dataloom

dataloom stands as a bespoke Object-Relational Mapping (ORM) solution meticulously crafted to empower Python developers in efficiently managing diverse databases. Unlike conventional ORMs, Dataloom has been built from the ground up, providing native support for SQLite3, PostgreSQL, and MySQL. Navigate effortlessly between database engines while enjoying a tailored and performant ORM experience.

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Development Status
- 5 - Production/Stable
- 6 - Mature
Intended Audience
- Developers
Natural Language
- English
Operating System
Programming Language
- Python :: 3.12

Project description

dataloom

dataloom is a lightweight and versatile Object-Relational Mapping (ORM) library for Python. With support for PostgreSQL, MySQL, and SQLite3 databases, dataloom simplifies database interactions, providing a seamless experience for developers.

dataloom

Why choose `dataloom`?

Ease of Use: dataloom offers a user-friendly interface, making it straightforward to work with.
Flexible SQL Driver: Write one codebase and seamlessly switch between PostgreSQL, MySQL, and SQLite3 drivers as needed.
Lightweight: Despite its powerful features, dataloom remains lightweight, ensuring efficient performance.
Comprehensive Documentation: Benefit from extensive documentation that guides users through various functionalities and use cases.
Active Maintenance: dataloom is actively maintained, ensuring ongoing support and updates for a reliable development experience.
Cross-platform Compatibility: dataloom works seamlessly across different operating systems, including Windows, macOS, and Linux.
Scalability: Scale your application effortlessly with dataloom, whether it's a small project or a large-scale enterprise application.

dataloom
- Why choose dataloom?
Table of Contents
Key Features:
Installation
Python Version Compatibility
Usage
Connection
Dataloom Classes
Syncing Tables
- 1. The sync method.
- 2. The connect_and_sync method.
CRUD Operations with Dataloom
Ordering
Filters
- Operators
Data Aggregation
- Aggregation Functions
Utilities
Associations
Query Builder.
- Why Use Query Builder?
Documentation
Contributing
License

Key Features:

Lightweight: dataloom is designed to be minimalistic and easy to use, ensuring a streamlined ORM experience without unnecessary complexities.
Database Support: dataloom supports popular relational databases such as PostgreSQL, MySQL, and SQLite3, making it suitable for a variety of projects.
Simplified Querying: The ORM simplifies the process of database querying, allowing developers to interact with the database using Python classes and methods rather than raw SQL queries.
Intuitive Syntax: dataloom's syntax is intuitive and Pythonic, making it accessible for developers familiar with the Python language.
Flexible Data Types: The ORM seamlessly handles various data types, offering flexibility in designing database schemas.

Installation

To install dataloom, you just need to run the following command using pip:

pip install dataloom

Python Version Compatibility

dataloom supports Python version 3.12 and above. Ensure that you are using a compatible version of Python before installing or using dataloom.

You can check your Python version by running:

python --version

Usage

In this section we are going to go through how you can use our orm package in your project.

Connection

To use Dataloom, you need to establish a connection with a specific database dialect. The available dialect options are mysql, postgres, and sqlite.

`Postgres`

The following is an example of how you can establish a connection with postgres database.

from dataloom import Loom

# Create a Loom instance with PostgreSQL configuration
pg_loom = Loom(
    dialect="postgres",
    database="hi",
    password="root",
    user="postgres",
    host="localhost",
    sql_logger="console",
    logs_filename="logs.sql",
    port=5432,
)

# Connect to the PostgreSQL database
conn = pg_loom.connect()


# Close the connection when the script completes
if __name__ == "__main__":
    conn.close()

In dataloom you can use connection uris to establish a connection to the database in postgres as follows:

pg_loom = Loom(
    dialect="postgres",
    connection_uri = "postgressql://root:root@localhost:5432/hi",
   # ...
)

This will establish a connection with postgres with the database hi.

`MySQL`

To establish a connection with a MySQL database using Loom, you can use the following example:

from dataloom import Loom

# Create a Loom instance with MySQL configuration
mysql_loom = Loom(
    dialect="mysql",
    database="hi",
    password="root",
    user="root",
    host="localhost",
    sql_logger="console",
    logs_filename="logs.sql",
    port=3306,
)

# Connect to the MySQL database
conn = mysql_loom.connect()

# Close the connection when the script completes
if __name__ == "__main__":
    conn.close()

In dataloom you can use connection uris to establish a connection to the database in mysql as follows:

mysql_loom = Loom(
    dialect="mysql",
    connection_uri = "mysql://root:root@localhost:3306/hi",
   # ...
)

This will establish a connection with mysql with the database hi.

`SQLite`

To establish a connection with an SQLite database using Loom, you can use the following example:

from dataloom import Loom

# Create a Loom instance with SQLite configuration
sqlite_loom = Loom(
    dialect="sqlite",
    database="hi.db",
    logs_filename="sqlite-logs.sql",
    logging=True,
    sql_logger="console",
)

# Connect to the SQLite database
conn = sqlite_loom.connect()

# Close the connection when the script completes
if __name__ == "__main__":
    conn.close()

In dataloom you can use connection uris to establish a connection to the database in sqlite as follows:

sqlite_loom = Loom(
    dialect="sqlite",
   connection_uri = "sqlite:///hi.db",
   # ...
)

This will establish a connection with sqlite with the database hi.

Dataloom Classes

The following are the list of classes that are available in dataloom.

`Loom` Class

This class is used to create a loom object that will be use to perform actions to a database. The following example show how you can create a loom object using this class.

from dataloom import Loom
loom = Loom(
    dialect="postgres",
    database="hi",
    password="root",
    user="postgres",
    host="localhost",
    sql_logger="console",
    logs_filename="logs.sql",
    port=5432,
)

# OR with connection_uri
loom = Loom(
    dialect="mysql",
    connection_uri = "mysql://root:root@localhost:3306/hi",
   # ...
)

The Loom class takes in the following options:

Parameter	Description	Value Type	Default Value	Required
`connection_uri`	The connection `uri` for the specified dialect.	`str` or `None`	`None`	`No`
`dialect`	Dialect for the database connection. Options are `mysql`, `postgres`, or `sqlite`	`"mysql" \| "postgres" \| "sqlite"`	`None`	`Yes`
`database`	Name of the database for `mysql` and `postgres`, filename for `sqlite`	`str` or `None`	`None`	`No`
`password`	Password for the database user (only for `mysql` and `postgres`)	`str` or `None`	`None`	`No`
`user`	Database user (only for `mysql` and `postgres`)	`str` or `None`	`None`	`No`
`host`	Database host (only for `mysql` and `postgres`)	`str` or `None`	`localhost`	`No`
`sql_logger`	Enable logging for the database queries. If you don't want to see the sql logs you can set this option to `None` which is the default value. If you set it to `file` then you will see the logs in the default `dataloom.sql` file, you can overide this by passing a `logs_filename` option. Setting this option to `console`, then sql statements will be printed on the console.	`console`or `file` or `None`	`True`	`No`
`logs_filename`	Filename for the query logs	`str` or `None`	`dataloom.sql`	`No`
`port`	Port number for the database connection (only for `mysql` and `postgres`)	`int` or `None`	`None`	`No`

`Model` Class

A model in Dataloom is a top-level class that facilitates the creation of complex SQL tables using regular Python classes. This example demonstrates how to define two tables, User and Post, by creating classes that inherit from the Model class.

from dataloom import (
    Loom,
    Model,
    PrimaryKeyColumn,
    Column,
    CreatedAtColumn,
    UpdatedAtColumn,
    TableColumn,
    ForeignKeyColumn,
)

class User(Model):
    __tablename__:TableColumn = TableColumn(name="users")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    name = Column(type="text", nullable=False, default="Bob")
    username = Column(type="varchar", unique=True, length=255)

    # timestamps
    createdAt = CreatedAtColumn()
    updatedAt = UpdatedAtColumn()


class Post(Model):
    __tablename__: TableColumn = TableColumn(name="posts")
    id = PrimaryKeyColumn(type="int", auto_increment=True, nullable=False, unique=True)
    completed = Column(type="boolean", default=False)
    title = Column(
        type="varchar",
        length=255,
        nullable=False,
    )
    # timestamps
    createdAt = CreatedAtColumn()
    updatedAt = UpdatedAtColumn()

    # relations
    userId = ForeignKeyColumn(
        User, type="int", required=True, onDelete="CASCADE", onUpdate="CASCADE"
    )

Within the User model definition, the table name is explicitly specified using the __tablename__ property, set to "users". This informs dataloom to use the provided name instead of automatically deriving it from the class name. If TableColumn is not specified, the class name becomes the default table name during the synchronization of tables. To achieve this, the TableColumn class is used, accepting the specified table name as an argument.

👉:Note: When defining a table name, it's not necessary to specify the property as __tablename__. However, it's considered good practice to name your table column like that to avoid potential clashes with other columns in the table.

Every table must include exactly one primary key column unless it is a joint_table for N-N relations that requires no primary key column. To define this, the PrimaryKeyColumn class is employed, signaling to dataloom that the specified field is a primary key.
The Column class represents a regular column, allowing the inclusion of various options such as type and whether it is required.
The CreatedAtColumn and UpdatedAt column types are automatically generated by the database as timestamps. If timestamps are unnecessary or only one of them is needed, they can be omitted.
The ForeignKeyColumn establishes a relationship between the current (child) table and a referenced (parent) table.

`Column` Class

In the context of a database table, each property marked as a column in a model is treated as an individual attribute. Here's an example of how to define a column in a table using the Column class:

username = Column(type="text", nullable=False, default="Hello there!!")

Here are some other options that you can pass to the Column:

Argument	Description	Type	Default
`type`	Required datatype of a column	any `datatype`
`nullable`	Optional to specify if the column will allow null values or not.	`bool`	`False`
`length`	Optional to specify the length of the type. If passed as `N` with type `T`, it yields an SQL statement with type `T(N)`.	`int` \| `None`	`None`
`auto_increment`	Optional to specify if the column will automatically increment or not.	`bool`	`False`
`default`	Optional to specify the default value in a column.	`any`	`None`
`unique`	Optional to specify if the column will contain unique values or not.	`bool`	`False`

Talking about data types, each dialect has its own accepted values. Here is a list of types supported by each and every dialect:

Column Datatypes

In this section we will list all the datatypes that are supported for each dialect.

