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July 28, 2024

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SQL Server 2022

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SQL Server 2022: Intelligent Query Processing Enhancements

SQL Server 2022 has ushered in a new era of database optimization, thanks to the remarkable advancements in Intelligent Query Processing (IQP). These enhancements are designed to automatically improve the performance of queries, making it easier to manage and optimize databases without extensive manual intervention. In this blog, we will delve into the latest IQP features, providing detailed explanations, examples, and code snippets to demonstrate their impact on query performance. Let’s explore these game-changing features! 🌟

1. Parameter Sensitive Plan Optimization (PSPO) 🔄

One of the common challenges in SQL Server query performance is parameter sniffing, where the query optimizer generates an execution plan based on the first parameter value it encounters. This can lead to suboptimal plans for subsequent executions with different parameter values. SQL Server 2022 introduces Parameter Sensitive Plan Optimization (PSPO) to address this issue.

How PSPO Works: PSPO allows SQL Server to create multiple execution plans for a single query, each tailored to different parameter values. This ensures that the most efficient plan is used for each specific scenario.

Example:

Consider the following query that retrieves orders based on CustomerID:

SELECT OrderID, OrderDate, TotalAmount
FROM Orders
WHERE CustomerID = @CustomerID;

Without PSPO, SQL Server might create a plan optimized for a specific CustomerID, potentially causing poor performance for other customers with different data distributions. With PSPO, SQL Server can store multiple plans, ensuring optimal performance across different parameter values.

2. Degree of Parallelism Feedback (DOP Feedback) 🔢

The Degree of Parallelism (DOP) determines how many threads SQL Server uses to execute a query. Incorrect DOP settings can lead to inefficient CPU usage and poor query performance. SQL Server 2022 introduces DOP Feedback, which dynamically adjusts the DOP based on actual runtime conditions.

How DOP Feedback Works: DOP Feedback monitors the performance of parallel queries and adjusts the DOP for subsequent executions, aiming to find the most efficient level of parallelism.

Example:

SELECT ProductID, SUM(Quantity) AS TotalQuantity
FROM Sales
GROUP BY ProductID;

For a query like this, SQL Server may initially choose a DOP based on its estimates. If the initial DOP is too high or too low, resulting in suboptimal performance, DOP Feedback will adjust it in future executions, optimizing both CPU utilization and query execution time.

3. Memory Grant Feedback (Persisted) 🧠

Memory Grant Feedback was first introduced in SQL Server 2017 to adjust memory grants dynamically based on actual execution requirements. SQL Server 2022 enhances this feature with persistence, meaning the adjustments are retained across query executions, even if the server restarts.

How Memory Grant Feedback (Persisted) Works: If a query is granted too much or too little memory, it can lead to resource contention or wasted resources. The persisted Memory Grant Feedback feature adjusts the memory grant size based on the query’s actual memory usage.

Example:

SELECT CustomerID, COUNT(*) AS OrderCount
FROM Orders
GROUP BY CustomerID;

If this query initially receives a larger memory grant than necessary, it may lead to wasted resources. Memory Grant Feedback will reduce the grant for future executions, improving resource utilization.

4. Query Store Hints 🎯

Query Store Hints provide a mechanism to apply hints to specific queries without modifying the source code. This feature is particularly useful for optimizing third-party applications or legacy code where you cannot directly alter the SQL statements.

How Query Store Hints Work: You can use Query Store Hints to influence the optimizer’s choices, such as forcing the use of a specific index or join type, without changing the application code.

Example:

Imagine you have a query that benefits from using a specific index:

SELECT * FROM Products
WHERE ProductName = 'Gadget';

You can apply a hint to force the use of a particular index:

EXEC sp_query_store_set_hints @query_id = 1, @hints = 'OPTION (FORCESEEK)';

This ensures that the query optimizer selects the most efficient execution plan, improving query performance.

5. Intelligent Query Processing (IQP) Mode 🚀

The IQP mode in SQL Server 2022 includes several key features that collectively enhance query performance. By enabling IQP mode, you automatically gain access to a suite of optimizations, including Adaptive Joins, Batch Mode on Rowstore, and more.

Key Features in IQP Mode:

Adaptive Joins: Dynamically choose between different join strategies based on runtime conditions.
Batch Mode on Rowstore: Use batch processing for rowstore data, significantly improving performance for certain workloads.
Approximate Query Processing: Speed up queries with approximate results where absolute precision is not required.

