This chapter describes some functions that are useful mainly for debugging and profiling purposes.
Probably the most important debugging tool in GAP is the break loop (see Section 6.4) which can be entered by putting an Error
(6.6-1) statement into your code or by hitting Control-C. In the break loop one can inspect variables, stack traces and issue commands as usual in an interactive GAP session. See also the DownEnv
(6.5-1), UpEnv
(6.5-1), Where
(6.4-5) and WhereWithVars
(6.4-5) functions.
Sections 7.2 and 7.3 show how to get information about the methods chosen by the method selection mechanism (see chapter 78).
The final sections describe functions for collecting statistics about computations (see Runtime
(7.6-2), 7.8).
When the method selection fails because there is no applicable method, an error as in the following example occurs and a break loop is entered:
gap> IsNormal(2,2); Error, no method found! For debugging hints type ?Recovery from NoMethodFound Error, no 1st choice method found for `IsNormal' on 2 arguments at GAPROOT/lib/methsel2.g:250 called from <function "HANDLE_METHOD_NOT_FOUND">( <arguments> ) called from read-eval loop at *stdin*:1 type 'quit;' to quit to outer loop brk>
This only says, that the method selection tried to find a method for IsNormal
on two arguments and failed. In this situation it is crucial to find out, why this happened. Therefore there are a few functions which can display further information. Note that you can leave the break loop by the quit
command (see 6.4-1) and that the information about the incident is no longer accessible afterwards.
‣ ShowArguments ( ) | ( function ) |
This function is only available within a break loop caused by a No Method Found
-error. It prints as a list the arguments of the operation call for which no method was found.
‣ ShowArgument ( nr ) | ( function ) |
This function is only available within a break loop caused by a No Method Found
-error. It prints the nr-th arguments of the operation call for which no method was found. ShowArgument
needs exactly one argument which is an integer between 0 and the number of arguments the operation was called with.
‣ ShowDetails ( ) | ( function ) |
This function is only available within a break loop caused by a No Method Found
-error. It prints the details of this error: The operation, the number of arguments, a flag which indicates whether the operation is being traced, a flag which indicates whether the operation is a constructor method, and the number of methods that refused to apply by calling TryNextMethod
(78.5-1). The last number is called Choice
and is printed as an ordinal. So if exactly k methods were found but called TryNextMethod
(78.5-1) and there were no more methods it says Choice:
kth
.
‣ ShowMethods ( [verbosity] ) | ( function ) |
This function is only available within a break loop caused by a No Method Found
-error. It prints an overview about the installed methods for those arguments the operation was called with (using 7.2. The verbosity can be controlled by the optional integer parameter verbosity. The default is 2, which lists all applicable methods. With verbosity 1 ShowMethods
only shows the number of installed methods and the methods matching, which can only be those that were already called but refused to work by calling TryNextMethod
(78.5-1). With verbosity 3 not only all installed methods but also the reasons why they do not match are displayed.
‣ ShowOtherMethods ( [verbosity] ) | ( function ) |
This function is only available within a break loop caused by a No Method Found
-error. It prints an overview about the installed methods for a different number of arguments than the number of arguments the operation was called with (using 7.2. The verbosity can be controlled by the optional integer parameter verbosity. The default is 1 which lists only the number of applicable methods. With verbosity 2 ShowOtherMethods
lists all installed methods and with verbosity 3 also the reasons, why they are not applicable. Calling ShowOtherMethods
with verbosity 3 in this function will normally not make any sense, because the different numbers of arguments are simulated by supplying the corresponding number of ones, for which normally no reasonable methods will be installed.
‣ ApplicableMethod ( opr, args[, printlevel[, nr]] ) | ( function ) |
‣ ApplicableMethodTypes ( opr, args[, printlevel[, nr]] ) | ( function ) |
Called with two arguments, ApplicableMethod
returns the method of highest rank that is applicable for the operation opr with the arguments in the list args. The default printlevel is 0
. If no method is applicable then fail
is returned.
If a positive integer is given as the fourth argument nr then ApplicableMethod
returns the nr-th applicable method for the operation opr with the arguments in the list args, where the methods are ordered according to descending rank. If less than nr methods are applicable then fail
is returned.
If the fourth argument nr is the string "all"
then ApplicableMethod
returns a list of all applicable methods for opr with arguments args, ordered according to descending rank.
Depending on the integer value printlevel, additional information is printed. Admissible values and their meaning are as follows.
no information,
information about the applicable method,
also information about the not applicable methods of higher rank,
also for each not applicable method the first reason why it is not applicable,
also for each not applicable method all reasons why it is not applicable.
also the function body of the selected method(s)
When a method returned by ApplicableMethod
is called then it returns either the desired result or the string "TRY_NEXT_METHOD"
, which corresponds to a call to TryNextMethod
(78.5-1) in the method and means that the method selection would call the next applicable method.
Note: The GAP kernel provides special treatment for the infix operations \+
, \-
, \*
, \/
, \^
, \mod
and \in
. For some kernel objects (notably cyclotomic numbers, finite field elements and row vectors thereof) it calls kernel methods circumventing the method selection mechanism. Therefore for these operations ApplicableMethod
may return a method which is not the kernel method actually used.
The function ApplicableMethodTypes
takes the types or filters of the arguments as argument (if only filters are given of course family predicates cannot be tested).
‣ TraceMethods ( opr1, opr2, ... ) | ( function ) |
‣ TraceMethods ( oprs ) | ( function ) |
After the call of TraceMethods
, whenever a method of one of the operations opr1, opr2, ... is called, the information string used in the installation of the method is printed. The second form has the same effect for each operation from the list oprs of operations.
‣ TraceAllMethods ( ) | ( function ) |
Invokes TraceMethods
for all operations.
‣ UntraceMethods ( opr1, opr2, ... ) | ( function ) |
‣ UntraceMethods ( oprs ) | ( function ) |
turns the tracing off for all operations opr1, opr2, ... or in the second form, for all operations in the list oprs.
gap> TraceMethods( [ Size ] ); gap> g:= Group( (1,2,3), (1,2) );; gap> Size( g ); #I Size: for a permutation group at /gap5/lib/grpperm.gi:487 #I Setter(Size): system setter #I Size: system getter #I Size: system getter 6 gap> UntraceMethods( [ Size ] );
‣ UntraceAllMethods ( ) | ( function ) |
Equivalent to calling UntraceMethods
for all operations.
