Simple library for writing composeable SQL queries
Project description
csql - Composeable SQL
csql is a Python library to help you write more manageable SQL queries. You can write your queries as small, self-contained chunks, preview the results without pulling a whole result-set down from your database, then refer to them in future queries.
There are also useful features for handling database parameters properly.
The intended use-case is for data analysis and exploration.
Full documentation is available at https://csql.readthedocs.io/en/latest/api.html .
Example
from csql import Q, Parameters
import pandas as pd
from datetime import date
con = your_database_connection()
Start with a straightforward query:
p = Parameters(
created_on = date(2020,1,1)
)
q1 = Q(f"""
select
customers.id,
first(customers.name) as name,
first(created_on) as created_on,
sum(sales.value) as sales
from
customers
join sales on customers.id = sales.customer_id
where created_on > {p['created_on']}}
group by customers.id
""")
print(q1.preview_pd(con))
id | name | created_on | sales | |
---|---|---|---|---|
1 | 111 | John Smith | 2020-02-05 | 32.0 |
2 | 112 | Amy Zhang | 2020-05-01 | 101.5 |
3 | 115 | Tran Thanh | 2020-03-02 | 100000.0 |
The preview will pull down 10 rows to a) sanity-check the result of what you've just written, and b) validate your sql.
Now, try building some new queries that build on your previous queries:
q2 = Q(f"""
select
ntile(100) over (order by sales)
as ntile_100,
name,
sales
from {q1}
""")
print(q2.preview_pd(con))
ntile_100 | name | sales | |
---|---|---|---|
1 | 29 | John Smith | 32.0 |
2 | 50 | Amy Zhang | 101.5 |
3 | 99 | Tran Thanh | 100000.0 |
q3 = Q(f"""
select
ntile_100,
min(sales),
max(sales)
from {q2}
group by ntile_100
order by ntile_100
""")
# this time, we'll pull the whole result instead of just previewing:
result = pd.read_sql(**q3.pd(), con=con)
print(result)
ntile_100 | min(sales) | max(sales) | |
---|---|---|---|
28 | 29 | 25 | 33.3 |
49 | 50 | 98 | 120 |
98 | 99 | 5004 | 100000.0 |
Cool! But, how does it work?
The basic idea is to turn your queries into a CTE by keeping track of what builds on top of what. For example, for the last query shown, q3
, what actually gets sent to the database is:
with _subQuery0 as (
select
customers.id,
first(customers.name) as name,
first(created_on) as created_on,
sum(sales.value) as sales
from
customers
join sales on customers.id = sales.customer_id
where created_on > :1
group by customers.id
),
_subQuery1 as (
select
ntile(100) over (order by sales)
as ntile_100,
name,
sales
from _subQuery0
)
select
ntile_100,
min(sales),
max(sales)
from _subQuery1
group by ntile_100
order by ntile_100
which is exactly the sort of unmaintainable and undebuggable monstrosity that this library is designed to help you avoid.
Design Notes
I am perhaps overly optimistic about this, but currently I think this should work with most SQL dialects. It doesn't attempt to parse your SQL, uses CTEs which are widely supported, and passes numeric style parameters.
It's also not actually tied to pandas
at all - .pd()
is just a convenience method to build a dict you can splat into pd.read_sql.
Easy Parameters
Using proper SQL prepared statements is great to do, but can be annoying to maintain. Additionally, it can be incredibly annoying when you are trying to use a list from Python:
con = my_connection()
ids_i_want = [1, 2, 3]
with con.cursor() as c:
# uh oh, you can't do this
c.execute('select * from customers where id in :1', (ids_i_want,))
# you need to do something like this instead
c.execute('select * from customers where id in (:1, :2, :3), (ids_i_want[0], ids_i_want[1], ids_i_want[2],))
csql
makes this much easier - you can embed your parameters naturally with string interpolation, and they will still be
sent as proper parameterized statements.
p = Parameters(
ids_i_want = [1, 2, 3],
name = 'Jarrad'
)
get_customers = Q(f'''
select * from customers
where
ids in {p['ids_i_want']}
or name = {p['name']}
''')
with con.cursor() as c:
c.execute(*get_customers.db)
That final statement is actually equivalent to:
with con.cursor() as c:
c.execute('''
select * from customers
where
ids in (:1, :2, :3)
or name = :4
''', [1, 2, 3, 'Jarrad'])
Changing Parameter Values
Parameters aren't super useful if they are set in stone, but csql
wants you
to give values at the query definition time! How can you pass different values later?
