| '''"Executable documentation" for the pickle module. |
| |
| Extensive comments about the pickle protocols and pickle-machine opcodes |
| can be found here. Some functions meant for external use: |
| |
| genops(pickle) |
| Generate all the opcodes in a pickle, as (opcode, arg, position) triples. |
| |
| dis(pickle, out=None, memo=None, indentlevel=4) |
| Print a symbolic disassembly of a pickle. |
| ''' |
| |
| __all__ = ['dis', 'genops', 'optimize'] |
| |
| # Other ideas: |
| # |
| # - A pickle verifier: read a pickle and check it exhaustively for |
| # well-formedness. dis() does a lot of this already. |
| # |
| # - A protocol identifier: examine a pickle and return its protocol number |
| # (== the highest .proto attr value among all the opcodes in the pickle). |
| # dis() already prints this info at the end. |
| # |
| # - A pickle optimizer: for example, tuple-building code is sometimes more |
| # elaborate than necessary, catering for the possibility that the tuple |
| # is recursive. Or lots of times a PUT is generated that's never accessed |
| # by a later GET. |
| |
| |
| """ |
| "A pickle" is a program for a virtual pickle machine (PM, but more accurately |
| called an unpickling machine). It's a sequence of opcodes, interpreted by the |
| PM, building an arbitrarily complex Python object. |
| |
| For the most part, the PM is very simple: there are no looping, testing, or |
| conditional instructions, no arithmetic and no function calls. Opcodes are |
| executed once each, from first to last, until a STOP opcode is reached. |
| |
| The PM has two data areas, "the stack" and "the memo". |
| |
| Many opcodes push Python objects onto the stack; e.g., INT pushes a Python |
| integer object on the stack, whose value is gotten from a decimal string |
| literal immediately following the INT opcode in the pickle bytestream. Other |
| opcodes take Python objects off the stack. The result of unpickling is |
| whatever object is left on the stack when the final STOP opcode is executed. |
| |
| The memo is simply an array of objects, or it can be implemented as a dict |
| mapping little integers to objects. The memo serves as the PM's "long term |
| memory", and the little integers indexing the memo are akin to variable |
| names. Some opcodes pop a stack object into the memo at a given index, |
| and others push a memo object at a given index onto the stack again. |
| |
| At heart, that's all the PM has. Subtleties arise for these reasons: |
| |
| + Object identity. Objects can be arbitrarily complex, and subobjects |
| may be shared (for example, the list [a, a] refers to the same object a |
| twice). It can be vital that unpickling recreate an isomorphic object |
| graph, faithfully reproducing sharing. |
| |
| + Recursive objects. For example, after "L = []; L.append(L)", L is a |
| list, and L[0] is the same list. This is related to the object identity |
| point, and some sequences of pickle opcodes are subtle in order to |
| get the right result in all cases. |
| |
| + Things pickle doesn't know everything about. Examples of things pickle |
| does know everything about are Python's builtin scalar and container |
| types, like ints and tuples. They generally have opcodes dedicated to |
| them. For things like module references and instances of user-defined |
| classes, pickle's knowledge is limited. Historically, many enhancements |
| have been made to the pickle protocol in order to do a better (faster, |
| and/or more compact) job on those. |
| |
| + Backward compatibility and micro-optimization. As explained below, |
| pickle opcodes never go away, not even when better ways to do a thing |
| get invented. The repertoire of the PM just keeps growing over time. |
| For example, protocol 0 had two opcodes for building Python integers (INT |
| and LONG), protocol 1 added three more for more-efficient pickling of short |
| integers, and protocol 2 added two more for more-efficient pickling of |
| long integers (before protocol 2, the only ways to pickle a Python long |
| took time quadratic in the number of digits, for both pickling and |
| unpickling). "Opcode bloat" isn't so much a subtlety as a source of |
| wearying complication. |
| |
| |
| Pickle protocols: |
| |
| For compatibility, the meaning of a pickle opcode never changes. Instead new |
| pickle opcodes get added, and each version's unpickler can handle all the |
| pickle opcodes in all protocol versions to date. So old pickles continue to |
| be readable forever. The pickler can generally be told to restrict itself to |
| the subset of opcodes available under previous protocol versions too, so that |
| users can create pickles under the current version readable by older |
| versions. However, a pickle does not contain its version number embedded |
| within it. If an older unpickler tries to read a pickle using a later |
| protocol, the result is most likely an exception due to seeing an unknown (in |
| the older unpickler) opcode. |
| |
| The original pickle used what's now called "protocol 0", and what was called |
| "text mode" before Python 2.3. The entire pickle bytestream is made up of |
| printable 7-bit ASCII characters, plus the newline character, in protocol 0. |
| That's why it was called text mode. Protocol 0 is small and elegant, but |
| sometimes painfully inefficient. |
| |
| The second major set of additions is now called "protocol 1", and was called |
| "binary mode" before Python 2.3. This added many opcodes with arguments |
| consisting of arbitrary bytes, including NUL bytes and unprintable "high bit" |
| bytes. Binary mode pickles can be substantially smaller than equivalent |
| text mode pickles, and sometimes faster too; e.g., BININT represents a 4-byte |
| int as 4 bytes following the opcode, which is cheaper to unpickle than the |
| (perhaps) 11-character decimal string attached to INT. Protocol 1 also added |
| a number of opcodes that operate on many stack elements at once (like APPENDS |
| and SETITEMS), and "shortcut" opcodes (like EMPTY_DICT and EMPTY_TUPLE). |
| |
| The third major set of additions came in Python 2.3, and is called "protocol |
| 2". This added: |
| |
| - A better way to pickle instances of new-style classes (NEWOBJ). |
| |
| - A way for a pickle to identify its protocol (PROTO). |
| |
| - Time- and space- efficient pickling of long ints (LONG{1,4}). |
| |
| - Shortcuts for small tuples (TUPLE{1,2,3}}. |
| |
| - Dedicated opcodes for bools (NEWTRUE, NEWFALSE). |
| |
| - The "extension registry", a vector of popular objects that can be pushed |
| efficiently by index (EXT{1,2,4}). This is akin to the memo and GET, but |
| the registry contents are predefined (there's nothing akin to the memo's |
| PUT). |
| |
| Another independent change with Python 2.3 is the abandonment of any |
| pretense that it might be safe to load pickles received from untrusted |
| parties -- no sufficient security analysis has been done to guarantee |
| this and there isn't a use case that warrants the expense of such an |
| analysis. |
| |
| To this end, all tests for __safe_for_unpickling__ or for |
| copy_reg.safe_constructors are removed from the unpickling code. |
| References to these variables in the descriptions below are to be seen |
| as describing unpickling in Python 2.2 and before. |
| """ |
| |
| # Meta-rule: Descriptions are stored in instances of descriptor objects, |
| # with plain constructors. No meta-language is defined from which |
| # descriptors could be constructed. If you want, e.g., XML, write a little |
| # program to generate XML from the objects. |
| |
| ############################################################################## |
| # Some pickle opcodes have an argument, following the opcode in the |
| # bytestream. An argument is of a specific type, described by an instance |
| # of ArgumentDescriptor. These are not to be confused with arguments taken |
| # off the stack -- ArgumentDescriptor applies only to arguments embedded in |
| # the opcode stream, immediately following an opcode. |
| |
| # Represents the number of bytes consumed by an argument delimited by the |
| # next newline character. |
| UP_TO_NEWLINE = -1 |
| |
| # Represents the number of bytes consumed by a two-argument opcode where |
| # the first argument gives the number of bytes in the second argument. |
| TAKEN_FROM_ARGUMENT1 = -2 # num bytes is 1-byte unsigned int |
| TAKEN_FROM_ARGUMENT4 = -3 # num bytes is 4-byte signed little-endian int |
| |
| class ArgumentDescriptor(object): |
| __slots__ = ( |
| # name of descriptor record, also a module global name; a string |
| 'name', |
| |
| # length of argument, in bytes; an int; UP_TO_NEWLINE and |
