Automated Data Visualizations in Python
Creating data visualizations in Python can be a challenge. For some it an be easy, but for most (and particularly new people to the language) they always have to search for the commands in the documentation or using some search engine. Over the past few years we have seem more and more libraries coming available to assist with many of the routine and tedious steps in most data science and machine learning projects. I’ve written previously about some data profiling libraries in Python. These are good up to a point, but additional work/code is needed to explore the data to suit your needs. One of these Python libraries, designed to make your initial work on a new data set easier is called AutoViz. It’s good to see there is continued development work on this library, which can be really help for creating initial sets of charts for all the variables in your data set, plus it has some additional features which help to make it very useful and cuts down on some of the additional code you might need to write.
The outputs from AutoViz are very extensive, and are just too long to show in this post. The images below will give you an indication of what if typically generated. I’d encourage you to install the library and run it on one of your data sets to see the full extent of what it can do. For this post, I’ll concentrate on some of the commands/parameters/settings to get the most out of AutoViz.
Firstly there is the install via pip command or install using Anaconda.
pip3 install autovizFor comparison purposes I’m going to use the same data set as I’ve used in the data profiling post (see above). Here’s a quick snippet from that post to load the data and perform the data profiling (see post for output)
import pandas as pd
import pandas_profiling as pp
#load the data into a pandas dataframe
df = pd.read_csv("/Users/brendan.tierney/Downloads/Video_Games_Sales_as_at_22_Dec_2016.csv")We can not skip to using AutoViz. It supports the loading and analzying of data sets direct from a file or from a pandas dataframe. In the following example I’m going to use the dataframe (df) created above.
from autoviz import AutoViz_Class
AV = AutoViz_Class()
df2 = AV.AutoViz(filename="", dfte=df) #for a file, fill in the filename and remove dfte parameterThis will analyze the data and create lots and lots of charts for you. Some are should in the following image. One the helpful features is the ‘data cleaning improvements’ section where it has performed a data quality assessment and makes some suggestions to improve the data, maybe as part of the data preparation/cleaning step.
There is also an option for creating different types of out put with perhaps the Bokeh charts being particularly useful.
chart_format='bokeh': interactive Bokeh dashboards are plotted in Jupyter Notebooks.chart_format='server', dashboards will pop up for each kind of chart on your web browser.chart_format='html', interactive Bokeh charts will be silently saved as Dynamic HTML files underAutoViz_Plotsdirectory
df2 = AV.AutoViz(filename="", dfte=df, chart_format='bokeh')
The next example allows for the report and charts to be focused on a particular dependent or target variable, particular in scenarios where classification will be used.
df2 = AV.AutoViz(filename="", dfte=df, depVar="Platform")
A little warning when using this library. It can take a little bit of time for it to run and create all the different charts. On the flip side, it save you from having to write lots and lots of code!
Annual Look at Database Trends (Jan 2023)
Monitoring trends in the popularity and usage of different Database vendors can be a interesting exercise. The marketing teams from each vendor do an excellent job of promoting their Database, along with the sales teams, developer advocates, and the user communities. Some of these are more active than others and it varies across the Database market on what their choice is for promoting their products. One of the problems with these various types of marketing, is how can be believe what they are saying about how “awesome” their Database is, and then there are some who actively talk about how “rubbish” (or saying something similar) other Databases area. I do wonder how this really works for these people and vendors when to go negative about their competitors. A few months ago I wrote about “What does Legacy Really Mean?“. That post was prompted by someone from one Database Vendor calling their main competitor Database a legacy product. They are just name calling withing providing any proof or evidence to support what they are saying.
Getting back to the topic of this post, I’ve gathered some data and obtained some league tables from some sites. These will help to have a closer look at what is really happening in the Database market throughout 2022. Two popular sites who constantly monitor the wider internet and judge how popular Databases area globally. These sites are DB-Engines and TOPDB Top Database index. These are well know and are frequently cited. Both of these sites give some details of how they calculate their scores, with one focused mainly on how common the Database appears in searches across different search engines, while the other one, in addition to search engine results/searches, also looks across different websites, discussion forms, social media, job vacancies, etc.