This is achieved by passing newParams
to {meth}csql.Query.build
:
p = Parameters(
start=datetime.now() - timedelta(days=3),
end=datetime.now()
)
q = Q(f'select count(*) from events where start <= date and date < end')
pd.read_sql(**q.pd, con=con)
# 42 # 3 days ago to now, as per `p`.
newParams = {'start': date(2010,1,1)}
pd.read_sql(**q.build(newParams=newParams).pd, con=con)
# 42000 # 2010 to now, with new value for `start` provided.
SQL Dialects
Different dialects can be specified at render time, or as the default dialect of your Queries. Currently the only things dialects control are parameter rendering and limits, but I expect to see some scope creep around here...
Dialects are instances of {class}csql.dialect.SQLDialect
and can be found in {mod}csql.dialect
. The default dialect is {class}csql.dialect.DefaultDialect
, which uses a numeric parameter renderer. You can specify your own prefered dialect per-query:
q = csql.Q(
f"select 1 from thinger",
dialect=csql.dialect.DuckDB
)
If you want to set a default, use functools.partial
like so:
import functools
Q = functools.partial(csql.Q, dialect=csql.dialect.DuckDB)
q = Q(f"select 1 from thinger")
Inferred Dialects
If a query q2
references a previous query q1
, and q1
has a dialect specified, then q2
will use q1
's dialect by default.
q1 = csql.Q('select 1 from thinger', dialect=csql.dialect.Snowflake)
q2 = csql.Q('select count(*) from {q1})
assert q2.default_dialect == csql.dialect.Snowflake
If you reference multiple queries with conflicting dialects, you'll get an error. Normally this is because you've actually
forgotten to specify something somewhere. If you're doing this on purpose, override by setting dialect=
to Q
manually.
DIY Dialects
You can construct your own dialects:
import csql.dialect
MyDialect = csql.dialect.SQLDialect(
paramstyle=csql.dialect.ParamStyle.qmark
)
There are presets for some common databases (see below), and I'm very happy to accept PRs for any others.
How to use Caching
Once you have a few queries chained together, you may start to get annoyed by how long one or two big things at the start take, and wonder if there's a way to stop them being executed each time.
For example,
q1 = Q(f'select id, date, rank() over (partition by name order by date) as rank from customers')
q2 = Q(f'select date, count(*) from {q1}')
print(q2.preview_pd(con))
# takes 2 mins becuase q1 is so slow
print(q2.preview_pd(con))
# same thing again, also takes 2 mins
q3 = Q(f'select max(date) from {q2}')
print(q3.preview_pd(con))
# also takes 2 mins because q1 is so slow
The solution is to use {meth}csql.Query.persist
on the slow query you want to re-use.
Above, we could either do this on q1
or q2
, depending on what works best with
our database. I'll demonstrate q2
:
q1 = Q(f'select id, date, rank() over (partition by name order by date) as rank from customers')
cache = TempTableCacher(con)
q2 = Q(f'select date, count(*) from {q1}').persist(cache) # <--- !!
print(q2.preview_pd(con))
# still takes 2 mins
print(q2.preview_pd(con))
# now this is fast!
q3 = Q(f'select max(date) from {q2}')
print(q3.preview_pd(con))
# now this is fast as well!
The only general builtin caching method is {class}csql.contrib.persist.TempTableCacher
, however it's straightforward
to write your own. You may want to also see {mod}csql.contrib.persist
as there is a Snowflake-specific example in there as well.
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