‣ TraceImmediateMethods ( [flag] ) | ( function ) |
‣ UntraceImmediateMethods ( ) | ( function ) |
TraceImmediateMethods
enables tracing for all immediate methods if flag is either true
, or not present. UntraceImmediateMethods
, or TraceImmediateMethods
with flag equal false
turns tracing off. (There is no facility to trace specific immediate methods.)
gap> TraceImmediateMethods( ); gap> g:= Group( (1,2,3), (1,2) );; #I RunImmediateMethods #I immediate: Size #I immediate: IsCyclic #I immediate: IsCommutative #I immediate: IsTrivial gap> Size( g ); #I immediate: IsPerfectGroup #I immediate: IsNonTrivial #I immediate: Size #I immediate: IsFreeAbelian #I immediate: IsTorsionFree #I immediate: IsNonTrivial #I immediate: IsPerfectGroup #I immediate: GeneralizedPcgs #I immediate: IsEmpty 6 gap> UntraceImmediateMethods( ); gap> UntraceMethods( [ Size ] );
This example gives an explanation for the two calls of the system getter
for Size
(30.4-6). Namely, there are immediate methods that access the known size of the group. Note that the group g
was known to be finitely generated already before the size was computed, the calls of the immediate method for IsFinitelyGeneratedGroup
(39.15-18) after the call of Size
(30.4-6) have other arguments than g
.
‣ TraceInternalMethods ( ) | ( function ) |
‣ UntraceInternalMethods ( ) | ( function ) |
‣ GetTraceInternalMethodsCounts ( ) | ( function ) |
‣ ClearTraceInternalMethodsCounts ( ) | ( function ) |
TraceInternalMethods
enables tracing for all internal methods. Internal methods are methods which implement many fundamental operations in GAP. In this version of GAP, the internal methods which can be traced are:
Mutable and Immutable Zero
(31.10-3)
Mutable and Immutable AdditiveInverse
(31.10-9)
Mutable and Immutable One
(31.10-2)
Mutable and Immutable Inverse
(31.10-8)
The operator \+
(31.12-1)
The operator -
operator
The operator \*
(31.12-1)
The operator \/
(31.12-1)
The left-quotient operator
The operator \^
(31.12-1)
The operator Comm
(31.12-3)
The operator \mod
(31.12-1)
UntraceInternalMethods
turns tracing off. As these methods can be called hundreds of thousands of times in simple GAP code, there isn't a statement printed each time one is called. Instead, the method GetTraceInternalMethodsCounts
returns how many times each operation has been applied to each type of variable (the type of a variable can be found with the TNAM_OBJ
method). The return value for two argument operators is a record of records r
, where r.op
stores information about operator op
. For one argument operators r.op.i
stores how many times op
was called with an argument of type i
, while for two argument operators r.op.i.j
stores how many times op
was called with arguments of type i
and j
.
gap> TraceInternalMethods(); true gap> 2+3+4+5+6;; gap> 2.0+2.0;; gap> 3^(1,2,3);; gap> GetTraceInternalMethodsCounts(); rec( Pow := rec( integer := rec( ("permutation (small)") := 1 ) ), Sum := rec( integer := rec( integer := 4 ), macfloat := rec( macfloat := 1 ) ) ) # 'macfloat' is a floating point number gap> UntraceInternalMethods();
The Info
(7.4-6) mechanism permits operations to display intermediate results or information about the progress of the algorithms. Information is always given according to one or more info classes. Each of the info classes defined in the GAP library usually covers a certain range of algorithms, so for example InfoLattice
covers all the cyclic extension algorithms for the computation of a subgroup lattice.
Note that not all info classes defined in the GAP library are currently documented. Many GAP packages define additional info classes, which are typically documented in the corresponding package documentation. The function ShowUsedInfoClasses
(7.4-5) will show all info classes which GAP considers while executing code.
The amount of information to be displayed by each info class can be separately specified by the user. This is done by selecting a non-negative integer level for the info class: no information will be displayed at level 0, and the higher the level, the more information that will be displayed. At creation, an info class has level 0. By default, all built-in GAP info classes have level 0, except for the following info classes, which have level 1:
InfoWarning
(7.4-8),
InfoPackageLoading
(76.2-5),
InfoDebug
,
InfoPerformance
,
InfoTempDirectories
,
InfoPrimeInt
, and
InfoSLP
.
‣ NewInfoClass ( name ) | ( operation ) |
creates a new info class with name name.
‣ DeclareInfoClass ( name ) | ( function ) |
creates a new info class with name name and binds it to the global variable name. The variable must previously be writable, and is made read-only by this function.
‣ SetInfoLevel ( infoclass, level ) | ( operation ) |
Sets the info level for infoclass to the non-negative integer level.
‣ InfoLevel ( infoclass ) | ( operation ) |
returns the info level of infoclass.
‣ ShowUsedInfoClasses ( infoclass ) | ( function ) |
Called with argument true
, this makes GAP print the info class and level of any executed Info
(7.4-6) statement. Calling with the argument false
stops this printing. Each level of each info class is only printed once. The history of printed info classes and levels is reset whenever true
is passed.
gap> ShowUsedInfoClasses(true); gap> Intersection(Group((1,3,2,4,5,6)), Group((1,2,3,4,5,6))); #I Would print info with SetInfoLevel(InfoBckt,1) #I Would print info with SetInfoLevel(InfoBckt,3) #I Would print info with SetInfoLevel(InfoBckt,5) Group(()) gap> Intersection(Group((1,3,2,4,5,6)), Group((1,2,3,4,5,6))); Group(()) gap> ShowUsedInfoClasses(false);
‣ Info ( infoclass, level, info[, moreinfo, ...] ) | ( function ) |
If the info level of infoclass is at least level, then the remaining arguments, info, and possibly moreinfo and so on, are evaluated. (Technically, Info
is a keyword and not a function.)
By default, the results of these evaluations are viewed, preceded by the string "#I "
and followed by a newline.
If the info level of infoclass is strictly less than level, then the third and subsequent arguments are not evaluated. (The latter can save substantial time when displaying difficult results.)
The behaviour can be customized with SetInfoHandler
(7.4-7).
gap> InfoExample:=NewInfoClass("InfoExample");; gap> Info(InfoExample,1,"one");Info(InfoExample,2,"two"); gap> SetInfoLevel(InfoExample,1); gap> Info(InfoExample,1,"one");Info(InfoExample,2,"two"); #I one gap> SetInfoLevel(InfoExample,2); gap> Info(InfoExample,1,"one");Info(InfoExample,2,"two"); #I one #I two gap> InfoLevel(InfoExample); 2 gap> Info(InfoExample,3,Length(Combinations([1..9999])));
Note that the last Info
call is executed without problems, since the actual level 2
of InfoExample
causes Info
to ignore the last argument, which prevents Length(Combinations([1..9999]))
from being evaluated; note that an evaluation would be impossible due to memory restrictions.
