Visible to Intel only — GUID: GUID-BB9D226C-3BD1-435A-995D-CDA11912C433
Tracing Conventional MPI Applications
Tracing Failing MPI Applications
Tracing OpenSHMEM* Applications
Tracing MPI File IO
Handling of Communicator Names
Tracing MPI Load Imbalance
Tracing User Defined Events
Configuring the Collector
Filtering Trace Data
Recording OpenMP* Regions Information
Tracing System Calls (Linux* OS)
Collecting Lightweight Statistics
Recording Source Location Information
Recording Hardware Performance Information (Linux* OS)
Recording Operating System Counters
Tracing Library Calls
Correctness Checking
Tracing Distributed Non-MPI Applications
ACTIVITY
ALTSTACK
AUTOFLUSH
CHECK
CHECK-LEAK-REPORT-SIZE
CHECK-MAX-DATATYPES
CHECK-MAX-ERRORS
CHECK-MAX-PENDING
CHECK-MAX-REPORTS
CHECK-MAX-REQUESTS
CHECK-SUPPRESSION-LIMIT
CHECK-TIMEOUT
CHECK-TRACING
CLUSTER
COMPRESS-RAW-DATA
COUNTER
CURRENT-DIR
DEADLOCK-TIMEOUT
DEADLOCK-WARNING
DEMANGLE
DETAILED-STATES
ENTER-USERCODE
ENVIRONMENT
EXTENDED-VTF
FLUSH-PID
FLUSH-PREFIX
GROUP
HANDLE-SIGNALS
INTERNAL-MPI
KEEP-RAW-EVENTS
LOGFILE-FORMAT
LOGFILE-NAME
LOGFILE-PREFIX
LOGFILE-RANK
MEM-BLOCKSIZE
MEM-FLUSHBLOCKS
MEM-INFO
MEM-MAXBLOCKS
MEM-MINBLOCKS
MEM-OVERWRITE
NMCMD
OS-COUNTER-DELAY
PCTRACE
PCTRACE-CACHE
PCTRACE-FAST
PLUGIN
PROCESS
PROGNAME
PROTOFILE-NAME
STATISTICS
STATE
STF-PROCS-PER-FILE
STF-USE-HW-STRUCTURE
STOPFILE-NAME
SYMBOL
SYNC-MAX-DURATION
SYNC-MAX-MESSAGES
SYNC-PERIOD
SYNCED-CLUSTER
SYNCED-HOST
TIME-WINDOWS (Experimental)
TIMER
TIMER-SKIP
UNIFY-COUNTERS
UNIFY-GROUPS
UNIFY-SCLS
UNIFY-SYMBOLS
VERBOSE
VT_START_PAUSED
VT_COMPRESS_TRACE
Parameter Checking
Premature Exit
Overlapping Memory
Detecting Illegal Buffer Modifications
Buffer Given to MPI Cannot Be Read or Written
Distributed Memory Checking
Illegal Memory Access
Request Handling
Datatype Handling
Buffered Sends
Deadlocks
Checking Message Transmission
Datatype Mismatches
Data Modified during Transmission
Checking Collective Operations
Freeing Communicators
Process Aggregation
Function Aggregation
Function Group Color Editor
Filtering Dialog Box
Tagging Dialog Box
Idealization Dialog Box
Imbalance Diagram Dialog Box
Trace Merge Dialog Box
Details Dialog Box
Source View Dialog
Time Interval Selection
Configuration Dialogs
Find Dialog Box
Command line for Intel® VTune™ Profiler and Intel® Advisor Dialog Box
OTF2 to STF Conversion Dialog Box
Configuration Assistant
Visible to Intel only — GUID: GUID-BB9D226C-3BD1-435A-995D-CDA11912C433
Level of Detail
Tracing all available events over time can generate billions of events even for a moderate program runtime of a few minutes and a handful of CPUs. The sheer amount of data is a challenge for any analysis tool that has to cope with this data. This is even worse as in most cases the analysis tool cannot make use of the same system resources as the parallel computer on which the trace was generated.
An aspect of this problem arises when generating graphical diagrams of the event data. Obviously, it is next to impossible to graphically display all the data. Firstly, it would take ages to do that. Secondly, it would depend on round-off errors in the scaling and on the order of the data traversal which events would actually make it to the screen without being erased by others. So it is clear that only representatives of the actual events are shown.
A valid choice would be to paint only every 100th or 1000th event and to hope that the resulting diagram gives a valid impression of the data. But this approach has its problems, because the pattern selects the representatives can interfere with the patterns in the underlying data.
Intel® Trace Analyzer uses a Level of Detail concept to solve this problem. The Event Timeline Chart (as the other timelines) calculates a hint for the analysis that describes a time span that can reasonably be painted and selected with the mouse. This hint is called Resolution. The resolution requested by the timeline takes into account the currently available screen space and the length of the current time interval. Hence a higher screen resolution or a wider timeline results in more data being displayed for the same time interval.
Intel® Trace Analyzer then tries to find a near match for the requested resolution. The exact resolution depends on internals, which will not be discussed here.
Intel Trace Analyzer divides the requested time interval into slots of length resolution. After that, representatives for the function events, the messages and the collectives in these slots are chosen in a deterministic way. If a functions spans more than the given resolution it results in a larger slot.
The representatives for function events are chosen as follows: for each slot and each process (or thread group respectively) there is only a single function event representing the function where the thread or group spent most of its time.
The representatives for messages are chosen as follows: for each tuple (sender, receiver, sender slot, receiver slot) only one message is generated that carries averaged attributes. These attributes are averaged over all messages matching the tuple.
The representatives for collective operations are chosen as follows: for each tuple (communicator, first slot) one collective operation is generated. So it can happen that an operation of type MPI_Gather is merged with an operation of type MPI_Bcast resulting in a merged operation with no particular type at all (mixed).
To prevent misconceptions, emphasis is given to the fact that the merging of events only applies to the timelines and not to the profiles. The profiles always show sums, minima, maxima or averages over the complete set of events. The calculation of these results does obviously not depend on the screen resolution.
Parent topic: Concepts