Skip to main content

A SQLAlchemy like ORM implementation for arangodb

Project description

Welcome to Arango ORM (Python ORM Layer For ArangoDB)

arango_orm is a python ORM layer inspired by SQLAlchemy but aimed to work with the multi-model database ArangoDB. It supports accessing both collections and graphs using the ORM. The actual communication with the database is done using python-arango (the database driver for accessing arangodb from python) and object serialization, validation, etc is handled by pydantic.

Installation

pip install arango-orm

Connecting to a Database

from arango import ArangoClient
from arango_orm import Database

client = ArangoClient(hosts='http://localhost:8529')
test_db = client.db('test', username='test', password='test')

db = Database(test_db)

Define a Collection

from datetime import date
from pydantic import Field
from arango_orm import Collection


class Student(Collection):

    __collection__ = 'students'

    name: str
    dob: date

Create Collection in the Database

db.create_collection(Student)

Drop a Collection

db.drop_collection(Student)

Check if a collection exists

db.has_collection(Student)
db.has_collection('students')

Add Records

from datetime import date
s = Student(name='test', _key='12312', dob=date(year=2016, month=9, day=12))
db.add(s)
print(s._id)  # students/12312

Get Total Records in the Collection

db.query(Student).count()

Get Record By Key

s = db.query(Student).by_key('12312')

Update a Record

s = db.query(Student).by_key('12312')
s.name = 'Anonymous'
db.update(s)

Delete a Record

s = db.query(Student).by_key('12312')
db.delete(s)

Get All Records in a Collection

students = db.query(Student).all()

Get First Record Matching the Query

first_student = db.query(Student).first()

Filter Records

Using bind parameters (recommended)

records = db.query(Student).filter("name==@name", name='Anonymous').all()

Using plain condition strings (not safe in case of unsanitized user supplied input)

records = db.query(Student).filter("name=='Anonymous'").all()

Filter Using OR

# Get all documents where student name starts with A or B
records = db.query(Student).filter(
            "LIKE(rec.name, 'A%')", prepend_rec_name=False).filter(
            "LIKE(rec.name, 'B%')", prepend_rec_name=False, _or=True).all()

Filter, Sort and Limit

# Last 5 students with names starting with A
records = db.query(Student).filter(
            "LIKE(rec.name, 'A%')", prepend_rec_name=False).sort("name DESC").limit(5).all()

# Query students with pagination (limit&offset)
page_num, per_page = 2, 10
page = db.query(Student).sort("name DESC").limit(per_page, start_from=(page_num - 1) * per_page)

Fetch Only Some Fields

c = db.query(Student).limit(2).returns('_key', 'name').first()

Update Multiple Records

db.query(Student).filter("name==@name", name='Anonymous').update(name='Mr. Anonymous')

Delete Multiple Records

db.query(Student).filter("LIKE(rec.name, 'test%')", prepend_rec_name=False).delete()

Delete All Records

db.query(Student).delete()

Bulk Create Records

s1 = Student(name='test1', _key='12345', dob=date(year=2016, month=9, day=12))
s2 = Student(name='test2', _key='22346', dob=date(year=2015, month=9, day=12)
car1 = Car(make="Honda", model="Fiat", year=2010)
car2 = Car(make="Honda", model="Skoda", year=2015)

db.bulk_add(entity_list=[p_ref_10, p_ref_11, car1, car2])

Bulk Update Records

p_ref1 = db.query(Person).by_key("12312")
p_ref2 = db.query(Person).by_key("12345")
p_ref1.name = "Bruce"
p_ref2.name = "Eliza"
db.bulk_update(entity_list=[p_ref1, p_ref2])

Query Using AQL

db.add(Student(name='test1', _key='12345', dob=date(year=2016, month=9, day=12)))
db.add(Student(name='test2', _key='22346', dob=date(year=2015, month=9, day=12)))

students = [Student._load(s) for s in db.aql.execute("FOR st IN students RETURN st")]

Reference Fields

Reference fields allow linking documents from another collection class within a collection instance. These are similar in functionality to SQLAlchemy's relationship function.

from arango import ArangoClient
from arango_orm.database import Database

from arango_orm.fields import String
from arango_orm import Collection, Relation, Graph, GraphConnection
from arango_orm.references import relationship, graph_relationship


class Person(Collection):

    __collection__ = 'persons'

    _index = [{'type': 'hash', 'unique': False, 'fields': ['name']}]
    _allow_extra_fields = False  # prevent extra properties from saving into DB

    _key = String(required=True)
    name = String(required=True, allow_none=False)

    cars = relationship(__name__ + ".Car", '_key', target_field='owner_key')

    def __str__(self):
        return "<Person(" + self.name + ")>"


class Car(Collection):