The first image below is a comparison of the league tables from DB-Engines taken in January 2022 and January 2023. I’ve divided this image into three sections/boxes. Overall for the first 10 places, not a lot has changed. The ranking scores have moved slightly in most cases but not enough to change their position in the rank. Even with a change of score by 30+ points is a very small change and doesn’t really indicate any great change in the score as these scores are ranked in a manner where, “when system A has twice as large a value in the DB-Engines Ranking as system B, then it is twice as popular when averaged over the individual evaluation criteria“. Using this explanation, Oracle would be twice as popular when compared to PostgreSQL. This is similar across 2022 and 2023.
Next we’ll look a ranking from TOPDB Top Database index. The image below compares January 2022 and January 2023. TOPDB uses a different search space and calculation for its calculation. The rankings from TOPDB do show some changes in the ranks and these are different to those from DB-Engines. Here we see the top three ranks remain the same with some small percentage changes, and nothing to get excited about. In the second box covering ranks 4-7 we do some changes with PostgreSQL improving by two position and MongoDB. These changes do seem to reflect what I’ve been seeing in the marketplace with MongoDB being replaced by PostgreSQL and MySQL, with this multi-model architecture where you can have relational, document, and other data models in the one Database. It’s important to note Oracle and SQL Server also support this. Over the past couple of years there has been a growing awareness of and benefits of having relation and document (and others) data models in the one database. This approach makes sense both for developer productivity, and for data storage and management.
The next gallery of images is based on some Python code I’ve written to look a little bit closer at the top five Databases. In this case these are Oracle, MySQL, SQL Server, PostgreSQL and MongoDB. This gallery plots a bar chart for each Database for their top 15 Counties, and compares them with the other four Databases. The results are interesting and we can see some geographic aspects to the popularity of the Databases.
Migrating SAS files to CSV and database
Many organizations have been using SAS Software to analyse their data for many decades. As with most technologies organisations will move to alternative technologies are some point. Recently I’ve experienced this kind of move. In doing so any data stored in one format for the older technology needed to be moved or migrated to the newer technology. SAS Software can process data in a variety of format, one of which is their own internal formats. Thankfully Pandas in Python as a function to read such SAS files into a pandas dataframe, from which it can be saved into some alternative format such as CSV. The following code illustrates this conversion, where it will migrate all the SAS files in a particular directory, converts them to CSV and saves the new file in a destination directory. It also copies any existing CSV files to the new destination, while ignore any other files. The following code is helpful for batch processing of files.
import os
import pandas as pd
#define the Source and Destination directories
source_dir='/Users/brendan.tierney/Dropbox/4-Datasets/SAS_Data_Sets'
dest_dir=source_dir+'/csv'
#What file extensions to read and convert
file_ext='.sas7bdat'
#Create output directory if it does not already exist
if not os.path.exists(dest_dir):
os.mkdir(dest_dir)
else: #If directory exists, delete all files
for filename in os.listdir(source_dir):
os.remove(filename)
#Process each file
for filename in os.listdir(source_dir):
#Process the SAS file
if filename.endswith(file_ext):
print('.processing file :',filename)
print('...converting file to csv')
df=pd.read_sas(os.path.join(source_dir, filename))
df.to_csv(os.path.join(dest_dir, filename))
print('.....finished creating CSV file')
elif filename.endswith('csv'):
#Copy any CSV files to the Destination Directory
print('.copying CSV file')
cmd_copy='cp '+os.path.join(source_dir, filename)+' '+os.path.join(dest_dir, filename)
os.system(cmd_copy)
print('.....finished copying CSV file')
else:
#Ignore any other type of files
print('.ignoring file :',filename)
print('--Finished--')That’s it. All the files have now been converted and located in the destination directory.
For most, the above might be all you need, but sometimes you’ll need to move the the newer technology. In most cases the newer technology will easily use the CSV files. But in some instance your final destination might be a database. In my scenarios I use the CSV2DB app developed by Gerald Venzi. You can download the code from GitHub. You can use this to load CSV files into Oracle, MySQL, PostgreSQL, SQL Server and Db2 databases. Here’s and example of the command line to load into an Oracle Database.
csv2db load -f /Users/brendan.tierney/Dropbox/4-Datasets/SAS_Data_Sets/csv -t pva97nk -u analytics -p analytics -d PDB1
Downloading your Twitter Archive
Over the past few weeks there has been various dramas with Twitter, its new owner, how the staff have been treated, etc. All this drama has also impacted the day-to-day users of Twitter. Will Twitter survive? If it does, how will it be different? Maybe nothing will change for now or for a while, and we might see some gradual changes as a use of the platform. Many people have either moved to Mastodon, although it has many limitations and might not be suitable for everyone.