| # TAKEN_FROM_ARGUMENT{1,4} are negative values for variable-length |
| # cases |
| 'n', |
| |
| # a function taking a file-like object, reading this kind of argument |
| # from the object at the current position, advancing the current |
| # position by n bytes, and returning the value of the argument |
| 'reader', |
| |
| # human-readable docs for this arg descriptor; a string |
| 'doc', |
| ) |
| |
| def __init__(self, name, n, reader, doc): |
| assert isinstance(name, str) |
| self.name = name |
| |
| assert isinstance(n, int) and (n >= 0 or |
| n in (UP_TO_NEWLINE, |
| TAKEN_FROM_ARGUMENT1, |
| TAKEN_FROM_ARGUMENT4)) |
| self.n = n |
| |
| self.reader = reader |
| |
| assert isinstance(doc, str) |
| self.doc = doc |
| |
| from struct import unpack as _unpack |
| |
| def read_uint1(f): |
| r""" |
| >>> import StringIO |
| >>> read_uint1(StringIO.StringIO('\xff')) |
| 255 |
| """ |
| |
| data = f.read(1) |
| if data: |
| return ord(data) |
| raise ValueError("not enough data in stream to read uint1") |
| |
| uint1 = ArgumentDescriptor( |
| name='uint1', |
| n=1, |
| reader=read_uint1, |
| doc="One-byte unsigned integer.") |
| |
| |
| def read_uint2(f): |
| r""" |
| >>> import StringIO |
| >>> read_uint2(StringIO.StringIO('\xff\x00')) |
| 255 |
| >>> read_uint2(StringIO.StringIO('\xff\xff')) |
| 65535 |
| """ |
| |
| data = f.read(2) |
| if len(data) == 2: |
| return _unpack("<H", data)[0] |
| raise ValueError("not enough data in stream to read uint2") |
| |
| uint2 = ArgumentDescriptor( |
| name='uint2', |
| n=2, |
| reader=read_uint2, |
| doc="Two-byte unsigned integer, little-endian.") |
| |
| |
| def read_int4(f): |
| r""" |
| >>> import StringIO |
| >>> read_int4(StringIO.StringIO('\xff\x00\x00\x00')) |
| 255 |
| >>> read_int4(StringIO.StringIO('\x00\x00\x00\x80')) == -(2**31) |
| True |
| """ |
| |
| data = f.read(4) |
| if len(data) == 4: |
| return _unpack("<i", data)[0] |
| raise ValueError("not enough data in stream to read int4") |
| |
| int4 = ArgumentDescriptor( |
| name='int4', |
| n=4, |
| reader=read_int4, |
| doc="Four-byte signed integer, little-endian, 2's complement.") |
| |
| |
| def read_stringnl(f, decode=True, stripquotes=True): |
| r""" |
| >>> import StringIO |
| >>> read_stringnl(StringIO.StringIO("'abcd'\nefg\n")) |
| 'abcd' |
| |
| >>> read_stringnl(StringIO.StringIO("\n")) |
| Traceback (most recent call last): |
| ... |
| ValueError: no string quotes around '' |
| |
| >>> read_stringnl(StringIO.StringIO("\n"), stripquotes=False) |
| '' |
| |
| >>> read_stringnl(StringIO.StringIO("''\n")) |
| '' |
| |
| >>> read_stringnl(StringIO.StringIO('"abcd"')) |
| Traceback (most recent call last): |
| ... |
| ValueError: no newline found when trying to read stringnl |
| |
| Embedded escapes are undone in the result. |
| >>> read_stringnl(StringIO.StringIO(r"'a\n\\b\x00c\td'" + "\n'e'")) |
| 'a\n\\b\x00c\td' |
| """ |
| |
| data = f.readline() |
| if not data.endswith('\n'): |
| raise ValueError("no newline found when trying to read stringnl") |
| data = data[:-1] # lose the newline |
| |
| if stripquotes: |
| for q in "'\"": |
| if data.startswith(q): |
| if not data.endswith(q): |
| raise ValueError("strinq quote %r not found at both " |
| "ends of %r" % (q, data)) |
| data = data[1:-1] |
| break |
| else: |
| raise ValueError("no string quotes around %r" % data) |
| |
| # I'm not sure when 'string_escape' was added to the std codecs; it's |
| # crazy not to use it if it's there. |
| if decode: |
| data = data.decode('string_escape') |
| return data |
| |
| stringnl = ArgumentDescriptor( |
| name='stringnl', |
| n=UP_TO_NEWLINE, |
| reader=read_stringnl, |
| doc="""A newline-terminated string. |
| |
| This is a repr-style string, with embedded escapes, and |
| bracketing quotes. |
| """) |
| |
| def read_stringnl_noescape(f): |
| return read_stringnl(f, decode=False, stripquotes=False) |
| |
| stringnl_noescape = ArgumentDescriptor( |
| name='stringnl_noescape', |
| n=UP_TO_NEWLINE, |
| reader=read_stringnl_noescape, |
| doc="""A newline-terminated string. |
| |
| This is a str-style string, without embedded escapes, |
| or bracketing quotes. It should consist solely of |
| printable ASCII characters. |
| """) |
| |
| def read_stringnl_noescape_pair(f): |
| r""" |
| >>> import StringIO |
| >>> read_stringnl_noescape_pair(StringIO.StringIO("Queue\nEmpty\njunk")) |
| 'Queue Empty' |
| """ |
| |
| return "%s %s" % (read_stringnl_noescape(f), read_stringnl_noescape(f)) |
| |
| stringnl_noescape_pair = ArgumentDescriptor( |
| name='stringnl_noescape_pair', |
| n=UP_TO_NEWLINE, |
| reader=read_stringnl_noescape_pair, |
| doc="""A pair of newline-terminated strings. |
| |
| These are str-style strings, without embedded |
| escapes, or bracketing quotes. They should |
| consist solely of printable ASCII characters. |
| The pair is returned as a single string, with |
| a single blank separating the two strings. |
| """) |
| |
| def read_string4(f): |
| r""" |
| >>> import StringIO |
| >>> read_string4(StringIO.StringIO("\x00\x00\x00\x00abc")) |
| '' |
| >>> read_string4(StringIO.StringIO("\x03\x00\x00\x00abcdef")) |
| 'abc' |
| >>> read_string4(StringIO.StringIO("\x00\x00\x00\x03abcdef")) |
| Traceback (most recent call last): |
| ... |
| ValueError: expected 50331648 bytes in a string4, but only 6 remain |
| """ |
| |
| n = read_int4(f) |
| if n < 0: |
| raise ValueError("string4 byte count < 0: %d" % n) |
| data = f.read(n) |
| if len(data) == n: |
| return data |
| raise ValueError("expected %d bytes in a string4, but only %d remain" % |
| (n, len(data))) |
| |
| string4 = ArgumentDescriptor( |
| name="string4", |
| n=TAKEN_FROM_ARGUMENT4, |
| reader=read_string4, |
| doc="""A counted string. |
| |
| The first argument is a 4-byte little-endian signed int giving |
| the number of bytes in the string, and the second argument is |
| that many bytes. |
| """) |
| |
| |
| def read_string1(f): |
| r""" |
| >>> import StringIO |
| >>> read_string1(StringIO.StringIO("\x00")) |
| '' |
| >>> read_string1(StringIO.StringIO("\x03abcdef")) |
| 'abc' |
| """ |
| |
| n = read_uint1(f) |
| assert n >= 0 |
| data = f.read(n) |
| if len(data) == n: |
| return data |
| raise ValueError("expected %d bytes in a string1, but only %d remain" % |
| (n, len(data))) |
| |
| string1 = ArgumentDescriptor( |
| name="string1", |
| n=TAKEN_FROM_ARGUMENT1, |
| reader=read_string1, |
| doc="""A counted string. |
| |
| The first argument is a 1-byte unsigned int giving the number |
| of bytes in the string, and the second argument is that many |
| bytes. |
| """) |
| |
| |
| def read_unicodestringnl(f): |
| r""" |
| >>> import StringIO |
| >>> read_unicodestringnl(StringIO.StringIO("abc\uabcd\njunk")) |
| u'abc\uabcd' |
| """ |
| |
| data = f.readline() |
| if not data.endswith('\n'): |
| raise ValueError("no newline found when trying to read " |
| "unicodestringnl") |
| data = data[:-1] # lose the newline |
| return unicode(data, 'raw-unicode-escape') |
| |
| unicodestringnl = ArgumentDescriptor( |
| name='unicodestringnl', |
| n=UP_TO_NEWLINE, |
| reader=read_unicodestringnl, |
| doc="""A newline-terminated Unicode string. |
| |
| This is raw-unicode-escape encoded, so consists of |
| printable ASCII characters, and may contain embedded |
| escape sequences. |
| """) |
| |
| def read_unicodestring4(f): |
| r""" |
| >>> import StringIO |
| >>> s = u'abcd\uabcd' |
| >>> enc = s.encode('utf-8') |
| >>> enc |
| 'abcd\xea\xaf\x8d' |
| >>> n = chr(len(enc)) + chr(0) * 3 # little-endian 4-byte length |
| >>> t = read_unicodestring4(StringIO.StringIO(n + enc + 'junk')) |
| >>> s == t |
| True |
| |
| >>> read_unicodestring4(StringIO.StringIO(n + enc[:-1])) |
| Traceback (most recent call last): |
| ... |
| ValueError: expected 7 bytes in a unicodestring4, but only 6 remain |
| """ |
| |
| n = read_int4(f) |
| if n < 0: |
| raise ValueError("unicodestring4 byte count < 0: %d" % n) |
| data = f.read(n) |
| if len(data) == n: |
| return unicode(data, 'utf-8') |
| raise ValueError("expected %d bytes in a unicodestring4, but only %d " |
| "remain" % (n, len(data))) |
| |
| unicodestring4 = ArgumentDescriptor( |
| name="unicodestring4", |
| n=TAKEN_FROM_ARGUMENT4, |
| reader=read_unicodestring4, |
| doc="""A counted Unicode string. |
| |
| The first argument is a 4-byte little-endian signed int |
| giving the number of bytes in the string, and the second |
| argument-- the UTF-8 encoding of the Unicode string -- |
| contains that many bytes. |
| """) |
| |
| |
| def read_decimalnl_short(f): |
| r""" |
| >>> import StringIO |
| >>> read_decimalnl_short(StringIO.StringIO("1234\n56")) |
| 1234 |
| |