    __collection__ = 'cars'
    _allow_extra_fields = True

    make = String(required=True)
    model = String(required=True)
    year = Integer(required=True)
    owner_key = String()

    owner = relationship(Person, 'owner_key', cache=False)

    def __str__(self):
        return "<Car({} - {} - {})>".format(self.make, self.model, self.year)

client = ArangoClient(hosts='http://localhost:8529')
test_db = client.db('test', username='test', password='test')
db = Database(test_db)

p = Person(_key='kashif', name='Kashif Iftikhar')
db.add(p)
p2 = Person(_key='azeen', name='Azeen Kashif')
db.add(p2)

c1 = Car(make='Honda', model='Civic', year=1984, owner_key='kashif')
db.add(c1)

c2 = Car(make='Mitsubishi', model='Lancer', year=2005, owner_key='kashif')
db.add(c2)

c3 = Car(make='Acme', model='Toy Racer', year=2016, owner_key='azeen')
db.add(c3)

print(c1.owner)
print(c1.owner.name)
print(c2.owner.name)
print(c3.owner.name)

print(p.cars)
print(p.cars[0].make)
print(p2.cars)

Working With Graphs

Working with graphs involves creating collection classes and optionally Edge/Relation classes. Users can use the built-in Relation class for specifying relations but if relations need to contain extra attributes then it's required to create a sub-class of Relation class. Graph functionality is explain below with the help of a university graph example containing students, teachers, subjects and the areas where students and teachers reside in.

First we create some collections and relationships

from typing import Literal
from arango_orm import Collection, Relation, Graph, GraphConnection


class Student(Collection):

    __collection__ = 'students'

    name: str
    age: int | None = None

    def __str__(self):
        return "<Student({})>".format(self.name)


class Teacher(Collection):

    __collection__ = 'teachers'

    name: str

    def __str__(self):
        return "<Teacher({})>".format(self.name)


class Subject(Collection):

    __collection__ = 'subjects'


    name: str
    credit_hours: int
    has_labs: bool = True

    def __str__(self):
        return "<Subject({})>".format(self.name)


class Area(Collection):

    __collection__ = 'areas'



class SpecializesIn(Relation):

    __collection__ = 'specializes_in'

    expertise_level: Literal["expert", "medium", "basic"]

    def __str__(self):
        return "<SpecializesIn(_key={}, expertise_level={}, _from={}, _to={})>".format(
            self.key_, self.expertise_level, self._from, self._to)

Next we sub-class the Graph class to specify the relationships between the various collections

class UniversityGraph(Graph):

    __graph__ = 'university_graph'

    graph_connections = [
        # Using general Relation class for relationship
        GraphConnection(Student, Relation("studies"), Subject),
        GraphConnection(Teacher, Relation("teaches"), Subject),

        # Using specific classes for vertex and edges
        GraphConnection(Teacher, SpecializesIn, Subject),
        GraphConnection([Teacher, Student], Relation("resides_in"), Area)
    ]

Now it's time to create the graph. Note that we don't need to create the collections individually, creating the graph will create all collections that it contains

from arango import ArangoClient
from arango_orm.database import Database

client = ArangoClient(hosts='http://localhost:8529')
test_db = client.db('test', username='test', password='test')

db = Database(test_db)

uni_graph = UniversityGraph(connection=db)
db.create_graph(uni_graph)

Now the graph and all it's collections have been created, we can verify their existence:

[c['name'] for c in db.collections()]
db.graphs()

Now let's insert some data into our graph:

students_data = [
    Student(_key='S1001', name='John Wayne', age=30),
    Student(_key='S1002', name='Lilly Parker', age=22),
    Student(_key='S1003', name='Cassandra Nix', age=25),
    Student(_key='S1004', name='Peter Parker', age=20)
]

teachers_data = [
    Teacher(_key='T001', name='Bruce Wayne'),
    Teacher(_key='T002', name='Barry Allen'),
    Teacher(_key='T003', name='Amanda Waller')
]

subjects_data = [
    Subject(_key='ITP101', name='Introduction to Programming', credit_hours=4, has_labs=True),
    Subject(_key='CS102', name='Computer History', credit_hours=3, has_labs=False),
    Subject(_key='CSOOP02', name='Object Oriented Programming', credit_hours=3, has_labs=True),
]

areas_data = [
    Area(_key="Gotham"),
    Area(_key="Metropolis"),
    Area(_key="StarCity")
]

for s in students_data:
    db.add(s)

for t in teachers_data:
    db.add(t)

for s in subjects_data:
    db.add(s)

for a in areas_data:
    db.add(a)

