#!/usr/bin/env python
# coding: utf-8

# ## NeoAccess library - Tutorial 1 : connection to the Neo4j database, 
# ## and basic `NeoAccess` library operations (incl. "NodeSpecs" objects)
# #### (`debug` mode **OFF**)
# 
# #### [Overview and Intro article](https://julianspolymathexplorations.blogspot.com/2023/06/neo4j-python-neoaccess-library.html) to accompany these tutorials
# 
# #### CAUTION: running this tutorial runs a risk of clearing out your database; best run on a test database!

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import os
import sys
import getpass

from neoaccess import NeoAccess
# In case of problems, try a sys.path.append(directory) , where directory is your project's root directory


# # Connect to the database
# #### You can use a free local install of the Neo4j database, or a remote one on a virtual machine under your control, or a hosted solution, or simply the FREE "Sandbox" : [instructions here](https://julianspolymathexplorations.blogspot.com/2023/03/neo4j-sandbox-tutorial-cypher.html)
# NOTE: This tutorial is tested on **version 4.4** of the Neo4j database, but will probably also work on the new version 5 (NOT guaranteed, however...)

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# Save your credentials here - or use the prompts given by the next cell
host = ""               # EXAMPLES:  bolt://123.456.789.012   OR   neo4j://localhost  
                        # (CAUTION: do NOT include the port number!)
password = ""


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db = NeoAccess(host=host,
               credentials=("neo4j", password), debug=False)   # Notice the debug option being OFF


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print("Version of the Neo4j driver: ", db.version())


# # Examples of basic `NeoAccess` library operations

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# CLEAR OUT THE DATABASE
#db.empty_dbase()       # UNCOMMENT IF DESIRED   *****************  WARNING: USE WITH CAUTION!!!  ************************


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# Create a "Car" node and a "Person" node

neo_car = db.create_node("Car", {'color': 'white', 'make': 'Toyota'})  # create_node returns the internal database ID of the new node

neo_person = db.create_node("Person", {'name': 'Julian'})


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# Link the "Car" node to the "Person" node (using internal database ID's to refer to existing nodes)
number_added = db.add_links(match_from=neo_car, match_to=neo_person, rel_name="OWNED_BY")  

number_added


# ![Two nodes and a link](https://raw.githubusercontent.com/BrainAnnex/brain-annex/main/docs/tutorials_1.png)

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# Retrieve the car node (in the most straightforward way, using an internal database ID)
db.get_nodes(neo_car)


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# Retrieve a single property of the car node (to be used when only 1 node is present)
db.get_nodes(neo_car, single_cell="color")


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# How many owners does the car have?
db.count_links(neo_car, rel_name="OWNED_BY", rel_dir="OUT") 


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# Look up information about the car owner(s)
db.follow_links(neo_car, rel_name="OWNED_BY", rel_dir="OUT") 


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# #### Let's pretend we didn't save the internal database ID's of our 2 nodes; let's specify those nodes, for the purpose of *LATER* retrieving them from the database

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# Lets provide a way to later look up the "Car" node, using the match() method.
# IMPORTANT: NO DATABASE OPERATION IS ACTUALLY PERFORMED HERE!  We're just saving up all the specs 
#            (to indentify a node, OR GROUP OF NODES) into an object of class "NodeSpecs"

car_match = db.match(labels="Car", properties={'color': 'white', 'make': 'Toyota'})

car_match


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print(car_match)    # Let's look at the specs we saved up; they will be used LATER in actual database operations


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# A lot of parameters can be passed to match().  Some examples of alternative ways to specify the same node as above:

car_match_alt = db.match(labels="Car", clause="n.color = 'white' AND n.make = 'Toyota'", dummy_node_name="n")

print(car_match_alt)


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# Various ways to specify our Person node (again, NO DATABASE OPERATION IS ACTUALLY PERFORMED HERE!)

person_match  = db.match(labels="Person", properties={'name': 'Julian'})
person_match_alt_1 = db.match(labels="Person", clause="n.name = 'Julian'", dummy_node_name="n")
person_match_alt_2 = db.match(labels="Person", key_name='name', key_value='Julian')


# #### Armed with the "NodeSpecs" objects, we can do all sort of operations - passing those objects (serving as "handles") in lieu of the internal database ID's that we lack (and which would require extra database operations to retrieve)
# Note: NO EXTRA DATABASE OPERATIONS ARE WASTED ON LOCATING THE NODES!  Efficient, 1-step, database queries are created and executed at the very LAST stage; for example to create the following link

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# Link the "Person" node to the "Car" node (a reverse link of the one we created before)
# HERE'S WHERE THE (SINGLE) DATABASE OPERATION ACTUALLY GETS PERFORMED
number_added = db.add_links(match_from=person_match, match_to=car_match, rel_name="OWNS")  

number_added


# ![Two nodes and a link](https://raw.githubusercontent.com/BrainAnnex/brain-annex/main/docs/tutorials_2.png)

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# #### Some verifications

# The "Car" node can be found and extracted (performing a DATABASE OPERATION), using EITHER its Internal Database ID (which we had saved at the very beginning, though we we were acting like we didn't) OR any of the alternative ways we created to specify it

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db.get_nodes(neo_car)    # Fetch by the internal database ID


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db.get_nodes(car_match)   # Fetch by "NodeSpecs" object returned by the match() method


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db.get_nodes(car_match_alt)   # Fetch by an alternate version of the "NodeSpecs" object


# _Likewise for the "Person" node:_

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db.get_nodes(neo_person)    # Fetch by the internal database ID


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db.get_nodes(person_match)   # Fetch by "NodeSpecs" object returned by the match() method


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db.get_nodes(person_match_alt_1)


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db.get_nodes(person_match_alt_2)


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# ## If you know the Cypher query language, and simply want to run a generic query, no problem!

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q = '''MATCH (p :Person) -[:OWNS] -> (c :Car) -[OWNED_BY] -> (p)
       RETURN p.name, c.color, c.make
    '''    # This query will verify the forward and reverse links that we created earlier


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db.query(q)    # Run the query; by default, it will return a list of records (each record is a dict)


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q_paint_car_red = '''MATCH (c :Car) -[OWNED_BY] -> (p :Person {name: 'Julian'})
                     SET c.color = 'red'
                  '''    # Paint all of Julian's cars red!

result = db.update_query(q_paint_car_red)   # It returns a dict of info about what it did

result


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db.query(q)   # Re-run the earlier query (to verify the forward and reverse links); notice how the car is now red


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# ## Are you knowledgeable about Cypher, and want an under-the-hood look at the NeoAcces library?  
# ### Everything in this tutorial is repeated indentically - but with the DEBUG option turned on - in tutorial 2 ; the Cypher queries and the data binding managed by NeoAccess will become visible

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