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All the docs I've seen imply that you might be able to do that, but there isn't anything official w/r/t ulong64/uint64 fields. There are a few off-the-shelf options that look quite promising in this arena:

  • BigIntegerField ... almost, but signed;
  • PositiveIntegerField ... suspiciously 32-bit-looking; and
  • DecimalField ... a fixed-pointer represented with a python decimal type, according to the docs -- which presumably turns into an analogously pedantic and slow database field when socked away, á la the DECIMAL or NUMERIC PostgreSQL types.

... all of which look like they might store a number like that. Except NONE OF THEM WILL COMMIT, much like every single rom-com character portrayed by Hugh Grant.

My primary criterion is that it works with Django's supported backends, without any if postgresql (...) elif mysql (...) type of special-case nonsense. After that, there is the need for speed -- this is for a model field in an visual-database application that will index image-derived data (e.g. perceptual hashes and extracted keypoint features), allowing ordering and grouping by the content of those images.

So: is there a good Django extension or app that furnishes some kind of PositiveBigIntegerField that will suit my purposes?

And, barring that: If there is a simple and reliable way to use Django's stock ORM to store unsigned 64-bit ints, I'd like to know it. Look, I'm no binary whiz; I have to do two's complement on paper -- so if this method of yours involves some bit-shifting trickery, don't hesitate to explain what it is, even if it strikes you as obvious. Thanks in advance.

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+1 for much like every single rom-com character portrayed by Hugh Grant made me chuckle on a dreary and humid morning. –  Burhan Khalid May 21 '12 at 4:29
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1 Answer 1

up vote 10 down vote accepted

Although I did not test it, but you may wish to just subclass BigIntegerField. The original BigIntegerField looks like that (source here):

class BigIntegerField(IntegerField):
    empty_strings_allowed = False
    description = _("Big (8 byte) integer")
    MAX_BIGINT = 9223372036854775807

    def get_internal_type(self):
        return "BigIntegerField"

    def formfield(self, **kwargs):
        defaults = {'min_value': -BigIntegerField.MAX_BIGINT - 1,
                    'max_value': BigIntegerField.MAX_BIGINT}
        defaults.update(kwargs)
        return super(BigIntegerField, self).formfield(**defaults)

Derived PositiveBigIntegerField may looks like this:

class PositiveBigIntegerField(BigIntegerField):
    empty_strings_allowed = False
    description = _("Big (8 byte) positive integer")

    def db_type(self, connection):
        """
        Returns MySQL-specific column data type. Make additional checks
        to support other backends.
        """
        return 'bigint UNSIGNED'

    def formfield(self, **kwargs):
        defaults = {'min_value': 0,
                    'max_value': BigIntegerField.MAX_BIGINT * 2 - 1}
        defaults.update(kwargs)
        return super(PositiveBigIntegerField, self).formfield(**defaults)

Although you should test it thoroughly, before using it. If you do, please share the results :)

EDIT:

I missed one thing - internal database representation. This is based on value returned by get_internal_type() and the definition of the column type is stored eg. here in case of MySQL backend and determined here. It looks like overwriting db_type() will give you control over how the field is represented in the database. However, you will need to find a way to return DBMS-specific value in db_type() by checking connection argument.

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Wow, that looks too good to be true, so to speak -- I'm not too concerned about validating human input via FormField (as this datum will come from an image analysis function) and if you take that stuff out, we're left with the description text, the MAX_BIGINT attribute, and the get_internal_type specification... which none of those additions let the subclass tell the ORM how to treat it like a uint64. I could very well be mistaken -- if I'm missing something here with any of these, do let me know. –  fish2000 May 21 '12 at 0:02
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@fish2000: You were right, see my edit. The part I was missing is db_field() that was meant to return DBMS-specific type based on internal type returned by get_internal_type() and looked up in DBMS-specific data_types dictionary (seen here). Does it solve your problem now? –  Tadeck May 21 '12 at 5:19
    
Nice! It's good to know where the ORM stashes its necessary heap of proprietary edge-case SQL fragments -- I hadn't run across that before and it's what one needs to implement get_internal_type() methods with the same vendor-specific logic as Django itself. That's a great tip, thank you! –  fish2000 May 21 '12 at 22:04
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As far as I can see, the db_field method should be db_type (submitted an edit which is waiting on peer review). –  Tikitu Mar 1 '13 at 14:13
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