Next let's add some relations, we can add relations by manually adding the relation/edge record into the edge collection, like:

db.add(SpecializesIn(_from="teachers/T001", _to="subjects/ITP101", expertise_level="medium"))

Or we can use the graph object's relation method to generate a relation document from given objects:

gotham = db.query(Area).by_key("Gotham")
metropolis = db.query(Area).by_key("Metropolis")
star_city = db.query(Area).by_key("StarCity")

john_wayne = db.query(Student).by_key("S1001")
lilly_parker = db.query(Student).by_key("S1002")
cassandra_nix = db.query(Student).by_key("S1003")
peter_parker = db.query(Student).by_key("S1004")

intro_to_prog = db.query(Subject).by_key("ITP101")
comp_history = db.query(Subject).by_key("CS102")
oop = db.query(Subject).by_key("CSOOP02")

barry_allen = db.query(Teacher).by_key("T002")
bruce_wayne = db.query(Teacher).by_key("T001")
amanda_waller = db.query(Teacher).by_key("T003")

db.add(uni_graph.relation(peter_parker, Relation("studies"), oop))
db.add(uni_graph.relation(peter_parker, Relation("studies"), intro_to_prog))
db.add(uni_graph.relation(john_wayne, Relation("studies"), oop))
db.add(uni_graph.relation(john_wayne, Relation("studies"), comp_history))
db.add(uni_graph.relation(lilly_parker, Relation("studies"), intro_to_prog))
db.add(uni_graph.relation(lilly_parker, Relation("studies"), comp_history))
db.add(uni_graph.relation(cassandra_nix, Relation("studies"), oop))
db.add(uni_graph.relation(cassandra_nix, Relation("studies"), intro_to_prog))

db.add(uni_graph.relation(barry_allen, SpecializesIn(expertise_level="expert"), oop))
db.add(uni_graph.relation(barry_allen, SpecializesIn(expertise_level="expert"), intro_to_prog))
db.add(uni_graph.relation(bruce_wayne, SpecializesIn(expertise_level="medium"), oop))
db.add(uni_graph.relation(bruce_wayne, SpecializesIn(expertise_level="expert"), comp_history))
db.add(uni_graph.relation(amanda_waller, SpecializesIn(expertise_level="basic"), intro_to_prog))
db.add(uni_graph.relation(amanda_waller, SpecializesIn(expertise_level="medium"), comp_history))

db.add(uni_graph.relation(bruce_wayne, Relation("teaches"), oop))
db.add(uni_graph.relation(barry_allen, Relation("teaches"), intro_to_prog))
db.add(uni_graph.relation(amanda_waller, Relation("teaches"), comp_history))

db.add(uni_graph.relation(bruce_wayne, Relation("resides_in"), gotham))
db.add(uni_graph.relation(barry_allen, Relation("resides_in"), star_city))
db.add(uni_graph.relation(amanda_waller, Relation("resides_in"), metropolis))
db.add(uni_graph.relation(john_wayne, Relation("resides_in"), gotham))
db.add(uni_graph.relation(lilly_parker, Relation("resides_in"), metropolis))
db.add(uni_graph.relation(cassandra_nix, Relation("resides_in"), star_city))
db.add(uni_graph.relation(peter_parker, Relation("resides_in"), metropolis))

With our graph populated with some sample data, let's explore the ways we can work with the graph.

Expanding Documents

We can expand any Collection (not Relation) object to access the data that is linked to it. We can sepcify which links ('inbound', 'outbound', 'any') to expand and the depth to which those should be expanded to. Let's see all immediate connections that Bruce Wayne has in our graph:

bruce = db.query(Teacher).by_key("T001")
uni_graph.expand(bruce, depth=1, direction='any')

Graph expansion on an object adds a _relations dictionary that contains all the relations for the object according to the expansion criteria:

bruce._relations

# Returns:

{
'resides_in': [<Relation(_key=4205290, _from=teachers/T001, _to=areas/Gotham)>],
'specializes_in': [<SpecializesIn(_key=4205114, expertise_level=medium, _from=teachers/T001, _to=subjects/ITP101)>,
    <SpecializesIn(_key=4205271, expertise_level=expert, _from=teachers/T001, _to=subjects/CS102)>,
    <SpecializesIn(_key=4205268, expertise_level=medium, _from=teachers/T001, _to=subjects/CSOOP02)>],
'teaches': [<Relation(_key=4205280, _from=teachers/T001, _to=subjects/CSOOP02)>]
}

We can use _from and _to of a relation object to access the id's for both sides of the link. We also have _object_from and _object_to to access the objects on both sides, for example:

bruce._relations['resides_in'][0]._object_from.name
# 'Bruce Wayne'

bruce._relations['resides_in'][0]._object_to._key
# 'Gotham'