Enabling IQP Mode:

To enable IQP mode, use the following T-SQL commands:

ALTER DATABASE [YourDatabaseName] SET QUERY_STORE = ON;
ALTER DATABASE SCOPED CONFIGURATION SET LEGACY_CARDINALITY_ESTIMATION = OFF;
ALTER DATABASE SCOPED CONFIGURATION SET INTERLEAVED_EXECUTION_TVF = ON;
ALTER DATABASE SCOPED CONFIGURATION SET BATCH_MODE_ADAPTIVE_JOINS = ON;
ALTER DATABASE SCOPED CONFIGURATION SET BATCH_MODE_ON_ROWSTORE = ON;

This configuration ensures that your database leverages the latest IQP features, providing significant performance improvements for complex queries.

Conclusion 🎉

SQL Server 2022’s Intelligent Query Processing enhancements represent a significant leap forward in database performance optimization. Whether dealing with parameter-sensitive queries, complex joins, or memory-intensive operations, these features provide automated, data-driven solutions that enhance efficiency and performance.

By adopting these advancements, you can ensure that your SQL Server environment operates at peak performance, with minimal manual intervention. Explore these features in your SQL Server 2022 deployment and experience the transformative impact of Intelligent Query Processing! 🚀✨

For more tutorials and tips on SQL Server, including performance tuning and database management, be sure to check out our JBSWiki YouTube channel.

Thank You,
Vivek Janakiraman

Disclaimer:
The views expressed on this blog are mine alone and do not reflect the views of my company or anyone else. All postings on this blog are provided “AS IS” with no warranties, and confers no rights.

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Vivek Janakiraman

Posted on

July 24, 2024

Posted under

Core

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Understanding Max Server Memory and Minimum Server Memory in SQL Server

SQL Server’s memory management is a crucial aspect of its performance and stability. Two important settings in this context are Max Server Memory and Minimum Server Memory. These settings help SQL Server efficiently manage its memory usage, ensuring optimal performance and avoiding system instability.

What is Max Server Memory?

Max Server Memory limits the amount of memory that SQL Server can use for its operations. This setting helps prevent SQL Server from consuming too much memory, which could negatively impact the operating system and other applications running on the same server.

Importance of Max Server Memory

System Stability: By capping the memory usage, you ensure that enough memory is available for the OS and other applications, preventing system-wide slowdowns or crashes.
Performance Optimization: Properly configuring Max Server Memory allows SQL Server to use memory efficiently, reducing the need for frequent data disk reads and writes, which can significantly slow down performance.
Resource Allocation: In environments where SQL Server shares resources with other applications, setting an appropriate Max Server Memory ensures fair resource distribution.

Calculating and Setting Max Server Memory

To start, you should leave enough memory for the operating system and any other applications. A common approach is to allocate at least 4 GB or 10% of total system memory (whichever is larger) to the OS. The rest can be allocated to SQL Server as Max Server Memory.

Example Calculation: Suppose you have a server with 32 GB of RAM:

Allocate memory for the OS and other applications:
- 4 GB (minimum recommended) or 10% of 32 GB = 3.2 GB
- Choosing the larger value: 4 GB
Subtract this from the total RAM:
- 32 GB – 4 GB = 28 GB
Set Max Server Memory to 28 GB.

Setting Max Server Memory in SQL Server: You can set Max Server Memory using SQL Server Management Studio (SSMS) or T-SQL commands:

Using SSMS:
1. Open SSMS and connect to your SQL Server instance.
2. Right-click on the server name and select “Properties.”
3. Navigate to the “Memory” tab.
4. Set the “Maximum server memory (in MB)” to the calculated value.
Using T-SQL:

EXEC sp_configure 'show advanced options', 1;
RECONFIGURE;
EXEC sp_configure 'max server memory', 28672; -- Set to 28 GB (28 * 1024 MB)
RECONFIGURE;

What is Minimum Server Memory?

Minimum Server Memory specifies the minimum amount of memory SQL Server should attempt to reserve after it has started. However, it’s worth noting that SQL Server doesn’t start with this memory allocation; instead, it gradually grows its memory usage up to this amount as needed.

Importance of Minimum Server Memory

Ensuring Performance: Setting a minimum ensures that SQL Server has enough memory for its operations, which is crucial for maintaining performance under varying workloads.
Avoiding Memory Pressure: It helps avoid situations where SQL Server might have to give up memory under pressure, which could degrade performance.

