An object is anything in GAP that can be assigned to a variable, so nearly everything in GAP is an object.
Different objects can be regarded as equal with respect to the equivalence relation
, in this case we say that the objects describe the same element.=
Nearly all things one deals with in GAP are objects. For example, an integer is an object, as is a list of integers, a matrix, a permutation, a function, a list of functions, a record, a group, a coset or a conjugacy class in a group.
Examples of things that are not objects are comments which are only lexical constructs, while
loops which are only syntactical constructs, and expressions, such as 1 + 1
; but note that the value of an expression, in this case the integer 2
, is an object.
Objects can be assigned to variables, and everything that can be assigned to a variable is an object. Analogously, objects can be used as arguments of functions, and can be returned by functions.
‣ IsObject ( obj ) | ( category ) |
IsObject
returns true
if the object obj is an object. Obviously it can never return false
.
It can be used as a filter in InstallMethod
(78.3-1) when one of the arguments can be anything.
The equality operation
defines an equivalence relation on all GAP objects. The equivalence classes are called elements.=
There are basically three reasons to regard different objects as equal. Firstly the same information may be stored in different places. Secondly the same information may be stored in different ways; for example, a polynomial can be stored sparsely or densely. Thirdly different information may be equal modulo a mathematical equivalence relation. For example, in a finitely presented group with the relation \(a^2 = 1\) the different objects \(a\) and \(a^3\) describe the same element.
As an example of all three reasons, consider the possibility of storing an integer in several places of the memory, of representing it as a fraction with denominator 1, or of representing it as a fraction with any denominator, and numerator a suitable multiple of the denominator.
In GAP there is no category whose definition corresponds to the mathematical property of being a set, however in the manual we will often refer to an object as a set in order to convey the fact that mathematically, we are thinking of it as a set. In particular, two sets \(A\) and \(B\) are equal if and only if, \(x \in A \iff x \in B\).
There are two types of object in GAP which exhibit this kind of behaviour with respect to equality, namely domains (see Section 12.4) and lists whose elements are strictly sorted see IsSSortedList
(21.17-4). In general, set in this manual will mean an object of one of these types.
More precisely: two domains can be compared with {
, the answer being =
}true
if and only if the sets of elements are equal (regardless of any additional structure) and; a domain and a list can be compared with
, the answer being =
true
if and only if the list is equal to the strictly sorted list of elements of the domain.
A discussion about sorted lists and sets can be found in Section 21.19.
An especially important class of objects in GAP are those whose underlying mathematical abstraction is that of a structured set, for example a group, a conjugacy class, or a vector space. Such objects are called domains. The equality relation between domains is always equality as sets, so that two domains are equal if and only if they contain the same elements.
Domains play a central role in GAP. In a sense, the only reason that GAP supports objects such as integers and permutations is the wish to form domains of them and compute the properties of those domains.
Domains are described in Chapter 31.
Two objects that are equal as objects (that is they actually refer to the same area of computer memory) and not only w.r.t. the equality relation
are called identical. Identical objects do of course describe the same element.=
‣ IsIdenticalObj ( obj1, obj2 ) | ( function ) |
IsIdenticalObj
tests whether the objects obj1 and obj2 are identical (that is they are either equal immediate objects or are both stored at the same location in memory.
If two copies of a simple constant object (see section 12.6) are created, it is not defined whether GAP will actually store two equal but non-identical objects, or just a single object. For mutable objects, however, it is important to know whether two values refer to identical or non-identical objects, and the documentation of operations that return mutable values should make clear whether the values returned are new, or may be identical to values stored elsewhere.
gap> IsIdenticalObj( 10^6, 10^6); true gap> IsIdenticalObj( 10^30, 10^30); false gap> IsIdenticalObj( true, true); true
Generally, one may compute with objects but think of the results in terms of the underlying elements because one is not interested in locations in memory, data formats or information beyond underlying equivalence relations. But there are cases where it is important to distinguish the relations identity and equality. This is best illustrated with an example. (The reader who is not familiar with lists in GAP, in particular element access and assignment, is referred to Chapter 21.)
