Logica is an open source declarative logic programming language for data manipulation. Logica is a successor to Yedalog, a language created at Google earlier.
Logica is for engineers, data scientists and other specialists who want to use logic programming syntax when writing queries and pipelines for databases and datawarehouses. Logica programs run on BigQuery, Postgres and SQLite.
Logica compiles to SQL and gives you access to the power of SQL ecosystem with the convenience of logic programming syntax.
This is useful because SQL enginers are magnitudes more powerful than state of the art native logic programming engines. For example, BigQuery is a distributed datawarehouse and thus logic programs written in Logica can be easily parallelized onto thousands of servers. Postgres and SQLite are among most popular databases, they are capable of processing substantial volumes of data right on your machine.
We encourage you to try Logica, especially if
- you already use logic programming and need more computational power, or
- you already have data in BigQuery, PostgreSQL or SQLite, or
- you want to learn logic programming and apply it to processing of Big Data.
Support for more SQL dialects and engines is coming in the future.
Logic programming is a declarative programming paradigm where the program is written as a set of logical statements.
Logic programming was developed in academia from the late 60s. Prolog and Datalog are the most prominent examples of logic programming languages. Logica is a language of the Datalog family.
Datalog and relational databases start from the same idea: think of data as relations and think of data manipulation as a sequence of operations over these relations. But Datalog and SQL differ in how these operations are described. Datalog is inspired by the mathematical syntax of the first order propositional logic and SQL follows the syntax of natural language.
SQL was based on the natural language to give access to databases to the people without formal training in computer programming or mathematics. This convenience may become costly when the logic that you want to express is non trivial. There are many examples of hard-to-read SQL queries that correspond to simple logic programs.
Logica compiles the logic program into a SQL expression, so it can be executed on BigQuery, the state of the art SQL engine.
Among database theoreticians Datalog and SQL are known to be equivalent. And indeed the conversion from Datalog to SQL and back is often straightforward. However there are a few nuances, for example how to treat disjunction and negation. In Logica we tried to make choices that make understanding of the resulting SQL structure as easy as possible, thus empowering user to write programs that are executed efficiently.
Logica stands for Logic with aggregation.
Learn basics of Logica with the CoLab tutorial located at tutorial
folder.
See examples of using Logica in examples
folder.
Tutorial and examples show how to access Logica from CoLab. You can also install Logica command line tool.
To run Logica programs on BigQuery you will need a Google Cloud Project. Once you have a project you can run Logica programs in CoLab providing your project id.
To run Logica locally you need Python3.
To initiate Logica predicates execution from the command line
you will need bq
, a
BigQuery command line tool. For that you need to install
Google Cloud SDK.
Google Cloud Project is the only thing you need to run Logica in Colab, see Hello World example.
You can install Logica command with pip
as follows.
# Install.
python3 -m pip install logica
# Run:
# To see usage message.
python3 -m logica
# To print SQL for HelloWorld program.
python3 -m logica - print Greet <<<'Greet(greeting: "Hello world!")'
If your PATH
includes Python's bin
folder then you will also be able to
run it simply as
logica - print Greet <<<'Greet(greeting: "Hello world!")'
Alternatively, you can clone GitHub repository:
git clone https://github.com/evgskv/logica
cd logica
./logica - print Greet <<<'Greet(greeting: "Hello world!")'
Here a couple examples of how Logica code looks like.
Find prime numbers less than 30.
Program primes.l
:
# Define numbers 1 to 30.
Number(x + 1) :- x in Range(30);
# Defining composite numbers.
Composite(a * b) distinct :- Number(a), Number(b), a > 1, b > 1;
# Defining primes as "not composite".
Prime(n) distinct :- Number(n), n > 1, ~Composite(n);
Running primes.l
$ logica primes.l run Prime
+-------+
| prime |
+-------+
| 2 |
| 3 |
| 5 |
| 7 |
| 11 |
| 13 |
| 17 |
| 19 |
| 23 |
| 29 |
+-------+
Let's use beer variety dataset from plotly.
Let us find top 5 states with largest variety of beers. In each state we will pick city with the largest variety in the state.
Program beer.l
:
@Engine("duckdb");
@Ground(Beer);
Beer(..r) :-
`('https://github.com/plotly/datasets/blob/master/beers.csv?raw=true')`(..r);
BeersInState(state) += 1 :- Beer(state:);
BeersInCity(state, city) += 1 :- Beer(state:, city:);
ArgMax5(x) = ArgMaxK(x, 5);
BestCityForBeer(state:, city:,
city_beers: BeersInCity(state, city),
state_beers: BeersInState(state)) :-
state in ArgMax5{s -> BeersInState(s)},
city = ArgMax{c -> BeersInCity(state, c)};
Running beer.l
:
# logica beer.l run BestCityForBeer
+-------+--------------+------------+-------------+
| state | city | city_beers | state_beers |
+-------+--------------+------------+-------------+
| IN | Indianapolis | 43 | 139 |
| CO | Boulder | 41 | 265 |
| CA | San Diego | 42 | 183 |
| TX | Austin | 25 | 130 |
| MI | Grand Rapids | 66 | 162 |
+-------+--------------+------------+-------------+
Feel free to create github issues for bugs and feature requests.
You questions and comments are welcome at our github discussions!
Unless otherwise noted, the Logica source files are distributed under the Apache 2.0 license found in the LICENSE file.
This is not an officially supported Google product.