1. `mysql`

Data Type	Description
`"int"`	Integer data type.
`"smallint"`	Small integer data type.
`"bigint"`	Big integer data type.
`"float"`	Floating-point number data type.
`"double"`	Double-precision floating-point number data type.
`"numeric"`	Numeric or decimal data type.
`"text"`	Text data type.
`"varchar"`	Variable-length character data type.
`"char"`	Fixed-length character data type.
`"boolean"`	Boolean data type.
`"date"`	Date data type.
`"time"`	Time data type.
`"timestamp"`	Timestamp data type.
`"json"`	JSON (JavaScript Object Notation) data type.
`"blob"`	Binary Large Object (BLOB) data type.

2. `postgres`

Data Type	Description
`"int"`	Integer data type (Alias: `"INTEGER"`).
`"smallint"`	Small integer data type (Alias: `"SMALLINT"`).
`"bigint"`	Big integer data type (Alias: `"BIGINT"`).
`"serial"`	Auto-incrementing integer data type (Alias: `"SERIAL"`).
`"bigserial"`	Auto-incrementing big integer data type (Alias: `"BIGSERIAL"`).
`"smallserial"`	Auto-incrementing small integer data type (Alias: `"SMALLSERIAL"`).
`"float"`	Real number data type (Alias: `"REAL"`).
`"double precision"`	Double-precision floating-point number data type (Alias: `"DOUBLE PRECISION"`).
`"numeric"`	Numeric data type (Alias: `"NUMERIC"`).
`"text"`	Text data type.
`"varchar"`	Variable-length character data type.
`"char"`	Fixed-length character data type.
`"boolean"`	Boolean data type.
`"date"`	Date data type.
`"time"`	Time data type.
`"timestamp"`	Timestamp data type.
`"interval"`	Time interval data type.
`"uuid"`	UUID (Universally Unique Identifier) data type.
`"json"`	JSON (JavaScript Object Notation) data type.
`"jsonb"`	Binary JSON (JavaScript Object Notation) data type.
`"bytea"`	Binary data type (Array of bytes).
`"array"`	Array data type.
`"inet"`	IP network address data type.
`"cidr"`	Classless Inter-Domain Routing (CIDR) address data type.
`"macaddr"`	MAC (Media Access Control) address data type.
`"tsvector"`	Text search vector data type.
`"point"`	Geometric point data type.
`"line"`	Geometric line data type.
`"lseg"`	Geometric line segment data type.
`"box"`	Geometric box data type.
`"path"`	Geometric path data type.
`"polygon"`	Geometric polygon data type.
`"circle"`	Geometric circle data type.
`"hstore"`	Key-value pair store data type.

3. `sqlite`

Data Type	Description
`"int"`	Integer data type.
`"smallint"`	Small integer data type.
`"bigint"`	Big integer data type.
`"float"`	Real number data type.
`"double precision"`	Double-precision floating-point number data type.
`"numeric"`	Numeric data type.
`"text"`	Text data type.
`"varchar"`	Variable-length character data type.
`"char"`	Fixed-length character data type.
`"boolean"`	Boolean data type.
`"date"`	Date data type.
`"time"`	Time data type.
`"timestamp"`	Timestamp data type.
`"json"`	JSON (JavaScript Object Notation) data type.
`"blob"`	Binary Large Object (BLOB) data type.

Note: Every table that is not a joint_table is required to have a primary key column and this column should be 1. Let's talk about the PrimaryKeyColumn

`PrimaryKeyColumn` Class

This class is used to create a unique index in every table you create. In the context of a table that inherits from the Model class, exactly one PrimaryKeyColumn is required. Below is an example of creating an id column as a primary key in a table named Post:

class Post(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="users")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    #...rest of your columns

The following are the arguments that the PrimaryKeyColumn class accepts.

Argument	Description	Type	Default
`type`	The datatype of your primary key.	`str`	`"int`"
`length`	Optional to specify the length of the type. If passed as `N` with type `T`, it yields an SQL statement with type `T(N)`.	`int` \| `None`	`None`
`auto_increment`	Optional to specify if the column will automatically increment or not.	`bool`	`False`
`default`	Optional to specify the default value in a column.	`any`	`None`
`nullable`	Optional to specify if the column will allow null values or not.	`bool`	`False`
`unique`	Optional to specify if the column will contain unique values or not.	`bool`	`True`

`ForeignKeyColumn` Class

This class is utilized when informing dataloom that a column has a relationship with a primary key in another table. Consider the following model definition of a Post:

class Post(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="posts")
    id = PrimaryKeyColumn(type="int", auto_increment=True, nullable=False, unique=True)
    completed = Column(type="boolean", default=False)
    title = Column(type="varchar", length=255, nullable=False)
    # timestamps
    createdAt = CreatedAtColumn()
    updatedAt = UpdatedAtColumn()
    # relations
    userId = ForeignKeyColumn(
        User, type="int", required=True, onDelete="CASCADE", onUpdate="CASCADE"
    )

userId is a foreign key in the table posts, indicating it has a relationship with a primary key in the users table.

This column accepts the following arguments:

Argument	Description	Type	Default
`table`	Required. This is the parent table that the current model references. In our example, this is referred to as `User`. It can be used as a string in self relations.	`Model`\| `str`
`type`	Optional. Specifies the data type of the foreign key. If not provided, dataloom can infer it from the parent table.	`str` \| `None`	`None`
`required`	Optional. Indicates whether the foreign key is required or not.	`bool`	`False`
`onDelete`	Optional. Specifies the action to be taken when the associated record in the parent table is deleted.	`"NO ACTION"`, `"SET NULL"`, `"CASCADE"`	`"NO ACTION"`
`onUpdate`	Optional. Specifies the action to be taken when the associated record in the parent table is updated.	`"NO ACTION"`, `"SET NULL"`, `"CASCADE"`	`"NO ACTION"`

It is crucial to specify the actions for onDelete and onUpdate to ensure that dataloom manages your model's relationship actions appropriately. The available actions are:

"NO ACTION" - If you delete or update the parent table, no changes will occur in the child table.
"SET NULL" - If you delete or update the parent table, the corresponding value in the child table will be set to null.
"CASCADE" - If you delete or update the table, the same action will also be applied to the child table.

`CreatedAtColumn` Class

When a column is designated as CreatedAtColumn, its value will be automatically generated each time you create a new record in a database, serving as a timestamp.

`UpdatedAtColumn` Class

When a column is designated as UpdatedAtColumn, its value will be automatically generated each time you create a new record or update an existing record in a database table, acting as a timestamp.

`Filter` Class

This Filter class in dataloom is designed to facilitate the application of filters when executing queries and mutations. It allows users to specify conditions that must be met for the operation to affect certain rows in a database table. Below is an example demonstrating how this class can be used:

affected_rows = pg_loom.update_one(
    Post,
    values=[
        ColumnValue(name="title", value="Hey"),
        ColumnValue(name="completed", value=True),
    ],
    filters=[
        Filter(column="id", value=1, join_next_with="AND"),
        Filter(column="userId", value=1, join_next_with="AND"),
    ],
)

So from the above example we are applying filters while updating a Post here are the options that you can pass on that filter class:

Argument	Description	Type	Default
`column`	The name of the column to apply the filter on	`String`	-
`value`	The value to filter against	`Any`	-
`operator`	The comparison operator to use for the filter	`'eq'`, `'neq'`. `'lt'`, `'gt'`, `'leq'`, `'geq'`, `'in'`, `'notIn'`, `'like'`, `'between'`, `'not'`	`'eq'`
`join_next_with`	The logical operator to join this filter with the next one	`'AND'`, `'OR'`	`'AND'`

👍Pro Tip: Note You can apply either a list of filters or a single filter when filtering records.

`ColumnValue` Class

Just like the Filter class, dataloom also provides a ColumnValue class. This class acts as a setter to update the values of columns in your database table.

The following code snippet demonstrates how the ColumnValue class is used to update records in the database:

re = pg_loom.update_one(
    Post,
    values=[
        ColumnValue(name="title", value="Hey"),
        ColumnValue(name="completed", value=True),
    ],
    filters=[
        Filter(column="id",  value=1, join_next_with="AND"),
        Filter(column="userId", value=1, join_next_with="AND"),
    ],
)

It accepts two arguments: name and value. name represents the column name, while value corresponds to the new value to be assigned to that column.

Argument	Description	Type	Default
`name`	The name of the column to be updated or inserted.	`str`	-
`value`	The value to assign to the column during update or insert.	`Any`	-

`Order` Class

The Order class enables us to specify the desired order in which documents should be returned. Below is an example illustrating its usage:

posts = pg_loom.find_all(
    Post,
    select=["id", "completed", "title", "createdAt"],
    limit=3,
    offset=0,
    order=[
        Order(column="createdAt", order="ASC"),
        Order(column="id", order="DESC"),
    ]
)

👍Pro Tip: Note when utilizing a list of orders, they are applied sequentially, one after the other:

Argument	Description	Type	Default
`column`	The name of the column to order by.	`str`	-
`order`	The order direction, either `"ASC"` (ascending) or `"DESC"` (descending).	`"ASC"` or `"DESC"`	`"ASC"`

`Include` Class

The Include class facilitates eager loading for models with relationships. Below is a table detailing the parameters available for the Include class:

Argument	Description	Type	Default	Required
`model`	The model to be included when eagerly fetching records.	`Model`	-	Yes
`junction_table`	The `junction_table` model that is used as a reference table in a many to many association.	`Model`	`None`	No
`order`	The list of order specifications for sorting the included data.	`list[Order]`	`[]`	No
`limit`	The maximum number of records to include.	`int \| None`	`0`	No
`offset`	The number of records to skip before including.	`int \| None`	`0`	No
`select`	The list of columns to include.	`list[str] \| None`	`None`	No
`has`	The relationship type between the current model and the included model.	`INCLUDE_LITERAL`	`"many"`	No
`include`	The extra included models.	`list[Include]`	`[]`	No
`alias`	The alias name for the included model. Very important when mapping self relations.	`str`	`None`	No

`Group` Class

This class is used for data aggregation and grouping data in dataloom. Below is a table detailing the parameters available for the Group class:

Argument	Description	Type	Default	Required
`column`	The name of the column to group by.	`str`		Yes
`function`	The aggregation function to apply on the grouped data.	`"COUNT" \| "AVG" \| "SUM" \| "MIN" \| "MAX"`	`"COUNT"`	No
`having`	Filters to apply to the grouped data.	`list[Having] \| Having \| None`	`None`	No
`return_aggregation_column`	Whether to return the aggregation column in the result.	`bool`	`False`	No

`Having` Class

This class method is used to specify the filters to be applied on Grouped data during aggregation in dataloom. Below is a table detailing the parameters available for the Group class:

Argument	Description	Type	Default	Required
`column`	The name of the column to filter on.	`str`		`Yes`
`operator`	The operator to use for the filter.	`OPERATOR_LITERAL\|None`	`"eq"`	`No`
`value`	The value to compare against.	`Any`		`Yes`
`join_next_with`	The SQL operand to join the next filter with.	`"AND" \| "OR"\|None`	`"AND"`	`No`

Syncing Tables

Syncing tables involves the process of creating tables from models and saving them to a database. After defining your tables, you will need to synchronize your database tables using the sync method.