Maybe Twitter will survive? Only time will tell.
But what about all your Twitter posts, replies and interactions? What if Twitter disappears and all your content over the past few years or even long (10+ years). One thing you can do, and do it now, is to download your Twitter Archive. This will contain a those tweets, replies and interactions over the years. There will be a lot of valuable information in those and it would be a shame to have lost it.
These are the step I’ve followed to Download your Twitter Archive:
1. To to your Twitter home page, and click on the More icon in the menu on the left hand side of the page. Select “Settings and Support” from the menu options. Click “Settings and privacy.” Select “Your account” from the menu options.
2. Click “Download an archive of your data.” You’ll be asked to enter your password, do so and click “Confirm.”
3. Next you’ll have to verify your identity. Click “Send code” to your email and/or your phone number. You’ll be redirected to the “Account information” page where you’ll be able to enter the code that was sent to your email or phone.
4. Once Twitter has verified it is really you, click “Request archive.”
5. When your download is ready to be downloaded, you’ll receive an email from Twitter with a link to the zip file containing your archive.
That’s it. You now have your Twitter data, to use as you want.
There are several reasons why downloading your Twitter archive can be valuable. Here are some additional benefits:
- It allows you to access and view your entire tweet history in one place, which can be useful for personal or professional purposes. For example, you might want to review your tweets to see what you have shared in the past, or to see how your online presence has evolved over time.
- It can be a useful backup of your tweet history, in case your account is ever deleted or suspended. By downloading your archive, you will have a copy of your tweets that you can refer to or use to restore your account if necessary.
- It can be useful for researching and analyzing your Twitter activity. For example, you might want to use the archive to see which tweets have been most popular, or to identify trends or patterns in your tweeting behavior.
- It can be useful for exporting your tweet data to other platforms or tools for further analysis or processing. For example, you might want to use the data in your archive to create visualizations or to perform sentiment analysis on your tweets.
Overall, downloading your Twitter archive can provide a range of benefits, including the ability to access and view your tweet history, create a backup of your tweets, and use the data for research or analysis.
What does Legacy really mean?
In the IT industry we hear the term “legacy” being using, but that does it mean? It can mean a lot of different things and it really depends on the person who is saying it, their context, what they want to portray and their intended meaning. In a lot of cases people seem to use it without knowing the meaning or the impact it can have. This can result in negative impact and not in the way the person intended.
Before looking at some (and there can be lots) possible meanings, lets have a look at what one person said recently.
“Migrating away from legacy databases like Oracle can seem like a daunting undertaking for businesses. But it doesn’t have to be.”
To give context to this quote, the person works for a company selling products, services, support, etc for PostgreSQL and wants everyone to move to ProtgreSQL (Postgres), which is understandable given their role. There’s nothing wrong with trying to convince people/companies to use software that you sell lots of services and additional software to support it. What is interesting is they used the work “legacy”.
Legacy can mean lots of different things to different people. Here are some examples of how legacy is used within the IT industry.
- The product is old and out of date
- The product has no relevancy in software industry today
- Software or hardware that has been superseded
- Any software that has just been released (yes I’ve come across this use)
- Outdated computing software and/or hardware that is still in use. The system still meets the needs it was originally designed for, but doesn’t allow for growth
- Anything in production
- Software that has come to an end of life with no updates, patching and/or no product roadmap
- …
Going back to the quote given above, let’s look a little closer at their intended use. As we can see from the list above the use of the word “legacy” can be used in derogatory way and can try to make one software appear better then it’s old, out of date, not current, hard to use, etc competitor.
If you were to do a side-by-side comparison of PostgreSQL and Oracle, there would be a lot of the same or very similar features. But there are differences too and this, in PostgreSQL case, we see various vendors offering add-on software you can pay for. This is kind of similar with Oracle where you need to license various add-ons, or if you are using a Cloud offering it may come as part of the package. On a features comparison level when these are similar, saying one is “legacy” doesn’t seem right. Maybe its about how old the software is, as in legacy being old software. The first release of Oracle was 1979 and we now get yearly update releases (previously it could be every 2-4 years). PostgresSQL, or its previous names date back to 1974 with the first release of Ingres, which later evolved to Postgres in early 1980s, and took on the new name of PostgreSQL in 1996. Are both products today still the same as what they had in the 1970s, 1980s, 1990s, etc. The simple answer is No, they have both evolved and matured since then. Based on this can we say PostgreSQL is legacy or is more of a Legacy product than Oracle Database which was released in 1979 (5 years after Ingres)? Yes we can.
I’m still very confused by the quote (given above) as to what “legacy” might mean, in their scenario. Apart from and (trying) to ignore the derogatory aspect of “they” are old and out of date, and look at us we are new and better, it is difficult to see what they are trying to achieve.
In a similar example on a LinkedIn discussion where one person said MongoDB was legacy, was a little surprising. MongoDB is very good at what it does and has a small number of use cases. The problem with MongoDB is it is used in scenarios when it shouldn’t be used and just causes too many data architecture problems. For me, the main problem driving these issues is how software engineering and programming is taught in Universities (and other third level institutions). They are focused on JavaScript which makes using MongoDB so so easy. And its’ Agile, and the data model can constantly change. This is great, up until you need to use that data. Then it becomes a nightmare.
Getting back to saying MongoDB is legacy, again comes back to the person saying it. They work at a company who is selling cloud based data engineering and analytic services. Is using cloud services the only thing people should be using? For me it is No but a hybrid cloud and on-premises approach will work based for most. Some of the industry analysts are now promoting this, saying vendors offering both will succeed into the future, where does only offering cloud based services will have limited growth, unless the adapt now.
What about other types legacy software applications. Here is an example Stew Ashton posted on Twitter. “I once had a colleague who argued, in writing, that changing the dev stack had the advantage of forcing a rewrite of “legacy applications” – which he had coded the previous year! Either he thought he had greatly improved, or he wanted guaranteed job security”
There are lots and lots of more examples out there and perhaps you will encounter some when you are attending presentations or sales pitches from various vendors. If you hear, then saying one product is “legacy” get them to define their meaning of it and to give specific examples to illustrate it. Does their meaning match with one from the list given above, or something else. Are they just using the word to make another product appear inferior without knowing the meaning or the differences in the product? Their intended meaning within their context is what defines their meaning, which may be different to yours.
AI Liability Act
Over the past few weeks we have seem a number of new Artificial Intelligence (AI) Acts or Laws, either being proposed or are at an advanced stage of enactment. One of these is the EU AI Liability Act (also), and is supposed be be enacted and work hand-in-hand with the EU AI Act.
There are different view or focus perspectives between these two EU AI acts. For the EU AI Act, the focus is from the technical perspective and those who develop AI solutions. On the other side of things is the EU AI Liability Act whose perspective is from the end-user/consumer point.
The aim of the EU AI Liability Act is to create a framework for trust in AI technology, and when a person has been harmed by the use of the AI, provides a structure to claim compensation. Just like other EU laws to protect the consumers from defective or harmful products, the AI Liability Act looks to do similar for when a person is harmed in some way by the use or application of AI.
Most of the examples given for how AI might harm a person includes the use of robotics, drones, and when AI is used in the recruitment process, where is automatically selects a candidate based on the AI algorithms. Some other examples include data loss from tech products or caused by tech products, smart-home systems, cyber security, products where people are selected or excluded based on algorithms.
Harm can be difficult to define, and although some attempt has been done to define this in the Act, additional work is needed to by the good people refining the Act, to provide clarifications on this and how its definition can evolve post enactment to ensure additional scenarios can be included without the need for updates to the Act, which can be a lengthy process. A similar task is being performed on the list of high-risk AI in the EU AI Act, where they are proposing to maintain a webpages listing such.
Vice-president for values and transparency, Věra Jourová, said that for AI tech to thrive in the EU, it is important for people to trust digital innovation. She added that the new proposals would give customers “tools for remedies in case of damage caused by AI so that they have the same level of protection as with traditional technologies”
Didier Reynders, the EU’s justice commissioner says, “The new rules apply when a product that functions thanks to AI technology causes damage and that this damage is the result of an error made by manufacturers, developers or users of this technology.
The EU defines “an error” in this case to include not just mistakes in how the A.I. is crafted, trained, deployed, or functions, but also if the “error” is the company failing to comply with a lot of the process and governance requirements stipulated in the bloc’s new A.I. Act. The new liability rules say that if an organization has not complied with their “duty of care” under the new A.I. Act—such as failing to conduct appropriate risk assessments, testing, and monitoring—and a liability claim later arises, there will be a presumption that the A.I. was at fault. This creates an additional way of forcing compliance with the EU AI Act.
