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Windows Performance Troubleshooting and Analysis

Join experts Daniel Pearson and David Solomon as they explore the components of performance analysis, tools for troubleshooting and analyzing performance issues, and techniques for troubleshooting CPU and memory issues. Learn from their years of experience at Microsoft and gain valuable insights into Windows performance.

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Windows Performance Troubleshooting and Analysis

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  1. Windows Performance Troubleshooting and Analysis Daniel Pearson David Solomon Expert Seminars

  2. Daniel Pearson • Started working with Windows NT 3.51 • Three years at Digital Equipment Corporation • Supporting Intel and Alpha systems running Windows NT • Seven years at Microsoft • Senior Escalation Lead in Windows base team • Worked in the Mobile Internet sustained engineering team • Instructor for David Solomon, co-author of the Windows Internalsbook series

  3. Agenda • Components of performance analysis • Understanding the tools for troubleshooting and analyzingperformance issues • Troubleshooting CPU and memory issues using variousWindows tools • Portions of this session are based on material developed byMark Russinovich and David Solomon

  4. Components of Performance Analysis • Event Tracing for Windows • Core component of the operating system • Kernel mode data structures • Used to store information about the system and system objects that can be read by various tools • e.g. dtnt!_KTHREADKernelTime • CPU performance monitoring events • Refer to the Intel 64 and IA-32 Architectures Software Developer’s Manual • http://developer.intel.com/products/processor/manuals

  5. Event Tracing for Windows • Built in to the system • High performance, low overhead and scalable • 2.5% CPU usage for a sustained rate of 10,000 events/sec ona 2 GHz CPU1 • Operations throughout the system that are of interest to performance are fully instrumented • e.g. process and thread activity, registry I/O, disk I/O Milirud, Michael. 2008. Windows Performance Analysis: Using Windows Performance Tools. Presented at Microsoft's WinHEC conference, November 5-7, Los Angeles, CA.

  6. Event Tracing for Windows • Uses a buffering and logging mechanism implemented in the kernel • Per-processor buffers that are written to disk by an asynchronous writer thread • Ability to enable and disable tracing dynamically • Supports a managed code provider

  7. Sysinternals Utilities

  8. Sysinternals Utilities • Process Explorer • Useful for displaying which files, registry keys and other objects processes have open and which DLLs they have loaded • Process Monitor • Useful for showing real-time file system, registry and process & thread activity • Available for download from the TechNet site • http://technet.microsoft.com/sysinternals

  9. Resource Monitor

  10. Resource Monitor • Included with Windows Vista and greatly enhanced in Windows 7 and Windows Server 2008 R2 • Allows the viewing of CPU, memory, disk and network resources as well as handles and modules in real time • Ability to end, suspend and resume processes as well as to start, stop and restart Windows services • Useful for identifying the highest resource consumers by individual resource type, e.g. CPU • Able to list the wait chain tree of a process to determine if a process is waiting on another

  11. Using Resource Monitor

  12. Performance Monitor

  13. Performance Monitor • Queries performance counters that measure system state or activity • Current values are read at specific intervals • Performance counters are included in the operating system and can be included as part of applications • Able to collect event trace data from trace providers that report actions or events • Can combine multiple trace providers into a single session • Configuration information can be collected from registry keys at a specific time or interval

  14. Using Performance Monitor

  15. Windows Performance Analyzer

  16. Windows Performance Analyzer • Part of the Windows Performance Toolkit • Support for both x86, x64, and IA64 architectures • Consists of three primary programs • xperf.exe • Used for controlling tracing and processing trace data • xbootmgr.exe • Automates on and off state transitions and captures traces during those transitions • xperfview.exe • A graphical trace visualization tool to represent data in the form of interactive graphs and summary tables

  17. Windows Performance Analyzer • Primarily uses the Event Tracing for Windows infrastructure built in to the system • Can be enabled or disabled at any time without requiring a system or process restart • Supports symbol decoding, sample profiling, and recording of call stacks on kernel events • Designed to be used during automation • All the functions of the tools are available via the command line tool xperf.exe