1. The `sync` method.

This method enables you to create and save tables into the database. For instance, if you have two models, User and Post, and you want to synchronize them with the database, you can achieve it as follows:

tables = sqlite_loom.sync([Post, User], drop=True, force=True)
print(tables)

The method returns a list of table names that have been created or that exist in your database. The sync method accepts the following arguments:

Argument	Description	Type	Default
`models`	A collection or a single instance(s) of your table classes that inherit from the Model class.	`list[Model]\|Model`	`[]`
`drop`	Whether to drop tables during syncing or not.	`bool`	`False`
`force`	Forcefully drop tables during syncing. In `mysql` this will temporarily disable foreign key checks when droping the tables.	`bool`	`False`
`alter`	Alter tables instead of dropping them during syncing or not.	`bool`	`False`

🥇 We recommend you to use drop or force if you are going to change or modify foreign and primary keys. This is because setting the option alter does not have an effect on primary key columns.

We've noticed two steps involved in starting to work with our orm. Initially, you need to create a connection and then synchronize the tables in another step.

2. The `connect_and_sync` method.

The connect_and_sync function proves to be very handy as it handles both the database connection and table synchronization. Here is an example demonstrating its usage:

# ....

sqlite_loom = Loom(
    dialect="sqlite", database="hi.db", logs_filename="sqlite-logs.sql", logging=True
)
conn, tables = sqlite_loom.connect_and_sync([Post, User], drop=True, force=True)
print(tables)

if __name__ == "__main__":
    conn.close()

Returns a conn and the list of tablenames that exist in the database. The method accepts the same arguments as the sync method.

CRUD Operations with Dataloom

In this section of the documentation, we will illustrate how to perform basic CRUD operations using dataloom on simple Models. Please note that in the following code snippets, I will be utilizing sqlite_loom, mysql_loom, pg_loom or loom interchangeably. However, it's important to highlight that you can use any loom of your choice to follow along.

1. Creating a Record

To insert a single or multiple records in a database you make use of the following functions:

insert_one()
insert_bulk()

1. `insert_one()`

The insert_one method allows you to save a single row in a specific table. Upon saving, it will return the primary key (pk) value of the inserted document. The following example shows how the insert_one() method works.

# Example: Creating a user record
userId = pg_loom.insert_one(
    instance=User, values=ColumnValue(name="username", value="@miller")
)

userId = pg_loom.insert_one(
    instance=User,
    values=[
        ColumnValue(name="username", value="@miller"),
        ColumnValue(name="name", value="Jonh"),
    ],
)

This function takes in two arguments which are instance and values. Where values are the column values that you are inserting in a user table or a single column value.

Argument	Description	`Type`	`Required`	`Default`
`instance`	The instance of the table where the row will be inserted.	`Model`	`Yes`	`None`
`values`	The column values to be inserted into the table. It can be a single column value or a list of column values.	`list[ColumnValue]` or `ColumnValue`	`Yes`	`None`

2. `insert_bulk()`.

The insert_bulk method facilitates the bulk insertion of records, as its name suggests. The following example illustrates how you can add 3 posts to the database table simultaneously.

# Example: Inserting multiple posts
rows = pg_loom.insert_bulk(
    User,
    values=[
        [
            ColumnValue(name="username", value="@miller"),
            ColumnValue(name="name", value="Jonh"),
        ],
        [
            ColumnValue(name="username", value="@brown"),
            ColumnValue(name="name", value="Jonh"),
        ],
        [
            ColumnValue(name="username", value="@blue"),
            ColumnValue(name="name", value="Jonh"),
        ],
    ],
)

The argument parameters for the insert_bulk methods are as follows.

Argument	Description	`Type`	`Required`	`Default`
`instance`	The instance of the table where the row will be inserted.	`Model`	`Yes`	`None`
`values`	The column values to be inserted into the table. It must be a list of list of column values with the same length, otherwise dataloom will fail to map the values correctly during the insert operation.	`list[list[ColumnValue]]` or `ColumnValue`	`Yes`	`None`

In contrast to the insert_one method, the insert_bulk method returns the row count of the inserted documents rather than the individual primary keys (pks) of those documents.

2. Reading records

To retrieve documents or a document from the database, you can make use of the following functions:

find_all(): This function is used to retrieve all documents from the database.
find_by_pk(): This function is used to retrieve a document by its primary key (or ID).
find_one(): This function is used to retrieve a single document based on a specific condition.
find_many(): This function is used to retrieve multiple documents based on a specific condition.

1. `find_all()`

This method is used to retrieve all the records that are in the database table. Below are examples demonstrating how to do it:

users = pg_loom.find_all(
    instance=User,
    select=["id", "username"],
    limit=3,
    offset=0,
    order=[Order(column="id", order="DESC")],
)
print(users) # ? [{'id': 1, 'username': '@miller'}]

The find_all() method takes in the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`select`	Collection or a string of fields to select from the documents.	`list[str]\|str`	`None`	`No`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before retrieving.	`int`	`0`	`No`
`order`	Collection of `Order` or a single `Order` to order the documents when querying.	`list[Order]\|Order`	`None`	`No`
`include`	Collection or a `Include` of related models to eagerly load.	`list[Include]\|Include`	`None`	`No`
`group`	Collection of `Group` which specifies how you want your data to be grouped during queries.	`list[Group]\|Group`	`None`	`No`
`distinct`	Boolean telling dataloom to return distinct row values based on selected fields or not.	`bool`	`False`	`No`

👍 Pro Tip: A collection can be any python iterable, the supported iterables are list, set, tuple.

2. `find_many()`

Here is an example demonstrating the usage of the find_many() function with specific filters.

users = mysql_loom.find_many(
    User,
    filters=[Filter(column="username", value="@miller")],
    select=["id", "username"],
    offset=0,
    limit=10,
)

print(users) # ? [{'id': 1, 'username': '@miller'}]

The find_many() method takes in the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`select`	Collection or a string of fields to select from the documents.	`list[str]\|str`	`None`	`No`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before retrieving.	`int`	`0`	`No`
`order`	Collection of `Order` or a single `Order` to order the documents when querying.	`list[Order]\|Order`	`None`	`No`
`include`	Collection or a `Include` of related models to eagerly load.	`list[Include]\|Include`	`None`	`No`
`group`	Collection of `Group` which specifies how you want your data to be grouped during queries.	`list[Group]\|Group`	`None`	`No`
`filters`	Collection of `Filter` or a `Filter` to apply to the query.	`list[Filter] \| Filter`	`None`	`No`
`distinct`	Boolean telling dataloom to return distinct row values based on selected fields or not.	`bool`	`False`	`No`

👍 Pro Tip: The distinction between the find_all() and find_many() methods lies in the fact that find_many() enables you to apply specific filters, whereas find_all() retrieves all the documents within the specified model.

3. `find_one()`

Here is an example showing you how you can use find_one() locate a single record in the database.

user = mysql_loom.find_one(
    User,
    filters=[Filter(column="username", value="@miller")],
    select=["id", "username"],
)
print(user) # ? {'id': 1, 'username': '@miller'}

This method take the following as arguments

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve instances from.	`Model`		`Yes`
`filters`	`Filter` or a collection of `Filter` to apply to the query.	`Filter \| list[Filter] \| None`	`None`	`No`
`select`	Collection of `str` or `str` of which is the name of the columns or column to be selected.	`list[str]\|str`	`[]`	`No`
`include`	Collection of `Include` or a single `Include` of related models to eagerly load.	`list[Include]\|Include`	`[]`	`No`
`offset`	Number of instances to skip before retrieving.	`int \| None`	`None`	`No`

4. `find_by_pk()`

Here is an example showing how you can use the find_by_pk() to locate a single record in the database.

user = mysql_loom.find_by_pk(User, pk=userId, select=["id", "username"])
print(user) # ? {'id': 1, 'username': '@miller'}

The method takes the following as arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve instances from.	`Model`		`Yes`
`pk`	The primary key value to use for retrieval.	`Any`		`Yes`
`select`	Collection column names to select from the instances.	`list[str]`	`[]`	`No`
`include`	A Collection of `Include` or a single `Include` of related models to eagerly load.	`list[Include]\|Include`	`[]`	`No`

3. Updating a record

To update records in your database table you make use of the following functions:

update_by_pk()
update_one()
update_bulk()

1. `update_by_pk()`

The update_pk() method can be used as follows:

affected_rows = mysql_loom.update_by_pk(
    instance=Post,
    pk=1,
    values=[
        ColumnValue(name="title", value="Updated?"),
    ],
)

The above method takes in the following as arguments:

Argument	Description	Type	Required
`instance`	The model class for which to update the instance.	`Model`	`Yes`
`pk`	The primary key value of the instance to update.	`Any`	`Yes`
`values`	Single or Collection of `ColumnValue` to update in the instance.	`ColumnValue \| list[ColumnValue]`	`Yes`

2. `update_one()`

Here is an example illustrating how to use the update_one() method:

affected_rows = mysql_loom.update_one(
    instance=Post,
    filters=[
        Filter(column="id", value=8, join_next_with="OR"),
        Filter(column="userId", value=1, join_next_with="OR"),
    ],
    values=[
        ColumnValue(name="title", value="Updated?"),
    ],
)

