Regina 7.3 Calculation Engine
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Represents a blocked pair of Seifert fibred spaces joined along a single connecting torus. More...
#include <subcomplex/blockedsfspair.h>
Public Member Functions | |
BlockedSFSPair (const BlockedSFSPair &src)=default | |
Creates a new copy of the given structure. More... | |
BlockedSFSPair (BlockedSFSPair &&src) noexcept=default | |
Moves the contents of the given structure into this new structure. More... | |
BlockedSFSPair & | operator= (const BlockedSFSPair &src)=default |
Sets this to be a copy of the given structure. More... | |
BlockedSFSPair & | operator= (BlockedSFSPair &&src) noexcept=default |
Moves the contents of the given structure into this structure. More... | |
void | swap (BlockedSFSPair &other) noexcept |
Swaps the contents of this and the given structure. More... | |
const SatRegion & | region (int which) const |
Returns details of one of the two bounded saturated regions that form this triangulation. More... | |
const Matrix2 & | matchingReln () const |
Returns the matrix describing how the two saturated region boundaries are joined. More... | |
bool | operator== (const BlockedSFSPair &other) const |
Determines whether this and the given structure represent the same type of blocked pair of Seifert fibred spaces. More... | |
bool | operator!= (const BlockedSFSPair &other) const |
Determines whether this and the given structure do not represent the same type of blocked pair of Seifert fibred spaces. More... | |
std::unique_ptr< Manifold > | manifold () const override |
Returns the 3-manifold represented by this triangulation, if such a recognition routine has been implemented. More... | |
std::ostream & | writeName (std::ostream &out) const override |
Writes the name of this triangulation as a human-readable string to the given output stream. More... | |
std::ostream & | writeTeXName (std::ostream &out) const override |
Writes the name of this triangulation in TeX format to the given output stream. More... | |
void | writeTextLong (std::ostream &out) const override |
Writes a detailed text representation of this object to the given output stream. More... | |
std::string | name () const |
Returns the name of this specific triangulation as a human-readable string. More... | |
std::string | texName () const |
Returns the name of this specific triangulation in TeX format. More... | |
virtual AbelianGroup | homology () const |
Returns the expected first homology group of this triangulation, if such a routine has been implemented. More... | |
virtual void | writeTextShort (std::ostream &out) const |
Writes a short text representation of this object to the given output stream. More... | |
std::string | str () const |
Returns a short text representation of this object. More... | |
std::string | utf8 () const |
Returns a short text representation of this object using unicode characters. More... | |
std::string | detail () const |
Returns a detailed text representation of this object. More... | |
Static Public Member Functions | |
static std::unique_ptr< BlockedSFSPair > | recognise (const Triangulation< 3 > &tri) |
Determines if the given triangulation is a blocked pair of Seifert fibred spaces, as described by this class. More... | |
static std::unique_ptr< StandardTriangulation > | recognise (Component< 3 > *component) |
Determines whether the given component represents one of the standard triangulations understood by Regina. More... | |
Represents a blocked pair of Seifert fibred spaces joined along a single connecting torus.
This is a particular type of triangulation of a graph manifold, formed from two saturated regions whose torus boundaries are identified. An optional layering may be placed between the two torus boundaries to allow for a more interesting relationship between the boundary curves of each region. For more detail on saturated regions and their constituent saturated blocks, see the SatRegion class; for more detail on layerings, see the Layering class.
Each of the two saturated regions must have precisely one boundary component formed from just one saturated annulus, and this boundary may not be twisted (i.e., it must be a torus, not a Klein bottle). The way in which the boundaries from each region are identified is specified by a 2-by-2 matrix M, which expresses curves representing the fibres and base orbifold of the second region in terms of the first (see the page on Notation for Seifert fibred spaces for terminology).
More specifically, suppose that f0 and o0 are directed curves on the first region boundary and f1 and o1 are directed curves on the second region boundary, where f0 and f1 represent the fibres of each region and o0 and o1 represent the base orbifolds. Then the boundaries are joined according to the following relation:
[f1] [f0] [ ] = M * [ ] [o1] [o0]
If a layering is present between the two boundaries, then the boundary curves are not identified directly. In this case, the matrix M shows how the layering relates the curves on each region boundary.