| >>> read_decimalnl_short(StringIO.StringIO("1234L\n56")) |
| Traceback (most recent call last): |
| ... |
| ValueError: trailing 'L' not allowed in '1234L' |
| """ |
| |
| s = read_stringnl(f, decode=False, stripquotes=False) |
| if s.endswith("L"): |
| raise ValueError("trailing 'L' not allowed in %r" % s) |
| |
| # It's not necessarily true that the result fits in a Python short int: |
| # the pickle may have been written on a 64-bit box. There's also a hack |
| # for True and False here. |
| if s == "00": |
| return False |
| elif s == "01": |
| return True |
| |
| try: |
| return int(s) |
| except OverflowError: |
| return long(s) |
| |
| def read_decimalnl_long(f): |
| r""" |
| >>> import StringIO |
| |
| >>> read_decimalnl_long(StringIO.StringIO("1234\n56")) |
| Traceback (most recent call last): |
| ... |
| ValueError: trailing 'L' required in '1234' |
| |
| Someday the trailing 'L' will probably go away from this output. |
| |
| >>> read_decimalnl_long(StringIO.StringIO("1234L\n56")) |
| 1234L |
| |
| >>> read_decimalnl_long(StringIO.StringIO("123456789012345678901234L\n6")) |
| 123456789012345678901234L |
| """ |
| |
| s = read_stringnl(f, decode=False, stripquotes=False) |
| if not s.endswith("L"): |
| raise ValueError("trailing 'L' required in %r" % s) |
| return long(s) |
| |
| |
| decimalnl_short = ArgumentDescriptor( |
| name='decimalnl_short', |
| n=UP_TO_NEWLINE, |
| reader=read_decimalnl_short, |
| doc="""A newline-terminated decimal integer literal. |
| |
| This never has a trailing 'L', and the integer fit |
| in a short Python int on the box where the pickle |
| was written -- but there's no guarantee it will fit |
| in a short Python int on the box where the pickle |
| is read. |
| """) |
| |
| decimalnl_long = ArgumentDescriptor( |
| name='decimalnl_long', |
| n=UP_TO_NEWLINE, |
| reader=read_decimalnl_long, |
| doc="""A newline-terminated decimal integer literal. |
| |
| This has a trailing 'L', and can represent integers |
| of any size. |
| """) |
| |
| |
| def read_floatnl(f): |
| r""" |
| >>> import StringIO |
| >>> read_floatnl(StringIO.StringIO("-1.25\n6")) |
| -1.25 |
| """ |
| s = read_stringnl(f, decode=False, stripquotes=False) |
| return float(s) |
| |
| floatnl = ArgumentDescriptor( |
| name='floatnl', |
| n=UP_TO_NEWLINE, |
| reader=read_floatnl, |
| doc="""A newline-terminated decimal floating literal. |
| |
| In general this requires 17 significant digits for roundtrip |
| identity, and pickling then unpickling infinities, NaNs, and |
| minus zero doesn't work across boxes, or on some boxes even |
| on itself (e.g., Windows can't read the strings it produces |
| for infinities or NaNs). |
| """) |
| |
| def read_float8(f): |
| r""" |
| >>> import StringIO, struct |
| >>> raw = struct.pack(">d", -1.25) |
| >>> raw |
| '\xbf\xf4\x00\x00\x00\x00\x00\x00' |
| >>> read_float8(StringIO.StringIO(raw + "\n")) |
| -1.25 |
| """ |
| |
| data = f.read(8) |
| if len(data) == 8: |
| return _unpack(">d", data)[0] |
| raise ValueError("not enough data in stream to read float8") |
| |
| |
| float8 = ArgumentDescriptor( |
| name='float8', |
| n=8, |
| reader=read_float8, |
| doc="""An 8-byte binary representation of a float, big-endian. |
| |
| The format is unique to Python, and shared with the struct |
| module (format string '>d') "in theory" (the struct and cPickle |
| implementations don't share the code -- they should). It's |
| strongly related to the IEEE-754 double format, and, in normal |
| cases, is in fact identical to the big-endian 754 double format. |
| On other boxes the dynamic range is limited to that of a 754 |
| double, and "add a half and chop" rounding is used to reduce |
| the precision to 53 bits. However, even on a 754 box, |
| infinities, NaNs, and minus zero may not be handled correctly |
| (may not survive roundtrip pickling intact). |
| """) |
| |
| # Protocol 2 formats |
| |
| from pickle import decode_long |
| |
| def read_long1(f): |
| r""" |
| >>> import StringIO |
| >>> read_long1(StringIO.StringIO("\x00")) |
| 0L |
| >>> read_long1(StringIO.StringIO("\x02\xff\x00")) |
| 255L |
| >>> read_long1(StringIO.StringIO("\x02\xff\x7f")) |
| 32767L |
| >>> read_long1(StringIO.StringIO("\x02\x00\xff")) |
| -256L |
| >>> read_long1(StringIO.StringIO("\x02\x00\x80")) |
| -32768L |
| """ |
| |
| n = read_uint1(f) |
| data = f.read(n) |
| if len(data) != n: |
| raise ValueError("not enough data in stream to read long1") |
| return decode_long(data) |
| |
| long1 = ArgumentDescriptor( |
| name="long1", |
| n=TAKEN_FROM_ARGUMENT1, |
| reader=read_long1, |
| doc="""A binary long, little-endian, using 1-byte size. |
| |
| This first reads one byte as an unsigned size, then reads that |
| many bytes and interprets them as a little-endian 2's-complement long. |
| If the size is 0, that's taken as a shortcut for the long 0L. |
| """) |
| |
| def read_long4(f): |
| r""" |
| >>> import StringIO |
| >>> read_long4(StringIO.StringIO("\x02\x00\x00\x00\xff\x00")) |
| 255L |
| >>> read_long4(StringIO.StringIO("\x02\x00\x00\x00\xff\x7f")) |
| 32767L |
| >>> read_long4(StringIO.StringIO("\x02\x00\x00\x00\x00\xff")) |
| -256L |
| >>> read_long4(StringIO.StringIO("\x02\x00\x00\x00\x00\x80")) |
| -32768L |
| >>> read_long1(StringIO.StringIO("\x00\x00\x00\x00")) |
| 0L |
| """ |
| |
| n = read_int4(f) |
| if n < 0: |
| raise ValueError("long4 byte count < 0: %d" % n) |
| data = f.read(n) |
| if len(data) != n: |
| raise ValueError("not enough data in stream to read long4") |
| return decode_long(data) |
| |
| long4 = ArgumentDescriptor( |
| name="long4", |
| n=TAKEN_FROM_ARGUMENT4, |
| reader=read_long4, |
| doc="""A binary representation of a long, little-endian. |
| |
| This first reads four bytes as a signed size (but requires the |
| size to be >= 0), then reads that many bytes and interprets them |
| as a little-endian 2's-complement long. If the size is 0, that's taken |
| as a shortcut for the long 0L, although LONG1 should really be used |
| then instead (and in any case where # of bytes < 256). |
| """) |
| |
| |
| ############################################################################## |
| # Object descriptors. The stack used by the pickle machine holds objects, |
| # and in the stack_before and stack_after attributes of OpcodeInfo |
| # descriptors we need names to describe the various types of objects that can |
| # appear on the stack. |
| |
| class StackObject(object): |
| __slots__ = ( |
| # name of descriptor record, for info only |
| 'name', |
| |
| # type of object, or tuple of type objects (meaning the object can |
| # be of any type in the tuple) |
| 'obtype', |
| |
| # human-readable docs for this kind of stack object; a string |
| 'doc', |
| ) |
| |
| def __init__(self, name, obtype, doc): |
| assert isinstance(name, str) |
| self.name = name |
| |
| assert isinstance(obtype, type) or isinstance(obtype, tuple) |
| if isinstance(obtype, tuple): |
| for contained in obtype: |
| assert isinstance(contained, type) |
| self.obtype = obtype |
| |
| assert isinstance(doc, str) |
| self.doc = doc |
| |
| def __repr__(self): |
| return self.name |
| |
| |
| pyint = StackObject( |
| name='int', |
| obtype=int, |
| doc="A short (as opposed to long) Python integer object.") |
| |
| pylong = StackObject( |
| name='long', |
| obtype=long, |
| doc="A long (as opposed to short) Python integer object.") |
| |
| pyinteger_or_bool = StackObject( |
| name='int_or_bool', |
| obtype=(int, long, bool), |
| doc="A Python integer object (short or long), or " |
| "a Python bool.") |
| |
| pybool = StackObject( |
| name='bool', |
| obtype=(bool,), |
| doc="A Python bool object.") |
| |
| pyfloat = StackObject( |
| name='float', |
| obtype=float, |
| doc="A Python float object.") |
| |
| pystring = StackObject( |
| name='str', |
| obtype=str, |
| doc="A Python string object.") |
| |
| pyunicode = StackObject( |
| name='unicode', |
| obtype=unicode, |
| doc="A Python Unicode string object.") |
| |
| pynone = StackObject( |
| name="None", |
| obtype=type(None), |
| doc="The Python None object.") |
| |
| pytuple = StackObject( |
| name="tuple", |
| obtype=tuple, |
| doc="A Python tuple object.") |
| |
| pylist = StackObject( |
| name="list", |
| obtype=list, |
| doc="A Python list object.") |
| |
| pydict = StackObject( |
| name="dict", |
| obtype=dict, |
| doc="A Python dict object.") |
| |
| anyobject = StackObject( |
| name='any', |
| obtype=object, |
| doc="Any kind of object whatsoever.") |
| |
| markobject = StackObject( |
| name="mark", |
| obtype=StackObject, |
| doc="""'The mark' is a unique object. |
| |
| Opcodes that operate on a variable number of objects |
| generally don't embed the count of objects in the opcode, |