Potential Issues with Incorrect Settings

Setting Max Server Memory Too High: This can lead to insufficient memory for the OS and other applications, causing system instability, swapping, and even crashes.
Setting Max Server Memory Too Low: SQL Server might not have enough memory for optimal performance, leading to excessive disk I/O, slower queries, and reduced throughput.
Incorrect Minimum Server Memory: If set too high, it can reserve more memory than necessary, potentially starving other processes. If set too low, SQL Server might not have enough resources to function efficiently under load.

Best Practices

Monitor and Adjust: Regularly monitor memory usage and adjust settings based on the workload and system performance.
Consider the Entire System: Take into account the memory requirements of the OS and other applications on the server.
Start Conservative: Begin with a conservative estimate and gradually increase Max Server Memory as needed, observing the system’s behavior.

In conclusion, correctly configuring Max Server Memory and Minimum Server Memory is vital for SQL Server’s performance and the overall system’s stability. By carefully calculating and setting these values, you can ensure a balanced and efficient use of resources, providing a stable and high-performing environment for your SQL Server workloads.

For more tutorials and tips on SQL Server, including performance tuning and database management, be sure to check out our JBSWiki YouTube channel.

Thank You,
Vivek Janakiraman

Posted by

Vivek Janakiraman

Posted on

February 17, 2024

Posted under

Replication

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Proactively Managing Transactional Replication Latency with SQL Server

Transactional replication is a critical component of many SQL Server environments, providing high availability, load balancing, and other essential benefits. However, managing replication latency, the delay between an action occurring on the publisher and it being reflected on the subscriber, is vital for ensuring system performance and data integrity. In this blog post, we’ll explore a proactive approach to monitor and alert on replication latency, helping database administrators (DBAs) maintain optimal system health.

The Issue:

Replication latency can sometimes go unnoticed until it impacts the system performance or data accuracy, leading to potential data loss or business disruptions. Traditional monitoring techniques may not provide real-time alerts or may require significant manual intervention, making them less effective for immediate latency identification and resolution.

The Script:

To address this challenge, we introduce a SQL script designed by Vivek Janakiraman from JBSWiki, specifically crafted to monitor transactional replication latency in SQL Server environments. This script efficiently posts tracer tokens to specified publications and measures the time taken for these tokens to move through the replication components, providing a clear picture of any latency present in the system.

/*
Author: Vivek Janakiraman
Company: JBSWiki
Description: This script is used to alert in case there is Transactional replication Log reader or distribution agent latency.
             It posts tracer tokens to specified publications and measures the latency to the distributor and subscriber.
*/

-- Switch to the publisher database to insert tracer tokens.
USE [Publisher_Database_Here]   -- Use your publisher database name here.
-- Insert tracer tokens into the specified publications.
EXEC sys.sp_posttracertoken @publication = 'Publication_Name' -- Change appropriate Publication that should be monitored.
EXEC sys.sp_posttracertoken @publication = 'Publication_Name1' -- Change appropriate Publication that should be monitored.
-- Wait for 5 minutes to allow the tokens to propagate.
WAITFOR DELAY '00:05:00'

-- Switch to the distribution database to query latency information.
USE distribution
;WITH LatestEntries AS (
       -- Select the latest entries for each publication and agent.
       SELECT publication_id, agent_id, MAX(publisher_commit) AS MaxDate       
       FROM MStracer_tokens t
       JOIN MStracer_history h ON t.tracer_id = h.parent_tracer_id
       GROUP BY publication_id, agent_id
)
-- Select latency information for the latest tokens.
SELECT c.name, t.publication_id, h.agent_id, t.publisher_commit,
       ISNULL(DATEDIFF(s,t.publisher_commit,t.distributor_commit), 299) as 'Time To Dist (sec)',
       ISNULL(DATEDIFF(s,t.distributor_commit,h.subscriber_commit), 299) as 'Time To Sub (sec)'
INTO #REPL_LATENCY
FROM MStracer_tokens t 
JOIN MStracer_history h ON t.tracer_id = h.parent_tracer_id
JOIN distribution.dbo.MSdistribution_agents c ON h.agent_id = c.id
JOIN LatestEntries le ON t.publication_id = le.publication_id AND h.agent_id = le.agent_id AND t.publisher_commit = le.MaxDate
ORDER BY t.publisher_commit DESC