The EU Liability Act says that a court can now order a company using a high-risk A.I. system to turn over evidence of how the software works. A balancing test will be applied to ensure that trade secrets and other confidential information is not needlessly disclosed. The EU warns that if a company or organization fails to comply with a court-ordered disclosure, the courts will be free to presume the entity using the A.I. software is liable.
The EU Liability Act will go through some changes and refinement with the aim for it to be enacted at the same time as the EU AI Act. How long will this process that is a little up in the air, considering the EU AI Act should have been adopted by now and we could be in the 2 year process for enactment. But the EU AI Act is still working its way through the different groups in the EU. There has been some indications these might conclude in 2023, but lets wait and see. If the EU Liability Act is only starting the process now, there could be some additional details if the EU wants both Acts to be effective at the same time.
Preparing images for #DeepLearning by removing background
There are a number of methods available for preparing images for input to a variety of purposes. For example, for input to deep learning, other image processing models/applications/systems, etc. But sometimes you just need a quick tool to perform a certain task. An example of this is I regularly have to edit images to extract just a certain part of it, or to filter out all the background colors and/or objects etc. There are a a variety of tools available to help you with this kind of task. For me, I’m a Mac user, so I use the instant alpha feature available in some of the Mac products. But what if you are not a Mac user, what can you use.
I’ve recently come across a very useful Python library that takes all or most of the hard work out of doing such tasks, and has proved to be extremely useful for some demos and projects I’ve been working on. The Python library I’m using is remgb (Remove Background). It isn’t perfect, but it does a pretty good job and only in a small number of modified images, did I need to do some additional processing.
Let’s get started with setting things up to use remgb. I did encounter some minor issues installing it, and I’ve give the workarounds below, just in case you encounter the same.
pip3 install remgbThis will install lots of required libraries and will check for compatibility with what you have installed. The first time I ran the install it generated some errors. It also suggested I update my version of pip, which I did, then uninstalled the remgb library and installed again. No errors this time.
When I ran the code below, I got some errors about accessing a document on google drive or it had reached the maximum number of views/downloads. The file it is trying to access is an onix model. If you click on the link, you can download the file. Create a directory called .u2net (in your home directory) and put the onix file into it. Make sure the directory is readable. After doing that everything runs smoothly for me.
The code I’ve given below is typical of what I’ve been doing on some projects. I have a folder with lots of images where I want to remove the background and only keep the key foreground object. Then save the modified images to another directory. It is these image that can be used in products like Amazon Rekognition, Oracle AI Services, and lots of other similar offerings.
from rembg import remove
from PIL import Image
import os
from colorama import Fore, Back, Style
sourceDir = '/Users/brendan.tierney/Dropbox/4-Datasets/F1-Drivers/'
destDir = '/Users/brendan.tierney/Dropbox/4-Datasets/F1-Drivers-NewImages/'
print('Searching = ', sourceDir)
files = os.listdir(sourceDir)
for file in files:
try:
inputFile = sourceDir + file
outputFile = destDir + file
with open(inputFile, 'rb') as i:
print(Fore.BLACK + '..reading file : ', file)
input = i.read()
print(Fore.CYAN + '...removing background...')
output = remove(input)
try:
with open(outputFile, 'wb') as o:
print(Fore.BLUE + '.....writing file : ', outputFile)
o.write(output)
except:
print(Fore.RED + 'Error writing file :', outputFile)
except:
print(Fore.RED + 'Error processing file :', file)
print(Fore.BLACK + '---')
print(Fore.BLACK + 'Finished processing all files')
print(Fore.BLACK + '---')For this demonstration I’ve used images of the F1 drivers for 2022. I had collected five images of each driver with different backgrounds including, crowds, pit-lane, giving media interviews, indoor and outdoor images.
Generally the results were very good. Here are some results with the before and after.
As you can see from these image there are some where a shadow remains and the library wasn’t able to remove it. The following images gives some additional examples of this. The first is with Bottas and his car, where the car wasn’t removed. The second driver is Vettel where the library captures his long hair and keeps it in the filtered image.
Number of rows in each Table – Various Databases
A possible common task developers perform is to find out how many records exists in every table in a schema. In the examples below I’ll show examples for the current schema of the developer, but these can be expanded easily to include tables in other schemas or for all schemas across a database.
These example include the different ways of determining this information across the main databases including Oracle, MySQL, Postgres, SQL Server and Snowflake.