The method takes the following as arguments:

Argument	Description	Type	Required
`instance`	The model class for which to update the instance(s).	`Model`	`Yes`
`filters`	Filter or collection of filters to apply to the update query.	`Filter \| list[Filter] \| None`	`Yes`
`values`	Single or collection of column-value pairs to update in the instance.	`ColumnValue \| list[ColumnValue]`	`Yes`

3. `update_bulk()`

The update_bulk() method updates all records that match a filter in a database table.

affected_rows = mysql_loom.update_bulk(
    instance=Post,
    filters=[
        Filter(column="id", value=8, join_next_with="OR"),
        Filter(column="userId", value=1, join_next_with="OR"),
    ],
    values=[
        ColumnValue(name="title", value="Updated?"),
    ],
)

The above method takes in the following as argument:

Argument	Description	Type	Required
`instance`	The model class for which to update instances.	`Model`	`Yes`
`filters`	Filter or collection of filters to apply to the update query.	`Filter \| list[Filter] \| None`	`Yes`
`values`	Single or collection of column-value pairs to update in the instance.	`ColumnValue \| list[ColumnValue]`	`Yes`

4. Deleting a record

To delete a record or records in a database table you make use of the following functions:

delete_by_pk()
delete_one()
delete_bulk()

1. `delete_by_pk()`

Using the delete_by_pk() method, you can delete a record in a database based on the primary-key value.

affected_rows = mysql_loom.delete_by_pk(instance=User, pk=1)

The above take the following as arguments:

Argument	Description	Type	Default	Required
`instance`	The model class from which to delete the instance.	`Model`		`Yes`
`pk`	The primary key value of the instance to delete.	`Any`		`Yes`

2. `delete_one()`

You can also use filters to delete a record in a database. The delete_one() function enables you to delete a single record in a database that matches a filter.

affected_rows = mysql_loom.delete_one(
    instance=User, filters=[Filter(column="username", value="@miller")]
)

The method takes in the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class from which to delete the instance(s).	`Model`		`Yes`
`filters`	Filter or collection of filters to apply to the deletion query.	`Filter \| list[Filter] \| None`	`None`	`No`
`offset`	Number of instances to skip before deleting.	`int \| None`	`None`	`No`
`order`	Collection of `Order` or as single `Order` to order the instances by before deletion.	`list[Order] \| Order\| None`	`[]`	`No`

3. `delete_bulk()`

You can also use the delete_bulk() method to delete a multitude of records that match a given filter:

affected_rows = mysql_loom.delete_bulk(
    instance=User, filters=[Filter(column="username", value="@miller")]
)

The method takes the following as arguments:

Argument	Description	Type	Default	Required
`instance`	The model class from which to delete instances.	`Model`		`Yes`
`filters`	Filter or collection of filters to apply to the deletion query.	`Filter \| list[Filter] \| None`	`None`	`No`
`limit`	Maximum number of instances to delete.	`int \| None`	`None`	`No`
`offset`	Number of instances to skip before deleting.	`int \| None`	`None`	`No`
`order`	Collection of `Order` or a single `Order` to order the instances by before deletion.	`list[Order] \|Order\| None`	`[]`	`No`

Warning: Potential Risk with `delete_bulk()`

⚠️ Warning: When using the delete_bulk() function, exercise caution as it can be aggressive. If the filter is not explicitly provided, there is a risk of mistakenly deleting all records in the table.

Guidelines for Safe Usage

To mitigate the potential risks associated with delete_bulk(), follow these guidelines:

Always Provide a Filter:

When calling delete_bulk(), make sure to provide a filter to specify the subset of records to be deleted. This helps prevent unintentional deletions.

 # Example: Delete records where 'status' is 'inactive'
 affected_rows = mysql_loom.delete_bulk(
     instance=User,
     filters=Filter(column="status",  value='inactive'),
 )

Consider Usage When Necessary:

When contemplating data deletion, it is advisable to consider more targeted methods before resorting to delete_bulk(). Prioritize the use of delete_one() or delete_by_pk() methods to remove specific records based on your needs. This ensures a more precise and controlled approach to data deletion.

Use limit and offsets options

You can consider using the limit and offset options during invocation of delete_bulk

affected_rows = mysql_loom.delete_bulk(
    instance=Post,
    order=[Order(column="id", order="DESC"), Order(column="createdAt", order="ASC")],
    filters=[Filter(column="id", operator="gt", value=0)],
    offset=0,
    limit=10,
)

By following these guidelines, you can use the delete_bulk() function safely and minimize the risk of unintended data loss. Always exercise caution and adhere to best practices when performing bulk deletion operations.

Ordering

In dataloom you can order documents in either DESC (descending) or ASC (ascending) order using the helper class Order.

posts = mysql_loom.find_all(
    instance=Post,
    order=[Order(column="id", order="DESC")],
)

You can apply multiple and these orders will ba applied in sequence of application here is an example:

posts = mysql_loom.find_all(
    instance=Post,
    order=[Order(column="id", order="DESC"), Order(column="createdAt", order="ASC")],
)

Filters

There are different find of filters that you can use when filtering documents for mutations and queries. Filters are very important to use when updating and deleting documents as they give you control on which documents should be updated or deleted. When doing a mutation you can use a single or multiple filters. Bellow is an example that shows you how you can use a single filter in deleting a single record that has an id greater than 1 from the database.

res2 = mysql_loom.delete_one(
    instance=Post,
    offset=0,
    order=Order(column="id", order="DESC"),
    filters=Filter(column="id", value=1, operator="gt"),
)

Or you can use it as follows:

res2 = mysql_loom.delete_one(
    instance=Post,
    offset=0,
    order=[Order(column="id", order="DESC")],
    filters=[Filter(column="id", value=1, operator="gt")],
)

As you have noticed, you can join your filters together and they will be applied sequentially using the join_next_with which can be either OR or AND te default value is AND. Here is an of filter usage in sequential.

res2 = mysql_loom.delete_one(
    instance=Post,
    offset=0,
    order=[Order(column="id", order="DESC")],
    filters=[
        Filter(column="id", value=1, operator="gt"),
        Filter(column="userId", value=1, operator="eq", join_next_with="OR"),
        Filter(
            column="title",
            value='"What are you doing general?"',
            operator="=",
            join_next_with="AND",
        ),
    ],
)

Operators

You can use the operator to match the values. Here is the table of description for these filters.

Operator	Explanation	Expect
`'eq'`	Indicates equality. It checks if the value is equal to the specified criteria.	Value == Criteria
`'lt'`	Denotes less than. It checks if the value is less than the specified criteria.	Value < Criteria
`'gt'`	Denotes greater than. It checks if the value is greater than the specified criteria.	Value > Criteria
`'leq'`	Denotes less than or equal to. It checks if the value is less than or equal to the specified criteria.	Value <= Criteria
`'geq'`	Denotes greater than or equal to. It checks if the value is greater than or equal to the specified criteria.	Value >= Criteria
`'in'`	Checks if the value is included in a specified list of values.	Value in List
`'notIn'`	Checks if the value is not included in a specified list of values.	Value not in List
`'like'`	Performs a pattern matching operation. It checks if the value is similar to a specified pattern.	Value matches Pattern
`'not'`	Indicates non-equality. It checks if the column value that does not equal to the specified criteria.	NOT id = Criteria
`'neq'`	Indicates non-equality. It checks if the value is not equal to the specified criteria.	Value != Criteria
`'between'`	It checks range values that matches a given range between the minimum and maximum.	id BETWEEN (min, max)

Let's talk about these filters in detail of code by example. Let's say you want to update a Post where the id matches 1 you can do it as follows:

res2 = mysql_loom.update_one(
    instance=Post,
    filters=Filter(
        column="id",
        value=1,
        operator="eq",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

What if you want to update a post where id is not equal to 1 you can do it as follows

res2 = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=1,
        operator="neq",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

What if i want to update the records that have an id less than 3?

res2 = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=3,
        operator="lt",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

What if i want to update the records that have an id less than or equal 3?

res2 = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=1,
        operator="neq",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

What if i want to update the records that have an id greater than 3?

res = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=3,
        operator="gt",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

What if i want to update the records that have an id greater or equal to 3?

res = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=3,
        operator="geq",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

You can use the in to update or query records that matches values in a specified list of values or tuple. Here is an example showing you how you can update records that does matches id in [1, 2].

res = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=[1, 2],
        operator="in",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

You can use the notIn to update or query records that does not matches values in a specified list of values or tuple. Here is an example showing you how you can update records that does not matches id in [1, 2].

res = mysql_loom.update_bulk(
    instance=Post,
    filters=Filter(
        column="id",
        value=[1, 2],
        operator="notIn",
    ),
    values=[ColumnValue(name="title", value="Bob")],
)

You can use the like operator to match some patens in your query filters. Let's say we want to match a post that has the title ends with general we can use the like operator as follows

general = mysql_loom.find_one(
    instance=Post,
    filters=Filter(
        column="title",
        value="% general?",
        operator="like",
    ),
    select=["id", "title"],
)

print(general) # ?  {'id': 1, 'title': 'What are you doing general?'}

The following table show you some expression that you can use with this like operator.

Value	Description
`%pattern`	Finds values that end with the specified pattern.
`pattern%`	Finds values that start with the specified pattern.
`%pattern%`	Finds values that contain the specified pattern anywhere within the string.
`_pattern`	Finds values that have any single character followed by the specified pattern.
`pattern_`	Finds values that have the specified pattern followed by any single character.
`[charlist]%`	Finds values that start with any character in the specified character list.
`[!charlist]%`	Finds values that start with any character not in the specified character list.
`_pattern_`	Finds values that have any single character followed by the specified pattern and then followed by any single character.

Data Aggregation

With the Having and the Group classes you can perform some powerful powerful queries. In this section we are going to demonstrate an example of how we can do the aggregate queries.

posts = mysql_loom.find_many(
    Post,
    select="id",
    filters=Filter(column="id", operator="gt", value=1),
    group=Group(
        column="id",
        function="MAX",
        having=Having(column="id", operator="in", value=(2, 3, 4)),
        return_aggregation_column=True,
    ),
)

The following will be the output from the above query.