There is also a special attribute called _next that allows accessing the other side of the relationship irrespective of the relationship direction. For example, for outbound relationships the _object_from contains the source object while for inbound_relationships _object_to contains the source object. But if we're only interested in traversal of the graph then it's more useful at times to access the other side of the relationship w.r.t the current object irrespective of it's direction:

bruce._relations['resides_in'][0]._next._key
# 'Gotham'

Let's expand the bruce object to 2 levels and see _next in more action:

uni_graph.expand(bruce, depth=2)

# All relations of the area where bruce resides in
bruce._relations['resides_in'][0]._object_to._relations
# -> {'resides_in': [<Relation(_key=4205300, _from=students/S1001, _to=areas/Gotham)>]}

# Name of the student that resides in the same area as bruce
bruce._relations['resides_in'][0]._object_to._relations['resides_in'][0]._object_from.name
# 'John Wayne'

# The same action using _next without worrying about direction
bruce._relations['resides_in'][0]._next._relations['resides_in'][0]._next.name
# 'John Wayne'

# Get names of all people that reside in the same area and Bruce Wayne
[p._next.name for p in bruce._relations['resides_in'][0]._next._relations['resides_in']]
# ['John Wayne']

Inheritance Mapping

For inheritance mapping, arango_orm offers you two ways to define it.

1. Discriminator field/mapping:

Discriminator field/mapping are defined at entity level:

class Vehicle(Collection):
    __collection__ = "vehicle"

    _inheritance_field = "discr"
    _inheritance_mapping = {
        'Bike': 'moto',
        'Truck': 'truck'
    }

    _key = String()
    brand = String()
    model = String()
    # discr field match what you defined in _inheritance_field
    # the field type depends on the values of your _inheritance_mapping
    discr = String(required=True)


class Bike(Vehicle):
    motor_size = Float()


class Truck(Vehicle):
    traction_power = Float()

2. Inheritance mapping resolver:

The inheritance_mapping_resolver is a function defined at graph level; it allows you to make either a simple test on a discriminator field, or complex inference

class OwnershipGraph2(Graph):
    __graph__ = "ownership_graph"

    graph_connections = [
        GraphConnection(Owner2, Own2, Vehicle2)
    ]

    def inheritance_mapping_resolver(self, col_name: str, doc_dict: dict = {}):
        if col_name == 'vehicle':
            if 'traction_power' in doc_dict:
                return Truck2
            else:
                return Bike2

        return self.vertices[col_name]

Graph Traversal Using AQL

The graph module also supports traversals using AQL, the results are converted to objects and have the same structure as graph.expand method:

obj = uni_graph.aql("FOR v, e, p IN 1..2 INBOUND 'areas/Gotham' GRAPH 'university_graph' RETURN p")
print(obj._key)
# Gotham

gotham_residents = [rel._next.name for rel in obj._relations['resides_in']]
print(gotham_residents)
# ['Bruce Wayne', 'John Wayne']

For Developers

Running the Test Cases

Set env variables in .env file, then load the env

set -a; source .env; set +a

Afterwards run tests

poetry run pytest

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

arango_orm-1.1.0.tar.gz (37.1 kB view details)

Uploaded Source

Built Distribution

arango_orm-1.1.0-py3-none-any.whl (35.5 kB view details)

Uploaded Python 3

File details

Details for the file arango_orm-1.1.0.tar.gz.

File metadata

  • Download URL: arango_orm-1.1.0.tar.gz
  • Upload date:
  • Size: 37.1 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: poetry/1.5.1 CPython/3.11.10 Linux/6.5.0-1025-azure

File hashes

Hashes for arango_orm-1.1.0.tar.gz
Algorithm Hash digest
SHA256 7c47e29fc6314e39e37fef3ea08a9429681c5c99d20f3039bf9a6aac8a49fde2
MD5 563534daa9c946791d563337dcf8795b
BLAKE2b-256 a5df4de504d0c72db24c7d94b8f595e7beabdf54058e3c8411d6504bbe1bd843

See more details on using hashes here.

File details

Details for the file arango_orm-1.1.0-py3-none-any.whl.

File metadata

  • Download URL: arango_orm-1.1.0-py3-none-any.whl
  • Upload date:
  • Size: 35.5 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: poetry/1.5.1 CPython/3.11.10 Linux/6.5.0-1025-azure

File hashes

Hashes for arango_orm-1.1.0-py3-none-any.whl
Algorithm Hash digest
SHA256 a78d25f4c8329b6af9a9428ca4648e374ef2f6fc712c92b474eb10beefb40087
MD5 222a9d649d7e565509895b6639b80352
BLAKE2b-256 f0f6968976e62a4b39883853663657b5b1ff6adf324e167d05d8153f57bbb9cf

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page