A little warning before using these queries. They may or may not give the true accurate number of records in the tables. These examples illustrate extracting the number of records from the data dictionaries of the databases. This is dependent on background processes being run to gather this information. These background processes run from time to time, anything from a few minutes to many tens of minutes. So, these results are good indication of the number of records in each table.
Oracle
SELECT table_name, num_rows
FROM user_tables
ORDER BY num_rows DESC;or
SELECT table_name,
to_number(
extractvalue(xmltype(
dbms_xmlgen.getxml('select count(*) c from '||table_name))
,'/ROWSET/ROW/C')) tab_count
FROM user_tables
ORDER BY tab_count desc;Using PL/SQL we can do something like the following.
DECLARE
val NUMBER;
BEGIN
FOR i IN (SELECT table_name FROM user_tables ORDER BY table_name desc) LOOP
EXECUTE IMMEDIATE 'SELECT count(*) FROM '|| i.table_name INTO val;
DBMS_OUTPUT.PUT_LINE(i.table_name||' -> '|| val );
END LOOP;
END;MySQL
SELECT table_name, table_rows
FROM INFORMATION_SCHEMA.TABLES
WHERE table_type = 'BASE TABLE'
AND TABLE_SCHEMA = current_user();
Using Common Table Expressions (CTE), using WITH clause
WITH table_list AS (
SELECT
table_name
FROM information_schema.tables
WHERE table_schema = current_user()
AND
table_type = 'BASE TABLE'
)
SELECT CONCAT(
GROUP_CONCAT(CONCAT("SELECT '",table_name,"' table_name,COUNT(*) rows FROM ",table_name) SEPARATOR " UNION "),
' ORDER BY table_name'
)
INTO @sql
FROM table_list;
Postgres
select relname as table_name, n_live_tup as num_rows from pg_stat_user_tables;
An alternative is
select n.nspname as table_schema,
c.relname as table_name,
c.reltuples as rows
from pg_class c
join pg_namespace n on n.oid = c.relnamespace
where c.relkind = 'r'
and n.nspname = current_user
order by c.reltuples desc;
SQL Server
SELECT tab.name,
sum(par.rows)
FROM sys.tables tab INNER JOIN sys.partitions par
ON tab.object_id = par.object_id
WHERE schema_name(tab.schema_id) = current_user
Snowflake
SELECT t.table_schema, t.table_name, t.row_count
FROM information_schema.tables t
WHERE t.table_type = 'BASE TABLE'
AND t.table_schema = current_user
order by t.row_count desc;
The examples give above are some of the ways to obtain this information. As with most things, there can be multiple ways of doing it, and most people will have their preferred one which is based on their background and preferences.
As you can see from the code given above they are all very similar, with similar syntax, etc. The only thing different is the name of the data dictionary table/view containing the information needed. Yes, knowing what data dictionary views to query can be a little challenging as you switch between databases.
AUTO_PARTITION – Inspecting & Implementing Recommendations
In a previous blog post I gave an overview of the DBMS_AUTO_PARTITION package in Oracle Autonomous Database. This looked at how you can get started and to setup Auto Partitioning and to allow it to automatically implement partitioning.
This might not be something the DBAs will want to happen for lots of different reasons. An alternative is to use DBMS_AUTO_PARTITION to make recommendations for tables where partitioning will have a performance improvement. The DBA can inspect these recommendations and decide which of these to implement.
In the previous post we set the CONFIGURE function to be ‘IMPLEMENT’. We need to change that to report the recommendations.
exec dbms_auto_partition.configure('AUTO_PARTITION_MODE','REPORT ONLY');Just remember, tables will only be considered by AUTO_PARTITION as outlined in my previous post.
Next we can ask for recommendations using the RECOMMEND_PARTITION_METHOD function.
exec dbms_auto_partition.recommend_partition_method(
table_owner => 'WHISKEY',
table_name => 'DIRECTIONS',
report_type => 'TEXT',
report_section => 'ALL',
report_level => 'ALL');The results from this are stored in DBA_AUTO_PARTITION_RECOMMENDATIONS, which you can query to view the recommendations.
select recommendation_id, partition_method, partition_key
from dba_auto_partition_recommendations;RECOMMENDATION_ID PARTITION_METHOD PARTITION_KEY
-------------------------------- ------------------------------------------------------------------------------------------------------------- --------------
D28FC3CF09DF1E1DE053D010000ABEA6 Method: LIST(SYS_OP_INTERVAL_HIGH_BOUND("D", INTERVAL '2' MONTH, TIMESTAMP '2019-08-10 00:00:00')) AUTOMATIC D
To apply the recommendation pass the RECOMMENDATION_KEY value to the APPLY_RECOMMENDATION function.
exec dbms_auto_partition.apply_recommendation('D28FC3CF09DF1E1DE053D010000ABEA6');It might takes some minutes for the partitioned table to become available. During this time the original table will remain available as the change will be implemented using a ALTER TABLE MODIFY PARTITION ONLINE command.