A set of info classes (called an info selector) may be passed to a single Info
statement. As a shorthand, info classes and selectors may be combined with +
rather than Union
(30.5-3). In this case, the message is triggered if the level of any of the classes is high enough.
gap> InfoExample:=NewInfoClass("InfoExample");; gap> SetInfoLevel(InfoExample,0); gap> Info(InfoExample + InfoWarning, 1, "hello"); #I hello gap> Info(InfoExample + InfoWarning, 2, "hello"); gap> SetInfoLevel(InfoExample,2); gap> Info(InfoExample + InfoWarning, 2, "hello"); #I hello gap> InfoLevel(InfoWarning); 1
Info
(7.4-6) statements‣ SetInfoHandler ( infoclass, handler ) | ( function ) |
‣ SetInfoOutput ( infoclass, out ) | ( function ) |
‣ UnbindInfoOutput ( infoclass ) | ( function ) |
‣ InfoOutput ( infoclass ) | ( function ) |
‣ SetDefaultInfoOutput ( out ) | ( function ) |
Returns: nothing
This allows one to customize what happens in an Info(infoclass, level, ...)
statement.
In the first function, handler must be a function with three arguments infoclass, level, list. Here list is the list containing the third argument and any subsequent optional arguments of the Info
(7.4-6) call.
The default handler is the function DefaultInfoHandler
. It prints "#I "
, then the third and further arguments of the info statement, and finally a "\n"
.
If the first argument of an Info
(7.4-6) statement is a sum of Info classes, the handler of the first summand is used.
The file or stream to which Info
(7.4-6) statements for individual Info
(7.4-6) classes print can be overridden with SetInfoOutput
, retrieved with InfoOutput
and reset to the default with UnbindInfoOutput
. The initial default for all Info
(7.4-6) classes is the string "*Print*"
which means the current output file. The default can be changed with SetDefaultInfoOutput
. The argument out can be a filename or an open stream, the special names "*Print*"
, "*errout*
and "*stdout*
are also recognized.
For example, SetDefaultInfoOutput("*errout*");
would send Info
(7.4-6) output to standard error, which can be interesting if GAPs output is redirected.
‣ InfoWarning | ( info class ) |
is an info class to which general warnings are sent at level 1, which is its default level. More specialised warnings are shown via calls of Info
(7.4-6) at InfoWarning
level 2, e.g. information about the autoloading of GAP packages and the initial line matched when displaying an on-line help topic.
Assertions are used to find errors in algorithms. They test whether intermediate results conform to required conditions and issue an error if not.
‣ SetAssertionLevel ( lev ) | ( function ) |
assigns the global assertion level to lev. By default it is zero.
‣ AssertionLevel ( ) | ( function ) |
returns the current assertion level.
‣ Assert ( lev, cond[, message] ) | ( function ) |
With two arguments, if the global assertion level is at least lev, condition cond is tested and if it does not return true
an error is raised. Thus Assert(lev, cond)
is equivalent to the code
if AssertionLevel() >= lev and not <cond> then Error("Assertion failure"); fi;
With the message argument form of the Assert
statement, if the global assertion level is at least lev, condition cond is tested and if it does not return true
then message is evaluated and printed.
Assertions are used at various places in the library. Thus turning assertions on can slow code execution significantly.
‣ Runtimes ( ) | ( function ) |
Runtimes
returns a record with components bound to integers or fail
. Each integer is the cpu time (processor time) in milliseconds spent by GAP in a certain status:
user_time
cpu time spent with GAP functions (without child processes).
system_time
cpu time spent in system calls, e.g., file access (fail
if not available).
user_time_children
cpu time spent in child processes (fail
if not available).
system_time_children
cpu time spent in system calls by child processes (fail
if not available).
Note that this function is not fully supported on all systems. Only the user_time
component is (and may on some systems include the system time).
The following example demonstrates tasks which contribute to the different time components:
gap> Runtimes(); # after startup rec( user_time := 3980, system_time := 60, user_time_children := 0, system_time_children := 0 ) gap> Exec("cat /usr/bin/*||wc"); # child process with a lot of file access 893799 7551659 200928302 gap> Runtimes(); rec( user_time := 3990, system_time := 60, user_time_children := 1590, system_time_children := 600 ) gap> a:=0;;for i in [1..100000000] do a:=a+1; od; # GAP user time gap> Runtimes(); rec( user_time := 12980, system_time := 70, user_time_children := 1590, system_time_children := 600 ) gap> ?blabla # first call of help, a lot of file access Help: no matching entry found gap> Runtimes(); rec( user_time := 13500, system_time := 440, user_time_children := 1590, system_time_children := 600 )
‣ Runtime ( ) | ( function ) |
Runtime
returns the time spent by GAP in milliseconds as an integer. It is the same as the value of the user_time
component given by Runtimes
(7.6-1), as explained above.
See StringTime
(27.10-9) for a translation from milliseconds into hour/minute format.
‣ NanosecondsSinceEpoch ( ) | ( function ) |
‣ NanosecondsSinceEpochInfo ( ) | ( function ) |
NanosecondsSinceEpoch
returns the time in nanoseconds that has passed since some fixed, but unspecified time in the past. This function is appropriate for doing wallclock time measurements. The actual resolution depends on the system that GAP is run on. Information about the used timers can be obtained by calling NanosecondsSinceEpochInfo
, which returns a record containing members Method
, Monotonic
, Reliable
and Resolution
.
Method
is a string describing the method used to obtain timer values. This will usually contain the name of the syscall used.
Monotonic
is a boolean. If it is true
, then the values returned by NanosecondsSinceEpoch
are guaranteed to be strictly monotonically increasing between two calls, if it is false
then there is no such guarantee.
Resolution
is an integer reflecting the resolution of the timer used in nanoseconds.
Reliable
is a boolean. If it is true
then the value Resolution
is deemed reliable in the sense that it was obtained by querying the operating system, otherwise Resolution
should be treated as an estimate.
‣ time | ( global variable ) |
In the read-eval-print loop, time
stores the number of milliseconds the last command took (see also memory_allocated
(7.7-2) for the number of bytes of memory it allocated).
‣ Sleep ( time ) | ( function ) |
‣ MicroSleep ( time ) | ( function ) |
These functions make GAP stop execution for a given period of time. The time to stop is given to Sleep
in seconds and MicroSleep
in microseconds.
‣ TotalMemoryAllocated ( ) | ( function ) |
TotalMemoryAllocated
returns the total amount of memory in bytes allocated by the GAP memory manager since GAP started.
‣ memory_allocated | ( global variable ) |
In the read-eval-print loop, memory_allocated
stores the number of bytes of memory allocated by the last completed statement (see also time
(7.6-4) for the number of milliseconds it took).