[{'id': 2, 'MAX(`id`)': 2}, {'id': 3, 'MAX(`id`)': 3}, {'id': 4, 'MAX(`id`)': 4}]

However you can remove the aggregation column from the above query by specifying the return_aggregation_column to be False:

posts = mysql_loom.find_many(
    Post,
    select="id",
    filters=Filter(column="id", operator="gt", value=1),
    group=Group(
        column="id",
        function="MAX",
        having=Having(column="id", operator="in", value=(2, 3, 4)),
        return_aggregation_column=False,
    ),
)
print(posts)

This will output:

[{'id': 2}, {'id': 3}, {'id': 4}]

Aggregation Functions

You can use the following aggregation functions that dataloom supports:

Aggregation Function	Description
`"AVG"`	Computes the average of the values in the group.
`"COUNT"`	Counts the number of items in the group.
`"SUM"`	Computes the sum of the values in the group.
`"MAX"`	Retrieves the maximum value in the group.
`"MIN"`	Retrieves the minimum value in the group.

👍 Pro Tip: Note that data aggregation only works without eager loading and also works only with find_may() and find_all() in dataloom.

Utilities

Dataloom comes up with some utility functions that works on an instance of a model. This is very useful when debuging your tables to see how do they look like. These function include:

1. `inspect()`

This function takes in a model as argument and inspect the model fields or columns. The following examples show how we can use this handy function in inspecting table names.

table = mysql_loom.inspect(instance=User, fields=["name", "type"], print_table=False)
print(table)

The above snippet returns a list of dictionaries containing the column name and the arguments that were passed.

[{'id': {'type': 'int'}}, {'name': {'type': 'varchar'}}, {'tokenVersion': {'type': 'int'}}, {'username': {'type': 'varchar'}}]

You can print table format these fields with their types as follows

mysql_loom.inspect(instance=User)

Output:

+--------------+---------+----------+---------+
| name         | type    | nullable | default |
+--------------+---------+----------+---------+
| id           | int     | NO       | None    |
| name         | varchar | NO       | Bob     |
| tokenVersion | int     | YES      | 0       |
| username     | varchar | YES      | None    |
+--------------+---------+----------+---------+

The inspect function take the following arguments.

Argument	Description	Type	Default	Required
`instance`	The model instance to inspect.	`Model`	-	Yes
`fields`	The list of fields to include in the inspection.	`list[str]`	`["name", "type", "nullable", "default"]`	No
`print_table`	Flag indicating whether to print the inspection table.	`bool`	`True`	No

2. `decorators`

These modules contain several decorators that can prove useful when creating models. These decorators originate from dataloom.decorators, and at this stage, we are referring to them as "experimental."

`@initialize()`

Let's examine a model named Profile, which appears as follows:

class Profile(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="profiles")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    avatar = Column(type="text", nullable=False)
    userId = ForeignKeyColumn(
        User,
        maps_to="1-1",
        type="int",
        required=True,
        onDelete="CASCADE",
        onUpdate="CASCADE",
    )

This is simply a Python class that inherits from the top-level class Model. However, it lacks some useful dunder methods such as __init__ and __repr__. In standard Python, we can achieve this functionality by using dataclasses. For example, we can modify our class as follows:

from dataclasses import dataclass

@dataclass
class Profile(Model):
    # ....

However, this approach doesn't function as expected in dataloom columns. Hence, we've devised these experimental decorators to handle the generation of essential dunder methods required for working with dataloom. If you prefer not to use decorators, you always have the option to manually create these dunder methods. Here's an example:

class Profile(Model):
    # ...
    def __init__(self, id: int | None, avatar: str | None, userId: int | None) -> None:
        self.id = id
        self.avatar = avatar
        self.userId = userId

    def __repr__(self) -> str:
        return f"<{self.__class__.__name__}:id={self.id}>"

    @property
    def to_dict(self):
        return {"id": self.id, "avatar": self.avatar, "userId": self.userId}

However, by using the initialize decorator, this functionality will be automatically generated for you. Here's all you need to do:

from dataloom.decorators import initialize

@initialize(repr=True, to_dict=True, init=True, repr_identifier="id")
class Profile(Model):
    # ...

👉 Tip: Dataloom has a clever way of skipping the TableColumn because it doesn't matter in this case.

The initialize decorator takes the following arguments:

Argument	Description	Type	Default	Required
`to_dict`	Flag indicating whether to generate a `to_dict` method.	`bool`	`False`	`No`
`init`	Flag indicating whether to generate an `__init__` method.	`bool`	`True`	`No`
`repr`	Flag indicating whether to generate a `__repr__` method.	`bool`	`False`	`No`
`repr_identifier`	Identifier for the attribute used in the `__repr__` method.	`str` or `None`	`None`	`No`

👍Pro Tip: Note that this decorator function allows us to interact with our data from the database in an object-oriented way in Python. Below is an example illustrating this concept:

profile = mysql_loom.find_by_pk(Profile, pk=1, select=["avatar", "id"])
profile = Profile(**profile)
print(profile)  # ? = <Profile:id=1>
print(profile.avatar)  # ? hello.jpg

3. `count()`

This is a utility function that comes within the loom object that is used to count rows in a database table that meets a specific criteria. Here is an example on how to use this utility function.

# example
count = mysql_loom.count(
    instance=Post,
    filters=Filter(
        column="id",
        operator="between",
        value=[1, 7],
    ),
    column="id",
    limit=3,
    offset=0,
    distinct=True,
)
print(count)

The count function takes the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`column`	A string of column to count values based on.	`str`	`None`	`Yes`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before counting.	`int`	`0`	`No`
`filters`	Collection of `Filter` or a `Filter` to apply to the rows to be counted.	`list[Filter] \| Filter`	`None`	`No`
`distinct`	Boolean telling dataloom to count distinct rows of values based on selected column or not.	`bool`	`False`	`No`

4. `min()`

This is a utility function that comes within the loom object that is used to find the minimum value in rows of data in a database table that meets a specific criteria. Here is an example on how to use this utility function.

# example
_min = mysql_loom.min(
    instance=Post,
    filters=Filter(
        column="id",
        operator="between",
        value=[1, 7],
    ),
    column="id",
    limit=3,
    offset=0,
    distinct=True,
)
print(_min)

The min function takes the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`column`	A string of column to find minimum values based on.	`str`	`None`	`Yes`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before finding the minimum.	`int`	`0`	`No`
`filters`	Collection of `Filter` or a `Filter` to apply to the rows to be used.	`list[Filter] \| Filter`	`None`	`No`
`distinct`	Boolean telling dataloom to find minimum value in distinct rows values based on selected column or not.	`bool`	`False`	`No`

5. `max()`

This is a utility function that comes within the loom object that is used to find the maximum value in rows of data in a database table that meets a specific criteria. Here is an example on how to use this utility function.

# example
_max = mysql_loom.max(
    instance=Post,
    filters=Filter(
        column="id",
        operator="between",
        value=[1, 7],
    ),
    column="id",
    limit=3,
    offset=0,
    distinct=True,
)
print(_max)

The max function takes the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`column`	A string of column to find maximum values based on.	`str`	`None`	`Yes`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before finding the maximum.	`int`	`0`	`No`
`filters`	Collection of `Filter` or a `Filter` to apply to the rows to be used.	`list[Filter] \| Filter`	`None`	`No`
`distinct`	Boolean telling dataloom to find maximum value in distinct rows of values based on selected column or not.	`bool`	`False`	`No`

6. `avg()`

This is a utility function that comes within the loom object that is used to calculate the average value in rows of data in a database table that meets a specific criteria. Here is an example on how to use this utility function.

# example
_avg = mysql_loom.avg(
    instance=Post,
    filters=Filter(
        column="id",
        operator="between",
        value=[1, 7],
    ),
    column="id",
    limit=3,
    offset=0,
    distinct=True,
)
print(_avg)

The max function takes the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`column`	A string of column to calculate average values based on.	`str`	`None`	`Yes`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before finding the calculating the average.	`int`	`0`	`No`
`filters`	Collection of `Filter` or a `Filter` to apply to the rows to be used.	`list[Filter] \| Filter`	`None`	`No`
`distinct`	Boolean telling dataloom to calculate the average value in distinct rows of values based on selected column or not.	`bool`	`False`	`No`

7. `sum()`

This is a utility function that comes within the loom object that is used to find the total sum in rows of data in a database table that meets a specific criteria. Here is an example on how to use this utility function.

# example
_sum = mysql_loom.sum(
    instance=Post,
    filters=Filter(
        column="id",
        operator="between",
        value=[1, 7],
    ),
    column="id",
    limit=3,
    offset=0,
    distinct=True,
)
print(_sum)

The sum function takes the following arguments:

Argument	Description	Type	Default	Required
`instance`	The model class to retrieve documents from.	`Model`	`None`	`Yes`
`column`	A string of column to sum values based on.	`str`	`None`	`Yes`
`limit`	Maximum number of documents to retrieve.	`int`	`None`	`No`
`offset`	Number of documents to skip before summing.	`int`	`0`	`No`
`filters`	Collection of `Filter` or a `Filter` to apply to the rows to be used.	`list[Filter] \| Filter`	`None`	`No`
`distinct`	Boolean telling dataloom to sum value in distinct rows values based on selected column or not.	`bool`	`False`	`No`

Associations

In dataloom you can create association using the foreign-keys column during model creation. You just have to specify a single model to have a relationship with another model using the ForeignKeyColum. Just by doing that dataloom will be able to learn bidirectional relationship between your models. Let's have a look at the following examples:

1. `1-1` Association

Let's consider an example where we want to map the relationship between a User and a Profile:

class User(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="users")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    name = Column(type="text", nullable=False, default="Bob")
    username = Column(type="varchar", unique=True, length=255)
    tokenVersion = Column(type="int", default=0)

class Profile(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="profiles")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    avatar = Column(type="text", nullable=False)
    userId = ForeignKeyColumn(
        User,
        maps_to="1-1",
        type="int",
        required=True,
        onDelete="CASCADE",
        onUpdate="CASCADE",
    )

The above code demonstrates how to establish a one-to-one relationship between a User and a Profile using the dataloom.