  18. Support for Earlier Systems • The Windows Performance Toolkit will fail to install on Windows XP and on Windows Server 2003 although data collection is supported • Copy xperf.exe and perfctrl.dll • Trace analysis is only supported on Windows Vista and later systems

  19. Capturing a Performance Trace • Kernel options divided into two parts • Kernel Flags • Identified by the use of uppercase characters • e.g. PROC_THREAD, LOADER, PROFILE • Kernel Groups • Indentified by the use of title case characters • e.g. Base, Diag, Latency, FileIO • Kernel Groups are made up of a collection of Kernel Flags • e.g. SysProf = PROC_THREAD+LOADER+PROFILE • Flags and groups are separated by the ‘+’ token • e.g. xperf.exe -on FileIO+DISK_IO_INIT

  20. Merging of Performance Trace Data • Traces can be copied to another system for analysis • The trace file should be “merged” on the collection system before analysis to include additional system information • xperf -d trace.etl System and symbolinformation Trace Merged trace Kernel trace XPerf

  21. Using the Windows Performance Toolkit

  22. Understanding CPU Activity • Windows uses 32 priority levels • The system implements a preemptive, priority driven scheduler • Priority adjustments can be applied to threads in the “dynamic” range • At least one runnable thread with the highest priority will be running 31 Real time 16 15 Dynamic 0

  23. Context Switching • A switch from one thread to another is known as a context switch • Switching involves saving the hardware state of a thread and restoring the state of another • When a thread is scheduled, that thread’s context switch count isalso incremented • The context switch count represents how often a thread begins running, not how long it ran

  24. Time Accounting Quirks • Looking at total CPU time for each process may not reveal where the system has spent its time • CPU time accounting is driven by an interrupt timer which is set by the Hardware Abstraction Layer • Usually at either 10 or 15 msec intervals • Thread execution and context switches that happen between clock intervals are not accounted for • e.g. a thread runs and enters a wait before the clock fires • Thus threads may run but never get charged

  25. Time Accounting Prior to Windows Vista • Windows accounted for CPU time based on the interval clock timer • Thread quantum expiration was not always fair • A thread might get almost no turn • Threads were also charged for interrupts that occurred while they were running Idle T1 T2 Idle T2

  26. Time Accounting Since Windows Vista • Windows Vista and later reads the Time Stamp Counter during every context switch • The actual CPU cycles consumed are charged to a thread • Any interrupt time is not charged to the interrupted thread • Allows for more accurate quantum accounting • A thread gets at least one turn and at most will be given one turn plus an additional tick Idle T1 T1 T2 Idle

  27. Troubleshooting HighCPU Utilization

  28. Understanding Memory Management • Windows provides two system memory pools • Nonpaged Pool and Paged Pool • Used for system wide persistent data • Prior to Windows Vista, pool sizes were a function of memory size and whether or not the system was configured as a server or a workstation • Windows Vista introduced the concept of a dynamic systemaddress space

  29. Dynamic System Address Space • In 32-bit Windows Vista and later, virtual memory is assigned as needed • Permits larger paged, nonpaged, and session pools • Components still cannot exceed 2 GB on 32-bit systems • On 64-bit systems, address space regions are configured to their current maximum limits for all memory sizes

  30. TroubleshootingMemory Leaks

  31. Additional Information • Windows Internals 5th edition • Windows Performance Analysis Developer Center • http://msdn.microsoft.com/performance • Windows Server Performance Team Blog • http://blogs.technet.com/winserverperformance • Ask the Performance Team Blog • http://blogs.technet.com/askperf

  32. Additional Information • David Solomon Expert Seminars offers trainingon Windows Internals both as public and private workshops and public webinars via the Internet • Currently scheduled up and coming classes • Public workshop in London, April 12th – April 16th • Public webinar, April 26th & April 28th • Public workshop in New York, May 3rd – May 7th • Public workshop in San Francisco, November 8th – November 12th • Visit http://www.solsem.com for further course descriptions and up to date information

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