Profiling of code can be used to determine in which parts of a program how much time has been spent and how much memory has been allocated during runtime. GAP has two different methods of profiling. GAP can either profile by function, or line-by-line. Line by line profiling is currently only used for code coverage, while function profiling tracks memory and time usage.
This section describes how to profiling at the function level. The idea is that
first one switches on profiling for those GAP functions the performance of which one wants to check,
then one runs some GAP computations,
then one looks at the profile information collected during these computations,
then one runs more computations (perhaps clearing all profile information before, see ClearProfile
(7.8-10)),
and finally one switches off profiling.
For switching on and off profiling, GAP supports entering a list of functions (see ProfileFunctions
(7.8-5), UnprofileFunctions
(7.8-6)) or a list of operations whose methods shall be (un)profiled (ProfileMethods
(7.8-7), UnprofileMethods
(7.8-8)), and DisplayProfile
(7.8-9) can be used to show profile information about functions in a given list.
Besides these functions, ProfileGlobalFunctions
(7.8-2), ProfileOperations
(7.8-3), and ProfileOperationsAndMethods
(7.8-4) can be used for switching on or off profiling for all global functions, operations, and operations together with all their methods, respectively, and for showing profile information about these functions.
Note that GAP will perform more slowly when profiling than when not.
‣ ProfileGlobalFunctions ( [bool] ) | ( function ) |
Called with argument true
, ProfileGlobalFunctions
starts profiling of all functions that have been declared via DeclareGlobalFunction
(79.10-5). Old profile information for all these functions is cleared. A function call with the argument false
stops profiling of all these functions. Recorded information is still kept, so you can display it even after turning the profiling off.
When ProfileGlobalFunctions
is called without argument, profile information for all global functions is displayed, see DisplayProfile
(7.8-9).
‣ ProfileOperations ( [bool] ) | ( function ) |
Called with argument true
, ProfileOperations
starts profiling of all operations. Old profile information for all operations is cleared. A function call with the argument false
stops profiling of all operations. Recorded information is still kept, so you can display it even after turning the profiling off.
When ProfileOperations
is called without argument, profile information for all operations is displayed (see DisplayProfile
(7.8-9)).
‣ ProfileOperationsAndMethods ( [bool] ) | ( function ) |
Called with argument true
, ProfileOperationsAndMethods
starts profiling of all operations and their methods. Old profile information for these functions is cleared. A function call with the argument false
stops profiling of all operations and their methods. Recorded information is still kept, so you can display it even after turning the profiling off.
When ProfileOperationsAndMethods
is called without argument, profile information for all operations and their methods is displayed, see DisplayProfile
(7.8-9).
‣ ProfileFunctions ( funcs ) | ( function ) |
starts profiling for all function in the list funcs. You can use ProfileGlobalFunctions
(7.8-2) to turn profiling on for all globally declared functions simultaneously.
‣ UnprofileFunctions ( funcs ) | ( function ) |
stops profiling for all function in the list funcs. Recorded information is still kept, so you can display it even after turning the profiling off.
‣ ProfileMethods ( ops ) | ( function ) |
starts profiling of the methods for all operations in the list ops.
‣ UnprofileMethods ( ops ) | ( function ) |
stops profiling of the methods for all operations in the list ops. Recorded information is still kept, so you can display it even after turning the profiling off.
‣ DisplayProfile ( [functions][,] [mincount, mintime] ) | ( function ) |
‣ GAPInfo.ProfileThreshold | ( global variable ) |
Called without arguments, DisplayProfile
displays the profile information for profiled operations, methods and functions. If an argument functions is given, only profile information for the functions in the list functions is shown. If two integer values mincount, mintime are given as arguments then the output is restricted to those functions that were called at least mincount times or for which the total time spent (see below) was at least mintime milliseconds. The defaults for mincount and mintime are the entries of the list stored in the global variable GAPInfo.ProfileThreshold
.
The default value of GAPInfo.ProfileThreshold
is [ 10000, 30 ]
.
Profile information is displayed in a list of lines for all functions (including operations and methods) which are profiled. For each function, count
gives the number of times the function has been called. self/ms
gives the time (in milliseconds) spent in the function itself, chld/ms
the time (in milliseconds) spent in profiled functions called from within this function, stor/kb
the amount of storage (in kilobytes) allocated by the function itself, chld/kb
the amount of storage (in kilobytes) allocated by profiled functions called from within this function, and package
the name of the GAP package to which the function belongs; the entry GAP
in this column means that the function belongs to the GAP library, the entry (oprt.)
means that the function is an operation (which may belong to several packages), and an empty entry means that FilenameFunc
(5.1-4) cannot determine in which file the function is defined.
The list is sorted according to the total time spent in the functions, that is the sum of the values in the columns self/ms
and chld/ms
.
At the end of the list, two lines are printed that show the total time used and the total memory allocated by the profiled functions not shown in the list (label OTHER
) and by all profiled functions (label TOTAL
), respectively.
An interactive variant of DisplayProfile
is the function BrowseProfile
(Browse: BrowseProfile) that is provided by the GAP package Browse.
‣ ClearProfile ( ) | ( function ) |
clears all stored profile information.
Let us suppose we want to get information about the computation of the conjugacy classes of a certain permutation group. For that, first we create the group, then we start profiling for all global functions and for all operations and their methods, then we compute the conjugacy classes, and then we stop profiling.
gap> g:= PrimitiveGroup( 24, 1 );; gap> ProfileGlobalFunctions( true ); gap> ProfileOperationsAndMethods( true ); gap> ConjugacyClasses( g );; gap> ProfileGlobalFunctions( false ); gap> ProfileOperationsAndMethods( false );
Now the profile information is available. We can list the information for all profiled functions with DisplayProfile
(7.8-9).
