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GAP 4.8.9 installation with standard packages -- copy to your CoCalc project to get it

Path: gap4r8 / doc / ref / chap12.txt
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12 Objects and Elements
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An object is anything in GAP that can be assigned to a variable, so nearly
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everything in GAP is an object.
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Different objects can be regarded as equal with respect to the equivalence
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relation =, in this case we say that the objects describe the same element.
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12.1 Objects
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Nearly all things one deals with in GAP are objects. For example, an integer
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is an object, as is a list of integers, a matrix, a permutation, a function,
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a list of functions, a record, a group, a coset or a conjugacy class in a
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group.
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Examples of things that are not objects are comments which are only lexical
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constructs, while loops which are only syntactical constructs, and
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expressions, such as 1 + 1; but note that the value of an expression, in
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this case the integer 2, is an object.
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Objects can be assigned to variables, and everything that can be assigned to
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a variable is an object. Analogously, objects can be used as arguments of
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functions, and can be returned by functions.
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12.1-1 IsObject
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IsObject( obj )  Category
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IsObject returns true if the object obj is an object. Obviously it can never
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return false.
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It can be used as a filter in InstallMethod (78.2-1) when one of the
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arguments can be anything.
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12.2 Elements as equivalence classes
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The equality operation = defines an equivalence relation on all GAP objects.
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The equivalence classes are called elements.
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There are basically three reasons to regard different objects as equal.
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Firstly the same information may be stored in different places. Secondly the
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same information may be stored in different ways; for example, a polynomial
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can be stored sparsely or densely. Thirdly different information may be
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equal modulo a mathematical equivalence relation. For example, in a finitely
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presented group with the relation a^2 = 1 the different objects a and a^3
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describe the same element.
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As an example of all three reasons, consider the possibility of storing an
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integer in several places of the memory, of representing it as a fraction
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with denominator 1, or of representing it as a fraction with any
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denominator, and numerator a suitable multiple of the denominator.
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12.3 Sets
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In GAP there is no category whose definition corresponds to the mathematical
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property of being a set, however in the manual we will often refer to an
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object as a set in order to convey the fact that mathematically, we are
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thinking of it as a set. In particular, two sets A and B are equal if and
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only if, x ∈ A <=> x ∈ B.
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There are two types of object in GAP which exhibit this kind of behaviour
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with respect to equality, namely domains (see Section 12.4) and lists whose
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elements are strictly sorted see IsSSortedList (21.17-4). In general, set in
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this manual will mean an object of one of these types.
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More precisely: two domains can be compared with {=}, the answer being true
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if and only if the sets of elements are equal (regardless of any additional
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structure) and; a domain and a list can be compared with =, the answer being
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true if and only if the list is equal to the strictly sorted list of
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elements of the domain.
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A discussion about sorted lists and sets can be found in Section 21.19.
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12.4 Domains
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An especially important class of objects in GAP are those whose underlying
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mathematical abstraction is that of a structured set, for example a group, a
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conjugacy class, or a vector space. Such objects are called domains. The
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equality relation between domains is always equality as sets, so that two
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domains are equal if and only if they contain the same elements.
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Domains play a central role in GAP. In a sense, the only reason that GAP
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supports objects such as integers and permutations is the wish to form
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domains of them and compute the properties of those domains.
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Domains are described in Chapter 31.
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12.5 Identical Objects
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Two objects that are equal as objects (that is they actually refer to the
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same area of computer memory) and not only w.r.t. the equality relation =
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are called identical. Identical objects do of course describe the same
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element.
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12.5-1 IsIdenticalObj
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IsIdenticalObj( obj1, obj2 )  function
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IsIdenticalObj tests whether the objects obj1 and obj2 are identical (that
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is they are either equal immediate objects or are both stored at the same
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location in memory.
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If two copies of a simple constant object (see section 12.6) are created, it
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is not defined whether GAP will actually store two equal but non-identical
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objects, or just a single object. For mutable objects, however, it is
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important to know whether two values refer to identical or non-identical
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objects, and the documentation of operations that return mutable values
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should make clear whether the values returned are new, or may be identical
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to values stored elsewhere.
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 Example 
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gap> IsIdenticalObj( 10^6, 10^6);
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true
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gap> IsIdenticalObj( 10^30, 10^30);
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false
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gap> IsIdenticalObj( true, true);
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true
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Generally, one may compute with objects but think of the results in terms of
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the underlying elements because one is not interested in locations in
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memory, data formats or information beyond underlying equivalence relations.
