Receive Window Auto-tuning Level Registry

Jan 20, 2019 Windows 10 have an auto-tuning feature which tries to dynamically adjust the receive buffer size for transmission and latency of the link. In-fact this feature is present in all Modern Operating systems including Windows 10. Mar 29, 2010  TCP Auto-Tuning To turn off the default RWIN auto tuning behavior, (in elevated command prompt) type: netsh int tcp set global autotuninglevel=disabled The default auto-tuning level is 'normal', and the possible settings for the above command are: disabled: uses a fixed value for the tcp receive window. Limits it to 64KB (limited at 65535).

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Oct 08, 2016  Bad Tweak – Disable Receive Window Auto-Tuning October 8, 2016, 11:11(EDT) By Eric (a.k.a. TweakHound) A reader just commented on this so this is a quickie article to debunk this “tweak”.

Applies To: Windows Server 2012

To change the value for Receive Window Auto-Tuning Level parameter in Windows, run an administrator command prompt, and then type in one of the following commands, depending on your preference how you want Windows to use the RWIN size. Netsh interface tcp set global autotuninglevel=disabled Disable the autotunning feature in Windows completely, and fit and lock the RWIN receive window to. The Receive Window Auto-Tuning feature is enabled for HTTP traffic if the TcpAutotuning registry entry is set to 1. The Receive Window Auto-Tuning feature is not enabled for HTTP traffic if the TcpAutotuning registry entry does not exist or if it is set to a value that is not 1.

THE INFORMATION IN THIS ARTICLE APPLIES TO: All Windows products; DISCUSSION. Tuning Windows for TCP/IP performance isn't specific to any one Globalscape product. Rather, it depends on which version of Windows you are using. Therefore, rather than listing the various options here, please refer to the Google search results listed here, which provides relevant links with information about. Aug 12, 2016 Like all modern operating systems Windows has receive window auto-tuning to dynamically adjust the receive buffer size to the throughput and latency of the link. Disabling this feature will definitely limit your Internet speeds. Auto-tuning is consistent throughout all variants of TCP and present in all modern operating systems.

This topic contains the following sections.

Determining the correct tuning settings for your network adapter depend on the following variables:

  • The network adapter and its feature set

  • The type of workload performed by the server

  • The server hardware and software resources

  • Your performance goals for the server

If your network adapter provides tuning options, you can optimize network throughput and resource usage to achieve optimum throughput based on the parameters described above.

The following sections describe some of your performance tuning options.

Enabling Offload Features

Turning on network adapter offload features is usually beneficial. Sometimes, however, the network adapter is not powerful enough to handle the offload capabilities with high throughput. For example, enabling segmentation offload can reduce the maximum sustainable throughput on some network adapters because of limited hardware resources. However, if the reduced throughput is not expected to be a limitation, you should enable offload capabilities, even for this type of network adapter.

Note

Some network adapters require offload features to be independently enabled for send and receive paths.

Enabling Receive Side Scaling (RSS) for Web Servers

RSS can improve web scalability and performance when there are fewer network adapters than logical processors on the server. When all the web traffic is going through the RSS-capable network adapters, incoming web requests from different connections can be simultaneously processed across different CPUs.

It is important to note that due to the logic in RSS and Hypertext Transfer Protocol (HTTP) for load distribution, performance might be severely degraded if a non-RSS-capable network adapter accepts web traffic on a server that has one or more RSS-capable network adapters. In this circumstance, you should use RSS-capable network adapters or disable RSS on the network adapter properties Advanced Properties tab. To determine whether a network adapter is RSS-capable, you can view the RSS information on the network adapter properties Advanced Properties tab.

RSS Profiles and RSS Queues

RSS predefined profiles are new in Windows Server 2012.

The default profile is NUMA Static, which changes the default behavior from previous versions of the operating system. To get started with RSS Profiles, you can review the available profiles to understand when they are beneficial and how they apply to your network environment and hardware.

For example, if you open Task Manager and review the logical processors on your server, and they seem to be underutilized for receive traffic, you can try increasing the number of RSS queues from the default of 2 to the maximum that is supported by your network adapter. Your network adapter might have options to change the number of RSS queues as part of the driver.

Increasing Network Adapter Resources

For network adapters that allow manual configuration of resources, such as receive and send buffers, you should increase the allocated resources. Some network adapters set their receive buffers low to conserve allocated memory from the host. The low value results in dropped packets and decreased performance. Therefore, for receive-intensive scenarios, we recommend that you increase the receive buffer value to the maximum.

Note

If a network adapter does not expose manual resource configuration, it either dynamically configures the resources, or the resources are set to a fixed value that cannot be changed.

Enabling Interrupt Moderation

To control interrupt moderation, some network adapters expose different interrupt moderation levels, buffer coalescing parameters (sometimes separately for send and receive buffers), or both.

You should consider interrupt moderation for CPU-bound workloads, and consider the trade-off between the host CPU savings and latency versus the increased host CPU savings because of more interrupts and less latency. If the network adapter does not perform interrupt moderation, but it does expose buffer coalescing, increasing the number of coalesced buffers allows more buffers per send or receive, which improves performance.

Performance Tuning for Low Latency Packet Processing

Many network adapters provide options to optimize operating system-induced latency. Latency is the elapsed time between the network driver processing an incoming packet and the network driver sending the packet back. This time is usually measured in microseconds. For comparison, the transmission time for packet transmissions over long distances is usually measured in milliseconds (an order of magnitude larger). This tuning will not reduce the time a packet spends in transit.