User and Profile are two model classes inheriting from Model.
Each model is associated with a corresponding table in the database, defined by the __tablename__ attribute.
Both models have a primary key column (id) defined using PrimaryKeyColumn.
Additional columns (name, username, tokenVersion for User and avatar, userId for Profile) are defined using Column.
The userId column in the Profile model establishes a foreign key relationship with the id column of the User model using ForeignKeyColumn. This relationship is specified to be a one-to-one relationship (maps_to="1-1").
Various constraints such as nullable, unique, default, and foreign key constraints (onDelete, onUpdate) are specified for the columns.

Inserting

In the following code example we are going to demonstrate how we can create a user with a profile, first we need to create a user first so that we get reference to the user of the profile that we will create.

userId = mysql_loom.insert_one(
    instance=User,
    values=ColumnValue(name="username", value="@miller"),
)

profileId = mysql_loom.insert_one(
    instance=Profile,
    values=[
        ColumnValue(name="userId", value=userId),
        ColumnValue(name="avatar", value="hello.jpg"),
    ],
)

This Python code snippet demonstrates how to insert data into the database using the mysql_loom.insert_one method, it also work on other methods like insert_bulk.

Inserting a User Record:
- The mysql_loom.insert_one method is used to insert a new record into the User table.
- The instance=User parameter specifies that the record being inserted belongs to the User model.
- The values=ColumnValue(name="username", value="@miller") parameter specifies the values to be inserted into the User table, where the username column will be set to "@miller".
- The ID of the newly inserted record is obtained and assigned to the variable userId.
Inserting a Profile Record:
- Again, the mysql_loom.insert_one method is called to insert a new record into the Profile table.
- The instance=Profile parameter specifies that the record being inserted belongs to the Profile model.
- The values parameter is a list containing two ColumnValue objects:
  - The first ColumnValue object specifies that the userId column of the Profile table will be set to the userId value obtained from the previous insertion.
  - The second ColumnValue object specifies that the avatar column of the Profile table will be set to "hello.jpg".
- The ID of the newly inserted record is obtained and assigned to the variable profileId.

Retrieving Records

The following example shows you how you can retrieve the data in a associations

profile = mysql_loom.find_one(
    instance=Profile,
    select=["id", "avatar"],
    filters=Filter(column="userId", value=userId),
)
user = mysql_loom.find_by_pk(
    instance=User,
    pk=userId,
    select=["id", "username"],
)
user_with_profile = {**user, "profile": profile}
print(user_with_profile) # ? = {'id': 1, 'username': '@miller', 'profile': {'id': 1, 'avatar': 'hello.jpg'}}

This Python code snippet demonstrates how to query data from the database using the mysql_loom.find_one and mysql_loom.find_by_pk methods, and combine the results of these two records that have association.

Querying a Profile Record:
- The mysql_loom.find_one method is used to retrieve a single record from the Profile table.
- The filters=Filter(column="userId", value=userId) parameter filters the results to only include records where the userId column matches the userId value obtained from a previous insertion.
Querying a User Record:
- The mysql_loom.find_by_pk method is used to retrieve a single record from the User table based on its primary key (pk=userId).
- The instance=User parameter specifies that the record being retrieved belongs to the User model.
- The select=["id", "username"] parameter specifies that only the id and username columns should be selected.
- The retrieved user data is assigned to the variable user.
Combining User and Profile Data:
- The user data (user) and profile data (profile) are combined into a single dictionary (user_with_profile) using dictionary unpacking ({**user, "profile": profile}).
- This dictionary represents a user with their associated profile.

🏒 We have realized that we are performing three steps when querying records, which can be verbose. However, in dataloom, we have introduced eager data fetching for all methods that retrieve data from the database. The following example demonstrates how we can achieve the same result as before using eager loading:

# With eager loading
user_with_profile = mysql_loom.find_by_pk(
    instance=User,
    pk=userId,
    select=["id", "username"],
    include=[Include(model=Profile, select=["id", "avatar"], has="one")],
)
print(user_with_profile) # ? = {'id': 1, 'username': '@miller', 'profile': {'id': 1, 'avatar': 'hello.jpg'}}

This Python code snippet demonstrates how to use eager loading with the mysql_loom.find_by_pk method to efficiently retrieve data from the User and Profile tables in a single query.

Eager loading allows us to retrieve related data from multiple tables in a single database query, reducing the need for multiple queries and improving performance.
In this example, the include parameter is used to specify eager loading for the Profile model associated with the User model.
By including the Profile model with the User model in the find_by_pk method call, we instruct the database to retrieve both the user data (id and username) and the associated profile data (id and avatar) in a single query.
This approach streamlines the data retrieval process and minimizes unnecessary database calls, leading to improved efficiency and performance in applications.

2. `N-1` Association

Models can have Many to One relationship, it depends on how you define them. Let's have a look at the relationship between a Category and a Post. Many categories can belong to a single post.

class Post(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="posts")
    id = PrimaryKeyColumn(type="int", auto_increment=True, nullable=False, unique=True)
    completed = Column(type="boolean", default=False)
    title = Column(type="varchar", length=255, nullable=False)
    # timestamps
    createdAt = CreatedAtColumn()
    # relations
    userId = ForeignKeyColumn(
        User,
        maps_to="1-N",
        type="int",
        required=True,
        onDelete="CASCADE",
        onUpdate="CASCADE",
    )

class Category(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="categories")
    id = PrimaryKeyColumn(type="int", auto_increment=True, nullable=False, unique=True)
    type = Column(type="varchar", length=255, nullable=False)

    postId = ForeignKeyColumn(
        Post,
        maps_to="N-1",
        type="int",
        required=True,
        onDelete="CASCADE",
        onUpdate="CASCADE",
    )

In the provided code, we have two models: Post and Category. The relationship between these two models can be described as a Many-to-One relationship.

This means that many categories can belong to a single post. In other words:

For each Post instance, there can be multiple Category instances associated with it.
However, each Category instance can only be associated with one Post.

For example, consider a blogging platform where each Post represents an article and each Category represents a topic or theme. Each article (post) can be assigned to multiple topics (categories), such as "Technology", "Travel", "Food", etc. However, each topic (category) can only be associated with one specific article (post).

This relationship allows for a hierarchical organization of data, where posts can be categorized into different topics or themes represented by categories.

Inserting

Let's illustrate the following example where we insert categories into a post with the id 1.

for title in ["Hey", "Hello", "What are you doing", "Coding"]:
    mysql_loom.insert_one(
        instance=Post,
        values=[
            ColumnValue(name="userId", value=userId),
            ColumnValue(name="title", value=title),
        ],
    )

for cat in ["general", "education", "tech", "sport"]:
    mysql_loom.insert_one(
        instance=Category,
        values=[
            ColumnValue(name="postId", value=1),
            ColumnValue(name="type", value=cat),
        ],
    )

Inserting Posts We're inserting new posts into the Post table. Each post is associated with a user (userId), and we're iterating over a list of titles to insert multiple posts.
Inserting Categories We're inserting new categories into the Category table. Each category is associated with a specific post (postId), and we're inserting categories for a post with id 1.

In summary, we're creating a relationship between posts and categories by inserting records into their respective tables. Each category record is linked to a specific post record through the postId attribute.

Retrieving Records

Let's attempt to retrieve a post with an ID of 1 along with its corresponding categories. We can achieve this as follows:

post = mysql_loom.find_by_pk(Post, 1, select=["id", "title"])
categories = mysql_loom.find_many(
    Category,
    select=["type", "id"],
    filters=Filter(column="postId", value=1),
    order=[
        Order(column="id", order="DESC"),
    ],
)
post_with_categories = {**post, "categories": categories}
print(post_with_categories)  # ? = {'id': 1, 'title': 'Hey', 'categories': [{'type': 'sport', 'id': 4}, {'type': 'tech', 'id': 3}, {'type': 'education', 'id': 2}, {'type': 'general', 'id': 1}]}

We use the mysql_loom.find_by_pk() method to retrieve a single post (Post) with an id equal to 1. We select only specific columns (id and title) for the post.
We use the mysql_loom.find_many() method to retrieve multiple categories (Category) associated with the post. We select only specific columns (type and id) for the categories. We apply a filter to only fetch categories associated with the post with postId equal to 1. We sort the categories based on the id column in descending order.
We create a dictionary (post_with_categories) that contains the retrieved post and its associated categories. The post information is stored under the key post, and the categories information is stored under the key categories.

The above task can be accomplished using eager document retrieval as shown below.

post_with_categories = mysql_loom.find_by_pk(
    Post,
    1,
    select=["id", "title"],
    include=[
        Include(
            model=Category,
            select=["type", "id"],
            order=[
                Order(column="id", order="DESC"),
            ],
        )
    ],
)

The code snippet queries a database to retrieve a post with an id of 1 along with its associated categories. Here's a breakdown:

Querying for Post:
- The mysql_loom.find_by_pk() method fetches a single post from the database.
- It specifies the Post model and ID 1, retrieving only the id and title columns.
Including Categories:
- The include parameter specifies additional related data to fetch.
- Inside include, an Include instance is created for categories related to the post.
- It specifies the Category model and selects only the type and id columns.
- Categories are ordered by id in descending order.
Result:
- The result is stored in post_with_categories, containing the post information and associated categories.

In summary, this code is retrieving a specific post along with its categories from the database, and it's using eager loading to efficiently fetch related data in a single query.

3. `1-N` Association

Let's consider a scenario where a User has multiple Post. here is how the relationships are mapped.

class User(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="users")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    name = Column(type="text", nullable=False, default="Bob")
    username = Column(type="varchar", unique=True, length=255)
    tokenVersion = Column(type="int", default=0)

class Post(Model):
    __tablename__: Optional[TableColumn] = TableColumn(name="posts")
    id = PrimaryKeyColumn(type="int", auto_increment=True, nullable=False, unique=True)
    completed = Column(type="boolean", default=False)
    title = Column(type="varchar", length=255, nullable=False)
    # timestamps
    createdAt = CreatedAtColumn()
    # relations
    userId = ForeignKeyColumn(
        User,
        maps_to="1-N",
        type="int",
        required=True,
        onDelete="CASCADE",
        onUpdate="CASCADE"
    )

So clearly we can see that when creating a post we need to have a userId

Inserting

Here is how we can insert a user and a post to the database tables.

userId = mysql_loom.insert_one(
    instance=User,
    values=ColumnValue(name="username", value="@miller"),
)
for title in ["Hey", "Hello", "What are you doing", "Coding"]:
    mysql_loom.insert_one(
        instance=Post,
        values=[
            ColumnValue(name="userId", value=userId),
            ColumnValue(name="title", value=title),
        ],
    )

We're performing database operations to insert records for a user and multiple posts associated with that user.