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But there are cases where it is important to distinguish the relations
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identity and equality. This is best illustrated with an example. (The reader
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who is not familiar with lists in GAP, in particular element access and
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assignment, is referred to Chapter 21.)
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 Example 
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gap> l1:= [ 1, 2, 3 ];; l2:= [ 1, 2, 3 ];;
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gap> l1 = l2;
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true
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gap> IsIdenticalObj( l1, l2 );
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false
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gap> l1[3]:= 4;; l1; l2;
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[ 1, 2, 4 ]
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[ 1, 2, 3 ]
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gap> l1 = l2;
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false
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The two lists l1 and l2 are equal but not identical. Thus a change in l1
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does not affect l2.
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 Example 
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gap> l1:= [ 1, 2, 3 ];; l2:= l1;;
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gap> l1 = l2;
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true
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gap> IsIdenticalObj( l1, l2 );
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true
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gap> l1[3]:= 4;; l1; l2;
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[ 1, 2, 4 ]
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[ 1, 2, 4 ]
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gap> l1 = l2;
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true
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Here, l1 and l2 are identical objects, so changing l1 means a change to l2
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as well.
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12.5-2 IsNotIdenticalObj
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IsNotIdenticalObj( obj1, obj2 )  function
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tests whether the objects obj1 and obj2 are not identical.
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12.6 Mutability and Copyability
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An object in GAP is said to be immutable if its mathematical value (as
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defined by =) does not change under any operation. More explicitly, suppose
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a is immutable and O is some operation on a, then if a = b evaluates to true
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before executing O(a), a = b also evaluates to true afterwards. (Examples
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for operations O that change mutable objects are Add (21.4-2) and Unbind
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(21.5-2) which are used to change list objects, see Chapter 21.) An
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immutable object may change, for example to store new information, or to
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adopt a more efficient representation, but this does not affect its
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behaviour under =.
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There are two points here to note. Firstly, operation above refers to the
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functions and methods which can legitimately be applied to the object, and
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not the !. operation whereby virtually any aspect of any GAP level object
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may be changed. The second point which follows from this, is that when
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implementing new types of objects, it is the programmer's responsibility to
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ensure that the functions and methods they write never change immutable
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objects mathematically.
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In fact, most objects with which one deals in GAP are immutable. For
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instance, the permutation (1,2) will never become a different permutation or
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a non-permutation (although a variable which previously had (1,2) stored in
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it may subsequently have some other value).
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For many purposes, however, mutable objects are useful. These objects may be
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changed to represent different mathematical objects during their life. For
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example, mutable lists can be changed by assigning values to positions or by
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unbinding values at certain positions. Similarly, one can assign values to
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components of a mutable record, or unbind them.
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12.6-1 IsCopyable
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IsCopyable( obj )  Category
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If a mutable form of an object obj can be made in GAP, the object is called
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copyable. Examples of copyable objects are of course lists and records. A
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new mutable version of the object can always be obtained by the operation
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ShallowCopy (12.7-1).
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Objects for which only an immutable form exists in GAP are called constants.
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Examples of constants are integers, permutations, and domains. Called with a
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constant as argument, Immutable (12.6-3) and ShallowCopy (12.7-1) return
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this argument.
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12.6-2 IsMutable
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IsMutable( obj )  Category
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tests whether obj is mutable.
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If an object is mutable then it is also copyable (see IsCopyable (12.6-1)),
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and a ShallowCopy (12.7-1) method should be supplied for it. Note that
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IsMutable must not be implied by another filter, since otherwise Immutable
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(12.6-3) would be able to create paradoxical objects in the sense that
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IsMutable for such an object is false but the filter that implies IsMutable
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is true.
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In many situations, however, one wants to ensure that objects are immutable.
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For example, take the identity of a matrix group. Since this matrix may be
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referred to as the identity of the group in several places, it would be
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fatal to modify its entries, or add or unbind rows. We can obtain an
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immutable copy of an object with Immutable (12.6-3).
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12.6-3 Immutable
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Immutable( obj )  function
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returns an immutable structural copy (see StructuralCopy (12.7-2)) of obj in
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which the subobjects are immutable copies of the subobjects of obj. If obj
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is immutable then Immutable returns obj itself.
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GAP will complain with an error if one tries to change an immutable object.