gap> l1:= [ 1, 2, 3 ];; l2:= [ 1, 2, 3 ];; gap> l1 = l2; true gap> IsIdenticalObj( l1, l2 ); false gap> l1[3]:= 4;; l1; l2; [ 1, 2, 4 ] [ 1, 2, 3 ] gap> l1 = l2; false
The two lists l1
and l2
are equal but not identical. Thus a change in l1
does not affect l2
.
gap> l1:= [ 1, 2, 3 ];; l2:= l1;; gap> l1 = l2; true gap> IsIdenticalObj( l1, l2 ); true gap> l1[3]:= 4;; l1; l2; [ 1, 2, 4 ] [ 1, 2, 4 ] gap> l1 = l2; true
Here, l1
and l2
are identical objects, so changing l1
means a change to l2
as well.
‣ IsNotIdenticalObj ( obj1, obj2 ) | ( function ) |
tests whether the objects obj1 and obj2 are not identical.
An object in GAP is said to be immutable if its mathematical value (as defined by \(=\)) does not change under any operation. More explicitly, suppose \(a\) is immutable and \(O\) is some operation on \(a\), then if \(a = b\) evaluates to true
before executing \(O(a)\), \(a = b\) also evaluates to true
afterwards. (Examples for operations \(O\) that change mutable objects are Add
(21.4-2) and Unbind
(21.5-3) which are used to change list objects, see Chapter 21.) An immutable object may change, for example to store new information, or to adopt a more efficient representation, but this does not affect its behaviour under \(=\).
There are two points here to note. Firstly, operation
above refers to the functions and methods which can legitimately be applied to the object, and not the !.
operation whereby virtually any aspect of any GAP level object may be changed. The second point which follows from this, is that when implementing new types of objects, it is the programmer's responsibility to ensure that the functions and methods they write never change immutable objects mathematically.
In fact, most objects with which one deals in GAP are immutable. For instance, the permutation (1,2)
will never become a different permutation or a non-permutation (although a variable which previously had (1,2)
stored in it may subsequently have some other value).
For many purposes, however, mutable objects are useful. These objects may be changed to represent different mathematical objects during their life. For example, mutable lists can be changed by assigning values to positions or by unbinding values at certain positions. Similarly, one can assign values to components of a mutable record, or unbind them.
‣ IsCopyable ( obj ) | ( category ) |
If a mutable form of an object obj can be made in GAP, the object is called copyable. Examples of copyable objects are of course lists and records. A new mutable version of the object can always be obtained by the operation ShallowCopy
(12.7-1).
Objects for which only an immutable form exists in GAP are called constants. Examples of constants are integers, permutations, and domains. Called with a constant as argument, Immutable
(12.6-3) and ShallowCopy
(12.7-1) return this argument.
‣ IsMutable ( obj ) | ( category ) |
tests whether obj is mutable.
If an object is mutable then it is also copyable (see IsCopyable
(12.6-1)), and a ShallowCopy
(12.7-1) method should be supplied for it. Note that IsMutable
must not be implied by another filter, since otherwise Immutable
(12.6-3) would be able to create paradoxical objects in the sense that IsMutable
for such an object is false
but the filter that implies IsMutable
is true
.
In many situations, however, one wants to ensure that objects are immutable. For example, take the identity of a matrix group. Since this matrix may be referred to as the identity of the group in several places, it would be fatal to modify its entries, or add or unbind rows. We can obtain an immutable copy of an object with Immutable
(12.6-3).
‣ Immutable ( obj ) | ( function ) |
returns an immutable structural copy (see StructuralCopy
(12.7-2)) of obj in which the subobjects are immutable copies of the subobjects of obj. If obj is immutable then Immutable
returns obj itself.
GAP will complain with an error if one tries to change an immutable object.
