The overhead for a `dict`

object is quite large. It depends on your Python version and your system architechture, but on Python 3.5 64bit

```
In [21]: sys.getsizeof({})
Out[21]: 288
```

So guesstimating:

```
250*36e6*1e-9 == 9.0
```

So that is a lower limit on my ram usage in **gigabytes** if I created that many dictionaries, not factoring in the `list`

!

Rather than use a dict as a record type, which isn't really the use case, use a `namedtuple`

.

And to get a view of how this compares, let's set up an equivalent list of tuples:

```
In [23]: Record = namedtuple("Record", "name age")
In [24]: records = [Record("john", 28) for _ in range(36000000)]
In [25]: getsizeof = sys.getsizeof
```

Consider:

```
In [31]: sum(getsizeof(record)+ getsizeof(record.name) + getsizeof(record.age) for record in records)
Out[31]: 5220000000
In [32]: _ + getsizeof(records)
Out[32]: 5517842208
In [33]: _ * 1e-9
Out[33]: 5.517842208
```

So 5 gigs is an upper limit that is quite conservative. For example, it assumes that there is no small-int caching going on, which for a record-type of *ages* will totally matter. On my own system, the python process is registering 2.7 gigs of memory usage (via `top`

).

So, what is actually going on in my machine is better modeled by being conservative for strings assuming -- unique strings that have an average size of 10, so no string interning -- but liberal for ints, assuming int-caching is taking care of our `int`

objects for us, so we just have to worry about the 8-byte pointers!

```
In [35]: sum(getsizeof("0123456789") + 8 for record in records)
Out[35]: 2412000000
In [36]: _ + getsizeof(records)
Out[36]: 2709842208
In [37]: _ * 1e-9
Out[37]: 2.709842208
```

Which is a good model for what I'm observing from `top`

.

### If you really want efficient storage

Now, if you really want to cram data into ram, you are going to have to lose the flexibility of Python. You could use the `array`

module in combination with `struct`

, to get C-like memory efficiency. An easier world to wade into might be `numpy`

instead, which allows for similar things. For example:

```
In [1]: import numpy as np
In [2]: recordtype = np.dtype([('name', 'S20'),('age', np.uint8)])
In [3]: records = np.empty((36000000), dtype=recordtype)
In [4]: records.nbytes
Out[4]: 756000000
In [5]: records.nbytes*1e-9
Out[5]: 0.756
```

Note, we are now allowed to be quite compact. I can use 8-bit unsigned integers (i.e. a single byte) to represent age. However, immediately I am faced with some inflexibility: if I want efficient storage of strings I must define a maximum size. I've used `'S20'`

, which is 20 characters. These are ASCII bytes, but a field of 20 ascii characters might very well suffice for names.

Now, `numpy`

gives you a lot of fast methods wrapping C-compiled code. So, just to play around with it, let's fill our records with some toy data. Names will simply be string of digits from a simple count, and age will be selected from a normal distribution with a mean of 50 and a standard deviation of 10.

```
In [8]: for i in range(1, 36000000+1):
...: records['name'][i - 1] = b"%08d" % i
...:
In [9]: import random
...: for i in range(36000000):
...: records['age'][i] = max(0, int(random.normalvariate(50, 10)))
...:
```

Now, we can use numpy to query our `records`

. For example, if you want the indices of your records *given some condition*, use `np.where`

:

```
In [10]: np.where(records['age'] > 70)
Out[10]: (array([ 58, 146, 192, ..., 35999635, 35999768, 35999927]),)
In [11]: idx = np.where(records['age'] > 70)[0]
In [12]: len(idx)
Out[12]: 643403
```

So `643403`

records that have an age `> 70`

. Now, let's try `100`

:

```
In [13]: idx = np.where(records['age'] > 100)[0]
In [14]: len(idx)
Out[14]: 9
In [15]: idx
Out[15]:
array([ 2315458, 5088296, 5161049, 7079762, 15574072, 17995993,
25665975, 26724665, 28322943])
In [16]: records[idx]
Out[16]:
array([(b'02315459', 101), (b'05088297', 102), (b'05161050', 101),
(b'07079763', 104), (b'15574073', 101), (b'17995994', 102),
(b'25665976', 101), (b'26724666', 102), (b'28322944', 101)],
dtype=[('name', 'S20'), ('age', 'u1')])
```

Of course, one major inflexibility is that `numpy`

arrays are *sized*. Resizing operations are expensive. Now, you could maybe wrap a `numpy.array`

in some class and it will act as an efficient backbone, but at that point, you might as well use a real data-base. Lucky for you, Python comes with `sqlite`

.