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12.6-4 MakeImmutable
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MakeImmutable( obj )  function
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One can turn the (mutable or immutable) object obj into an immutable one
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with MakeImmutable; note that this also makes all subobjects of obj
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immutable, so one should call MakeImmutable only if obj and its mutable
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subobjects are newly created. If one is not sure about this, Immutable
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(12.6-3) should be used.
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Note that it is not possible to turn an immutable object into a mutable one;
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only mutable copies can be made (see 12.7).
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Using Immutable (12.6-3), it is possible to store an immutable identity
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matrix or an immutable list of generators, and to pass around references to
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this immutable object safely. Only when a mutable copy is really needed does
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the actual object have to be duplicated. Compared to the situation without
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immutable objects, much unnecessary copying is avoided this way. Another
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advantage of immutability is that lists of immutable objects may remember
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whether they are sorted (see 21.19), which is not possible for lists of
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mutable objects.
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Since the operation Immutable (12.6-3) must work for any object in GAP, it
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follows that an immutable form of every object must be possible, even if it
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is not sensible, and user-defined objects must allow for the possibility of
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becoming immutable without notice.
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12.6-5 Mutability of Iterators
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An interesting example of mutable (and thus copyable) objects is provided by
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iterators, see 30.8. (Of course an immutable form of an iterator is not very
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useful, but clearly Immutable (12.6-3) will yield such an object.) Every
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call of NextIterator (30.8-5) changes a mutable iterator until it is
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exhausted, and this is the only way to change an iterator. ShallowCopy
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(12.7-1) for an iterator iter is defined so as to return a mutable iterator
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that has no mutable data in common with iter, and that behaves equally to
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iter w.r.t. IsDoneIterator (30.8-4) and (if iter is mutable) NextIterator
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(30.8-5). Note that this meaning of the shallow copy of an iterator that is
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returned by ShallowCopy (12.7-1) is not as obvious as for lists and records,
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and must be explicitly defined.
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12.6-6 Mutability of Results of Arithmetic Operations
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Many operations return immutable results, among those in particular
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attributes (see 13.5). Examples of attributes are Size (30.4-6), Zero
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(31.10-3), AdditiveInverse (31.10-9), One (31.10-2), and Inverse (31.10-8).
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Arithmetic operations, such as the binary infix operations +, -, *, /, ^,
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mod, the unary -, and operations such as Comm (31.12-3) and LeftQuotient
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(31.12-2), return mutable results, except if all arguments are immutable. So
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the product of two matrices or of a vector and a matrix is immutable if and
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only if the two matrices or both the vector and the matrix are immutable
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(see also 21.11). There is one exception to this rule, which arises where
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the result is less deeply nested than at least one of the argument, where
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mutable arguments may sometimes lead to an immutable result. For instance, a
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mutable matrix with immutable rows, multiplied by an immutable vector gives
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an immutable vector result. The exact rules are given in 21.11.
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It should be noted that 0 * obj is equivalent to ZeroSM( obj ), -obj is
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equivalent to AdditiveInverseSM( obj ), obj^0 is equivalent to OneSM( obj),
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and obj^-1 is equivalent to InverseSM( obj ). The SM stands for same
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mutability, and indicates that the result is mutable if and only if the
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argument is mutable.
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The operations ZeroOp (31.10-3), AdditiveInverseOp (31.10-9), OneOp
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(31.10-2), and InverseOp (31.10-8) return mutable results whenever a mutable
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version of the result exists, contrary to the attributes Zero (31.10-3),
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AdditiveInverse (31.10-9), One (31.10-2), and Inverse (31.10-8).
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If one introduces new arithmetic objects then one need not install methods
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for the attributes One (31.10-2), Zero (31.10-3), etc. The methods for the
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associated operations OneOp (31.10-2) and ZeroOp (31.10-3) will be called,
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and then the results made immutable.
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All methods installed for the arithmetic operations must obey the rule about
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the mutability of the result. This means that one may try to avoid the
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perhaps expensive creation of a new object if both operands are immutable,
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and of course no problems of this kind arise at all in the (usual) case that
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the objects in question do not admit a mutable form, i.e., that these
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objects are not copyable.
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In a few, relatively low-level algorithms, one wishes to treat a matrix
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partly as a data structure, and manipulate and change its entries. For this,
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the matrix needs to be mutable, and the rule that attribute values are
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immutable is an obstacle. For these situations, a number of additional
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operations are provided, for example TransposedMatMutable (24.5-6)
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constructs a mutable matrix (contrary to the attribute TransposedMat
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(24.5-6)), while TriangulizeMat (24.7-3) modifies a mutable matrix (in
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place) into upper triangular form.
