JSON term, rval is a PyList */
PyObject *newobj;
int rv;
if (obj == Py_None || obj == Py_True || obj == Py_False) {
PyObject *cstr = _encoded_const(obj);
if (cstr == NULL)
return -1;
return _steal_list_append(rval, cstr);
}
else if (PyUnicode_Check(obj))
{
PyObject *encoded = encoder_encode_string(s, obj);
if (encoded == NULL)
return -1;
return _steal_list_append(rval, encoded);
}
else if (PyLong_Check(obj)) {
PyObject *encoded = PyObject_Str(obj);
if (encoded == NULL)
return -1;
return _steal_list_append(rval, encoded);
}
else if (PyFloat_Check(obj)) {
PyObject *encoded = encoder_encode_float(s, obj);
if (encoded == NULL)
return -1;
return _steal_list_append(rval, encoded);
}
else if (PyList_Check(obj) || PyTuple_Check(obj)) {
return encoder_listencode_list(s, rval, obj, indent_level);
}
else if (PyDict_Check(obj)) {
return encoder_listencode_dict(s, rval, obj, indent_level);
}
else {
PyObject *ident = NULL;
if (s->markers != Py_None) {
int has_key;
ident = PyLong_FromVoidPtr(obj);
if (ident == NULL)
return -1;
has_key = PyDict_Contains(s->markers, ident);
if (has_key) {
if (has_key != -1)
PyErr_SetString(PyExc_ValueError, "Circular reference detected");
Py_DECREF(ident);
return -1;
}
if (PyDict_SetItem(s->markers, ident, obj)) {
Py_DECREF(ident);
return -1;
}
}
newobj = PyObject_CallFunctionObjArgs(s->defaultfn, obj, NULL);
if (newobj == NULL) {
Py_XDECREF(ident);
return -1;
}
rv = encoder_listencode_obj(s, rval, newobj, indent_level);
Py_DECREF(newobj);
if (rv) {
Py_XDECREF(ident);
return -1;
}
if (ident != NULL) {
if (PyDict_DelItem(s->markers, ident)) {
Py_XDECREF(ident);
return -1;
}
Py_XDECREF(ident);
}
return rv;
}
}
static int
encoder_listencode_dict(PyEncoderObject *s, PyObject *rval, PyObject *dct, Py_ssize_t indent_level)
{
/* Encode Python dict dct a JSON term, rval is a PyList */
static PyObject *open_dict = NULL;
static PyObject *close_dict = NULL;
static PyObject *empty_dict = NULL;
PyObject *kstr = NULL;
PyObject *ident = NULL;
PyObject *key, *value;
Py_ssize_t pos;
int skipkeys;
Py_ssize_t idx;
if (open_dict == NULL || close_dict == NULL || empty_dict == NULL) {
open_dict = PyUnicode_InternFromString("{");
close_dict = PyUnicode_InternFromString("}");
empty_dict = PyUnicode_InternFromString("{}");
if (open_dict == NULL || close_dict == NULL || empty_dict == NULL)
return -1;
}
if (PyDict_Size(dct) == 0)
return PyList_Append(rval, empty_dict);
if (s->markers != Py_None) {
int has_key;
ident = PyLong_FromVoidPtr(dct);
if (ident == NULL)
goto bail;
has_key = PyDict_Contains(s->markers, ident);
if (has_key) {
if (has_key != -1)
PyErr_SetString(PyExc_ValueError, "Circular reference detected");
goto bail;
}
if (PyDict_SetItem(s->markers, ident, dct)) {
goto bail;
}
}
if (PyList_Append(rval, open_dict))
goto bail;
if (s->indent != Py_None) {
/* TODO: DOES NOT RUN */
indent_level += 1;
/*
newline_indent = '\n' + (' ' * (_indent * _current_indent_level))
separator = _item_separator + newline_indent
buf += newline_indent
*/
}
/* TODO: C speedup not implemented for sort_keys */
pos = 0;
skipkeys = PyObject_IsTrue(s->skipkeys);
idx = 0;
while (PyDict_Next(dct, &pos, &key, &value)) {
PyObject *encoded;
if (PyUnicode_Check(key)) {