gap> DisplayProfile(); count self/ms chld/ms stor/kb chld/kb package function 17647 0 0 275 0 GAP BasePoint 10230 0 0 226 0 (oprt.) ShallowCopy 10139 0 0 0 0 PositionSortedOp: for* 10001 0 0 688 0 UniteSet: for two int* 10001 8 0 28 688 (oprt.) UniteSet 14751 12 0 0 0 =: for two families: * 10830 8 4 182 276 GAP Concatenation 2700 20 12 313 55 GAP AddRefinement 2444 28 4 3924 317 GAP ConjugateStabChain 4368 0 32 7 714 (oprt.) Size 2174 32 4 1030 116 GAP List 585 4 32 45 742 GAP RRefine 1532 32 8 194 56 GAP AddGeneratorsExtendSc* 1221 8 32 349 420 GAP Partition 185309 28 12 0 0 (oprt.) Length 336 4 40 95 817 GAP ExtendSeriesPermGroup 4 28 20 488 454 (oprt.) Sortex 2798 0 52 54 944 GAP StabChainForcePoint 560 4 48 83 628 GAP StabChainSwap 432 16 40 259 461 GAP SubmagmaWithInversesNC 185553 48 8 915 94 (oprt.) Add 26 0 64 0 2023 (oprt.) CentralizerOp 26 0 64 0 2023 GAP CentralizerOp: perm g* 26 0 64 0 2023 GAP Centralizer: try to e* 152 4 64 0 2024 (oprt.) Centralizer 1605 0 68 0 2032 (oprt.) StabilizerOfExternalS* 26 0 68 0 2024 GAP Meth(StabilizerOfExte* 382 0 96 69 1922 GAP TryPcgsPermGroup 5130 4 96 309 3165 GAP ForAll 7980 24 116 330 6434 GAP ChangeStabChain 12076 12 136 351 6478 GAP ProcessFixpoint 192 0 148 4 3029 GAP StabChainMutable: cal* 2208 4 148 3 3083 (oprt.) StabChainMutable 217 0 160 0 3177 (oprt.) StabChainOp 217 12 148 60 3117 GAP StabChainOp: group an* 216 36 464 334 12546 GAP PartitionBacktrack 1479 12 668 566 18474 GAP RepOpElmTuplesPermGro* 1453 12 684 56 18460 GAP in: perm class rep 126 0 728 13 19233 GAP ConjugacyClassesTry 1 0 736 0 19671 GAP ConjugacyClassesByRan* 2 0 736 2 19678 (oprt.) ConjugacyClasses 1 0 736 0 19675 GAP ConjugacyClasses: per* 13400 1164 0 0 0 (oprt.) Position 484 12052 OTHER 2048 23319 TOTAL
We can restrict the list to global functions with ProfileGlobalFunctions
(7.8-2).
gap> ProfileGlobalFunctions(); count self/ms chld/ms stor/kb chld/kb package function 17647 0 0 275 0 GAP BasePoint 10830 8 4 182 276 GAP Concatenation 2700 20 12 313 55 GAP AddRefinement 2444 28 4 3924 317 GAP ConjugateStabChain 2174 32 4 1030 116 GAP List 585 4 32 45 742 GAP RRefine 1532 32 8 194 56 GAP AddGeneratorsExtendSc* 1221 8 32 349 420 GAP Partition 336 4 40 95 817 GAP ExtendSeriesPermGroup 2798 0 52 54 944 GAP StabChainForcePoint 560 4 48 83 628 GAP StabChainSwap 432 16 40 259 461 GAP SubmagmaWithInversesNC 382 0 96 69 1922 GAP TryPcgsPermGroup 5130 4 96 309 3165 GAP ForAll 7980 24 116 330 6434 GAP ChangeStabChain 12076 12 136 351 6478 GAP ProcessFixpoint 216 36 464 334 12546 GAP PartitionBacktrack 1479 12 668 566 18474 GAP RepOpElmTuplesPermGro* 126 0 728 13 19233 GAP ConjugacyClassesTry 1 0 736 0 19671 GAP ConjugacyClassesByRan* 1804 14536 OTHER 2048 23319 TOTAL
We can restrict the list to operations with ProfileOperations
(7.8-3).
gap> ProfileOperations(); count self/ms chld/ms stor/kb chld/kb package function 10230 0 0 226 0 (oprt.) ShallowCopy 10001 8 0 28 688 (oprt.) UniteSet 4368 0 32 7 714 (oprt.) Size 185309 28 12 0 0 (oprt.) Length 4 28 20 488 454 (oprt.) Sortex 185553 48 8 915 94 (oprt.) Add 26 0 64 0 2023 (oprt.) CentralizerOp 152 4 64 0 2024 (oprt.) Centralizer 1605 0 68 0 2032 (oprt.) StabilizerOfExternalS* 2208 4 148 3 3083 (oprt.) StabChainMutable 217 0 160 0 3177 (oprt.) StabChainOp 2 0 736 2 19678 (oprt.) ConjugacyClasses 13400 1164 0 0 0 (oprt.) Position 764 21646 OTHER 2048 23319 TOTAL
We can restrict the list to operations and their methods with ProfileOperationsAndMethods
(7.8-4).
gap> ProfileOperationsAndMethods(); count self/ms chld/ms stor/kb chld/kb package function 10230 0 0 226 0 (oprt.) ShallowCopy 10139 0 0 0 0 PositionSortedOp: for* 10001 0 0 688 0 UniteSet: for two int* 10001 8 0 28 688 (oprt.) UniteSet 14751 12 0 0 0 =: for two families: * 4368 0 32 7 714 (oprt.) Size 185309 28 12 0 0 (oprt.) Length 4 28 20 488 454 (oprt.) Sortex 185553 48 8 915 94 (oprt.) Add 26 0 64 0 2023 (oprt.) CentralizerOp 26 0 64 0 2023 GAP CentralizerOp: perm g* 26 0 64 0 2023 GAP Centralizer: try to e* 152 4 64 0 2024 (oprt.) Centralizer 1605 0 68 0 2032 (oprt.) StabilizerOfExternalS* 26 0 68 0 2024 GAP Meth(StabilizerOfExte* 192 0 148 4 3029 GAP StabChainMutable: cal* 2208 4 148 3 3083 (oprt.) StabChainMutable 217 0 160 0 3177 (oprt.) StabChainOp 217 12 148 60 3117 GAP StabChainOp: group an* 1453 12 684 56 18460 GAP in: perm class rep 2 0 736 2 19678 (oprt.) ConjugacyClasses 1 0 736 0 19675 GAP ConjugacyClasses: per* 13400 1164 0 0 0 (oprt.) Position 728 20834 OTHER 2048 23319 TOTAL
Finally, we can restrict the list to explicitly given functions with DisplayProfile
(7.8-9), by entering the list of functions as an argument.
gap> DisplayProfile( [ StabChainOp, Centralizer ] ); count self/ms chld/ms stor/kb chld/kb package function 152 4 64 0 2024 (oprt.) Centralizer 217 0 160 0 3177 (oprt.) StabChainOp 2044 23319 OTHER 2048 23319 TOTAL
Line By Line profiling tracks which lines have been executed in a piece of GAP code. Built into GAP are the methods necessary to generate profiles, the resulting profiles can be displayed with the 'profiling' package.