Note that the routines writeName() and writeTeXName() do not offer enough information to uniquely identify the triangulation, since this essentially requires 2-dimensional assemblings of saturated blocks. For full details, writeTextLong() may be used instead.
The optional StandardTriangulation routine manifold() is implemented for this class, but homology() is not.
This class implements C++ move semantics and adheres to the C++ Swappable requirement. It is designed to avoid deep copies wherever possible, even when passing or returning objects by value. Note, however, that the only way to create objects of this class (aside from copying or moving) is via the static member function recognise().
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default |
Creates a new copy of the given structure.
This will induce a deep copy of src.
src | the structure to copy. |
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defaultnoexcept |
Moves the contents of the given structure into this new structure.
This is a constant time operation.
The structure that was passed (src) will no longer be usable.
src | the structure to move from. |
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inherited |
Returns a detailed text representation of this object.
This text may span many lines, and should provide the user with all the information they could want. It should be human-readable, should not contain extremely long lines (which cause problems for users reading the output in a terminal), and should end with a final newline. There are no restrictions on the underlying character set.
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virtualinherited |
Returns the expected first homology group of this triangulation, if such a routine has been implemented.
This routine does not work by calling Triangulation<3>::homology() on the associated real triangulation. Instead the homology is calculated directly from the known properties of this standard triangulation.
This means that homology() needs to be implemented separately for each class of standard triangulation. See the class notes for each subclass of StandardTriangulation for details on whether homology has been implemented for that particular subclass. The default implementation of this routine just throws a NotImplemented exception.
Most users will not need this routine, since presumably you already have an explicit Triangulation<3> available and so you can just call Triangulation<3>::homology() instead (which, unlike this routine, is always implemented). This StandardTriangulation::homology() routine should be seen as more of a verification/validation tool for the Regina developers.
If this StandardTriangulation describes an entire Triangulation<3> (and not just a part thereof) then the results of this routine should be identical to the homology group obtained by calling Triangulation<3>::homology() upon the associated real triangulation.
NotImplemented | Homology calculation has not yet been implemented for this particular type of standard triangulation. |
FileError | The homology needs to be read from file (as opposed to computed), but the file is inaccessible or its contents cannot be read and parsed correctly. Currently this can only happen for the subclass SnapPeaCensusTri, which reads its results from the SnapPea census databases that are installed with Regina. |
Reimplemented in regina::LayeredChain, regina::LayeredChainPair, regina::LayeredLensSpace, regina::LayeredLoop, regina::LayeredSolidTorus, regina::LayeredTorusBundle, regina::SnapPeaCensusTri, regina::SnappedBall, regina::SpiralSolidTorus, regina::TriSolidTorus, and regina::TrivialTri.
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overridevirtual |
Returns the 3-manifold represented by this triangulation, if such a recognition routine has been implemented.
If the 3-manifold cannot be recognised then this routine will return null
.
The details of which standard triangulations have 3-manifold recognition routines can be found in the notes for the corresponding subclasses of StandardTriangulation. The default implementation of this routine returns null
.
It is expected that the number of triangulations whose underlying 3-manifolds can be recognised will grow between releases.
Reimplemented from regina::StandardTriangulation.
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inline |
Returns the matrix describing how the two saturated region boundaries are joined.
Note that if a layering is placed between the two region boundaries, then any changes to the boundary relationships caused by the layering are included in this matrix.
See the class notes above for precise information on how this matrix is presented.
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inherited |
Returns the name of this specific triangulation as a human-readable string.
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inline |
Determines whether this and the given structure do not represent the same type of blocked pair of Seifert fibred spaces.
Specifically, two structures will compare as equal if and only if both structures are formed from the same pair of combinatorial presentations of saturated regions (as returned by the SatRegion comparison operators), presented in the same order, and with their torus boundaries joined using the same 2-by-2 matrix.
This test follows the general rule for most subclasses of StandardTriangulation (excluding fixed structures such as SnappedBall and TriSolidTorus): two objects compare as equal if and only if they have the same combinatorial parameters (which for this subclass is more specific than combinatorial isomorphism, since this test does not account for the many symmetries in a blocked Seifert fibred space).
other | the structure with which this will be compared. |
true
if and only if this and the given structure do not represent the same type of blocked pair of Seifert fibred spaces.