We insert a user record into the database using mysql_loom.insert_one() method.
We iterate over a list of titles.
For each title in the list, we insert a new post record into the database.
Each post is associated with the user we inserted earlier, identified by the userId.
The titles for the posts are set based on the titles in the list.

Retrieving Records

Now let's query the user with his respective posts. we can do it as follows:

user = mysql_loom.find_by_pk(
    User,
    1,
    select=["id", "username"],
)
posts = mysql_loom.find_many(
    Post,
    filters=Filter(column="userId", value=userId, operator="eq"),
    select=["id", "title"],
    order=[Order(column="id", order="DESC")],
    limit=2,
    offset=1,
)

user_with_posts = {**user, "posts": posts}
print(
    user_with_posts
)  # ? = {'id': 1, 'username': '@miller', 'posts': [{'id': 3, 'title': 'What are you doing'}, {'id': 2, 'title': 'Hello'}]}

We're querying the database to retrieve information about a user and their associated posts.

Querying User:
- We use mysql_loom.find_by_pk() to fetch a single user record from the database.
- The user's ID is specified as 1.
- We select only the id and username columns for the user.
Querying Posts:
- We use mysql_loom.find_many() to retrieve multiple post records associated with the user.
- A filter is applied to only fetch posts where the userId matches the ID of the user retrieved earlier.
- We select only the id and title columns for the posts.
- The posts are ordered by the id column in descending order.
- We set a limit of 2 posts to retrieve, and we skip the first post using an offset of 1.
- We create a dictionary user_with_posts containing the user information and a list of their associated posts under the key "posts".

With eager loading this can be done as follows the above can be done as follows:

user_with_posts = mysql_loom.find_by_pk(
    User,
    1,
    select=["id", "username"],
    include=[
        Include(
            model=Post,
            select=["id", "title"],
            order=[Order(column="id", order="DESC")],
            limit=2,
            offset=1,
        )
    ],
)
print(
    user_with_posts
)  # ? = {'id': 1, 'username': '@miller', 'posts': [{'id': 3, 'title': 'What are you doing'}, {'id': 2, 'title': 'Hello'}]}

We use mysql_loom.find_by_pk() to fetch a single user record from the database.
The user's ID is specified as 1.
We select only the id and username columns for the user.
Additionally, we include associated post records using eager loading.
Inside the include parameter, we specify the Post model and select only the id and title columns for the posts.
The posts are ordered by the id column in descending order.
We set a limit of 2 posts to retrieve, and we skip the first post using an offset of 1.

4. What about bidirectional queries?

In Dataloom, we support bidirectional relations with eager loading on-the-fly. You can query from a parent to a child and from a child to a parent. You just need to know how the relationship is mapped between these two models. In this case, the has option is very important in the Include class. Here are some examples demonstrating bidirectional querying between user and post, where the user is the parent table and the post is the child table in this case.

1. Child to Parent

Here is an example illustrating how we can query a parent from child table.

posts_users = mysql_loom.find_many(
    Post,
    limit=2,
    offset=3,
    order=[Order(column="id", order="DESC")],
    select=["id", "title"],
    include=[
        Include(
            model=User,
            select=["id", "username"],
            has="one",
            include=[Include(model=Profile, select=["id", "avatar"], has="one")],
        ),
        Include(
            model=Category,
            select=["id", "type"],
            order=[Order(column="id", order="DESC")],
            has="many",
            limit=2,
        ),
    ],
)
print(posts_users) # ? = [{'id': 1, 'title': 'Hey', 'user': {'id': 1, 'username': '@miller', 'profile': {'id': 1, 'avatar': 'hello.jpg'}}, 'categories': [{'id': 4, 'type': 'sport'}, {'id': 3, 'type': 'tech'}]}]

2. Parent to Child

Here is an example of how we can query a child table from parent table

user_post = mysql_loom.find_by_pk(
    User,
    pk=userId,
    select=["id", "username"],
    include=[
        Include(
            model=Post,
            limit=2,
            offset=3,
            order=[Order(column="id", order="DESC")],
            select=["id", "title"],
            include=[
                Include(
                    model=User,
                    select=["id", "username"],
                    has="one",
                    include=[
                        Include(model=Profile, select=["id", "avatar"], has="one")
                    ],
                ),
                Include(
                    model=Category,
                    select=["id", "type"],
                    order=[Order(column="id", order="DESC")],
                    has="many",
                    limit=2,
                ),
            ],
        ),
        Include(model=Profile, select=["id", "avatar"], has="one"),
    ],
)


print(user_post) """ ? =
{'id': 1, 'username': '@miller', 'user': {'id': 1, 'username': '@miller', 'profile': {'id': 1, 'avatar': 'hello.jpg'}}, 'categories': [{'id': 4, 'type': 'sport'}, {'id': 3, 'type': 'tech'}], 'posts': [{'id': 1, 'title': 'Hey', 'user': {'id': 1, 'username': '@miller', 'profile': {'id': 1, 'avatar': 'hello.jpg'}}, 'categories': [{'id': 4, 'type': 'sport'}, {'id': 3, 'type': 'tech'}]}], 'profile': {'id': 1, 'avatar': 'hello.jpg'}}
"""

5. `Self` Association

Let's consider a scenario where we have a table Employee, where an employee can have a supervisor, which in this case a supervisor is also an employee. This is an example of self relations. The model definition for this can be done as follows in dataloom.

class Employee(Model):
    __tablename__: TableColumn = TableColumn(name="employees")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    name = Column(type="text", nullable=False, default="Bob")
    supervisorId = ForeignKeyColumn(
        "Employee", maps_to="1-1", type="int", required=False
    )

So clearly we can see that when creating a employee it is not a must to have a supervisorId as this relationship is optional.

👍 Pro Tip: Note that when doing self relations the referenced table must be a string that matches the table class name irrespective of case. In our case we used "Employee" and also "employee" and "EMPLOYEe" will be valid, however "Employees" and also "employees" and "EMPLOYEEs" are invalid.

Inserting

Here is how we can insert employees to this table and we will make John the supervisor of other employees.

empId = mysql_loom.insert_one(
    instance=Employee, values=ColumnValue(name="name", value="John Doe")
)

rows = mysql_loom.insert_bulk(
    instance=Employee,
    values=[
        [
            ColumnValue(name="name", value="Michael Johnson"),
            ColumnValue(name="supervisorId", value=empId),
        ],
        [
            ColumnValue(name="name", value="Jane Smith"),
            ColumnValue(name="supervisorId", value=empId),
        ],
    ],
)

Some employees is are associated with a supervisor John which are Jane and Michael.
However the employee John does not have a supervisor.

Retrieving Records

Now let's query employee Michael with his supervisor.

emp = mysql_loom.find_by_pk(
    instance=Employee, pk=2, select=["id", "name", "supervisorId"]
)
sup = mysql_loom.find_by_pk(
    instance=Employee, select=["id", "name"], pk=emp["supervisorId"]
)
emp_and_sup = {**emp, "supervisor": sup}
print(emp_and_sup) # ? = {'id': 2, 'name': 'Michael Johnson', 'supervisorId': 1, 'supervisor': {'id': 1, 'name': 'John Doe'}}

We're querying the database to retrieve information about a employee and their associated supervisor.

Querying an Employee:
- We use mysql_loom.find_by_pk() to fetch a single employee record from the database.
- The employee's ID is specified as 2.
Querying Supervisor:
- We use mysql_loom.find_by_pk() to retrieve a supervisor that is associated with this employee.
- We create a dictionary emp_and_sup containing the employee information and their supervisor.

With eager loading this can be done in one query as follows the above can be done as follows:

emp_and_sup = mysql_loom.find_by_pk(
    instance=Employee,
    pk=2,
    select=["id", "name", "supervisorId"],
    include=Include(
        model=Employee,
        has="one",
        select=["id", "name"],
        alias="supervisor",
    ),
)

print(emp_and_sup) # ? = {'id': 2, 'name': 'Michael Johnson', 'supervisorId': 1, 'supervisor': {'id': 1, 'name': 'John Doe'}}

We use mysql_loom.find_by_pk() to fetch a single an employee record from the database.
Additionally, we include associated employee record using eager loading with an alias of supervisor.

👍 Pro Tip: Note that the alias is very important in this situation because it allows you to get the included relationships with objects that are named well, if you don't give an alias dataloom will just use the model class name as the alias of your included models, in this case you will get an object that looks like {'id': 2, 'name': 'Michael Johnson', 'supervisorId': 1, 'employee': {'id': 1, 'name': 'John Doe'}}, which practically and theoretically doesn't make sense.

6. `N-N` Relationship

Let's consider a scenario where we have tables for Students and Courses. In this scenario, a student can enroll in many courses, and a single course can have many students enrolled. This represents a Many-to-Many relationship. The model definitions for this scenario can be done as follows in dataloom:

Table: Student

Column Name	Data Type
`id`	`INT`
`name`	`VARCHAR`

Table: Course

Column Name	Data Type
`id`	`INT`
`name`	`VARCHAR`
...	...

Table: Student_Courses (junction table)

Column Name	Data Type
`studentId`	`INT`
`courseId`	`INT`

👍 Pro Tip: Note that the junction table can also be called association-table or reference-table or joint-table.

In dataloom we can model the above relations as follows:

class Course(Model):
    __tablename__: TableColumn = TableColumn(name="courses")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    name = Column(type="text", nullable=False, default="Bob")


class Student(Model):
    __tablename__: TableColumn = TableColumn(name="students")
    id = PrimaryKeyColumn(type="int", auto_increment=True)
    name = Column(type="text", nullable=False, default="Bob")


class StudentCourses(Model):
    __tablename__: TableColumn = TableColumn(name="students_courses")
    studentId = ForeignKeyColumn(table=Student, type="int")
    courseId = ForeignKeyColumn(table=Course, type="int")

The tables students and courses will not have foreign keys.
The students_courses table will have two columns that joins these two tables together in an N-N relational mapping.

👍 Pro Tip: In a joint table no other columns such as CreateAtColumn, UpdatedAtColumn, Column and PrimaryKeyColumn are allowed and only exactly 2 foreign keys should be in this table.

