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Debugging Threads in Intel Parallel Studio
Group Members
Intel® Parallel Studio XE
Intel Parallel Studio XE is a software development tool suite for compiling applications and optimizing performance with less effort.
The Intel C++ Compiler is not the only tool that comes with IPS XE 2019. It also includes next applications:
- Intel® Advisor
- Intel® Inspector
- Intel® VTune™ Amplifier
Let's take a quick look at each of them:
Intel® Advisor
Vectorization optimization and thread prototyping.
Use this tool in the vectorization and threading stages of the flow.
Intel® Inspector
Memory and thread debugger.
Use this tool to find races, deadlocks, and illegal memory accesses.
- Locate root cause errors early―before you release
- Quickly debug intermittent races and deadlocks
Intel® VTune™ Amplifier
Performance profiler.
Use this tool in the threading and bandwidth optimization stages and for advanced vectorization optimization.
- Save money: Locate root cause errors early―before you release
- Save time: Quickly debug intermittent races and deadlocks
Intel Inspector
Intel Inspector is a dynamic memory and threading error checking instrument to inspect serial and multi-threaded programs.
Intel Inspector comes with Intel Parallel Studio XE along with two other debugging tools - VTune and Advisor.
Create a project
There are 2 ways to work with inspector.
- Run inspector directly from Visual Studio
This is the easiest and fastest way that requires no additional configurations.
- Run as a separate program.
Working with Intel Inspector application requires passing it a compiled version of your program. Additionally you may need to link some libraries (lib, dll, etc).
Configure a project
Intel suggests using small data set sizes and load threads with small chunks of work..
This will reduce run time and the speed of the analysis.
Choose analysis type
Inspector allows you to choose between predefined types of analysis.
Choose the type of Analysis using a drop-down menu (2):
- Memory error analysis
- Detect leaks
- Detect Memory problems
- Locate memory problems
- Threading error analysis
- Detect deadlocks
- Detect deadlocks and data races
- Locate deadlocks and data races
- Custom analysis types - users can create their own types based on selected preset type.
Use a slider (3) to select a predefined analysis type.
Types at the the top have smaller a scope but faster in execution;
Types at the the bottom have larger a scope but they are considerably slower;
Edit settings of the analysis in the settings section (4)
How it works
Inspector performs the analysis in multiple steps:
1. The program is executed
2. It identifies problems that may need to be resolved.
3. Gathers problems.
4. Converts symbol information into filenames and line numbers.
5. Applies suppression rules.
6. Removes duplicates.
7. Creates problem sets.
8. Opens a debugging session.
Interpreting results
After the analysis completes, IPS XE Inspector will show you information on 2 pages:
- Collection Log
Gives a general information about the execution of the program.
From there you can see the execution time, number of threads, the caller of threads, if they were active or not.
- Summary
The Summary window is divided into 4 parts:
1) Problems section.
It shows problems (if any found) that we asked the Inspector to look for.
It provides you with a name of the problem, the file where the problem is located, the executable module which contains it, and the state of problem (which changes when do you a rescan).
2) Filters (On the right side of the Problems section)
Gives the summary of all problems (Source files affected, total of problems by type, etc)
3) Code locations
When we select a problem, code locations will show a preview of a source file and highlights the line on which the problems was detected!
Moreover it shows the operation that is performed (Read, Write), including thread operations.
4) Timeline
Shows threads that involved at the certain step.
Memory leak problem : https://www.codeproject.com/Tips/1184749/Allocating-Memory-in-C-Cplusplus-How-to-Avoid-Memo
Intel VTune™ Amplifier
Introduction
Intel VTune amplifier is a analysis software that allows you the ability to measure performance of your serial or multithreaded program. VTune allows you to analyze the performance of your algorithms and multithreading. It can help with debugging threads by calculating overhead, finding bottlenecks or inefficiencies.
Create a project
I will be explaining how to use VTune part Intel® Parallel Studio XE 2019 of the alongside Visual Studio 2017. Intel® Parallel Studio XE can be found here: https://software.intel.com/en-us/parallel-studio-xe. Once installed you will be able to find VTune in the tools tab inside Visual Studio.
Configure a project
When you hover over Intel VTune Amplifier 2019 in the tool’s menu. You will see more options appear. Select configure Analysis.
The following screen will be displayed. Click on the three little dots circled in the below picture. To expand more options for running VTune.
This menu will appear, it contains different tests that you can run against your program. The I am going to look through is the default test Hotspots. Depending on your program you may want too to look into the other options.
How it works
On the main page we can run the test, by clicking on the blue play button.
When the test completes, the summary page will be displayed. This will outline the results from the test.
Interpreting results
The following picture is the different tabs available from a hotspot analysis.
- Analysis configuration
- Main configuration page for VTune
- Collection log
- Logs from the analysis
- Summary
- Elapsed Time: this is the amount of time your program took to run
- The CPU time: displays the effective, spin and overhead times.
- Top Hotspots: Displays the area’s that were most active in your program.
- Effective CPU Utilization Histogram: This shows the time your program spent using x number of threads. The graph shows x axis is the moments that your program was a certain number of threads. And the y axis is the time that your program used that number of threads for.
- Collection and Platform Info: this display’s all the hardware information about the computer the test was run on.
- Elapsed Time: this is the amount of time your program took to run
- Bottom-up
- Allows you to se the call stack of a function starting from the first call.
- Caller/Callee
- Allows you to see details on each function and see callers and callees for each function
- Top-down tree
- Shows the call stack of the program as a tree starting from the top.
- Platform
- Displays the time and the utilization of each thread.