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defaultnoexcept |
Moves the contents of the given structure into this structure.
This is a constant time operation.
The structure that was passed (src) will no longer be usable.
src | the structure to move from. |
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default |
Sets this to be a copy of the given structure.
This will induce a deep copy of src.
src | the structure to copy. |
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inline |
Determines whether this and the given structure represent the same type of blocked pair of Seifert fibred spaces.
Specifically, two structures will compare as equal if and only if both structures are formed from the same pair of combinatorial presentations of saturated regions (as returned by the SatRegion comparison operators), presented in the same order, and with their torus boundaries joined using the same 2-by-2 matrix.
This test follows the general rule for most subclasses of StandardTriangulation (excluding fixed structures such as SnappedBall and TriSolidTorus): two objects compare as equal if and only if they have the same combinatorial parameters (which for this subclass is more specific than combinatorial isomorphism, since this test does not account for the many symmetries in a blocked Seifert fibred space).
other | the structure with which this will be compared. |
true
if and only if this and the given structure represent the same type of blocked pair of Seifert fibred spaces.
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staticinherited |
Determines whether the given component represents one of the standard triangulations understood by Regina.
The list of recognised triangulations is expected to grow between releases.
If the standard triangulation returned has boundary triangles then the given component must have the same corresponding boundary triangles, i.e., the component cannot have any further identifications of these boundary triangles with each other.
Note that the triangulation-based routine recognise(const Triangulation<3>&) may recognise more triangulations than this routine, since passing an entire triangulation allows access to more information.
component | the triangulation component under examination. |
null
otherwise.
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static |
Determines if the given triangulation is a blocked pair of Seifert fibred spaces, as described by this class.
This function returns by (smart) pointer for consistency with StandardTriangulation::recognise(), which makes use of the polymorphic nature of the StandardTriangulation class hierarchy.
tri | the triangulation to examine. |
null
if the given triangulation is not of this form.
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inline |
Returns details of one of the two bounded saturated regions that form this triangulation.
See the class notes above for further information.
which | 0 if the first region should be returned, or 1 if the second region should be returned. |
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inherited |
Returns a short text representation of this object.
This text should be human-readable, should use plain ASCII characters where possible, and should not contain any newlines.
Within these limits, this short text ouptut should be as information-rich as possible, since in most cases this forms the basis for the Python __str__()
and __repr__()
functions.
__str__()
will use precisely this function, and for most classes the Python __repr__()
function will incorporate this into its output.
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inlinenoexcept |
Swaps the contents of this and the given structure.
other | the structure whose contents should be swapped with this. |
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inherited |
Returns the name of this specific triangulation in TeX format.
No leading or trailing dollar signs will be included.
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inherited |
Returns a short text representation of this object using unicode characters.
Like str(), this text should be human-readable, should not contain any newlines, and (within these constraints) should be as information-rich as is reasonable.
Unlike str(), this function may use unicode characters to make the output more pleasant to read. The string that is returned will be encoded in UTF-8.
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overridevirtual |
Writes the name of this triangulation as a human-readable string to the given output stream.
out | the output stream to which to write. |
Implements regina::StandardTriangulation.
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overridevirtual |
Writes the name of this triangulation in TeX format to the given output stream.
No leading or trailing dollar signs will be included.
out | the output stream to which to write. |
Implements regina::StandardTriangulation.
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overridevirtual |
Writes a detailed text representation of this object to the given output stream.
This may be reimplemented by subclasses, but the parent StandardTriangulation class offers a reasonable default implementation based on writeTextShort().
out | the output stream to which to write. |
Reimplemented from regina::StandardTriangulation.
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inlinevirtualinherited |
Writes a short text representation of this object to the given output stream.
This may be reimplemented by subclasses, but the parent StandardTriangulation class offers a reasonable default implementation based on writeName().
out | the output stream to which to write. |
Reimplemented in regina::LayeredChain, regina::LayeredSolidTorus, regina::SnappedBall, regina::SpiralSolidTorus, and regina::TriSolidTorus.