Py_INCREF(key);
kstr = key;
}
else if (PyFloat_Check(key)) {
kstr = encoder_encode_float(s, key);
if (kstr == NULL)
goto bail;
}
else if (PyLong_Check(key)) {
kstr = PyObject_Str(key);
if (kstr == NULL)
goto bail;
}
else if (key == Py_True || key == Py_False || key == Py_None) {
kstr = _encoded_const(key);
if (kstr == NULL)
goto bail;
}
else if (skipkeys) {
continue;
}
else {
/* TODO: include repr of key */
PyErr_SetString(PyExc_ValueError, "keys must be a string");
goto bail;
}
if (idx) {
if (PyList_Append(rval, s->item_separator))
goto bail;
}
encoded = encoder_encode_string(s, kstr);
Py_CLEAR(kstr);
if (encoded == NULL)
goto bail;
if (PyList_Append(rval, encoded)) {
Py_DECREF(encoded);
goto bail;
}
Py_DECREF(encoded);
if (PyList_Append(rval, s->key_separator))
goto bail;
if (encoder_listencode_obj(s, rval, value, indent_level))
goto bail;
idx += 1;
}
if (ident != NULL) {
if (PyDict_DelItem(s->markers, ident))
goto bail;
Py_CLEAR(ident);
}
if (s->indent != Py_None) {
/* TODO: DOES NOT RUN */
indent_level -= 1;
/*
yield '\n' + (' ' * (_indent * _current_indent_level))
*/
}
if (PyList_Append(rval, close_dict))
goto bail;
return 0;
bail:
Py_XDECREF(kstr);
Py_XDECREF(ident);
return -1;
}
static int
encoder_listencode_list(PyEncoderObject *s, PyObject *rval, PyObject *seq, Py_ssize_t indent_level)
{
/* Encode Python list seq to a JSON term, rval is a PyList */
static PyObject *open_array = NULL;
static PyObject *close_array = NULL;
static PyObject *empty_array = NULL;
PyObject *ident = NULL;
PyObject *s_fast = NULL;
Py_ssize_t num_items;
PyObject **seq_items;
Py_ssize_t i;
if (open_array == NULL || close_array == NULL || empty_array == NULL) {
open_array = PyUnicode_InternFromString("[");
close_array = PyUnicode_InternFromString("]");
empty_array = PyUnicode_InternFromString("[]");
if (open_array == NULL || close_array == NULL || empty_array == NULL)
return -1;
}
ident = NULL;
s_fast = PySequence_Fast(seq, "_iterencode_list needs a sequence");
if (s_fast == NULL)
return -1;
num_items = PySequence_Fast_GET_SIZE(s_fast);
if (num_items == 0) {
Py_DECREF(s_fast);
return PyList_Append(rval, empty_array);
}
if (s->markers != Py_None) {
int has_key;
ident = PyLong_FromVoidPtr(seq);
if (ident == NULL)
goto bail;
has_key = PyDict_Contains(s->markers, ident);
if (has_key) {
if (has_key != -1)
PyErr_SetString(PyExc_ValueError, "Circular reference detected");
goto bail;
}
if (PyDict_SetItem(s->markers, ident, seq)) {
goto bail;
}
}
seq_items = PySequence_Fast_ITEMS(s_fast);
if (PyList_Append(rval, open_array))
goto bail;
if (s->indent != Py_None) {
/* TODO: DOES NOT RUN */
indent_level += 1;
/*
newline_indent = '\n' + (' ' * (_indent * _current_indent_level))
separator = _item_separator + newline_indent
buf += newline_indent
*/
}
for (i = 0; i < num_items; i++) {
PyObject *obj = seq_items[i];
if (i) {
if (PyList_Append(rval, s->item_separator))
goto bail;
}
if (encoder_listencode_obj(s, rval, obj, indent_level))
goto bail;
}
if (ident != NULL) {
if (PyDict_DelItem(s->markers, ident))
goto bail;
Py_CLEAR(ident);
}
if (s->indent != Py_None) {
/* TODO: DOES NOT RUN */
indent_level -= 1;
/*
yield '\n' + (' ' * (_indent * _current_indent_level))
*/
}
