# Background

Suppose we have a set of *questions*, and a set of *students* that answered these questions.
The answers have been reviewed, and *scores* have been assigned, on some unknown range.

Now, we need to normalize the *scores* with respect to the extreme values within each *question*.
For example, if *question 1* has a minimum *score* of 4 and a maximum *score* of 12, those scores would be normalized to 0 and 1 respectively. Scores in between are interpolated linearly (as described e.g. in Normalization to bring in the range of [0,1]).

Then, for each *student*, we would like to know the mean of the *normalized scores* for all *questions* combined.

# Minimal example

Here's a *very naive* minimal implementation, just to illustrate what we would like to achieve:

```
class Question(models.Model):
pass
class Student(models.Model):
def mean_normalized_score(self):
normalized_scores = []
for score in self.score_set.all():
normalized_scores.append(score.normalized_value())
return mean(normalized_scores) if normalized_scores else None
class Score(models.Model):
student = models.ForeignKey(to=Student, on_delete=models.CASCADE)
question = models.ForeignKey(to=Question, on_delete=models.CASCADE)
value = models.FloatField()
def normalized_value(self):
limits = Score.objects.filter(question=self.question).aggregate(
min=models.Min('value'), max=models.Max('value'))
return (self.value - limits['min']) / (limits['max'] - limits['min'])
```

This works well, but it is quite inefficient in terms of database queries, etc.

# Goal

Instead of the implementation above, I would prefer to offload the number-crunching on to the database.

# What I've tried

Consider, for example, these two use cases:

- list the
`normalized_value`

for all`Score`

objects - list the
`mean_normalized_score`

for all`Student`

objects

The first use case can be covered using window functions in a query, something like this:

```
w_min = Window(expression=Min('value'), partition_by=[F('question')])
w_max = Window(expression=Max('value'), partition_by=[F('question')])
annotated_scores = Score.objects.annotate(
normalized_value=(F('value') - w_min) / (w_max - w_min))
```

This works nicely, so the `Score.normalized_value()`

method from the example is no longer needed.

Now, I would like to do something similar for the second use case, to replace the `Student.mean_normalized_score()`

method by a single database query.

The raw SQL could look something like this (for sqlite):

```
SELECT id, student_id, AVG(normalized_value) AS mean_normalized_score
FROM (
SELECT
myapp_score.*,
((myapp_score.value - MIN(myapp_score.value) OVER (PARTITION BY myapp_score.question_id)) / (MAX(myapp_score.value) OVER (PARTITION BY myapp_score.question_id) - MIN(myapp_score.value) OVER (PARTITION BY myapp_score.question_id)))
AS normalized_value
FROM myapp_score
)
GROUP BY student_id
```

I can make this work as a raw Django query, but I have *not* yet been able to reproduce this query using Django's ORM.

I've tried building on the `annotated_scores`

queryset described above, using Django's Subquery, `annotate()`

, `aggregate()`

, `Prefetch`

, and combinations of those, but I must be making a mistake somewhere.

Probably the closest I've gotten is this:

```
subquery = Subquery(annotated_scores.values('normalized_value'))
Score.objects.values('student_id').annotate(mean=Avg(subquery))
```

But this is incorrect.

Could someone point me in the right direction, without resorting to raw queries?

`annotated_scores = Score.objects.filter(student=OuterRef('pk').annotate(normalized_value=(F('value') - w_min) / (w_max - w_min)).values('student').annotate(mean=Avg('normalized_value'))`

and then from the Student,`Student.objects.annotate(mean_normalized_score=Subquery(annotated_scores.values('mean')[:1]))`

`filter()`

? Unfortunately, after fixing this, I get an`OperationalError: misuse of window function MIN()`

. The same error arises e.g. if I try to`annotate()`

my`annotated_scores`

.