When you discover authentication time-outs or delays (also known as MaxConcurrentApi bottlenecks) in an environment, the typical way to resolve the problem is to raise the maximum allowed worker threads that service that authentication. You do this by altering the MaxConcurrentApi registry value and then restarting the Net Logon service on the servers.
Identifying which servers are victims of the bottleneck and which servers are actually the source of the bottleneck delays can be difficult. This article describes how to do performance tuning for NT LAN Manager (NTLM) authentication by using the MaxConcurrentApi setting. This article contains guidance for administrators in identifying the servers on which to raise the MaxConcurrentApi value and the amount to which that value should be set.
Note The CSS MaxConcurrentApi Diagnostic will detect the presence of MaxConcurrentApi issues and calculate the best MaxConcurrentApi setting for a server automatically. It uses the formula outlined in this article. More information on the diagnostic is available in the article below:
2714382 Problems Detected in MaxConcurrentApi Check (SDP)
The only performance data counters that can consistently show the authentication bottleneck are the Net Logon performance object counters. By default, these counters are present in Windows Server 2008 and in later versions of Windows. The Net Logon performance object is discussed in more detail in the following article in the Microsoft Knowledge Base:
There are Netlogon Events available that report NTLM authentication problems, see:
2654097 New event log entries that track NTLM authentication delays and failures in Windows Server 2008 R2 are available
The Events indicate activity for two counters:
- Events 5818/5819: There are "Sempahore Waiters", if the events are enabled.
- Events 5816/5817: There are "Sempahore Timeouts".
In order to determine the best MaxConcurrentApi value for your servers, several data points must be brought together and calculated by using a formula. The data to be used to estimate MaxConcurrentApi is as follows:
- Net Logon semaphore acquires
- Net Logon semaphore time-outs
- Net Logon average semaphore hold time
- Duration of the performance logging that is completed, measured in seconds
Note The placeholders semaphore_acquires and semaphore_time-outs represent cumulative numbers that indicate how many time-outs occurred during the lifetime of a security channel. Therefore, the numbers will most likely not start at zero in the data that is collected. The starting number must be subtracted from the ending number when you use Line View in the Performance Monitor (Perfmon.msc). Then, you use this calculated number in the formula for the new MaxConcurrentApi setting. To determine the number of time-outs that occurred during data collection, use Line View in Perfmon.msc, and rest the mouse pointer over the line for that counter at the end and the start, and then subtract the starting number from the ending number. That result is the number to put into the equation.
The average semaphore hold time can be determined by changing the default view from Line View to Report View in Perfmon.msc. For example, consider the following scenario:
- The semaphore acquires value is 8,286.
- The semaphore time-outs value is 883.
- The average semaphore hold time is .5 (that is, a half second).
- The duration of reporting is 90 seconds.
If the value that is derived from the formula is 150 or larger, you should add more servers to service the legacy authentication load.
If the value is less than 150, you should alter the MaxConcurrentApi registry value on that server to the value that is suggested by the formula or to a larger value.
Note If you decide to increase the MaxConcurrentApi value to greater than 10, the load and the performance of the desired setting should be tested in a nonproduction environment before you implement the change in a production environment. This is recommended to make sure that increasing this value does not cause other resource bottlenecks. Additionally, be aware that load conditions may change based on each scenario and business environment. Therefore, the MaxConcurrentApi value may have to have a different setting at a later date if the service load changes.
To change the MaxConcurrentApi setting, follow these steps:
- Click Start, click Run, type regedit, and then click OK.
- Locate and then click the following registry subkey: HKEY_LOCAL_MACHINE\SYSTEM\CurrentControlSet\Services\Netlogon\Parameters
- On the Edit menu, point to New, and then click DWORD Value.
- Type MaxConcurrentApi, and then press Enter.
- On the Edit menu, click Modify.
- Type the new MaxConcurrentApi setting in decimal, and then click OK.
- At a command prompt, type the following command, and then press Enter: net stop netlogon
- Type the following command, and then press Enter: net start netlogon
The counters for semaphore acquires, for semaphore time-outs, and for average semaphore hold time must be reviewed on all application servers, domain controllers, and trusted domain controllers that are involved in servicing client requests.