if (PyList_Append(rval, close_array))
goto bail;
Py_DECREF(s_fast);
return 0;
bail:
Py_XDECREF(ident);
Py_DECREF(s_fast);
return -1;
}
static void
encoder_dealloc(PyObject *self)
{
/* Deallocate Encoder */
encoder_clear(self);
Py_TYPE(self)->tp_free(self);
}
static int
encoder_traverse(PyObject *self, visitproc visit, void *arg)
{
PyEncoderObject *s;
assert(PyEncoder_Check(self));
s = (PyEncoderObject *)self;
Py_VISIT(s->markers);
Py_VISIT(s->defaultfn);
Py_VISIT(s->encoder);
Py_VISIT(s->indent);
Py_VISIT(s->key_separator);
Py_VISIT(s->item_separator);
Py_VISIT(s->sort_keys);
Py_VISIT(s->skipkeys);
return 0;
}
static int
encoder_clear(PyObject *self)
{
/* Deallocate Encoder */
PyEncoderObject *s;
assert(PyEncoder_Check(self));
s = (PyEncoderObject *)self;
Py_CLEAR(s->markers);
Py_CLEAR(s->defaultfn);
Py_CLEAR(s->encoder);
Py_CLEAR(s->indent);
Py_CLEAR(s->key_separator);
Py_CLEAR(s->item_separator);
Py_CLEAR(s->sort_keys);
Py_CLEAR(s->skipkeys);
return 0;
}
PyDoc_STRVAR(encoder_doc, "_iterencode(obj, _current_indent_level) -> iterable");
static
PyTypeObject PyEncoderType = {
PyVarObject_HEAD_INIT(NULL, 0)
"_json.Encoder", /* tp_name */
sizeof(PyEncoderObject), /* tp_basicsize */
0, /* tp_itemsize */
encoder_dealloc, /* tp_dealloc */
0, /* tp_print */
0, /* tp_getattr */
0, /* tp_setattr */
0, /* tp_compare */
0, /* tp_repr */
0, /* tp_as_number */
0, /* tp_as_sequence */
0, /* tp_as_mapping */
0, /* tp_hash */
encoder_call, /* tp_call */
0, /* tp_str */
0, /* tp_getattro */
0, /* tp_setattro */
0, /* tp_as_buffer */
Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC, /* tp_flags */
encoder_doc, /* tp_doc */
encoder_traverse, /* tp_traverse */
encoder_clear, /* tp_clear */
0, /* tp_richcompare */
0, /* tp_weaklistoffset */
0, /* tp_iter */
0, /* tp_iternext */
0, /* tp_methods */
encoder_members, /* tp_members */
0, /* tp_getset */
0, /* tp_base */
0, /* tp_dict */
0, /* tp_descr_get */
0, /* tp_descr_set */
0, /* tp_dictoffset */
encoder_init, /* tp_init */
0, /* tp_alloc */
encoder_new, /* tp_new */
0, /* tp_free */
};
static PyMethodDef speedups_methods[] = {
{"encode_basestring_ascii",
(PyCFunction)py_encode_basestring_ascii,
METH_O,
pydoc_encode_basestring_ascii},
{"scanstring",
(PyCFunction)py_scanstring,
METH_VARARGS,
pydoc_scanstring},
{NULL, NULL, 0, NULL}
};
PyDoc_STRVAR(module_doc,
"json speedups\n");
static struct PyModuleDef jsonmodule = {
PyModuleDef_HEAD_INIT,
"_json",
module_doc,
-1,
speedups_methods,
NULL,
NULL,
NULL,
NULL
};
PyObject*
PyInit__json(void)
{
PyObject *m = PyModule_Create(&jsonmodule);
if (!m)
return NULL;
PyScannerType.tp_new = PyType_GenericNew;
if (PyType_Ready(&PyScannerType) < 0)
goto fail;
PyEncoderType.tp_new = PyType_GenericNew;
if (PyType_Ready(&PyEncoderType) < 0)
goto fail;
Py_INCREF((PyObject*)&PyScannerType);
if (PyModule_AddObject(m, "make_scanner", (PyObject*)&PyScannerType) < 0) {
Py_DECREF((PyObject*)&PyScannerType);
goto fail;
}
Py_INCREF((PyObject*)&PyEncoderType);
if (PyModule_AddObject(m, "make_encoder", (PyObject*)&PyEncoderType) < 0) {
Py_DECREF((PyObject*)&PyEncoderType);
goto fail;
}
return m;
fail:
Py_DECREF(m);
return NULL;
}
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