‣ MakeImmutable ( obj ) | ( function ) |
One can turn the (mutable or immutable) object obj into an immutable one with MakeImmutable
; note that this also makes all subobjects of obj immutable, so one should call MakeImmutable
only if obj and its mutable subobjects are newly created. If one is not sure about this, Immutable
(12.6-3) should be used.
Note that it is not possible to turn an immutable object into a mutable one; only mutable copies can be made (see 12.7).
Using Immutable
(12.6-3), it is possible to store an immutable identity matrix or an immutable list of generators, and to pass around references to this immutable object safely. Only when a mutable copy is really needed does the actual object have to be duplicated. Compared to the situation without immutable objects, much unnecessary copying is avoided this way. Another advantage of immutability is that lists of immutable objects may remember whether they are sorted (see 21.19), which is not possible for lists of mutable objects.
Since the operation Immutable
(12.6-3) must work for any object in GAP, it follows that an immutable form of every object must be possible, even if it is not sensible, and user-defined objects must allow for the possibility of becoming immutable without notice.
An interesting example of mutable (and thus copyable) objects is provided by iterators, see 30.8. (Of course an immutable form of an iterator is not very useful, but clearly Immutable
(12.6-3) will yield such an object.) Every call of NextIterator
(30.8-5) changes a mutable iterator until it is exhausted, and this is the only way to change an iterator. ShallowCopy
(12.7-1) for an iterator iter is defined so as to return a mutable iterator that has no mutable data in common with iter, and that behaves equally to iter w.r.t. IsDoneIterator
(30.8-4) and (if iter is mutable) NextIterator
(30.8-5). Note that this meaning of the shallow copy
of an iterator that is returned by ShallowCopy
(12.7-1) is not as obvious as for lists and records, and must be explicitly defined.
Many operations return immutable results, among those in particular attributes (see 13.5). Examples of attributes are Size
(30.4-6), Zero
(31.10-3), AdditiveInverse
(31.10-9), One
(31.10-2), and Inverse
(31.10-8). Arithmetic operations, such as the binary infix operations +
, -
, *
, /
, ^
, mod
, the unary -
, and operations such as Comm
(31.12-3) and LeftQuotient
(31.12-2), return mutable results, except if all arguments are immutable. So the product of two matrices or of a vector and a matrix is immutable if and only if the two matrices or both the vector and the matrix are immutable (see also 21.11). There is one exception to this rule, which arises where the result is less deeply nested than at least one of the argument, where mutable arguments may sometimes lead to an immutable result. For instance, a mutable matrix with immutable rows, multiplied by an immutable vector gives an immutable vector result. The exact rules are given in 21.11.
It should be noted that 0 * obj
is equivalent to ZeroSameMutability( obj )
, -obj
is equivalent to AdditiveInverseSameMutability( obj )
, obj^0
is equivalent to OneSameMutability( obj)
, and obj^-1
is equivalent to InverseSameMutability( obj )
. The suffix SameMutability
indicates that the result is mutable if and only if the argument is mutable.
The operations ZeroOp
(31.10-3), AdditiveInverseOp
(31.10-9), OneOp
(31.10-2), and InverseOp
(31.10-8) return mutable results whenever a mutable version of the result exists, contrary to the attributes Zero
(31.10-3), AdditiveInverse
(31.10-9), One
(31.10-2), and Inverse
(31.10-8).
If one introduces new arithmetic objects then one need not install methods for the attributes One
(31.10-2), Zero
(31.10-3), etc. The methods for the associated operations OneOp
(31.10-2) and ZeroOp
(31.10-3) will be called, and then the results made immutable.
All methods installed for the arithmetic operations must obey the rule about the mutability of the result. This means that one may try to avoid the perhaps expensive creation of a new object if both operands are immutable, and of course no problems of this kind arise at all in the (usual) case that the objects in question do not admit a mutable form, i.e., that these objects are not copyable.
In a few, relatively low-level algorithms, one wishes to treat a matrix partly as a data structure, and manipulate and change its entries. For this, the matrix needs to be mutable, and the rule that attribute values are immutable is an obstacle. For these situations, a number of additional operations are provided, for example TransposedMatMutable
(24.5-7) constructs a mutable matrix (contrary to the attribute TransposedMat
(24.5-7)), while TriangulizeMat
(24.7-3) modifies a mutable matrix (in place) into upper triangular form.