-- Check if there is any latency beyond acceptable limits and select those records.
IF EXISTS (SELECT 1 FROM #REPL_LATENCY WHERE ([Time To Dist (sec)] > 30 OR [Time To Sub (sec)] > 30))
BEGIN
    SELECT name, publication_id, agent_id, publisher_commit, [Time To Dist (sec)], [Time To Sub (sec)]
    INTO #REPL_LATENCY_Email 
    FROM #REPL_LATENCY 
    WHERE ([Time To Dist (sec)] > 30 OR [Time To Sub (sec)] > 30)
END

-- Prepare the HTML body content for the email alert.
DECLARE @body_content NVARCHAR(MAX);
SET @body_content = N'
<style>
table.GeneratedTable {
  width: 100%;
  background-color: #D3D3D3;
  border-collapse: collapse;
  border-width: 2px;
  border-color: #A9A9A9;
  border-style: solid;
  color: #000000;
}
table.GeneratedTable td, table.GeneratedTable th {
  border-width: 2px;
  border-color: #A9A9A9;
  border-style: solid;
  padding: 3px;
}
table.GeneratedTable thead {
  background-color: #A9A9A9;
}
</style>
<table class="GeneratedTable">
  <thead>
    <tr>
         <th>name</th>
         <th>publication_id</th>
         <th>agent_id</th>
         <th>publisher_commit</th>
         <th>[Time To Dist (sec)]</th>
         <th>[Time To Sub (sec)]</th>
    </tr>
  </thead>
  <tbody>' +
CAST(
          (SELECT td = name, '',
                               td = publication_id, '',
                               td = agent_id, '',
                               td = publisher_commit, '',
                               td = [Time To Dist (sec)], '',
                               td = [Time To Sub (sec)], ''
        FROM [dbo].#REPL_LATENCY_Email
        FOR XML PATH('tr'), TYPE   
        ) AS NVARCHAR(MAX)
    ) +
  N'</tbody>
</table>';

-- Send an email alert if there is any latency issue found.
IF EXISTS (SELECT TOP 1 * FROM [dbo].#REPL_LATENCY_Email) 
BEGIN
    EXEC msdb.dbo.sp_send_dbmail @profile_name = 'JBSWIKI',
                                 @body = @body_content,
                                 @body_format = 'HTML',
                                 @recipients = 'jvivek2k1@yahoo.com',
                                 @subject = 'ALERT: Transactional Replication Latency Alert'; 
END

-- Cleanup temporary tables.
DROP TABLE #REPL_LATENCY
DROP TABLE #REPL_LATENCY_Email

The Solution:

The script works by first posting tracer tokens to the specified publications within the publisher database. It then waits for a predetermined amount of time (defaulted to 5 minutes in the script) to allow the tokens to propagate through the system. Following this, the script measures the latency to the distributor and subscriber, providing a detailed report of the time taken in each stage of the replication process.

This information is then used to generate an HTML-formatted email alert if the latency exceeds predefined thresholds (30 seconds in the provided script), allowing for immediate action to be taken. The use of HTML formatting in the email ensures that the information is presented in an easily digestible format, facilitating quick understanding and response by the DBA.

Conclusion:

Proactive monitoring and management of transactional replication latency are paramount for maintaining the health and performance of SQL Server environments. The script provided offers a straightforward and effective solution for DBAs to stay ahead of potential replication issues. By automating the process of latency detection and alerting, this approach not only saves valuable time but also helps in preventing the negative impact of replication latency on business operations.

Remember, while this script serves as a valuable tool in your monitoring arsenal, it’s also important to tailor the solution to your specific environment and requirements. Regularly reviewing and adjusting the latency thresholds and monitoring frequency will ensure you continue to get the most out of your replication setup.

For more tutorials and tips on SQL Server, including performance tuning and database management, be sure to check out our JBSWiki YouTube channel.

Thank You,
Vivek Janakiraman

JBs Wiki

Tag Archives: SQL Server Automation

SQL Server 2022: Intelligent Query Processing Enhancements

1. Parameter Sensitive Plan Optimization (PSPO) 🔄

2. Degree of Parallelism Feedback (DOP Feedback) 🔢

3. Memory Grant Feedback (Persisted) 🧠

4. Query Store Hints 🎯

5. Intelligent Query Processing (IQP) Mode 🚀

Conclusion 🎉

Understanding Max Server Memory and Minimum Server Memory in SQL Server

What is Max Server Memory?

Importance of Max Server Memory

Calculating and Setting Max Server Memory

What is Minimum Server Memory?

Importance of Minimum Server Memory

Potential Issues with Incorrect Settings

Best Practices

Proactively Managing Transactional Replication Latency with SQL Server

The Issue:

The Script:

The Solution:

Conclusion: