Differences between revisions 9 and 16 (spanning 7 versions)

Sage 4.1 Release Tour

Sage 4.1 was released on July 09, 2009. For the official, comprehensive release note, please refer to sage-4.1.txt. A nicely formatted version of this release tour can be found at FIXME. The following points are some of the foci of this release:

Upgrade to Python 2.6.x
Support for building Singular with GCC 4.4
Optimized integer division
Combinatorics: irreducible matrix representations of symmetric groups; and Yang-Baxter Graphs
Cryptography: Mini Advanced Encryption Standard for educational purposes
Graph theory: back-end for graph theory with Cython (c_graph); and improve accuracy of graph eigenvalues
Linear algebra: a general package for finitely generated, not-necessarily free R-modules; and multiplicative order for matrices over finite fields
Miscellaneous: optimized Sudoku solver; a decorator for declaring abstract methods; and support Unicode in LaTeX cells (notebook)
Number theory: improved random element generation for number field orders and ideals; support Michael Stoll's ratpoints package; and elliptic exponential
Numerical: computing numerical values of constants using mpmath
Update, upgrade 18 packages to latest upstream releases

Algebraic Geometry

Construct an elliptic curve from a plane curve of genus one (Lloyd Kilford, John Cremona ) -- New function EllipticCurve_from_plane_curve() in the module sage/schemes/elliptic_curves/constructor.py to allow the construction of an elliptic curve from a smooth plane cubic with a rational point. Currently, this function uses Magma and it will not work on machines that do not have Magma installed. Assuming you have Magma installed on your computer, we can use the function EllipticCurve_from_plane_curve() to first check that the Fermat cubic is isomorphic to the curve with Cremona label "27a1":
```
sage: x, y, z = PolynomialRing(QQ, 3, 'xyz').gens() # optional - magma  
sage: C = Curve(x^3 + y^3 + z^3) # optional - magma 
sage: P = C(1, -1, 0) # optional - magma 
sage: E = EllipticCurve_from_plane_curve(C, P) # optional - magma 
sage: E # optional - magma 
Elliptic Curve defined by y^2 + y = x^3 - 7 over Rational Field 
sage: E.label() # optional - magma 
'27a1'
```
Here is a quartic example:
```
sage: u, v, w = PolynomialRing(QQ, 3, 'uvw').gens() # optional - magma  
sage: C = Curve(u^4 + u^2*v^2 - w^4) # optional - magma 
sage: P = C(1, 0, 1) # optional - magma 
sage: E = EllipticCurve_from_plane_curve(C, P) # optional - magma 
sage: E # optional - magma 
Elliptic Curve defined by y^2  = x^3 + 4*x over Rational Field 
sage: E.label() # optional - magma 
'32a1'
```

Basic Arithmetic

Speed-up integer division (Robert Bradshaw ) -- In some cases, integer division is now up to 31% faster than previously. The following timing statistics were obtained using the machine sage.math:

# BEFORE

sage: a = next_prime(2**31)
sage: b = Integers(a)(100)
sage: %timeit a % b;
1000000 loops, best of 3: 1.12 µs per loop
sage: %timeit 101 // int(5);
1000000 loops, best of 3: 215 ns per loop
sage: %timeit 100 // int(-3)
1000000 loops, best of 3: 214 ns per loop
sage: a = ZZ.random_element(10**50)
sage: b = ZZ.random_element(10**15)
sage: %timeit a.quo_rem(b)
1000000 loops, best of 3: 454 ns per loop


# AFTER

sage: a = next_prime(2**31)
sage: b = Integers(a)(100)
sage: %timeit a % b;
1000000 loops, best of 3: 1.02 µs per loop
sage: %timeit 101 // int(5);
1000000 loops, best of 3: 201 ns per loop
sage: %timeit 100 // int(-3)
1000000 loops, best of 3: 194 ns per loop
sage: a = ZZ.random_element(10**50)
sage: b = ZZ.random_element(10**15)
sage: %timeit a.quo_rem(b)
1000000 loops, best of 3: 313 ns per loop

Combinatorics

Irreducible matrix representations of symmetric groups (Franco Saliola) -- Support for constructing irreducible representations of the symmetric group. This is based on Alain Lascoux's article Young representations of the symmetric group. The following types of representations are supported:

Specht representations -- The matrices have integer entries:

sage: chi = SymmetricGroupRepresentation([3, 2]); chi
Specht representation of the symmetric group corresponding to [3, 2]
sage: chi([5, 4, 3, 2, 1])

[ 1 -1  0  1  0]
[ 0  0 -1  0  1]
[ 0  0  0 -1  1]
[ 0  1 -1 -1  1]
[ 0  1  0 -1  1]

Young's seminormal representation -- The matrices have rational entries:
```
sage: snorm = SymmetricGroupRepresentation([2, 1], "seminormal"); snorm
Seminormal representation of the symmetric group corresponding to [2, 1]
sage: snorm([1, 3, 2])

[-1/2  3/2]
[ 1/2  1/2]
```

Young's orthogonal representation (the matrices are orthogonal) -- These matrices are defined over Sage's Symbolic Ring:

sage: ortho = SymmetricGroupRepresentation([3, 2], "orthogonal"); ortho
Orthogonal representation of the symmetric group corresponding to [3, 2]
sage: ortho([1, 3, 2, 4, 5])

[          1           0           0           0           0]
[          0        -1/2 1/2*sqrt(3)           0           0]
[          0 1/2*sqrt(3)         1/2           0           0]
[          0           0           0        -1/2 1/2*sqrt(3)]
[          0           0           0 1/2*sqrt(3)         1/2]

You can also create the CombinatorialClass of all irreducible matrix representations of a given symmetric group. Then particular representations can be created by providing partitions. For example:

sage: chi = SymmetricGroupRepresentations(5); chi
Specht representations of the symmetric group of order 5! over Integer Ring
sage: chi([5]) # the trivial representation
Specht representation of the symmetric group corresponding to [5]
sage: chi([5])([2, 1, 3, 4, 5])
[1]
sage: chi([1, 1, 1, 1, 1]) # the sign representation
Specht representation of the symmetric group corresponding to [1, 1, 1, 1, 1]
sage: chi([1, 1, 1, 1, 1])([2, 1, 3, 4, 5])
[-1]
sage: chi([3, 2])
Specht representation of the symmetric group corresponding to [3, 2]
sage: chi([3, 2])([5, 4, 3, 2, 1])

[ 1 -1  0  1  0]
[ 0  0 -1  0  1]
[ 0  0  0 -1  1]
[ 0  1 -1 -1  1]
[ 0  1  0 -1  1]

See the documentation of SymmetricGroupRepresentation and SymmetricGroupRepresentations for more information and examples.

Yang-Baxter Graphs (Franco Saliola) -- Besides being used for constructing the irreducible matrix representations of the symmetric group, Yang-Baxter graphs can also be used to construct the Cayley graph of a finite group. For example:
- ```
sage: def left_multiplication_by(g):
....:     return lambda h : h*g
....: 
sage: G = AlternatingGroup(4)
sage: operators = [ left_multiplication_by(gen) for gen in G.gens() ]
sage: Y = YangBaxterGraph(root=G.identity(), operators=operators); Y
Yang-Baxter graph with root vertex ()
sage: Y.plot(edge_labels=False)
```

Yang-Baxter graphs can also be used to construct the permutahedron:

sage: from sage.combinat.yang_baxter_graph import SwapIncreasingOperator
sage: operators = [SwapIncreasingOperator(i) for i in range(3)]
sage: Y = YangBaxterGraph(root=(1,2,3,4), operators=operators); Y
Yang-Baxter graph with root vertex (1, 2, 3, 4)
sage: Y.plot()

See the documentation of YangBaxterGraph for more information and examples.

Commutative Algebra

Cryptography

FIXME: summarize #6164

Geometry

Graph Theory

FIXME: summarize #6085
Improve accuracy of graph eigenvalues (Ticket #6258), Rob Beezer. New routines compute eigenvalues and eigenvectors of integer matrices more precisely than before. Rather than convert adjacency matrices of graphs to computations over the reals or complexes, this patch retains adjacency matrices as matrices over the integers, yielding more accurate and informative results for eigenvalues, eigenvectors, and eigenspaces.
- Examples follow for a circuit on 8 vertices:
```
g = graphs.CycleGraph(8)
```
- Integer eigenvalues are exact, irrational eigenvalues are more precise, making multiplicities easier to determine.
```
sage: g.spectrum()

[2, 1.414213562373095?, 1.414213562373095?, 0, 0, -1.414213562373095?, -1.414213562373095?, -2]
```
- Similar comments apply to eigenvectors.
```
sage: g.eigenvectors()

[(2, [
(1, 1, 1, 1, 1, 1, 1, 1)
], 1),
 (-2, [
(1, -1, 1, -1, 1, -1, 1, -1)
], 1),
 (0, [
(1, 0, -1, 0, 1, 0, -1, 0),
(0, 1, 0, -1, 0, 1, 0, -1)
], 2),
 (-1.414213562373095?,
  [(1, 0, -1, 1.414213562373095?, -1, 0, 1, -1.414213562373095?),
   (0, 1, -1.414213562373095?, 1, 0, -1, 1.414213562373095?, -1)],
  2),
 (1.414213562373095?,
  [(1, 0, -1, -1.414213562373095?, -1, 0, 1, 1.414213562373095?),
   (0, 1, 1.414213562373095?, 1, 0, -1, -1.414213562373095?, -1)],
  2)]
```
- Eigenspaces are exact, in that they can be expressed as vector spaces over number fields. When the defining polynomial has several roots, the eigenspaces are not repeated. Previously eigenspaces were "fractured" owing to slight computational differences in identical eigenvalues. In concert with eigenvectors() this command illuminates the structure of a graph's eigenspaces more than purely numerical results.
```
sage: g.eigenspaces()

[
(2, Vector space of degree 8 and dimension 1 over Rational Field
User basis matrix:
[1 1 1 1 1 1 1 1]),
(-2, Vector space of degree 8 and dimension 1 over Rational Field
User basis matrix:
[ 1 -1  1 -1  1 -1  1 -1]),
(0, Vector space of degree 8 and dimension 2 over Rational Field
User basis matrix:
[ 1  0 -1  0  1  0 -1  0]
[ 0  1  0 -1  0  1  0 -1]),
(a3, Vector space of degree 8 and dimension 2 over Number Field in a3 with defining polynomial x^2 - 2
User basis matrix:
[  1   0  -1 -a3  -1   0   1  a3]
[  0   1  a3   1   0  -1 -a3  -1])
```
- Complex eigenvalues (of digraphs) previously were missing their imaginary parts. This bug has been fixed as part of this ticket.

Graphics

FIXME: summarize #6162

Group Theory

Interfaces

FIXME: summarize #4313

Linear Algebra

FIXME: summarize #6261
FIXME: summarize #5882

Miscellaneous

FIXME: summarize #3084
FIXME: summarize #6097
FIXME: summarize #6417

Modular Forms

Notebook

FIXME: summarize #5637

Number Theory

FIXME: summarize #6273
FIXME: summarize #5854
FIXME: summarize #6386

Numerical

FIXME: summarize #6200

Packages

Upgrade Singular to version singular-3-1-0-2-20090620 with support for compiling with GCC 4.4.
FIXME: summarize #6359
FIXME: summarize #6196
FIXME: summarize #6276
FIXME: summarize #5517
FIXME: summarize #5854
FIXME: summarize #5866
FIXME: summarize #5867
FIXME: summarize #5868
FIXME: summarize #5869
FIXME: summarize #5870
FIXME: summarize #5872
FIXME: summarize #5874
FIXME: summarize #5875
FIXME: summarize #6281
FIXME: summarize #6470
FIXME: summarize #6470
FIXME: summarize #6492
FIXME: summarize #6408

-  ⇤ ← Revision 9 as of 2009-07-10 09:23:40 → 
  Size: 1874
  Editor: Minh Nguyen
  Comment: Reminders to showcase features
+   ← Revision 16 as of 2009-07-12 00:44:55 → ⇥
  Size: 11991
  Editor: Minh Nguyen
  Comment: Summarize #5878
-Deletions are marked like this.
+Additions are marked like this.
 Line 3:
-Sage 4.1 was released on FIXME. For the official, comprehensive release note, please refer to FIXME. A nicely formatted version of this release tour can be found at FIXME. The following points are some of the foci of this release:

 * 


== Algebra ==


 * FIXME: summarize #6362
+Sage 4.1 was released on July 09, 2009. For the official, comprehensive release note, please refer to [[http://www.sagemath.org/src/announce/sage-4.1.txt|sage-4.1.txt]]. A nicely formatted version of this release tour can be found at FIXME. The following points are some of the foci of this release:

 * Upgrade to Python 2.6.x
 * Support for building Singular with GCC 4.4
 * Optimized integer division
 * Combinatorics: irreducible matrix representations of symmetric groups; and Yang-Baxter Graphs
 * Cryptography: Mini Advanced Encryption Standard for educational purposes
 * Graph theory: back-end for graph theory with Cython (c_graph); and improve accuracy of graph eigenvalues
 * Linear algebra: a general package for finitely generated, not-necessarily free R-modules; and multiplicative order for matrices over finite fields
 * Miscellaneous: optimized Sudoku solver; a decorator for declaring abstract methods; and support Unicode in LaTeX cells (notebook)
 * Number theory: improved random element generation for number field orders and ideals; support Michael Stoll's ratpoints package; and elliptic exponential
 * Numerical: computing numerical values of constants using mpmath
 * Update, upgrade 18 packages to latest upstream releases
-Line 17:
+Line 21:
- * FIXME: summarize #4290
+ * Construct an elliptic curve from a plane curve of genus one (Lloyd Kilford, John Cremona ) -- New function {{{EllipticCurve_from_plane_curve()}}} in the module {{{sage/schemes/elliptic_curves/constructor.py}}} to allow the construction of an elliptic curve from a smooth plane cubic with a rational point. Currently, this function uses Magma and it will not work on machines that do not have Magma installed. Assuming you have Magma installed on your computer, we can use the function {{{EllipticCurve_from_plane_curve()}}} to first check that the Fermat cubic is isomorphic to the curve with Cremona label "27a1":
 {{{#!python numbers=off
sage: x, y, z = PolynomialRing(QQ, 3, 'xyz').gens() # optional - magma  
sage: C = Curve(x^3 + y^3 + z^3) # optional - magma 
sage: P = C(1, -1, 0) # optional - magma 
sage: E = EllipticCurve_from_plane_curve(C, P) # optional - magma 
sage: E # optional - magma 
Elliptic Curve defined by y^2 + y = x^3 - 7 over Rational Field 
sage: E.label() # optional - magma 
'27a1'
 }}}
 Here is a quartic example:
 {{{#!python numbers=off
sage: u, v, w = PolynomialRing(QQ, 3, 'uvw').gens() # optional - magma  
sage: C = Curve(u^4 + u^2*v^2 - w^4) # optional - magma 
sage: P = C(1, 0, 1) # optional - magma 
sage: E = EllipticCurve_from_plane_curve(C, P) # optional - magma 
sage: E # optional - magma 
Elliptic Curve defined by y^2  = x^3 + 4*x over Rational Field 
sage: E.label() # optional - magma 
'32a1'
 }}}
-Line 23:
+Line 48:
- * FIXME: summarize #6083
+ * Speed-up integer division (Robert Bradshaw ) -- In some cases, integer division is now up to 31% faster than previously. The following timing statistics were obtained using the machine sage.math:
 {{{#!python numbers=off
# BEFORE

sage: a = next_prime(2**31)
sage: b = Integers(a)(100)
sage: %timeit a % b;
1000000 loops, best of 3: 1.12 µs per loop
sage: %timeit 101 // int(5);
1000000 loops, best of 3: 215 ns per loop
sage: %timeit 100 // int(-3)
1000000 loops, best of 3: 214 ns per loop
sage: a = ZZ.random_element(10**50)
sage: b = ZZ.random_element(10**15)
sage: %timeit a.quo_rem(b)
1000000 loops, best of 3: 454 ns per loop


# AFTER

sage: a = next_prime(2**31)
sage: b = Integers(a)(100)
sage: %timeit a % b;
1000000 loops, best of 3: 1.02 µs per loop
sage: %timeit 101 // int(5);
1000000 loops, best of 3: 201 ns per loop
sage: %timeit 100 // int(-3)
1000000 loops, best of 3: 194 ns per loop
sage: a = ZZ.random_element(10**50)
sage: b = ZZ.random_element(10**15)
sage: %timeit a.quo_rem(b)
1000000 loops, best of 3: 313 ns per loop
 }}}
-Line 28:
+Line 85:
- * FIXME: summarize #5878
+ * Irreducible matrix representations of symmetric groups (Franco Saliola) -- Support for constructing irreducible representations of the symmetric group. This is based on [[http://www-igm.univ-mlv.fr/~al|Alain Lascoux's]] article [[http://phalanstere.univ-mlv.fr/~al/ARTICLES/ProcCrac.ps.gz|Young representations of the symmetric group]]. The following types of representations are supported:

    * Specht representations -- The matrices have integer entries:
    {{{#!python numbers=off
sage: chi = SymmetricGroupRepresentation([3, 2]); chi
Specht representation of the symmetric group corresponding to [3, 2]
sage: chi([5, 4, 3, 2, 1])

[ 1 -1  0  1  0]
[ 0  0 -1  0  1]
[ 0  0  0 -1  1]
[ 0  1 -1 -1  1]
[ 0  1  0 -1  1]
}}}

    * Young's seminormal representation -- The matrices have rational entries:
    {{{#!python numbers=off
sage: snorm = SymmetricGroupRepresentation([2, 1], "seminormal"); snorm
Seminormal representation of the symmetric group corresponding to [2, 1]
sage: snorm([1, 3, 2])

[-1/2  3/2]
[ 1/2  1/2]
}}}

    * Young's orthogonal representation (the matrices are orthogonal) -- These matrices are defined over Sage's {{{Symbolic Ring}}}:
    {{{#!python numbers=off
sage: ortho = SymmetricGroupRepresentation([3, 2], "orthogonal"); ortho
Orthogonal representation of the symmetric group corresponding to [3, 2]
sage: ortho([1, 3, 2, 4, 5])

[          1           0           0           0           0]
[          0        -1/2 1/2*sqrt(3)           0           0]
[          0 1/2*sqrt(3)         1/2           0           0]
[          0           0           0        -1/2 1/2*sqrt(3)]
[          0           0           0 1/2*sqrt(3)         1/2]
}}}

 You can also create the {{{CombinatorialClass}}} of all irreducible matrix representations of a given symmetric group. Then particular representations can be created by providing partitions. For example:
    {{{#!python numbers=off
sage: chi = SymmetricGroupRepresentations(5); chi
Specht representations of the symmetric group of order 5! over Integer Ring
sage: chi([5]) # the trivial representation
Specht representation of the symmetric group corresponding to [5]
sage: chi([5])([2, 1, 3, 4, 5])
[1]
sage: chi([1, 1, 1, 1, 1]) # the sign representation
Specht representation of the symmetric group corresponding to [1, 1, 1, 1, 1]
sage: chi([1, 1, 1, 1, 1])([2, 1, 3, 4, 5])
[-1]
sage: chi([3, 2])
Specht representation of the symmetric group corresponding to [3, 2]
sage: chi([3, 2])([5, 4, 3, 2, 1])

[ 1 -1  0  1  0]
[ 0  0 -1  0  1]
[ 0  0  0 -1  1]
[ 0  1 -1 -1  1]
[ 0  1  0 -1  1]
}}}
 See the documentation of {{{SymmetricGroupRepresentation}}} and  {{{SymmetricGroupRepresentations}}} for more information and examples.

 * Yang-Baxter Graphs (Franco Saliola) -- Besides being used for constructing the irreducible matrix representations of the symmetric group, Yang-Baxter graphs can also be used to construct the Cayley graph of a finite group. For example:
    {{{#!python numbers=off
sage: def left_multiplication_by(g):
....:     return lambda h : h*g
....: 
sage: G = AlternatingGroup(4)
sage: operators = [ left_multiplication_by(gen) for gen in G.gens() ]
sage: Y = YangBaxterGraph(root=G.identity(), operators=operators); Y
Yang-Baxter graph with root vertex ()
sage: Y.plot(edge_labels=False)
}}}
{{attachment:cayley-graph.png}}
 Yang-Baxter graphs can also be used to construct the permutahedron:
    {{{#!python numbers=off
sage: from sage.combinat.yang_baxter_graph import SwapIncreasingOperator
sage: operators = [SwapIncreasingOperator(i) for i in range(3)]
sage: Y = YangBaxterGraph(root=(1,2,3,4), operators=operators); Y
Yang-Baxter graph with root vertex (1, 2, 3, 4)
sage: Y.plot()
}}}
{{attachment:permutahedron.png}}
 See the documentation of {{{YangBaxterGraph}}} for more information and examples.
-Line 47:
+Line 186:
- * FIXME: summarize #6085
 * FIXME: summarize #6258
+. FIXME: summarize #6085


  1.  '''Improve accuracy of graph eigenvalues  (Ticket #6258)''', Rob Beezer.  New routines compute eigenvalues and eigenvectors of integer matrices more precisely than before.  Rather than convert adjacency matrices of graphs to computations over the reals or complexes, this patch retains adjacency matrices as matrices over the integers, yielding more accurate and informative results for eigenvalues, eigenvectors, and eigenspaces.

    *  Examples follow for a circuit on 8 vertices:
    {{{#!python numbers=off
g = graphs.CycleGraph(8)
    }}}

    *  Integer eigenvalues are exact, irrational eigenvalues are more precise, making multiplicities easier to determine.
    {{{#!python numbers=off
sage: g.spectrum()

[2, 1.414213562373095?, 1.414213562373095?, 0, 0, -1.414213562373095?, -1.414213562373095?, -2]
    }}}

    *  Similar comments apply to eigenvectors.
    {{{#!python numbers=off
sage: g.eigenvectors()

[(2, [
(1, 1, 1, 1, 1, 1, 1, 1)
], 1),
 (-2, [
(1, -1, 1, -1, 1, -1, 1, -1)
], 1),
 (0, [
(1, 0, -1, 0, 1, 0, -1, 0),
(0, 1, 0, -1, 0, 1, 0, -1)
], 2),
 (-1.414213562373095?,
  [(1, 0, -1, 1.414213562373095?, -1, 0, 1, -1.414213562373095?),
   (0, 1, -1.414213562373095?, 1, 0, -1, 1.414213562373095?, -1)],
  2),
 (1.414213562373095?,
  [(1, 0, -1, -1.414213562373095?, -1, 0, 1, 1.414213562373095?),
   (0, 1, 1.414213562373095?, 1, 0, -1, -1.414213562373095?, -1)],
  2)]
   }}}

    *  Eigenspaces are exact, in that they can be expressed as vector spaces over number fields.  When the defining polynomial has several roots, the eigenspaces are not repeated.  Previously eigenspaces were "fractured" owing to slight computational differences in identical eigenvalues.  In concert with {{{eigenvectors()}}} this command illuminates the structure of a graph's eigenspaces more than purely numerical results.
    {{{#!python numbers=off
sage: g.eigenspaces()

[
(2, Vector space of degree 8 and dimension 1 over Rational Field
User basis matrix:
[1 1 1 1 1 1 1 1]),
(-2, Vector space of degree 8 and dimension 1 over Rational Field
User basis matrix:
[ 1 -1  1 -1  1 -1  1 -1]),
(0, Vector space of degree 8 and dimension 2 over Rational Field
User basis matrix:
[ 1  0 -1  0  1  0 -1  0]
[ 0  1  0 -1  0  1  0 -1]),
(a3, Vector space of degree 8 and dimension 2 over Number Field in a3 with defining polynomial x^2 - 2
User basis matrix:
[  1   0  -1 -a3  -1   0   1  a3]
[  0   1  a3   1   0  -1 -a3  -1])
    }}}

    *  Complex eigenvalues (of digraphs) previously were missing their imaginary parts.  This bug has been fixed as part of this ticket.
-Line 107:
+Line 307:
+ * Upgrade [[http://www.singular.uni-kl.de|Singular]] to version singular-3-1-0-2-20090620 with support for compiling with GCC 4.4.

Diff for "ReleaseTours/sage-4.1"