| or pull it off the stack. Instead the MARK opcode is used |
| to push a special marker object on the stack, and then |
| some other opcodes grab all the objects from the top of |
| the stack down to (but not including) the topmost marker |
| object. |
| """) |
| |
| stackslice = StackObject( |
| name="stackslice", |
| obtype=StackObject, |
| doc="""An object representing a contiguous slice of the stack. |
| |
| This is used in conjuction with markobject, to represent all |
| of the stack following the topmost markobject. For example, |
| the POP_MARK opcode changes the stack from |
| |
| [..., markobject, stackslice] |
| to |
| [...] |
| |
| No matter how many object are on the stack after the topmost |
| markobject, POP_MARK gets rid of all of them (including the |
| topmost markobject too). |
| """) |
| |
| ############################################################################## |
| # Descriptors for pickle opcodes. |
| |
| class OpcodeInfo(object): |
| |
| __slots__ = ( |
| # symbolic name of opcode; a string |
| 'name', |
| |
| # the code used in a bytestream to represent the opcode; a |
| # one-character string |
| 'code', |
| |
| # If the opcode has an argument embedded in the byte string, an |
| # instance of ArgumentDescriptor specifying its type. Note that |
| # arg.reader(s) can be used to read and decode the argument from |
| # the bytestream s, and arg.doc documents the format of the raw |
| # argument bytes. If the opcode doesn't have an argument embedded |
| # in the bytestream, arg should be None. |
| 'arg', |
| |
| # what the stack looks like before this opcode runs; a list |
| 'stack_before', |
| |
| # what the stack looks like after this opcode runs; a list |
| 'stack_after', |
| |
| # the protocol number in which this opcode was introduced; an int |
| 'proto', |
| |
| # human-readable docs for this opcode; a string |
| 'doc', |
| ) |
| |
| def __init__(self, name, code, arg, |
| stack_before, stack_after, proto, doc): |
| assert isinstance(name, str) |
| self.name = name |
| |
| assert isinstance(code, str) |
| assert len(code) == 1 |
| self.code = code |
| |
| assert arg is None or isinstance(arg, ArgumentDescriptor) |
| self.arg = arg |
| |
| assert isinstance(stack_before, list) |
| for x in stack_before: |
| assert isinstance(x, StackObject) |
| self.stack_before = stack_before |
| |
| assert isinstance(stack_after, list) |
| for x in stack_after: |
| assert isinstance(x, StackObject) |
| self.stack_after = stack_after |
| |
| assert isinstance(proto, int) and 0 <= proto <= 2 |
| self.proto = proto |
| |
| assert isinstance(doc, str) |
| self.doc = doc |
| |
| I = OpcodeInfo |
| opcodes = [ |
| |
| # Ways to spell integers. |
| |
| I(name='INT', |
| code='I', |
| arg=decimalnl_short, |
| stack_before=[], |
| stack_after=[pyinteger_or_bool], |
| proto=0, |
| doc="""Push an integer or bool. |
| |
| The argument is a newline-terminated decimal literal string. |
| |
| The intent may have been that this always fit in a short Python int, |
| but INT can be generated in pickles written on a 64-bit box that |
| require a Python long on a 32-bit box. The difference between this |
| and LONG then is that INT skips a trailing 'L', and produces a short |
| int whenever possible. |
| |
| Another difference is due to that, when bool was introduced as a |
| distinct type in 2.3, builtin names True and False were also added to |
| 2.2.2, mapping to ints 1 and 0. For compatibility in both directions, |
| True gets pickled as INT + "I01\\n", and False as INT + "I00\\n". |
| Leading zeroes are never produced for a genuine integer. The 2.3 |
| (and later) unpicklers special-case these and return bool instead; |
| earlier unpicklers ignore the leading "0" and return the int. |
| """), |
| |
| I(name='BININT', |
| code='J', |
| arg=int4, |
| stack_before=[], |
| stack_after=[pyint], |
| proto=1, |
| doc="""Push a four-byte signed integer. |
| |
| This handles the full range of Python (short) integers on a 32-bit |
| box, directly as binary bytes (1 for the opcode and 4 for the integer). |
| If the integer is non-negative and fits in 1 or 2 bytes, pickling via |
| BININT1 or BININT2 saves space. |
| """), |
| |
| I(name='BININT1', |
| code='K', |
| arg=uint1, |
| stack_before=[], |
| stack_after=[pyint], |
| proto=1, |
| doc="""Push a one-byte unsigned integer. |
| |
| This is a space optimization for pickling very small non-negative ints, |
| in range(256). |
| """), |
| |
| I(name='BININT2', |
| code='M', |
| arg=uint2, |
| stack_before=[], |
| stack_after=[pyint], |
| proto=1, |
| doc="""Push a two-byte unsigned integer. |
| |
| This is a space optimization for pickling small positive ints, in |
| range(256, 2**16). Integers in range(256) can also be pickled via |
| BININT2, but BININT1 instead saves a byte. |
| """), |
| |
| I(name='LONG', |
| code='L', |
| arg=decimalnl_long, |
| stack_before=[], |
| stack_after=[pylong], |
| proto=0, |
| doc="""Push a long integer. |
| |
| The same as INT, except that the literal ends with 'L', and always |
| unpickles to a Python long. There doesn't seem a real purpose to the |
| trailing 'L'. |
| |
| Note that LONG takes time quadratic in the number of digits when |
| unpickling (this is simply due to the nature of decimal->binary |
| conversion). Proto 2 added linear-time (in C; still quadratic-time |
| in Python) LONG1 and LONG4 opcodes. |
| """), |
| |
| I(name="LONG1", |
| code='\x8a', |
| arg=long1, |
| stack_before=[], |
| stack_after=[pylong], |
| proto=2, |
| doc="""Long integer using one-byte length. |
| |
| A more efficient encoding of a Python long; the long1 encoding |
| says it all."""), |
| |
| I(name="LONG4", |
| code='\x8b', |
| arg=long4, |
| stack_before=[], |
| stack_after=[pylong], |
| proto=2, |
| doc="""Long integer using found-byte length. |
| |
| A more efficient encoding of a Python long; the long4 encoding |
| says it all."""), |
| |
| # Ways to spell strings (8-bit, not Unicode). |
| |
| I(name='STRING', |
| code='S', |
| arg=stringnl, |
| stack_before=[], |
| stack_after=[pystring], |
| proto=0, |
| doc="""Push a Python string object. |
| |
| The argument is a repr-style string, with bracketing quote characters, |
| and perhaps embedded escapes. The argument extends until the next |
| newline character. |
| """), |
| |
| I(name='BINSTRING', |
| code='T', |
| arg=string4, |
| stack_before=[], |
| stack_after=[pystring], |
| proto=1, |
| doc="""Push a Python string object. |
| |
| There are two arguments: the first is a 4-byte little-endian signed int |
| giving the number of bytes in the string, and the second is that many |
| bytes, which are taken literally as the string content. |
| """), |
| |
| I(name='SHORT_BINSTRING', |
| code='U', |
| arg=string1, |
| stack_before=[], |
| stack_after=[pystring], |
| proto=1, |
| doc="""Push a Python string object. |
| |
| There are two arguments: the first is a 1-byte unsigned int giving |
| the number of bytes in the string, and the second is that many bytes, |
| which are taken literally as the string content. |
| """), |
| |
| # Ways to spell None. |
| |
| I(name='NONE', |
| code='N', |
| arg=None, |
| stack_before=[], |
| stack_after=[pynone], |
| proto=0, |
| doc="Push None on the stack."), |
| |
| # Ways to spell bools, starting with proto 2. See INT for how this was |
| # done before proto 2. |
| |
| I(name='NEWTRUE', |
| code='\x88', |
| arg=None, |
| stack_before=[], |
| stack_after=[pybool], |
| proto=2, |
| doc="""True. |
| |
| Push True onto the stack."""), |
| |
| I(name='NEWFALSE', |
| code='\x89', |
| arg=None, |
| stack_before=[], |
| stack_after=[pybool], |
| proto=2, |
| doc="""True. |
| |
| Push False onto the stack."""), |
| |
| # Ways to spell Unicode strings. |
| |
| I(name='UNICODE', |
| code='V', |
| arg=unicodestringnl, |
| stack_before=[], |
| stack_after=[pyunicode], |
| proto=0, # this may be pure-text, but it's a later addition |
| doc="""Push a Python Unicode string object. |
| |
| The argument is a raw-unicode-escape encoding of a Unicode string, |
| and so may contain embedded escape sequences. The argument extends |
| until the next newline character. |
| """), |
| |
| I(name='BINUNICODE', |
| code='X', |
| arg=unicodestring4, |
| stack_before=[], |
| stack_after=[pyunicode], |
| proto=1, |
| doc="""Push a Python Unicode string object. |
| |
| There are two arguments: the first is a 4-byte little-endian signed int |
| giving the number of bytes in the string. The second is that many |
| bytes, and is the UTF-8 encoding of the Unicode string. |
| """), |
| |
| # Ways to spell floats. |
| |
| I(name='FLOAT', |
| code='F', |
| arg=floatnl, |
| stack_before=[], |
| stack_after=[pyfloat], |
| proto=0, |
| doc="""Newline-terminated decimal float literal. |
| |
| The argument is repr(a_float), and in general requires 17 significant |
| digits for roundtrip conversion to be an identity (this is so for |
| IEEE-754 double precision values, which is what Python float maps to |
| on most boxes). |
| |
| In general, FLOAT cannot be used to transport infinities, NaNs, or |
| minus zero across boxes (or even on a single box, if the platform C |
| library can't read the strings it produces for such things -- Windows |
| is like that), but may do less damage than BINFLOAT on boxes with |
| greater precision or dynamic range than IEEE-754 double. |
| """), |
| |
| I(name='BINFLOAT', |
| code='G', |
| arg=float8, |
| stack_before=[], |
| stack_after=[pyfloat], |
| proto=1, |
| doc="""Float stored in binary form, with 8 bytes of data. |
| |
| This generally requires less than half the space of FLOAT encoding. |
| In general, BINFLOAT cannot be used to transport infinities, NaNs, or |
| minus zero, raises an exception if the exponent exceeds the range of |
| an IEEE-754 double, and retains no more than 53 bits of precision (if |
| there are more than that, "add a half and chop" rounding is used to |
| cut it back to 53 significant bits). |
| """), |
| |
| # Ways to build lists. |
| |
| I(name='EMPTY_LIST', |
| code=']', |
| arg=None, |
| stack_before=[], |
| stack_after=[pylist], |
| proto=1, |
| doc="Push an empty list."), |
| |
| I(name='APPEND', |
| code='a', |
| arg=None, |
| stack_before=[pylist, anyobject], |
| stack_after=[pylist], |
| proto=0, |
| doc="""Append an object to a list. |
| |
| Stack before: ... pylist anyobject |
| Stack after: ... pylist+[anyobject] |
| |
| although pylist is really extended in-place. |
| """), |
| |
| I(name='APPENDS', |
| code='e', |
| arg=None, |
| stack_before=[pylist, markobject, stackslice], |
| stack_after=[pylist], |
| proto=1, |
| doc="""Extend a list by a slice of stack objects. |
| |
| Stack before: ... pylist markobject stackslice |
| Stack after: ... pylist+stackslice |
| |
| although pylist is really extended in-place. |
| """), |
| |
| I(name='LIST', |
| code='l', |
| arg=None, |
| stack_before=[markobject, stackslice], |
| stack_after=[pylist], |
| proto=0, |
| doc="""Build a list out of the topmost stack slice, after markobject. |
| |
| All the stack entries following the topmost markobject are placed into |
| a single Python list, which single list object replaces all of the |
| stack from the topmost markobject onward. For example, |
| |
| Stack before: ... markobject 1 2 3 'abc' |
| Stack after: ... [1, 2, 3, 'abc'] |
| """), |
| |
| # Ways to build tuples. |
| |
| I(name='EMPTY_TUPLE', |
| code=')', |
| arg=None, |
| stack_before=[], |
| stack_after=[pytuple], |
| proto=1, |
| doc="Push an empty tuple."), |
| |
| I(name='TUPLE', |
| code='t', |
| arg=None, |
| stack_before=[markobject, stackslice], |
| stack_after=[pytuple], |
| proto=0, |
| doc="""Build a tuple out of the topmost stack slice, after markobject. |
| |
| All the stack entries following the topmost markobject are placed into |
| a single Python tuple, which single tuple object replaces all of the |
| stack from the topmost markobject onward. For example, |
| |
| Stack before: ... markobject 1 2 3 'abc' |
| Stack after: ... (1, 2, 3, 'abc') |
| """), |
| |
| I(name='TUPLE1', |
| code='\x85', |
| arg=None, |
| stack_before=[anyobject], |
| stack_after=[pytuple], |
| proto=2, |
| doc="""One-tuple. |
| |
| This code pops one value off the stack and pushes a tuple of |
| length 1 whose one item is that value back onto it. IOW: |
| |
| stack[-1] = tuple(stack[-1:]) |
| """), |
| |
| I(name='TUPLE2', |
| code='\x86', |
| arg=None, |
| stack_before=[anyobject, anyobject], |
| stack_after=[pytuple], |
| proto=2, |
| doc="""One-tuple. |
| |
| This code pops two values off the stack and pushes a tuple |
| of length 2 whose items are those values back onto it. IOW: |
| |
| stack[-2:] = [tuple(stack[-2:])] |
| """), |
| |
| I(name='TUPLE3', |
| code='\x87', |
| arg=None, |
| stack_before=[anyobject, anyobject, anyobject], |
| stack_after=[pytuple], |
| proto=2, |
| doc="""One-tuple. |
| |
| This code pops three values off the stack and pushes a tuple |
| of length 3 whose items are those values back onto it. IOW: |
| |
| stack[-3:] = [tuple(stack[-3:])] |
| """), |
| |
| # Ways to build dicts. |
| |
| I(name='EMPTY_DICT', |
| code='}', |
| arg=None, |
| stack_before=[], |
| stack_after=[pydict], |
| proto=1, |
| doc="Push an empty dict."), |
| |
| I(name='DICT', |
| code='d', |
| arg=None, |
| stack_before=[markobject, stackslice], |
| stack_after=[pydict], |
| proto=0, |
| doc="""Build a dict out of the topmost stack slice, after markobject. |
| |
| All the stack entries following the topmost markobject are placed into |
| a single Python dict, which single dict object replaces all of the |
| stack from the topmost markobject onward. The stack slice alternates |
| key, value, key, value, .... For example, |
| |
| Stack before: ... markobject 1 2 3 'abc' |
| Stack after: ... {1: 2, 3: 'abc'} |
| """), |
| |
| I(name='SETITEM', |
| code='s', |
| arg=None, |
| stack_before=[pydict, anyobject, anyobject], |
| stack_after=[pydict], |
| proto=0, |
| doc="""Add a key+value pair to an existing dict. |
| |
| Stack before: ... pydict key value |
| Stack after: ... pydict |
| |
| where pydict has been modified via pydict[key] = value. |
| """), |
| |
| I(name='SETITEMS', |
| code='u', |
| arg=None, |
| stack_before=[pydict, markobject, stackslice], |
| stack_after=[pydict], |
| proto=1, |
| doc="""Add an arbitrary number of key+value pairs to an existing dict. |
| |
| The slice of the stack following the topmost markobject is taken as |
| an alternating sequence of keys and values, added to the dict |
| immediately under the topmost markobject. Everything at and after the |
| topmost markobject is popped, leaving the mutated dict at the top |
| of the stack. |
| |
| Stack before: ... pydict markobject key_1 value_1 ... key_n value_n |
| Stack after: ... pydict |
| |
| where pydict has been modified via pydict[key_i] = value_i for i in |
| 1, 2, ..., n, and in that order. |
| """), |
| |
| # Stack manipulation. |
| |
| I(name='POP', |
| code='0', |
| arg=None, |
| stack_before=[anyobject], |
| stack_after=[], |
| proto=0, |
| doc="Discard the top stack item, shrinking the stack by one item."), |
| |
| I(name='DUP', |
| code='2', |
| arg=None, |
| stack_before=[anyobject], |
| stack_after=[anyobject, anyobject], |
| proto=0, |
| doc="Push the top stack item onto the stack again, duplicating it."), |
| |
| I(name='MARK', |
| code='(', |
| arg=None, |
| stack_before=[], |
| stack_after=[markobject], |
| proto=0, |
| doc="""Push markobject onto the stack. |
| |
| markobject is a unique object, used by other opcodes to identify a |
| region of the stack containing a variable number of objects for them |
| to work on. See markobject.doc for more detail. |
| """), |
| |
| I(name='POP_MARK', |
| code='1', |
| arg=None, |
| stack_before=[markobject, stackslice], |
| stack_after=[], |
| proto=0, |
| doc="""Pop all the stack objects at and above the topmost markobject. |
| |
| When an opcode using a variable number of stack objects is done, |
| POP_MARK is used to remove those objects, and to remove the markobject |
| that delimited their starting position on the stack. |
| """), |
| |
| # Memo manipulation. There are really only two operations (get and put), |
| # each in all-text, "short binary", and "long binary" flavors. |
| |
| I(name='GET', |
| code='g', |
| arg=decimalnl_short, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=0, |
| doc="""Read an object from the memo and push it on the stack. |
| |
| The index of the memo object to push is given by the newline-teriminated |
| decimal string following. BINGET and LONG_BINGET are space-optimized |
| versions. |
| """), |
| |
| I(name='BINGET', |
| code='h', |
| arg=uint1, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=1, |
| doc="""Read an object from the memo and push it on the stack. |
| |
| The index of the memo object to push is given by the 1-byte unsigned |
| integer following. |
| """), |
| |
| I(name='LONG_BINGET', |
| code='j', |
| arg=int4, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=1, |
| doc="""Read an object from the memo and push it on the stack. |
| |
| The index of the memo object to push is given by the 4-byte signed |
| little-endian integer following. |
| """), |
| |
| I(name='PUT', |
| code='p', |
| arg=decimalnl_short, |
| stack_before=[], |
| stack_after=[], |
| proto=0, |
| doc="""Store the stack top into the memo. The stack is not popped. |