There are two kinds of profiles GAP can build:
Coverage : This records which lines of code are executed
Timing : This records how much time is spend executing each line of code
A timing profile provides more information, but will take longer to generate and parse. A timing profile is generated using the functions ProfileLineByLine
(7.8-14) and UnprofileLineByLine
(7.8-16), as follows:
gap> ProfileLineByLine("output.gz"); gap> Size(AlternatingGroup(10)); ; # Execute some GAP code you want to profile gap> UnprofileLineByLine();
For code coverage, use instead the functions CoverageLineByLine
(7.8-15) and UncoverageLineByLine
(7.8-17). The profiler will only record lines which are read and executed while the profiler is running. If you want to perform code coverage or profile GAP's library, then you can use the GAP command line option '--cover filename.gz', which executes CoverageLineByLine
(7.8-15) before GAP starts. Similarly the option '--prof filename.gz' executes ProfileLineByLine
(7.8-14) before GAP starts. The profiler is designed for high performance, because of this, there are some limitations which users should be aware of:
By default the profiler records the wall-clock time which has passed, rather than the CPU time taken (because it is lower overhead), so any time taken writing commands will be charged to the last GAP statement which was executed. Therefore it is better to write a function which starts profiling, executes your code, and then stops profiling.
If you end the filename with ".gz", the resulting file will automatically be compressed. This is highly recommended!
The profiler can only track GAP code which occurs in a function -- this is most obvious when looking at code coverage examples, which will appear to miss lines of code in files not in a function.
If the current GAP is forked, using the IO_fork
function in the IO package, a new profile output file will be created for the new child process, with the process ID of the child attached to the end of the filename.
Profiles are transformed into a human-readable form with 'profiling' package, for example with the 'OutputAnnotatedCodeCoverageFiles' function.
‣ ProfileLineByLine ( filename[, options] ) | ( function ) |
ProfileLineByLine
begins GAP recording profiling data to the file filename. This file will get *very* large very quickly. This file is compressed using gzip to reduce its size. options is an optional dictionary, which sets various configuration options. These are
Boolean (defaults to false). If this is enabled, only information about which lines are read and executed is stored. Enabling this is the same as calling CoverageLineByLine
(7.8-15). Using this ignores all other options.
Boolean (defaults to true). Sets if time should be measured using wall-clock time (true) or CPU time (false). (measuring CPU-time has a higher overhead).
Boolean (defaults to false). Instead of recording the CPU time taken by statements, record the total size of all new objects created by each line.
Integer (defaults to 0). By default profiling will record a trace of all executed code. When resolution non-zero, GAP instead samples which piece of code is being executed every resolution nanoseconds. Increasing this improves performance and produces smaller traces, at the cost of accuracy. GAP will still accurately record which statements are executed at least once.
‣ CoverageLineByLine ( filename ) | ( function ) |
CoverageLineByLine
begins GAP recording code coverage to the file filename. This is equivalent to calling ProfileLineByLine
(7.8-14) with coverage=true.
‣ UnprofileLineByLine ( ) | ( function ) |
Stops profiling which was previously started with ProfileLineByLine
(7.8-14) or CoverageLineByLine
(7.8-15).
‣ UncoverageLineByLine ( ) | ( function ) |
Stops profiling which was previously started with ProfileLineByLine
(7.8-14) or CoverageLineByLine
(7.8-15).
‣ IsLineByLineProfileActive ( ) | ( function ) |
IsLineByLineProfileActive
returns if line-by-line profiling is currently activated.
‣ DisplayCacheStats ( ) | ( function ) |
displays statistics about the different caches used by the method selection.
‣ ClearCacheStats ( ) | ( function ) |
clears all statistics about the different caches used by the method selection.
The global variable GAPInfo.Version
(see GAPInfo
(3.5-1)) contains the version number of the version of GAP. Its value can be checked other version number using CompareVersionNumbers
(76.3-9).
To produce sample citations for the used version of GAP or for a package available in this GAP installation, use Cite
(76.3-19).
If you wish to report a problem to GAP Support or GAP Forum, it may be useful to not only report the version used, but also to include the GAP banner displays the information about the architecture for which the GAP binary is built, used libraries and loaded packages.
Test files are used to check that GAP produces correct results in certain computations. A selection of test files for the library can be found in the tst
directory of the GAP distribution.
‣ START_TEST ( name ) | ( function ) |
‣ STOP_TEST ( name ) | ( function ) |
START_TEST
and STOP_TEST
may be optionally used in files that are read via Test
(7.10-2). If used, START_TEST
reinitialize the caches and the global random number generator, in order to be independent of the reading order of several test files. Furthermore, the assertion level (see Assert
(7.5-3)) is set to 2 (if it was lower before) by START_TEST
and set back to the previous value in the subsequent STOP_TEST
call.
To use these options, a test file should be started with a line
gap> START_TEST( "arbitrary identifier string" );
(Note that the gap>
prompt is part of the line!)
and should be finished with a line
gap> STOP_TEST( "same identifier string as for START_TEST" );
If you want to run a quick test of your GAP installation (though this is not required), you can read in a test script that exercises some GAP's capabilities.
gap> Read( Filename( DirectoriesLibrary( "tst" ), "testinstall.g" ) );
test file time(msec) ------------------------------------------- testing: ................/gap4r5/tst/zlattice.tst zlattice.tst 0 testing: ................/gap4r5/tst/gaussian.tst gaussian.tst 10 [ further lines deleted ]
If you want to run a more advanced check (this is not required and make take up to an hour), you can read teststandard.g
which is an extended test script performing all tests from the tst
directory.
gap> Read( Filename( DirectoriesLibrary( "tst" ), "teststandard.g" ) );
‣ Test ( fname[, optrec] ) | ( function ) |
Returns: true
or false
.
The argument fname must be the name of a file or an open input stream. The content of this file or stream should contain GAP input and output. The function Test
runs the input lines, compares the actual output with the output stored in fname and reports differences. With an optional record as argument optrec details of this process can be adjusted. Note that the rewriteToFile
option is especially useful for generating test files.
More precisely, the content of fname must have the following format.
Lines starting with "gap> "
are considered as GAP input, they can be followed by lines starting with "> "
if the input is continued over several lines.
To allow for comments in fname the following lines are ignored by default: lines at the beginning of fname that start with "#"
or are empty, and one empty line together with one or more lines starting with "#"
.
All other lines are considered as GAP output from the preceding GAP input.
Lines which begin "#@" define special configuration options for tests. The #@local
and #@exec
options can only be used before any GAP input, and the other commands can only be used between individual tests (just before a line starting gap>
, or at end of the file). Currently defined options are:
Run all the tests in the input as if it is in a function with local variable list identifierlist
, which is a comma-separated list of identifiers. Multiple #@local lines may be used. These lines should not end with a comma or semicolon. If this option is used then an error will occur unless all the variables used are included in the local list.
As an example, the Utils package has a test file tst/iterator.tst
which starts with the lines:
#@local c3c3, cart, G, h, it1, it2, iter, iter0, iter4, iterL #@local L, n, pairs0, pairs4, pairsL, s3, s4
Execute the code gapcode
before any test in the input is run. This allows defining global variables when using #@local
.
