Visible to Intel only — GUID: GUID-9D95CDBA-83A3-47CE-BBE8-E7E914CE1B5A
Context Menus: Project Navigator
Context Menus: Sources Window Panes
Context Menus: Summary Window Panes
Dialog Box: Corresponding inspxe-cl Command Options
Dialog Box: Create a Project
Dialog Box: Create Suppression
Dialog Box: Custom Analysis
Dialog Box: Delete Suppressions
Dialog Box: Export Result
Dialog Box: Merge States
Dialog Box: Options-Debugger
Dialog Box: Options-General
Dialog Box: Options-Result Location
Dialog Box: Options-State Management
Dialog Box: Problem Report
Dialog Box: Project Properties-Binary/Symbol Search
Dialog Box: Project Properties-Source Search
Dialog Box: Project Properties-Suppressions
Dialog Box: Project Properties-Target
Dialog Box: Refine Source File Set
Dialog Box: Select Stack Frame(s)
Dialog Box: View Stack
Hot Keys
Pane: Analysis Type-Custom
Pane: Analysis Type-Memory Errors
Pane: Analysis Type-Threading Errors
Pane: Application Output
Pane: Code and Stack
Pane: Code Locations
Pane: Collection Log
Pane: Collector Messages
Pane: Compare Results
Pane: Filters
Pane: Import Result
Pane: Launch Application
Pane: Problems
Pane: Project Navigator
Pane: Timeline
Toolbar: Command
Toolbar: Intel Inspector
Toolbar: Navigation
Window: Collection Log
Window: Compare Results
Window: Import Result
Window: Sources
Window: Summary After Analysis Is Complete
Window: Summary During Analysis
Asynchronous Buffer
Cross-thread Stack Access
Data Race
Deadlock
Host Pointer Used on Device
Incorrect memcpy Call
Invalid Deallocation
Invalid Kernel Argument
Invalid Kernel Argument Size
Invalid Memory Access
Invalid Partial Memory Access
Lock Hierarchy Violation
Memory Growth
Memory Leak
Memory Not Deallocated
Mismatched Allocation/Deallocation
Mismatched Queue
Missing Allocation
Non-Host Pointer
Pointer from Different Device
Thread Exit Information
Thread Start Information
Unhandled Application Exception
Uninitialized Memory Access
Uninitialized Partial Memory Access
appdebug
app-working-dir
archive-name
baseline-result
collect
collect-with
command
convert-suppression-file
create-breakpoints
create-suppression-file
csv-delimiter
debug-this
executable-of-interest
export
filter
finalize
format
help
include-snippets
include-sources
import
knob
knob-list
merge-states
module-filter
module-filter-mode
no-auto-finalize
no-summary
option-file
quiet
report
report-all
report-output
result-dir
return-app-exitcode
search-dir
sort-asc
sort-desc
suppression-file
user-data-dir
verbose
version
Visible to Intel only — GUID: GUID-9D95CDBA-83A3-47CE-BBE8-E7E914CE1B5A
Examine Result Data During Analysis
You can start managing the Intel Inspector analysis results before analysis (collection and finalization) is complete; however, some features are not available until after analysis is complete, such as:
Problem sets - During analysis, the Intel Inspector displays detected problems in the order detected. Intel Inspector does not group problems into problem sets or prioritize problem sets into a to-do list until after analysis is complete.
States - You cannot determine if an issue in the new result corresponds to an issue in a project baseline result until after analysis is complete.
Filters - You cannot temporarily limit the items in the Problems pane until after analysis is complete.
You also have the following options while the Intel Inspector performs an analysis:
About On-demand Memory Leak Detection
A Memory leak problem occurs when a block of memory is allocated, never deallocated, and not reachable (there is no pointer available to deallocate the block). As a result, the block of memory cannot be:
Used by the application (because the application has no reference to it)
Freed (again because the application has no reference to it to pass to the free routine)
An application that leaks enough memory may run out of address space and fail, or cause the system to run out of swap space, resulting in system-wide instability or performance issues.
Intel Inspector customarily displays memory leaks at the end of an analysis run when an application exits; however, you can also use the Intel Inspector on-demand memory leak detection feature to gather memory leak information while an application is running. This is useful if:
An application does not terminate (such as a server process).
You want memory leak information, but you do not want to wait for an application to terminate.
You want to determine if memory is leaked during a specific interval of application execution, or during a specific user action.
You want to discard information about allocations performed during initialization as a way of filtering out allocations that are not currently of interest.
TIP:
For more precision, consider using the GUI-based on-demand memory leak detection functions in tandem with APIs for custom memory allocation.
About Memory Growth Detection
A Memory growth problem occurs when a block of memory is allocated, but not deallocated, within a specific time segment during application execution.
Intel Inspector can measure memory growth to help you ensure an application uses no more memory than expected. This includes:
Memory an application has allocated and still needs for future calculations
Memory an application has allocated and no longer needs, but has not deallocated
Memory an application has allocated and then leaked
TIP:
For more precision, consider using the GUI-based memory growth detection functions in tandem with APIs for custom memory allocation.