| |
| The index of the memo location to write into is given by the newline- |
| terminated decimal string following. BINPUT and LONG_BINPUT are |
| space-optimized versions. |
| """), |
| |
| I(name='BINPUT', |
| code='q', |
| arg=uint1, |
| stack_before=[], |
| stack_after=[], |
| proto=1, |
| doc="""Store the stack top into the memo. The stack is not popped. |
| |
| The index of the memo location to write into is given by the 1-byte |
| unsigned integer following. |
| """), |
| |
| I(name='LONG_BINPUT', |
| code='r', |
| arg=int4, |
| stack_before=[], |
| stack_after=[], |
| proto=1, |
| doc="""Store the stack top into the memo. The stack is not popped. |
| |
| The index of the memo location to write into is given by the 4-byte |
| signed little-endian integer following. |
| """), |
| |
| # Access the extension registry (predefined objects). Akin to the GET |
| # family. |
| |
| I(name='EXT1', |
| code='\x82', |
| arg=uint1, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=2, |
| doc="""Extension code. |
| |
| This code and the similar EXT2 and EXT4 allow using a registry |
| of popular objects that are pickled by name, typically classes. |
| It is envisioned that through a global negotiation and |
| registration process, third parties can set up a mapping between |
| ints and object names. |
| |
| In order to guarantee pickle interchangeability, the extension |
| code registry ought to be global, although a range of codes may |
| be reserved for private use. |
| |
| EXT1 has a 1-byte integer argument. This is used to index into the |
| extension registry, and the object at that index is pushed on the stack. |
| """), |
| |
| I(name='EXT2', |
| code='\x83', |
| arg=uint2, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=2, |
| doc="""Extension code. |
| |
| See EXT1. EXT2 has a two-byte integer argument. |
| """), |
| |
| I(name='EXT4', |
| code='\x84', |
| arg=int4, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=2, |
| doc="""Extension code. |
| |
| See EXT1. EXT4 has a four-byte integer argument. |
| """), |
| |
| # Push a class object, or module function, on the stack, via its module |
| # and name. |
| |
| I(name='GLOBAL', |
| code='c', |
| arg=stringnl_noescape_pair, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=0, |
| doc="""Push a global object (module.attr) on the stack. |
| |
| Two newline-terminated strings follow the GLOBAL opcode. The first is |
| taken as a module name, and the second as a class name. The class |
| object module.class is pushed on the stack. More accurately, the |
| object returned by self.find_class(module, class) is pushed on the |
| stack, so unpickling subclasses can override this form of lookup. |
| """), |
| |
| # Ways to build objects of classes pickle doesn't know about directly |
| # (user-defined classes). I despair of documenting this accurately |
| # and comprehensibly -- you really have to read the pickle code to |
| # find all the special cases. |
| |
| I(name='REDUCE', |
| code='R', |
| arg=None, |
| stack_before=[anyobject, anyobject], |
| stack_after=[anyobject], |
| proto=0, |
| doc="""Push an object built from a callable and an argument tuple. |
| |
| The opcode is named to remind of the __reduce__() method. |
| |
| Stack before: ... callable pytuple |
| Stack after: ... callable(*pytuple) |
| |
| The callable and the argument tuple are the first two items returned |
| by a __reduce__ method. Applying the callable to the argtuple is |
| supposed to reproduce the original object, or at least get it started. |
| If the __reduce__ method returns a 3-tuple, the last component is an |
| argument to be passed to the object's __setstate__, and then the REDUCE |
| opcode is followed by code to create setstate's argument, and then a |
| BUILD opcode to apply __setstate__ to that argument. |
| |
| If type(callable) is not ClassType, REDUCE complains unless the |
| callable has been registered with the copy_reg module's |
| safe_constructors dict, or the callable has a magic |
| '__safe_for_unpickling__' attribute with a true value. I'm not sure |
| why it does this, but I've sure seen this complaint often enough when |
| I didn't want to <wink>. |
| """), |
| |
| I(name='BUILD', |
| code='b', |
| arg=None, |
| stack_before=[anyobject, anyobject], |
| stack_after=[anyobject], |
| proto=0, |
| doc="""Finish building an object, via __setstate__ or dict update. |
| |
| Stack before: ... anyobject argument |
| Stack after: ... anyobject |
| |
| where anyobject may have been mutated, as follows: |
| |
| If the object has a __setstate__ method, |
| |
| anyobject.__setstate__(argument) |
| |
| is called. |
| |
| Else the argument must be a dict, the object must have a __dict__, and |
| the object is updated via |
| |
| anyobject.__dict__.update(argument) |
| |
| This may raise RuntimeError in restricted execution mode (which |
| disallows access to __dict__ directly); in that case, the object |
| is updated instead via |
| |
| for k, v in argument.items(): |
| anyobject[k] = v |
| """), |
| |
| I(name='INST', |
| code='i', |
| arg=stringnl_noescape_pair, |
| stack_before=[markobject, stackslice], |
| stack_after=[anyobject], |
| proto=0, |
| doc="""Build a class instance. |
| |
| This is the protocol 0 version of protocol 1's OBJ opcode. |
| INST is followed by two newline-terminated strings, giving a |
| module and class name, just as for the GLOBAL opcode (and see |
| GLOBAL for more details about that). self.find_class(module, name) |
| is used to get a class object. |
| |
| In addition, all the objects on the stack following the topmost |
| markobject are gathered into a tuple and popped (along with the |
| topmost markobject), just as for the TUPLE opcode. |
| |
| Now it gets complicated. If all of these are true: |
| |
| + The argtuple is empty (markobject was at the top of the stack |
| at the start). |
| |
| + It's an old-style class object (the type of the class object is |
| ClassType). |
| |
| + The class object does not have a __getinitargs__ attribute. |
| |
| then we want to create an old-style class instance without invoking |
| its __init__() method (pickle has waffled on this over the years; not |
| calling __init__() is current wisdom). In this case, an instance of |
| an old-style dummy class is created, and then we try to rebind its |
| __class__ attribute to the desired class object. If this succeeds, |
| the new instance object is pushed on the stack, and we're done. In |
| restricted execution mode it can fail (assignment to __class__ is |
| disallowed), and I'm not really sure what happens then -- it looks |
| like the code ends up calling the class object's __init__ anyway, |
| via falling into the next case. |
| |
| Else (the argtuple is not empty, it's not an old-style class object, |
| or the class object does have a __getinitargs__ attribute), the code |
| first insists that the class object have a __safe_for_unpickling__ |
| attribute. Unlike as for the __safe_for_unpickling__ check in REDUCE, |
| it doesn't matter whether this attribute has a true or false value, it |
| only matters whether it exists (XXX this is a bug; cPickle |
| requires the attribute to be true). If __safe_for_unpickling__ |
| doesn't exist, UnpicklingError is raised. |
| |
| Else (the class object does have a __safe_for_unpickling__ attr), |
| the class object obtained from INST's arguments is applied to the |
| argtuple obtained from the stack, and the resulting instance object |
| is pushed on the stack. |
| |
| NOTE: checks for __safe_for_unpickling__ went away in Python 2.3. |
| """), |
| |
| I(name='OBJ', |
| code='o', |
| arg=None, |
| stack_before=[markobject, anyobject, stackslice], |
| stack_after=[anyobject], |
| proto=1, |
| doc="""Build a class instance. |
| |
| This is the protocol 1 version of protocol 0's INST opcode, and is |
| very much like it. The major difference is that the class object |
| is taken off the stack, allowing it to be retrieved from the memo |
| repeatedly if several instances of the same class are created. This |
| can be much more efficient (in both time and space) than repeatedly |
| embedding the module and class names in INST opcodes. |
| |
| Unlike INST, OBJ takes no arguments from the opcode stream. Instead |
| the class object is taken off the stack, immediately above the |
| topmost markobject: |
| |
| Stack before: ... markobject classobject stackslice |
| Stack after: ... new_instance_object |
| |
| As for INST, the remainder of the stack above the markobject is |
| gathered into an argument tuple, and then the logic seems identical, |
| except that no __safe_for_unpickling__ check is done (XXX this is |