A #@if
allows to conditionally skip parts of the test input depending on the value of a boolean expression. The exact behavior is done as follows:
If the GAP expression EXPR
evaluates to true
, then the lines after the #@if
are used until either a #@else
or #@fi
is reached. If a #@else
is present then the code after the #@else
is used if and only if EXPR
evaluated to false
. Finally, once #fi
is reached, evaluation continues normally.
Note that EXPR
is evaluated after all #@exec
lines have been executed but before any tests are run. Thus, it cannot depend on test results or packages loaded in tests, but it can depend on packages loaded via #@exec
.
As an example, the GAP test suite contains the test file tst/testinstall/pperm.tst
which contains the lines:
#@if GAPInfo.BytesPerVariable = 8 gap> HASH_FUNC_FOR_PPERM(f, 10 ^ 6) in [260581, 402746]; true #@else gap> HASH_FUNC_FOR_PPERM(f, 10 ^ 6); 953600 #@fi
By default the actual GAP output is compared exactly with the stored output, and if these are different some information about the differences is printed.
If any differences are found then Test
returns false
, otherwise true
.
If the optional argument optrec is given it must be a record. The following components of optrec are recognized and can change the default behaviour of Test
:
ignoreComments
If set to false
then no lines in fname are ignored as explained above (default is true
).
width
The screen width used for the new output (default is 80
).
compareFunction
This must be a function that gets two strings as input, the newly generated and the stored output of some GAP input. The function must return true
or false
, indicating if the strings should be considered equivalent or not. By default \=
(31.11-1) is used.
Two strings are recognized as abbreviations in this component: "uptowhitespace"
checks if the two strings become equal after removing all white space. And "uptonl"
compares the string up to trailing newline characters.
transformFunction
This must be a function that gets one string as input, either the newly generated or the stored output of some GAP input. The function must return a new string which will be used to compare the actual and the expected output. By default IdFunc
(5.4-6) is used.
Two strings are recognized as abbreviations in this component: "removewhitespace"
removes all white space. And "removenl"
removes all trailing newline characters.
reportDiff
A function that gets six arguments and reports a difference in the output: the GAP input, the expected GAP output, the newly generated output, the name of tested file, the line number of the input, the time to run the input. (The default is demonstrated in the example below.)
rewriteToFile
If this is bound to a string it is considered as a file name and that file is written with the same input and comment lines as fname but the output substituted by the newly generated version; if it is bound to true
, then this is treated as if it was bound to fname (default is false
). This is especially useful for generating test files because it ensures that the test files are formatted exactly as Test
expects them to be.
writeTimings
If this is bound to a string it is considered as a file name, that file is written and contains timing information for each input in fname.
compareTimings
If this is bound to a string it is considered as name of a file to which timing information was stored via writeTimings
in a previous call. The new timings are compared to the stored ones. By default only commands which take more than a threshold of 100 milliseconds are considered, and only differences of more than 20% are considered significant. These defaults can be overwritten by assigning a list [timingfile, threshold, percentage]
to this component. (The default of compareTimings
is false
.)
reportTimeDiff
This component can be used to overwrite the default function to display timing differences. It must be a function with 5 arguments: GAP input, name of test file, line number, stored time, new time.
ignoreSTOP_TEST
By default set to true
, in that case the output of GAP input starting with "STOP_TEST"
is not checked.
showProgress
If this is true
then GAP prints position information and the input line before it is processed; if set to "some"
, then GAP shows the current line number of the test being processed; if set to false
, no progress updates are displayed (default is "some"
if GAP's output goes to a terminal, otherwise false
).
subsWindowsLineBreaks
If this is true
then GAP substitutes DOS/Windows style line breaks "\r\n" by UNIX style line breaks "\n" after reading the test file. (default is true
).
returnNumFailures
If this is true
then GAP returns the number of input lines of the test file which had differences in their output, instead of returning true
or false
.
gap> tnam := Filename(DirectoriesLibrary(), "../doc/ref/demo.tst");; gap> mask := function(str) return Concatenation("| ", > JoinStringsWithSeparator(SplitString(str, "\n", ""), "\n| "), > "\n"); end;; gap> Print(mask(StringFile(tnam))); | # this is a demo file for the 'Test' function | # | gap> g := Group((1,2), (1,2,3)); | Group([ (1,2), (1,2,3) ]) | | # another comment following an empty line | # the following fails: | gap> a := 13+29; | 41 gap> ss := InputTextString(StringFile(tnam));; gap> Test(ss); ########> Diff in test stream, line 8: # Input is: a := 13+29; # Expected output: 41 # But found: 42 ######## false gap> RewindStream(ss); true gap> dtmp := DirectoryTemporary();; gap> ftmp := Filename(dtmp,"demo.tst");; gap> Test(ss, rec(reportDiff := Ignore, rewriteToFile := ftmp)); false gap> Test(ftmp); true gap> Print(mask(StringFile(ftmp))); | # this is a demo file for the 'Test' function | # | gap> g := Group((1,2), (1,2,3)); | Group([ (1,2), (1,2,3) ]) | | # another comment following an empty line | # the following fails: | gap> a := 13+29; | 42
‣ TestDirectory ( inlist[, optrec] ) | ( function ) |
Returns: true
or false
.
The argument inlist must be either a single filename or directory name, or a list of filenames and directories. The function TestDirectory
will create a list of files to be tested by taking any files in inlist, and recursively searching any directories in inlist for files ending in .tst
. Each of these files is then run through Test
(7.10-2), and the results printed, and true
returned if all tests passed.
If the optional argument optrec is given it must be a record. Note that the rewriteToFile
option is especially useful for generating test files. The following components of optrec are recognized and can change the default behaviour of TestDirectory
:
testOptions
A record which will be passed on as the second argument of Test
(7.10-2) if present.
earlyStop
If true
, stop as soon as any Test
(7.10-2) fails (defaults to false
).
showProgress
Print information about how tests are progressing (defaults to "some"
if GAP's output goes to a terminal, otherwise false
).
suppressStatusMessage
suppress displaying status messages #I Errors detected while testing
and #I No errors detected while testing
after the test (defaults to false
).
rewriteToFile
If true
, then rewrite each test file to disc, with the output substituted by the results of running the test (defaults to false
). This is especially useful for generating test files because it ensures that the test files are formatted exactly as Test
(7.10-2) expects them to be.
exclude
A list of file and directory names which will be excluded from testing (defaults to []
).
exitGAP
Rather than returning true
or false
, exit GAP with the return value of GAP set to success or fail, depending on if all tests passed (defaults to false
).
See also TestPackage
(76.3-5) for the information on running standard tests for GAP packages.