Receive window auto tuning

Following are some performance tuning suggestions for microsecond-sensitive networks.

  • Set the computer BIOS to High Performance, with C-states disabled. However, note that this is system and BIOS dependent, and some systems will provide higher performance if the operating system controls power management. You can check and adjust your power management settings from Control Panel or by using the powercfg command. For more information, see Powercfg Command-Line Options

  • Set the operating system power management profile to High Performance System. Note that this will not work properly if the system BIOS has been set to disable operating system control of power management.

  • Enable Static Offloads, for example, UDP Checksums, TCP Checksums, and Send Large Offload (LSO).

  • Enable RSS if the traffic is multi-streamed, such as high-volume multicast receive.

  • Disable the Interrupt Moderation setting for network card drivers that require the lowest possible latency. Remember, this can use more CPU time and it represents a tradeoff.

  • Handle network adapter interrupts and DPCs on a core processor that shares CPU cache with the core that is being used by the program (user thread) that is handling the packet. CPU affinity tuning can be used to direct a process to certain logical processors in conjunction with RSS configuration to accomplish this. Using the same core for the interrupt, DPC, and user mode thread exhibits worse performance as load increases because the ISR, DPC, and thread contend for the use of the core.

System Management Interrupts

Many hardware systems use System Management Interrupts (SMI) for a variety of maintenance functions, including reporting of error correction code (ECC) memory errors, legacy USB compatibility, fan control, and BIOS controlled power management. The SMI is the highest priority interrupt on the system and places the CPU in a management mode, which preempts all other activity while it runs an interrupt service routine, typically contained in BIOS.

Unfortunately, this can result in latency spikes of 100 microseconds or more. If you need to achieve the lowest latency, you should request a BIOS version from your hardware provider that reduces SMIs to the lowest degree possible. These are frequently referred to as “low latency BIOS” or “SMI free BIOS.” In some cases, it is not possible for a hardware platform to eliminate SMI activity altogether because it is used to control essential functions (for example, cooling fans).

Note

The operating system can exert no control over SMIs because the logical processor is running in a special maintenance mode, which prevents operating system intervention.

Performance Tuning TCP

You can performance tune TCP using the following items.

Details are provided in the following sections.

TCP Receive Window Auto-Tuning

Prior to Windows Server 2008, the network stack used a fixed-size receive-side window that limited the overall potential throughput for connections. One of the most significant changes to the TCP stack is TCP receive window auto-tuning. You can calculate the total throughput of a single connection when you use this fixed size default as:

Total achievable throughput in bytes = TCP window * (1 / connection latency)

For example, the total achievable throughput is only 51 Mbps on a 1 GB connection with 10 ms latency – which is a reasonable value for a large corporate network infrastructure.

Auto-tuning

With auto-tuning, however, the receive-side window is adjustable, and it can grow to meet the demands of the sender. It is entirely possible for a connection to achieve the full line rate of a 1 GB connection. Network usage scenarios that might have been limited in the past by the total achievable throughput of TCP connections can now fully use the network.

Windows Filtering Platform

The Windows Filtering Platform (WFP) that was introduced in Windows Vista and Windows Server 2008 provides APIs to non-Microsoft independent software vendors (ISVs) to create packet processing filters. Examples include firewall and antivirus software.

Note

A poorly written WFP filter can significantly decrease a server’s networking performance.

Receive Window Auto-tuning Level Registry Online

For more information, see Windows Filtering Platform in the Windows Dev Center.

TCP Parameters

The following registry keywords from Windows Server 2003 are no longer supported, and they are ignored in Windows Server 2012, Windows Server 2008 R2, and Windows Server 2008.

  • TcpWindowSize

  • NumTcbTablePartitions

  • MaxHashTableSize

Receive window auto-tuning level registry 2017


If you use Microsoft Office Outlook 2007 or Microsoft Outlook 2010 there is an annoying problem. If you are trying to download an e-mail message bigger than 1MB, you will have to wait too much. Also, if you want to sent an e-mail using a SMTP server you will receive the following error: “Sending and Receiving’ reported error (0x800CCC0F) : ‘The connection to the server was interrupted. If this problem continues, contact your server administrator or Internet service provider (ISP)’ “. This happens if you have a router that doesn’t supports TCP Window Scaling.

First you will have to make sure that the problem is caused by a network hardware device that does not support TCP Window Scaling. This is how you will do it:

Receive Window Auto-tuning Level Registry Windows 10

1.Run Command Prompt as an Administrator

2. Enter this command: netsh interface tcp show global

Receive Window Auto-tuning Level Registry 2017

3. Look for Receive Window Auto-Tuning Level. You will have to see what value is written there. If you don’t know what to choose, use the following command: netsh interface tcp set global autotuninglevel=disabled.

You can choose between 5 values: disabled( sets the receive window at the default value), highlyrestricted (lets the receive window grow beyond the default value, but does so very conservatively), restricted (it is similar with highlyrestricted, but limits the growth only in some scenarious), normal (lets the receive window grow to accommodate most scenarios) and experimental (lets the receive window grow to accommodate extreme scenarios).

Receive Window Auto-tuning Level Registry List

4. Restart your computer and see if the problem is solved. You can also try other values to see which one is perfect for you.