| a bug; cPickle does test __safe_for_unpickling__). See INST for |
| the gory details. |
| |
| NOTE: In Python 2.3, INST and OBJ are identical except for how they |
| get the class object. That was always the intent; the implementations |
| had diverged for accidental reasons. |
| """), |
| |
| I(name='NEWOBJ', |
| code='\x81', |
| arg=None, |
| stack_before=[anyobject, anyobject], |
| stack_after=[anyobject], |
| proto=2, |
| doc="""Build an object instance. |
| |
| The stack before should be thought of as containing a class |
| object followed by an argument tuple (the tuple being the stack |
| top). Call these cls and args. They are popped off the stack, |
| and the value returned by cls.__new__(cls, *args) is pushed back |
| onto the stack. |
| """), |
| |
| # Machine control. |
| |
| I(name='PROTO', |
| code='\x80', |
| arg=uint1, |
| stack_before=[], |
| stack_after=[], |
| proto=2, |
| doc="""Protocol version indicator. |
| |
| For protocol 2 and above, a pickle must start with this opcode. |
| The argument is the protocol version, an int in range(2, 256). |
| """), |
| |
| I(name='STOP', |
| code='.', |
| arg=None, |
| stack_before=[anyobject], |
| stack_after=[], |
| proto=0, |
| doc="""Stop the unpickling machine. |
| |
| Every pickle ends with this opcode. The object at the top of the stack |
| is popped, and that's the result of unpickling. The stack should be |
| empty then. |
| """), |
| |
| # Ways to deal with persistent IDs. |
| |
| I(name='PERSID', |
| code='P', |
| arg=stringnl_noescape, |
| stack_before=[], |
| stack_after=[anyobject], |
| proto=0, |
| doc="""Push an object identified by a persistent ID. |
| |
| The pickle module doesn't define what a persistent ID means. PERSID's |
| argument is a newline-terminated str-style (no embedded escapes, no |
| bracketing quote characters) string, which *is* "the persistent ID". |
| The unpickler passes this string to self.persistent_load(). Whatever |
| object that returns is pushed on the stack. There is no implementation |
| of persistent_load() in Python's unpickler: it must be supplied by an |
| unpickler subclass. |
| """), |
| |
| I(name='BINPERSID', |
| code='Q', |
| arg=None, |
| stack_before=[anyobject], |
| stack_after=[anyobject], |
| proto=1, |
| doc="""Push an object identified by a persistent ID. |
| |
| Like PERSID, except the persistent ID is popped off the stack (instead |
| of being a string embedded in the opcode bytestream). The persistent |
| ID is passed to self.persistent_load(), and whatever object that |
| returns is pushed on the stack. See PERSID for more detail. |
| """), |
| ] |
| del I |
| |
| # Verify uniqueness of .name and .code members. |
| name2i = {} |
| code2i = {} |
| |
| for i, d in enumerate(opcodes): |
| if d.name in name2i: |
| raise ValueError("repeated name %r at indices %d and %d" % |
| (d.name, name2i[d.name], i)) |
| if d.code in code2i: |
| raise ValueError("repeated code %r at indices %d and %d" % |
| (d.code, code2i[d.code], i)) |
| |
| name2i[d.name] = i |
| code2i[d.code] = i |
| |
| del name2i, code2i, i, d |
| |
| ############################################################################## |
| # Build a code2op dict, mapping opcode characters to OpcodeInfo records. |
| # Also ensure we've got the same stuff as pickle.py, although the |
| # introspection here is dicey. |
| |
| code2op = {} |
| for d in opcodes: |
| code2op[d.code] = d |
| del d |
| |
| def assure_pickle_consistency(verbose=False): |
| import pickle, re |
| |
| copy = code2op.copy() |
| for name in pickle.__all__: |
| if not re.match("[A-Z][A-Z0-9_]+$", name): |
| if verbose: |
| print "skipping %r: it doesn't look like an opcode name" % name |
| continue |
| picklecode = getattr(pickle, name) |
| if not isinstance(picklecode, str) or len(picklecode) != 1: |
| if verbose: |
| print ("skipping %r: value %r doesn't look like a pickle " |
| "code" % (name, picklecode)) |
| continue |
| if picklecode in copy: |
| if verbose: |
| print "checking name %r w/ code %r for consistency" % ( |
| name, picklecode) |
| d = copy[picklecode] |
| if d.name != name: |
| raise ValueError("for pickle code %r, pickle.py uses name %r " |
| "but we're using name %r" % (picklecode, |
| name, |
| d.name)) |
| # Forget this one. Any left over in copy at the end are a problem |
| # of a different kind. |
| del copy[picklecode] |
| else: |
| raise ValueError("pickle.py appears to have a pickle opcode with " |
| "name %r and code %r, but we don't" % |
| (name, picklecode)) |
| if copy: |
| msg = ["we appear to have pickle opcodes that pickle.py doesn't have:"] |
| for code, d in copy.items(): |
| msg.append(" name %r with code %r" % (d.name, code)) |
| raise ValueError("\n".join(msg)) |
| |
| assure_pickle_consistency() |
| del assure_pickle_consistency |
| |
| ############################################################################## |
| # A pickle opcode generator. |
| |
| def genops(pickle): |
| """Generate all the opcodes in a pickle. |
| |
| 'pickle' is a file-like object, or string, containing the pickle. |
| |
| Each opcode in the pickle is generated, from the current pickle position, |
| stopping after a STOP opcode is delivered. A triple is generated for |
| each opcode: |
| |
| opcode, arg, pos |
| |
| opcode is an OpcodeInfo record, describing the current opcode. |
| |
| If the opcode has an argument embedded in the pickle, arg is its decoded |
| value, as a Python object. If the opcode doesn't have an argument, arg |
| is None. |
| |
| If the pickle has a tell() method, pos was the value of pickle.tell() |
| before reading the current opcode. If the pickle is a string object, |
| it's wrapped in a StringIO object, and the latter's tell() result is |
| used. Else (the pickle doesn't have a tell(), and it's not obvious how |
| to query its current position) pos is None. |
| """ |
| |
| import cStringIO as StringIO |
| |
| if isinstance(pickle, str): |
| pickle = StringIO.StringIO(pickle) |
| |
| if hasattr(pickle, "tell"): |
| getpos = pickle.tell |
| else: |
| getpos = lambda: None |
| |
| while True: |
| pos = getpos() |
| code = pickle.read(1) |
| opcode = code2op.get(code) |
| if opcode is None: |
| if code == "": |
| raise ValueError("pickle exhausted before seeing STOP") |
| else: |
| raise ValueError("at position %s, opcode %r unknown" % ( |
| pos is None and "<unknown>" or pos, |
| code)) |
| if opcode.arg is None: |
| arg = None |
| else: |
| arg = opcode.arg.reader(pickle) |
| yield opcode, arg, pos |
| if code == '.': |
| assert opcode.name == 'STOP' |
| break |
| |
| ############################################################################## |
| # A pickle optimizer. |
| |
| def optimize(p): |
| 'Optimize a pickle string by removing unused PUT opcodes' |
| gets = set() # set of args used by a GET opcode |
| puts = [] # (arg, startpos, stoppos) for the PUT opcodes |
| prevpos = None # set to pos if previous opcode was a PUT |
| for opcode, arg, pos in genops(p): |
| if prevpos is not None: |
| puts.append((prevarg, prevpos, pos)) |
| prevpos = None |
| if 'PUT' in opcode.name: |
| prevarg, prevpos = arg, pos |
| elif 'GET' in opcode.name: |
| gets.add(arg) |
| |
| # Copy the pickle string except for PUTS without a corresponding GET |
| s = [] |
| i = 0 |
| for arg, start, stop in puts: |
| j = stop if (arg in gets) else start |
| s.append(p[i:j]) |
| i = stop |
| s.append(p[i:]) |
| return ''.join(s) |
| |
| ############################################################################## |
| # A symbolic pickle disassembler. |
| |
| def dis(pickle, out=None, memo=None, indentlevel=4): |
| """Produce a symbolic disassembly of a pickle. |
| |
| 'pickle' is a file-like object, or string, containing a (at least one) |
| pickle. The pickle is disassembled from the current position, through |
| the first STOP opcode encountered. |
| |
| Optional arg 'out' is a file-like object to which the disassembly is |
| printed. It defaults to sys.stdout. |
| |
| Optional arg 'memo' is a Python dict, used as the pickle's memo. It |
| may be mutated by dis(), if the pickle contains PUT or BINPUT opcodes. |
| Passing the same memo object to another dis() call then allows disassembly |
| to proceed across multiple pickles that were all created by the same |
| pickler with the same memo. Ordinarily you don't need to worry about this. |
| |
| Optional arg indentlevel is the number of blanks by which to indent |
| a new MARK level. It defaults to 4. |
| |
| In addition to printing the disassembly, some sanity checks are made: |
| |
| + All embedded opcode arguments "make sense". |
| |
| + Explicit and implicit pop operations have enough items on the stack. |