Note that being immutable does not forbid an object to store knowledge. For example, if it is found out that an immutable list is strictly sorted then the list may store this information. More precisely, an immutable object may change in any way, provided that it continues to represent the same mathematical object.
‣ ShallowCopy ( obj ) | ( operation ) |
ShallowCopy
returns a new mutable object equal to its argument, if this is possible. The subobjects of ShallowCopy( obj )
are identical to the subobjects of obj.
If GAP does not support a mutable form of the immutable object obj (see 12.6) then ShallowCopy
returns obj itself.
Since ShallowCopy
is an operation, the concrete meaning of subobject
depends on the type of obj. But for any copyable object obj, the definition should reflect the idea of first level copying
.
The definition of ShallowCopy
for lists (in particular for matrices) can be found in 21.7.
‣ StructuralCopy ( obj ) | ( function ) |
In a few situations, one wants to make a structural copy scp
of an object obj. This is defined as follows. scp
and obj are identical if obj is immutable. Otherwise, scp
is a mutable copy of obj such that each subobject of scp
is a structural copy of the corresponding subobject of obj. Furthermore, if two subobjects of obj are identical then also the corresponding subobjects of scp
are identical.
gap> obj:= [ [ 0, 1 ] ];; gap> obj[2]:= obj[1];; gap> obj[3]:= Immutable( obj[1] );; gap> scp:= StructuralCopy( obj );; gap> scp = obj; IsIdenticalObj( scp, obj ); true false gap> IsIdenticalObj( scp[1], obj[1] ); false gap> IsIdenticalObj( scp[3], obj[3] ); true gap> IsIdenticalObj( scp[1], scp[2] ); true
That both ShallowCopy
(12.7-1) and StructuralCopy
return the argument obj itself if it is not copyable is consistent with this definition, since there is no way to change obj by modifying the result of any of the two functions, because in fact there is no way to change this result at all.
There are a number of general operations which can be applied, in principle, to any object in GAP. Some of these are documented elsewhere –see String
(27.7-6), PrintObj
(6.3-5) and Display
(6.3-6). Others are mainly somewhat technical.
‣ SetName ( obj, name ) | ( operation ) |
for a suitable object obj sets that object to have name name (a string).
‣ Name ( obj ) | ( attribute ) |
returns the name, a string, previously assigned to obj via a call to SetName
(12.8-1). The name of an object is used only for viewing the object via this name.
There are no methods installed for computing names of objects, but the name may be set for suitable objects, using SetName
(12.8-1).
gap> R := PolynomialRing(Integers,2); Integers[x_1,x_2] gap> SetName(R,"Z[x,y]"); gap> R; Z[x,y] gap> Name(R); "Z[x,y]"
‣ InfoText ( obj ) | ( attribute ) |
is a mutable string with information about the object obj. There is no default method to create an info text.
‣ IsInternallyConsistent ( obj ) | ( operation ) |
For debugging purposes, it may be useful to check the consistency of an object obj that is composed from other (composed) objects.
There is a default method of IsInternallyConsistent
, with rank zero, that returns true
. So it is possible (and recommended) to check the consistency of subobjects of obj recursively by IsInternallyConsistent
.
(Note that IsInternallyConsistent
is not an attribute.)
‣ MemoryUsage ( obj ) | ( function ) |
Returns the amount of memory in bytes used by the object obj and its subobjects. Note that in general, objects can reference each other in very difficult ways such that determining the memory usage is a recursive procedure. In particular, computing the memory usage of a complicated structure itself uses some additional memory, which is however no longer used after completion of this operation. This procedure descends into lists and records, positional and component objects; however it deliberately does not take into account the type and family objects. For functions, it only takes the memory usage of the function body, not of the local context the function was created in, although the function keeps a reference to that as well.
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