The GAP interpreter monitors the level of nesting of GAP functions during execution. By default, whenever this nesting reaches a multiple of 5000, GAP enters a break loop (6.4) allowing you to terminate the calculation, or enter Return;
to continue it.
gap> dive:= function(depth) if depth>1 then dive(depth-1); fi; return; end; function( depth ) ... end gap> dive(100); gap> OnBreak:= function() Where(1); end; # shorter traceback function( ) ... end gap> dive(6000); recursion depth trap (5000) at dive( depth - 1 ); called from dive( depth - 1 ); called from ... Entering break read-eval-print loop ... you can 'quit;' to quit to outer loop, or you may 'return;' to continue brk> return; gap> dive(11000); recursion depth trap (5000) at dive( depth - 1 ); called from dive( depth - 1 ); called from ... Entering break read-eval-print loop ... you can 'quit;' to quit to outer loop, or you may 'return;' to continue brk> return; recursion depth trap (10000) at dive( depth - 1 ); called from dive( depth - 1 ); called from ... Entering break read-eval-print loop ... you can 'quit;' to quit to outer loop, or you may 'return;' to continue brk> return; gap>
This behaviour can be controlled using the following procedures.
‣ SetRecursionTrapInterval ( interval ) | ( function ) |
‣ GetRecursionDepth ( ) | ( function ) |
GetRecursionDepth
returns the nesting level of the GAP interpreter. This is reset to 0 every time the break loop is entered. SetRecursionTrapInterval
sets the depth of the stack at which GAP will enter the Break loop. interval must be a non-negative small integer (between 0 and 2^28). An interval of 0 suppresses the monitoring of recursion altogether. In this case excessive recursion may cause GAP to crash.
gap> GetRecursionDepth(); 0 gap> dive := function(depth) > if depth>1 then > dive(depth-1); > else > Print("Depth ", GetRecursionDepth()); > fi; > end;; gap> SetRecursionTrapInterval(1000); gap> dive(100); Depth 100 gap> dive(2500); recursion depth trap (1000) at dive( depth - 1 ); called from dive( depth - 1 ); called from ... Entering break read-eval-print loop ... you can 'quit;' to quit to outer loop, or you may 'return;' to continue brk> return; recursion depth trap (2000) at dive( depth - 1 ); called from dive( depth - 1 ); called from ... Entering break read-eval-print loop ... you can 'quit;' to quit to outer loop, or you may 'return;' to continue brk> GetRecursionDepth(); 0 brk> return; gap> SetRecursionTrapInterval(-1); Error, SetRecursionTrapInterval: <interval> must be a small integer greater than 5 (n\ ot the integer -1) not in any function Entering break read-eval-print loop ... you can 'quit;' to quit to outer loop, or you can replace <interval> via 'return <interval>;' to continue brk> return 0; gap> dive(20000); Depth 20000 gap> dive(2000000); Segmentation fault
The GAP environment provides automatic memory management, so that the programmer does not need to concern themselves with allocating space for objects, or recovering space when objects are no longer needed. The memory manager that shall be used by GAP is specified at compile time. One of the choices is called GASMAN
(GAP Storage MANager). (The name of the currently used garbage collector is stored in the variable GAPInfo.KernelInfo.GC
.)
If GAP uses GASMAN
then messages reporting garbage collections performed by GASMAN
can be switched on by the -g
command line option (see section 3.1). There are also some facilities to access information from GASMAN
from GAP programs, see below.
‣ CollectGarbage ( full ) | ( function ) |
Returns: nothing.
This function forces a garbage collection. If full is true
then it triggers a full garbage collection, otherwise a partial one.
GAP invokes its garbage collector automatically, thus there is normally no need to call CollectGarbage
.
The function CollectGarbage
was introduced in GAP 4.12. In older GAP versions, one can use GASMAN( "collect" )
(if full is true
) or GASMAN( "partial" )
(if full is not true
) instead.
gap> CollectGarbage( false ); gap> CollectGarbage( true );
‣ GasmanStatistics ( ) | ( function ) |
This function is meaningful only if GASMAN
is the garbage collector used by GAP, see Section 7.12-1.
GasmanStatistics
returns a record containing some information from the garbage collection mechanism. The record may contain up to four components: full
, partial
, npartial
, and nfull
.
The full
component will be present if a full garbage collection has taken place since GAP started. It contains information about the most recent full garbage collection. It is a record, with eight components: livebags
contains the number of bags which survived the garbage collection; livekb
contains the total number of kilobytes occupied by those bags; deadbags
contains the total number of bags which were reclaimed by that garbage collection and all the partial garbage collections preceding it, since the previous full garbage collection; deadkb
contains the total number of kilobytes occupied by those bags; freekb
reports the total number of kilobytes available in the GAP workspace for new objects; totalkb
reports the actual size of the workspace; time
reports the CPU time in milliseconds spent on the last garbage collection and cumulative
the total CPU time in milliseconds spent on that type of garbage collection since GAP started.
These figures should be viewed with some caution. They are stored internally in fixed length integer formats, and deadkb
and deadbags
are liable to overflow if there are many partial collections before a full collection. Also, note that livekb
and freekb
will not usually add up to totalkb
. The difference is essentially the space overhead of the memory management system.
The partial
component will be present if there has been a partial garbage collection since the last full one. It is also a record with the same six components as full
. In this case deadbags
and deadkb
refer only to the number and total size of the garbage bags reclaimed in this partial garbage collection and livebags
and livekb
only to the numbers and total size of the young bags that were considered for garbage collection, and survived.
The npartial
and nfull
components will contain the number of full and partial garbage collections performed since GAP started.
‣ GasmanMessageStatus ( ) | ( function ) |
‣ SetGasmanMessageStatus ( stat ) | ( function ) |
This function is meaningful only if GASMAN
is the garbage collector used by GAP, see Section 7.12-1.
GasmanMessageStatus
returns one of the strings "none"
, "full"
, or "all"
, depending on whether the garbage collector is currently set to print messages on no collections, full collections only, or all collections, respectively.
Calling SetGasmanMessageStatus
with the argument stat, which should be one of the three strings mentioned above, sets the garbage collector messaging level.
‣ GasmanLimits ( ) | ( function ) |
This function is meaningful only if GASMAN
is the garbage collector used by GAP, see Section 7.12-1.
GasmanLimits
returns a record with three components: min
is the minimum workspace size as set by the -m
command line option in kilobytes. The workspace size will never be reduced below this by the garbage collector. max
is the maximum workspace size, as set by the -o
command line option, also in kilobytes. If the workspace would need to grow past this point, GAP will enter a break loop to warn the user. A value of 0 indicates no limit. kill
is the absolute maximum, set by the -K
command line option. The workspace will never be allowed to grow past this limit.
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