| |
| + When an opcode implicitly refers to a markobject, a markobject is |
| actually on the stack. |
| |
| + A memo entry isn't referenced before it's defined. |
| |
| + The markobject isn't stored in the memo. |
| |
| + A memo entry isn't redefined. |
| """ |
| |
| # Most of the hair here is for sanity checks, but most of it is needed |
| # anyway to detect when a protocol 0 POP takes a MARK off the stack |
| # (which in turn is needed to indent MARK blocks correctly). |
| |
| stack = [] # crude emulation of unpickler stack |
| if memo is None: |
| memo = {} # crude emulation of unpicker memo |
| maxproto = -1 # max protocol number seen |
| markstack = [] # bytecode positions of MARK opcodes |
| indentchunk = ' ' * indentlevel |
| errormsg = None |
| for opcode, arg, pos in genops(pickle): |
| if pos is not None: |
| print >> out, "%5d:" % pos, |
| |
| line = "%-4s %s%s" % (repr(opcode.code)[1:-1], |
| indentchunk * len(markstack), |
| opcode.name) |
| |
| maxproto = max(maxproto, opcode.proto) |
| before = opcode.stack_before # don't mutate |
| after = opcode.stack_after # don't mutate |
| numtopop = len(before) |
| |
| # See whether a MARK should be popped. |
| markmsg = None |
| if markobject in before or (opcode.name == "POP" and |
| stack and |
| stack[-1] is markobject): |
| assert markobject not in after |
| if __debug__: |
| if markobject in before: |
| assert before[-1] is stackslice |
| if markstack: |
| markpos = markstack.pop() |
| if markpos is None: |
| markmsg = "(MARK at unknown opcode offset)" |
| else: |
| markmsg = "(MARK at %d)" % markpos |
| # Pop everything at and after the topmost markobject. |
| while stack[-1] is not markobject: |
| stack.pop() |
| stack.pop() |
| # Stop later code from popping too much. |
| try: |
| numtopop = before.index(markobject) |
| except ValueError: |
| assert opcode.name == "POP" |
| numtopop = 0 |
| else: |
| errormsg = markmsg = "no MARK exists on stack" |
| |
| # Check for correct memo usage. |
| if opcode.name in ("PUT", "BINPUT", "LONG_BINPUT"): |
| assert arg is not None |
| if arg in memo: |
| errormsg = "memo key %r already defined" % arg |
| elif not stack: |
| errormsg = "stack is empty -- can't store into memo" |
| elif stack[-1] is markobject: |
| errormsg = "can't store markobject in the memo" |
| else: |
| memo[arg] = stack[-1] |
| |
| elif opcode.name in ("GET", "BINGET", "LONG_BINGET"): |
| if arg in memo: |
| assert len(after) == 1 |
| after = [memo[arg]] # for better stack emulation |
| else: |
| errormsg = "memo key %r has never been stored into" % arg |
| |
| if arg is not None or markmsg: |
| # make a mild effort to align arguments |
| line += ' ' * (10 - len(opcode.name)) |
| if arg is not None: |
| line += ' ' + repr(arg) |
| if markmsg: |
| line += ' ' + markmsg |
| print >> out, line |
| |
| if errormsg: |
| # Note that we delayed complaining until the offending opcode |
| # was printed. |
| raise ValueError(errormsg) |
| |
| # Emulate the stack effects. |
| if len(stack) < numtopop: |
| raise ValueError("tries to pop %d items from stack with " |
| "only %d items" % (numtopop, len(stack))) |
| if numtopop: |
| del stack[-numtopop:] |
| if markobject in after: |
| assert markobject not in before |
| markstack.append(pos) |
| |
| stack.extend(after) |
| |
| print >> out, "highest protocol among opcodes =", maxproto |
| if stack: |
| raise ValueError("stack not empty after STOP: %r" % stack) |
| |
| # For use in the doctest, simply as an example of a class to pickle. |
| class _Example: |
| def __init__(self, value): |
| self.value = value |
| |
| _dis_test = r""" |
| >>> import pickle |
| >>> x = [1, 2, (3, 4), {'abc': u"def"}] |
| >>> pkl = pickle.dumps(x, 0) |
| >>> dis(pkl) |
| 0: ( MARK |
| 1: l LIST (MARK at 0) |
| 2: p PUT 0 |
| 5: I INT 1 |
| 8: a APPEND |
| 9: I INT 2 |
| 12: a APPEND |
| 13: ( MARK |
| 14: I INT 3 |
| 17: I INT 4 |
| 20: t TUPLE (MARK at 13) |
| 21: p PUT 1 |
| 24: a APPEND |
| 25: ( MARK |
| 26: d DICT (MARK at 25) |
| 27: p PUT 2 |
| 30: S STRING 'abc' |
| 37: p PUT 3 |
| 40: V UNICODE u'def' |
| 45: p PUT 4 |
| 48: s SETITEM |
| 49: a APPEND |
| 50: . STOP |
| highest protocol among opcodes = 0 |
| |
| Try again with a "binary" pickle. |
| |
| >>> pkl = pickle.dumps(x, 1) |
| >>> dis(pkl) |
| 0: ] EMPTY_LIST |
| 1: q BINPUT 0 |
| 3: ( MARK |
| 4: K BININT1 1 |
| 6: K BININT1 2 |
| 8: ( MARK |
| 9: K BININT1 3 |
| 11: K BININT1 4 |
| 13: t TUPLE (MARK at 8) |
| 14: q BINPUT 1 |
| 16: } EMPTY_DICT |
| 17: q BINPUT 2 |
| 19: U SHORT_BINSTRING 'abc' |
| 24: q BINPUT 3 |
| 26: X BINUNICODE u'def' |
| 34: q BINPUT 4 |
| 36: s SETITEM |
| 37: e APPENDS (MARK at 3) |
| 38: . STOP |
| highest protocol among opcodes = 1 |
| |
| Exercise the INST/OBJ/BUILD family. |
| |
| >>> import pickletools |
| >>> dis(pickle.dumps(pickletools.dis, 0)) |
| 0: c GLOBAL 'pickletools dis' |
| 17: p PUT 0 |
| 20: . STOP |
| highest protocol among opcodes = 0 |
| |
| >>> from pickletools import _Example |
| >>> x = [_Example(42)] * 2 |
| >>> dis(pickle.dumps(x, 0)) |
| 0: ( MARK |
| 1: l LIST (MARK at 0) |
| 2: p PUT 0 |
| 5: ( MARK |
| 6: i INST 'pickletools _Example' (MARK at 5) |
| 28: p PUT 1 |
| 31: ( MARK |
| 32: d DICT (MARK at 31) |
| 33: p PUT 2 |
| 36: S STRING 'value' |
| 45: p PUT 3 |
| 48: I INT 42 |
| 52: s SETITEM |
| 53: b BUILD |
| 54: a APPEND |
| 55: g GET 1 |
| 58: a APPEND |
| 59: . STOP |
| highest protocol among opcodes = 0 |
| |
| >>> dis(pickle.dumps(x, 1)) |
| 0: ] EMPTY_LIST |
| 1: q BINPUT 0 |
| 3: ( MARK |
| 4: ( MARK |
| 5: c GLOBAL 'pickletools _Example' |
| 27: q BINPUT 1 |
| 29: o OBJ (MARK at 4) |
| 30: q BINPUT 2 |
| 32: } EMPTY_DICT |
| 33: q BINPUT 3 |
| 35: U SHORT_BINSTRING 'value' |
| 42: q BINPUT 4 |
| 44: K BININT1 42 |
| 46: s SETITEM |
| 47: b BUILD |
| 48: h BINGET 2 |
| 50: e APPENDS (MARK at 3) |
| 51: . STOP |
| highest protocol among opcodes = 1 |
| |
| Try "the canonical" recursive-object test. |
| |
| >>> L = [] |
| >>> T = L, |
| >>> L.append(T) |
| >>> L[0] is T |
| True |
| >>> T[0] is L |
| True |
| >>> L[0][0] is L |
| True |
| >>> T[0][0] is T |
| True |
| >>> dis(pickle.dumps(L, 0)) |
| 0: ( MARK |
| 1: l LIST (MARK at 0) |
| 2: p PUT 0 |
| 5: ( MARK |
| 6: g GET 0 |
| 9: t TUPLE (MARK at 5) |
| 10: p PUT 1 |
| 13: a APPEND |
| 14: . STOP |
| highest protocol among opcodes = 0 |
| |
| >>> dis(pickle.dumps(L, 1)) |
| 0: ] EMPTY_LIST |
| 1: q BINPUT 0 |
| 3: ( MARK |
| 4: h BINGET 0 |
| 6: t TUPLE (MARK at 3) |
| 7: q BINPUT 1 |
| 9: a APPEND |
| 10: . STOP |
| highest protocol among opcodes = 1 |
| |
| Note that, in the protocol 0 pickle of the recursive tuple, the disassembler |
| has to emulate the stack in order to realize that the POP opcode at 16 gets |
| rid of the MARK at 0. |
| |
| >>> dis(pickle.dumps(T, 0)) |
| 0: ( MARK |
| 1: ( MARK |
| 2: l LIST (MARK at 1) |
| 3: p PUT 0 |
| 6: ( MARK |
| 7: g GET 0 |
| 10: t TUPLE (MARK at 6) |
| 11: p PUT 1 |
| 14: a APPEND |
| 15: 0 POP |
| 16: 0 POP (MARK at 0) |
| 17: g GET 1 |
| 20: . STOP |
| highest protocol among opcodes = 0 |
| |
| >>> dis(pickle.dumps(T, 1)) |
| 0: ( MARK |
| 1: ] EMPTY_LIST |
| 2: q BINPUT 0 |
| 4: ( MARK |
| 5: h BINGET 0 |
| 7: t TUPLE (MARK at 4) |
| 8: q BINPUT 1 |
| 10: a APPEND |
| 11: 1 POP_MARK (MARK at 0) |
| 12: h BINGET 1 |
| 14: . STOP |
| highest protocol among opcodes = 1 |
| |
| Try protocol 2. |
| |
| >>> dis(pickle.dumps(L, 2)) |
| 0: \x80 PROTO 2 |
| 2: ] EMPTY_LIST |
| 3: q BINPUT 0 |
| 5: h BINGET 0 |
| 7: \x85 TUPLE1 |
| 8: q BINPUT 1 |
| 10: a APPEND |
| 11: . STOP |
| highest protocol among opcodes = 2 |
| |
| >>> dis(pickle.dumps(T, 2)) |
| 0: \x80 PROTO 2 |
| 2: ] EMPTY_LIST |
| 3: q BINPUT 0 |
| 5: h BINGET 0 |
| 7: \x85 TUPLE1 |
| 8: q BINPUT 1 |
| 10: a APPEND |
| 11: 0 POP |
| 12: h BINGET 1 |
| 14: . STOP |
| highest protocol among opcodes = 2 |
| """ |
| |
| _memo_test = r""" |
| >>> import pickle |
| >>> from StringIO import StringIO |
| >>> f = StringIO() |
| >>> p = pickle.Pickler(f, 2) |
| >>> x = [1, 2, 3] |
| >>> p.dump(x) |
| >>> p.dump(x) |
| >>> f.seek(0) |
| >>> memo = {} |
| >>> dis(f, memo=memo) |
| 0: \x80 PROTO 2 |
| 2: ] EMPTY_LIST |
| 3: q BINPUT 0 |
| 5: ( MARK |
| 6: K BININT1 1 |
| 8: K BININT1 2 |
| 10: K BININT1 3 |
| 12: e APPENDS (MARK at 5) |
| 13: . STOP |
| highest protocol among opcodes = 2 |
| >>> dis(f, memo=memo) |
| 14: \x80 PROTO 2 |
| 16: h BINGET 0 |
| 18: . STOP |
| highest protocol among opcodes = 2 |
| """ |
| |
| __test__ = {'disassembler_test': _dis_test, |
| 'disassembler_memo_test': _memo_test, |
| } |
| |
| def _test(): |
| import doctest |
| return doctest.testmod() |
| |
| if __name__ == "__main__": |
| _test() |