Two other functions include REPORT_ACTIVITY and REPORT_LAST_ACTIVITY. These can be used to export a detailed report on the recommendations in text or HTML form. It is probably a good idea to create and download these for your change records.
spool autoPartitionFinding.html
select dbms_auto_partition.report_last_activity(type=>'HTML') from dual;
exit;AUTO_PARTITION – Basic setup
Partitioning is an effective way to improve performance of SQL queries on large volumes of data in a database table. But only so, if a bit of care and attention is taken by both the DBA and Developer (or someone with both of these roles). Care is needed on the database side to ensure the correct partitioning method is deployed and the management of these partitions, as some partitioning methods can create a significantly large number of partitions, which in turn can affect the management of these and possibly performance too, which is not what you want. Care is also needed from the developer side to ensure their code is written in a way that utilises the partitioning method deployed. If doesn’t then you may not see much improvement in performance of your queries, and somethings things can run slower. Which not one wants!
With the Oracle Autonomous Database we have the expectation it will ‘manage’ a lot of the performance features behind the scenes without the need for the DBA and Developing getting involved (‘Autonomous’). This is kind of true up to a point, as the serverless approach can work up to a point. Sometimes a little human input is needed to give a guiding hand to the Autonomous engine to help/guide it towards what data needs particular focus.
In this (blog post) case we will have a look at DBMS_AUTO_PARTITION and how you can do a basic setup, config and enablement. I’ll have another post that will look at the recommendation feature of DBMS_AUTO_PARTITION. Just a quick reminder, DBMS_AUTO_PARTITION is for the Oracle Autonomous Database (ADB) (on the Cloud). You’ll need to run the following as ADMIN user.
The first step is to enable auto partitioning on the ADB using the CONFIGURE function. This function can have three parameters:
- IMPLEMENT : generates a report and implements the recommended partitioning method. (Autonomous!)
- REPORT_ONLY : {default} reports recommendations for partitioning on tables
- OFF : Turns off auto partitioning (reporting and implementing)
For example, to enable auto partitioning and to automatically implement the recommended partitioning method.
exec DBMS_AUTO_PARTITION.CONFIGURE('AUTO_PARTITION_MODE', 'IMPLEMENT');The changes can be inspected in the DBA_AUTO_PARTITION_CONFIG view.
SELECT * FROM DBA_AUTO_PARTITION_CONFIG;When you look at the listed from the above select we can see IMPLEMENT is enabled
The next step with using DBMS_AUTO_PARTITION is to tell the ADB what schemas and/or tables to include for auto partitioning. This first example shows how to turn on auto partitioning for a particular schema, and to allow the auto partitioning (engine) to determine what is needed and to just go and implement that it thinks is the best partitioning methods.
exec DBMS_AUTO_PARTITION.CONFIGURE(
parameter_name => 'AUTO_PARTITION_SCHEMA',
parameter_value => 'WHISKEY',
ALLOW => TRUE);If you query the DBA view again we now get.
We have not enabled a schema (called WHISKEY) to be included as part of the auto partitioning engine.
Auto Partitioning may not do anything for a little while, with some reports suggesting to wait for 15 minutes for the database to pick up any changes and to make suggestions. But there are some conditions for a table needs to meet before it can be considered, this is referred to as being a ‘Candidate’. These conditions include:
- Table passes inclusion and exclusion tests specified by AUTO_PARTITION_SCHEMA and AUTO_PARTITION_TABLE configuration parameters.
- Table exists and has up-to-date statistics.
- Table is at least 64 GB.
- Table has 5 or more queries in the SQL tuning set that scanned the table.
- Table does not contain a LONG data type column.
- Table is not manually partitioned.
- Table is not an external table, an internal/external hybrid table, a temporary table, an index-organized table, or a clustered table.
- Table does not have a domain index or bitmap join index.
