Strict Weak Ordering
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Category: functors |
Component type: concept |
Description
A Strict Weak Ordering is a Binary Predicate that compares two
objects, returning true if the first precedes the second. This
predicate must satisfy the standard mathematical definition of
a strict weak ordering. The precise requirements are stated
below, but what they roughly mean is that a Strict Weak Ordering has
to behave the way that "less than" behaves: if a is less than b
then b is not less than a, if a is less than b and b is less
than c then a is less than c, and so on.
Refinement of
Binary Predicate
Associated types
First argument type
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The type of the Strict Weak Ordering's first argument.
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Second argument type
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The type of the Strict Weak Ordering's second argument. The first
argument type and second argument type must be the same.
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Result type
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The type returned when the Strict Weak Ordering is called. The result type
must be convertible to bool.
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Notation
F
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A type that is a model of Strict Weak Ordering
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X
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The type of Strict Weak Ordering's arguments.
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f
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Object of type F
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x, y, z
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Object of type X
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Definitions
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Two objects x and y are equivalent if both f(x, y) and
f(y, x) are false. Note that an object is always (by the
irreflexivity invariant) equivalent to itself.
Valid expressions
None, except for those defined in the Binary Predicate requirements.
Expression semantics
Name
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Expression
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Precondition
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Semantics
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Postcondition
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Function call
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f(x, y)
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The ordered pair (x,y) is in the domain of f
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Returns true if x precedes y, and false otherwise
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The result is either true or false
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Complexity guarantees
Invariants
Irreflexivity
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f(x, x) must be false.
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Antisymmetry
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f(x, y) implies !f(y, x)
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Transitivity
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f(x, y) and f(y, z) imply f(x, z).
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Transitivity of equivalence
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Equivalence (as defined above) is transitive: if x is equivalent
to y and y is equivalent to z, then x is equivalent to z.
(This implies that equivalence does in fact satisfy the mathematical
definition of an equivalence relation.) [1]
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Models
Notes
[1]
The first three axioms, irreflexivity, antisymmetry, and
transitivity, are the definition of a partial ordering;
transitivity of equivalence is required by the definition of a
strict weak ordering. A total ordering is one that satisfies
an even stronger condition: equivalence must be the same as equality.
See also
LessThan Comparable, less, Binary Predicate,
function objects
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1996 Silicon Graphics, Inc. All Rights Reserved.
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