Inserting

Here is how we can insert students and courses in their respective tables.

# insert the courses
mathId = mysql_loom.insert_one(
    instance=Course, values=ColumnValue(name="name", value="Mathematics")
)
engId = mysql_loom.insert_one(
    instance=Course, values=ColumnValue(name="name", value="English")
)
phyId = mysql_loom.insert_one(
    instance=Course, values=ColumnValue(name="name", value="Physics")
)

# create students

stud1 = mysql_loom.insert_one(
    instance=Student, values=ColumnValue(name="name", value="Alice")
)
stud2 = mysql_loom.insert_one(
    instance=Student, values=ColumnValue(name="name", value="Bob")
)
stud3 = mysql_loom.insert_one(
    instance=Student, values=ColumnValue(name="name", value="Lisa")
)

You will notice that we are keeping in track of the studentIds and the courseIds because we will need them in the joint-table or association-table.
Now we can enrol students to their courses by inserting them in their id's in the association table.

# enrolling students
mysql_loom.insert_bulk(
    instance=StudentCourses,
    values=[
        [
            ColumnValue(name="studentId", value=stud1),
            ColumnValue(name="courseId", value=mathId),
        ],  # enrolling Alice to mathematics
        [
            ColumnValue(name="studentId", value=stud1),
            ColumnValue(name="courseId", value=phyId),
        ],  # enrolling Alice to physics
        [
            ColumnValue(name="studentId", value=stud1),
            ColumnValue(name="courseId", value=engId),
        ],  # enrolling Alice to english
        [
            ColumnValue(name="studentId", value=stud2),
            ColumnValue(name="courseId", value=engId),
        ],  # enrolling Bob to english
        [
            ColumnValue(name="studentId", value=stud3),
            ColumnValue(name="courseId", value=phyId),
        ],  # enrolling Lisa to physics
        [
            ColumnValue(name="studentId", value=stud3),
            ColumnValue(name="courseId", value=engId),
        ],  # enrolling Lisa to english
    ],
)

Retrieving Records

Now let's query a student called Alice with her courses. We can do it as follows:

s = mysql_loom.find_by_pk(
    Student,
    pk=stud1,
    select=["id", "name"],
)
c = mysql_loom.find_many(
    StudentCourses,
    filters=Filter(column="studentId", value=stud1),
    select=["courseId"],
)
courses = mysql_loom.find_many(
    Course,
    filters=Filter(column="id", operator="in", value=[list(i.values())[0] for i in c]),
    select=["id", "name"],
)

alice = {**s, "courses": courses}
print(courses) # ? = {'id': 1, 'name': 'Alice', 'courses': [{'id': 1, 'name': 'Mathematics'}, {'id': 2, 'name': 'English'}, {'id': 3, 'name': 'Physics'}]}

We're querying the database to retrieve information about a student and their associated courses. Here are the steps in achieving that:

Querying Student:
- We use mysql_loom.find_by_pk() to fetch a single student record from the database in the table students.
Querying Course Id's:
- Next we are going to query all the course ids of that student and store them in c in the joint table students_courses.
- We use mysql_loom.find_many() to retrieve the course ids of alice.
Querying Course:
- Next we will query all the courses using the operator in in the courses table based on the id's we obtained previously.

As you can see we are doing a lot of work to get the information about Alice. With eager loading this can be done in one query as follows the above can be done as follows:

alice = mysql_loom.find_by_pk(
    Student,
    pk=stud1,
    select=["id", "name"],
    include=Include(
        model=Course, junction_table=StudentCourses, alias="courses", has="many"
    ),
)

print(alice) # ? = {'id': 1, 'name': 'Alice', 'courses': [{'id': 1, 'name': 'Mathematics'}, {'id': 2, 'name': 'English'}, {'id': 3, 'name': 'Physics'}]}

We use mysql_loom.find_by_pk() to retrieve a single student record from the database.
Furthermore, we include the associated course records using eager loading with an alias of courses.
We specify a junction_table in our Include statement. This allows dataloom to recognize the relationship between the students and courses tables through this junction_table.

👍 Pro Tip: It is crucial to specify the junction_table when querying in a many-to-many (N-N) relationship. This is because, by default, the models will not establish a direct many-to-many relationship without referencing the junction_table. They lack foreign key columns within them to facilitate this relationship.

As for our last example let's query all the students that are enrolled in the English class. We can easily do it as follows:

english = mysql_loom.find_by_pk(
    Course,
    pk=engId,
    select=["id", "name"],
    include=Include(model=Student, junction_table=StudentCourses, has="many"),
)

print(english) # ? = {'id': 2, 'name': 'English', 'students': [{'id': 1, 'name': 'Alice'}, {'id': 2, 'name': 'Bob'}, {'id': 3, 'name': 'Lisa'}]}

Query Builder.

Dataloom exposes a method called getQueryBuilder, which allows you to obtain a qb object. This object enables you to execute SQL queries directly from SQL scripts.

qb = loom.getQueryBuilder()

print(qb) # ? = Loom QB<mysql>

The qb object contains the method called run, which is used to execute SQL scripts or SQL queries.

ids = qb.run("select id from posts;", fetchall=True)
print(ids) # ? = [(1,), (2,), (3,), (4,)]

You can also execute SQL files. In the following example, we will demonstrate how you can execute SQL scripts using the qb. Let's say we have an SQL file called qb.sql which contains the following SQL code:

SELECT id, title FROM posts WHERE id IN (1, 3, 2, 4) LIMIT 4 OFFSET  1;
SELECT COUNT(*) FROM (
    SELECT DISTINCT `id`
    FROM `posts`
    WHERE `id` < 5
    LIMIT 3 OFFSET 2
) AS subquery;

We can use the query builder to execute the SQL as follows:

with open("qb.sql", "r") as reader:
    sql = reader.read()
res = qb.run(
    sql,
    fetchall=True,
    is_script=True,
)
print(res)

👍 Pro Tip: Executing a script using query builder does not return a result. The result value is always None.

The run method takes the following as arguments:

Argument	Description	Type	Required	Default
`sql`	SQL query to execute.	`str`	Yes
`args`	Parameters for the SQL query.	`Any \| None`	No	`None`
`fetchone`	Whether to fetch only one result.	`bool`	No	`False`
`fetchmany`	Whether to fetch multiple results.	`bool`	No	`False`
`fetchall`	Whether to fetch all results.	`bool`	No	`False`
`mutation`	Whether the query is a mutation (insert, update, delete).	`bool`	No	`True`
`bulk`	Whether the query is a bulk operation.	`bool`	No	`False`
`affected_rows`	Whether to return affected rows.	`bool`	No	`False`
`operation`	Type of operation being performed.	`'insert', 'update', 'delete', 'read' \| None`	No	`None`
`verbose`	Verbosity level for logging . Set this option to `0` if you don't want logging at all.	`int`	No	`1`
`is_script`	Whether the SQL is a script.	`bool`	No	`False`

Why Use Query Builder?

The query builder empowers developers to seamlessly execute SQL queries directly.
While Dataloom primarily utilizes subqueries for eager data fetching on models, developers may prefer to employ JOIN operations, which are achievable through the qb object.
```
qb = loom.getQueryBuilder()
result = qb.run("SELECT * FROM table1 INNER JOIN table2 ON table1.id = table2.table1_id;")
print(result)
```

Documentation

You can read the full documentation of dataloom on readthedocs.io

Contributing

Contributions to dataloom are welcome! Feel free to submit bug reports, feature requests, or pull requests on GitHub.

License

This project is licensed under the MIT License - see the LICENSE file for details.

Project details

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Development Status
- 5 - Production/Stable
- 6 - Mature
Intended Audience
- Developers
Natural Language
- English
Operating System
Programming Language
- Python :: 3.12

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dataloom 2.4.2

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Project description

dataloom

Why choose dataloom?

Table of Contents

Key Features:

Installation

Python Version Compatibility

Usage

Connection

Postgres

MySQL

SQLite

Dataloom Classes

Loom Class

Model Class

Column Class

Column Datatypes

1. mysql

2. postgres

3. sqlite

PrimaryKeyColumn Class

ForeignKeyColumn Class

CreatedAtColumn Class

UpdatedAtColumn Class

Filter Class

ColumnValue Class

Order Class

Include Class

Group Class

Having Class

Syncing Tables

1. The sync method.

2. The connect_and_sync method.

CRUD Operations with Dataloom

1. Creating a Record

1. insert_one()

2. insert_bulk().

2. Reading records

1. find_all()

2. find_many()

3. find_one()

4. find_by_pk()

3. Updating a record

1. update_by_pk()

2. update_one()

3. update_bulk()

4. Deleting a record

1. delete_by_pk()

2. delete_one()

3. delete_bulk()

Warning: Potential Risk with delete_bulk()

Guidelines for Safe Usage

Ordering

Filters

Operators

Data Aggregation

Aggregation Functions

Utilities

1. inspect()

2. decorators

@initialize()

3. count()

4. min()

5. max()

6. avg()

7. sum()

Associations

1. 1-1 Association

Inserting

Retrieving Records

2. N-1 Association

Why choose `dataloom`?

`Postgres`

`MySQL`

`SQLite`

`Loom` Class

`Model` Class

`Column` Class

1. `mysql`

2. `postgres`

3. `sqlite`

`PrimaryKeyColumn` Class

`ForeignKeyColumn` Class

`CreatedAtColumn` Class

`UpdatedAtColumn` Class

`Filter` Class

`ColumnValue` Class

`Order` Class

`Include` Class

`Group` Class

`Having` Class

1. The `sync` method.

2. The `connect_and_sync` method.

1. `insert_one()`

2. `insert_bulk()`.

1. `find_all()`

2. `find_many()`

3. `find_one()`

4. `find_by_pk()`

1. `update_by_pk()`

2. `update_one()`

3. `update_bulk()`

1. `delete_by_pk()`

2. `delete_one()`

3. `delete_bulk()`

Warning: Potential Risk with `delete_bulk()`

1. `inspect()`

2. `decorators`

`@initialize()`

3. `count()`

4. `min()`

5. `max()`

6. `avg()`

7. `sum()`

1. `1-1` Association

2. `N-1` Association

3. `1-N` Association

5. `Self` Association

6. `N-N` Relationship