- Table is not an advance queuing, materialized view, or flashback archive storage table.
- Table does not have nested tables, or certain other object features.
If you find Auto Partitioning isn’t partitioning your tables (i.e. not a valid Candidate) it could be because the table isn’t meeting the above list of conditions.
This can be verified using the VALIDATE_CANDIDATE_TABLE function.
select DBMS_AUTO_PARTITION.VALIDATE_CANDIDATE_TABLE(
table_owner => 'WHISKEY',
table_name => 'DIRECTIONS')
from dual;If the table has met the above list of conditions, the above query will return ‘VALID’, otherwise one or more of the above conditions have not been met, and the query will return ‘INVALID:’ followed by one or more reasons
Check out my other blog post on using the AUTO_PARTITION to explore it’s recommendations and how to implement.
Postgres on Docker
Prostgres is one of the most popular databases out there, being used in Universities, open source projects and also widely used in the corporate marketplace. I’ve written a previous post on running Oracle Database on Docker. This post is similar, as it will show you the few simple steps to have a persistent Postgres Database running on Docker.
The first step is go to Docker Hub and locate the page for Postgres. You should see something like the following. Click through to the Postgres page.
There are lots and lots of possible Postgres images to download and use. The simplest option is to download the latest image using the following command in a command/terminal window. Make sure Docker is running on your machine before running this command.
docker pull postgresAlthough, if you needed to install a previous release, you can do that.
After the docker image has been downloaded, you can now import into Docker and create a container.
docker run --name postgres -p 5432:5432 -e POSTGRES_USER=postgres -e POSTGRES_PASSWORD=pgPassword -e POSTGRES_DB=postgres -d postgresImportant: I’m using Docker on a Mac. If you are using Windows, the format of the parameter list is slightly different. For example, remove the = symbol after POSTGRES_DB
If you now check with Docker you’ll see Postgres is now running on post 5432.
Next you will need pgAdmin to connect to the Postgres Database and start working with it. You can download and install it, or run another Docker container with pgAdmin running in it.
First, let’s have a look at installing pgAdmin. Download the image and run, accepting the initial requirements. Just let it run and finish installing.
When pgAdmin starts it looks for you to enter a password. This can be anything really, but one that you want to remember. For example, I set mine to pgPassword.
Then create (or Register) a connection to your Postgres Database. Enter the details you used when creating the docker image including username=postgres, password=pgPassword and IP address=0.0.0.0.
The IP address on your machine might be a little different, and to check what it is, run the following
docker ps -a
When your (above) connection works, the next step is to create another schema/user in the database. The reason we need to do this is because the user we connected to above (postgres) is an admin user. This user/schema should never be used for database development work.
Let’s setup a user we can use for our development work called ‘student’. To do this, right click on the ‘postgres’ user connection and open the query tool.
Then run the following.
After these two commands have been run successfully we can now create a connection to the postgres database, open the query tool and you’re now all set to write some SQL.
OML4R available on ADB
Oracle Machine Learning for R (OML4R) is available on Oracle Autonomous Database. Finally. After waiting for way, way too long we can now run R code in the Autonomous Database (in the Cloud). It’s based on using Oracle R Distribution 4.0.5 (which is based on R 4.0.5). This product was previously called Oracle R Enterprise, which I was a fan of many few years ago, so much so I wrote a book about it.
OML4R comes with all (or most) of the benefits of Oracle R Enterprise, whereby you can connect to, in this case an Oracle Autonomous Database (in the Cloud), allowing data scientists work with R code and manipulate data in the database instead of in their local environment. Embed R code in the database and enable other database users (and applications) to call this R code. Although with OML4R on ADB (in the Cloud) does come with some limitations and restrictions, which will put people/customers off from using it.
Waiting for OML4R reminds me of Eurovision Song Contest winning song by Johnny Logan titled,
I’ve been waiting such a long time
Looking out for you
But you’re not here
What’s another year
It has taken Oracle way, way too long to migrate OML4R to ADB. They’ve probably just made it available because one or two customers needed/asked it.
As the lyrics from Johnny Logan says (changing I’ve to We’ve), We’ve been waiting such a long time, most customers have moved to other languages, tools and other cloud data science platforms for their data science work. The market has moved on, many years ago.
Hopefully over the next few months, and with Oracle 23c Database, we might see some innovation, or maybe their data science and AI focus lies elsewhere within Oracle development teams.
Oralytics 
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