The performance data must be tracked while the servers are under heavy load. Heavy load occurs when the servers see the most client requests. For example, in an email server scenario, the best time to collect the performance data is when users arrive at work and check their email messages.
Additional items for consideration are as follows:
- No values mean no action is needed. The Semaphore Holders and Semaphore Hold Time counters will not show any values unless there is sustained load on a server. If there are no values present, no change in the MaxConcurrentApi value is needed.
- One size does not fit all. The MaxConcurrentApi value may have to be a different value for each server. This situation can be caused by multiple application servers gaining authentication from a single domain controller or by similar scenarios in which multiple servers provide a larger volume of load with which the domain controller must deal.
- Trusts. If the users who are being authenticated are from trusted domains, this can cause longer delays, because the local domain controller must wait for the reply from the trusted domain controller before the local domain controller provides the response to the application server.
- Network latency. Network latency can also play a major part in causing MaxConcurrentApi bottlenecks. This can occur when the MaxConcurrentApi semaphore uses a time-based time-out counter so that clients do not wait indefinitely for legacy authentication.
- Collocation. If network latency exists and is causing delays and bottlenecks in completing MaxConcurrentApi threads, a common solution is to put the servers in the same physical location so that network latency is reduced. In a domain model in which a trusted domain has Microsoft Exchange CAS servers, for example, and the user's domain is in another region or Active Directory site, this would mean putting the user's domain controllers into the same physical location and Active Directory site as the Exchange CAS servers and their domain controllers.
- Possible downstream delay. If the Semaphore Waiters counter value is continually greater than 0 (zero) for any time and the Semaphore Holders value is less than the MaxConcurrentApi setting on that server, the bottleneck is not located on that server. In this case, look to the domain controller that is cited in the counter name that is listed as a host computer fully qualified domain name. That domain controller’s Semaphore Waiters and Semaphore Holders performance data should be reviewed.
- Changes in load or in network configuration. Future changes in the load that is being serviced or in network configurations may produce network latency and could lead to a need for gauging the correct MaxConcurrentApi setting again. For environments in which legacy authentication volume is seen to the extent that MaxConcurrentApi settings are being examined, we strongly recommend that you continually monitor and review the Net Logon performance object counters. You can do this by using scheduled custom Perfmon.msc data collectors, by using Microsoft System Center Operations Manager, or by using other methods.
- Windows Server 2008 maximum. The maximum setting that is allowed for MaxConcurrentApi in Windows Server 2008 and in later versions of Windows is 150. You must apply the hotfix that is described in the following Knowledge Base article to have the 150 maximum available setting if the server that you are using is not running Windows Server 2008 R2: 975363 You are intermittently prompted for credentials or experience time-outs when you connect to Authenticated Services
- Windows Server 2003 maximum. The maximum setting that is allowed for MaxConcurrentApi in Windows Server 2003 and in earlier versions is 10.
- Windows Server 2012 and newer Defaults. The default for MaxConcurrentApi has been changed in Windows Server 2012. It is 10 for member Servers and Domain Controllers. It remains at 1 for member Workstations.
- Windows Server 2003 and performance counters. The original release of Windows Server 2003 did not contain the Net Logon performance counters. They have to be added by applying a hotfix. For more information about how to add these counters, click the following article number to view the article in the Microsoft Knowledge Base: 928576 New performance counters for Windows Server 2003 let you monitor the performance of Netlogon authentication
Additionally, it is very likely that legacy authentication performance time-outs that are related to MaxConcurrentApi will be seen but not reflected in any performance counter other than the Net Logon counter. This means that other performance metrics such as CPU use and disk and network use may show no load even though the MaxConcurrentApi load is heavy and users are having problems.
An additional minimizing procedure can be performed on domain controllers that have entries in their Net Logon service debug log that indicate that clients are submitting <null>\username instead of domainname\username. This procedure is described in the following article in the Microsoft Knowledge Base:
ID článku: 2688798 – Posledná kontrola: 20. 1. 2017 – Revízia: 2