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Note that being immutable does not forbid an object to store knowledge. For
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example, if it is found out that an immutable list is strictly sorted then
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the list may store this information. More precisely, an immutable object may
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change in any way, provided that it continues to represent the same
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mathematical object.
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12.7 Duplication of Objects
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12.7-1 ShallowCopy
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ShallowCopy( obj )  operation
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ShallowCopy returns a new mutable object equal to its argument, if this is
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possible. The subobjects of ShallowCopy( obj ) are identical to the
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subobjects of obj.
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If GAP does not support a mutable form of the immutable object obj
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(see 12.6) then ShallowCopy returns obj itself.
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Since ShallowCopy is an operation, the concrete meaning of subobject depends
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on the type of obj. But for any copyable object obj, the definition should
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reflect the idea of first level copying.
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The definition of ShallowCopy for lists (in particular for matrices) can be
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found in 21.7.
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12.7-2 StructuralCopy
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StructuralCopy( obj )  function
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In a few situations, one wants to make a structural copy scp of an object
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obj. This is defined as follows. scp and obj are identical if obj is
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immutable. Otherwise, scp is a mutable copy of obj such that each subobject
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of scp is a structural copy of the corresponding subobject of obj.
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Furthermore, if two subobjects of obj are identical then also the
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corresponding subobjects of scp are identical.
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 Example 
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gap> obj:= [ [ 0, 1 ] ];;
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gap> obj[2]:= obj[1];;
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gap> obj[3]:= Immutable( obj[1] );;
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gap> scp:= StructuralCopy( obj );;
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gap> scp = obj; IsIdenticalObj( scp, obj );
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true
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false
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gap> IsIdenticalObj( scp[1], obj[1] );
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false
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gap> IsIdenticalObj( scp[3], obj[3] );
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true
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gap> IsIdenticalObj( scp[1], scp[2] );
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true
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That both ShallowCopy (12.7-1) and StructuralCopy return the argument obj
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itself if it is not copyable is consistent with this definition, since there
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is no way to change obj by modifying the result of any of the two functions,
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because in fact there is no way to change this result at all.
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12.8 Other Operations Applicable to any Object
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There are a number of general operations which can be applied, in principle,
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to any object in GAP. Some of these are documented elsewhere –see String
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(27.7-6), PrintObj (6.3-5) and Display (6.3-6). Others are mainly somewhat
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technical.
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12.8-1 SetName
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SetName( obj, name )  operation
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for a suitable object obj sets that object to have name name (a string).
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12.8-2 Name
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Name( obj )  attribute
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returns the name, a string, previously assigned to obj via a call to SetName
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(12.8-1). The name of an object is used only for viewing the object via this
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name.
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There are no methods installed for computing names of objects, but the name
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may be set for suitable objects, using SetName (12.8-1).
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 Example 
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gap> R := PolynomialRing(Integers,2);
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Integers[x_1,x_2]
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gap> SetName(R,"Z[x,y]");
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gap> R;
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Z[x,y]
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gap> Name(R);
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"Z[x,y]"
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12.8-3 InfoText
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InfoText( obj )  attribute
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is a mutable string with information about the object obj. There is no
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default method to create an info text.
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12.8-4 IsInternallyConsistent
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IsInternallyConsistent( obj )  operation
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For debugging purposes, it may be useful to check the consistency of an
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object obj that is composed from other (composed) objects.
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There is a default method of IsInternallyConsistent, with rank zero, that
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returns true. So it is possible (and recommended) to check the consistency
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of subobjects of obj recursively by IsInternallyConsistent.
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(Note that IsInternallyConsistent is not an attribute.)
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12.8-5 MemoryUsage
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MemoryUsage( obj )  operation
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returns the amount of memory in bytes used by the object obj and its
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subobjects. Note that in general, objects can reference each other in very
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difficult ways such that determining the memory usage is a recursive
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procedure. In particular, computing the memory usage of a complicated
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structure itself uses some additional memory, which is however no longer
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used after completion of this operation. This procedure descends into lists
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and records, positional and component objects, however it does not take into
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account the type and family objects! For functions, it only takes the memory
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usage of the function body, not of the local context the function was
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created in, although the function keeps a reference to that as well!
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