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| * Add support for Python 3.10 | * Add support for macOS Big Sur that does not depend on homebrew's gcc@10 |
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| * Add support for gcc 11 | * packages upgrades - https://repology.org/projects/?inrepo=sagemath_develop - many upgrades enabled by dropping support for Python 3.6 * Drop support for optional packages with system gcc 4.x |
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| == Symbolics == === Extended interface with SymPy === The [[https://www.sympy.org/en/index.html|SymPy]] package has been updated to version 1.8. !SageMath has a bidirectional interface with !SymPy. Symbolic expressions in Sage provide a `_sympy_` method, which converts to !SymPy; also, Sage attaches `_sage_` methods to various !SymPy classes, which provide the opposite conversion. In Sage 9.4, several conversions have been added. Now there is a bidirectional interface as well for matrices and vectors. [[https://trac.sagemath.org/ticket/31942|#31942]] {{{ sage: M = matrix([[sin(x), cos(x)], [-cos(x), sin(x)]]); M [ sin(x) cos(x)] [-cos(x) sin(x)] sage: sM = M._sympy_(); sM Matrix([ [ sin(x), cos(x)], [-cos(x), sin(x)]]) sage: sM.subs(x, pi/4) # computation in SymPy Matrix([ [ sqrt(2)/2, sqrt(2)/2], [-sqrt(2)/2, sqrt(2)/2]]) }}} Work is underway to make !SymPy's symbolic linear algebra methods available in Sage via this route. Sage has added a formal set membership function `element_of` for use in symbolic expressions; it converts to a !SymPy's `Contains` expression. [[https://trac.sagemath.org/ticket/24171|#24171]] Moreover, all sets and algebraic structures (`Parent`s) of !SageMath are now accessible to !SymPy by way of a wrapper class, which implements the [[https://docs.sympy.org/latest/modules/sets.html#set|SymPy Set API]]. [[https://trac.sagemath.org/ticket/31938|#31938]] {{{ sage: F = Family([2, 3, 5, 7]); F Family (2, 3, 5, 7) sage: sF = F._sympy_(); sF SageSet(Family (2, 3, 5, 7)) # this is how the wrapper prints sage: sF._sage_() is F True # bidirectional sage: bool(sF) True sage: len(sF) 4 sage: sF.is_finite_set # SymPy property True }}} Finite or infinite, we can wrap it: {{{ sage: W = WeylGroup(["A",1,1]) sage: sW = W._sympy_(); sW SageSet(Weyl Group of type ['A', 1, 1] (as a matrix group acting on the root space)) sage: sW.is_finite_set False sage: sW.is_iterable True sage: sB3 = WeylGroup(["B", 3])._sympy_(); sB3 SageSet(Weyl Group of type ['B', 3] (as a matrix group acting on the ambient space)) sage: len(sB3) 48 }}} Some parents or constructions have a more specific conversion to !SymPy [[https://trac.sagemath.org/ticket/31931|#31931]]. {{{ sage: ZZ3 = cartesian_product([ZZ, ZZ, ZZ]) sage: sZZ3 = ZZ3._sympy_(); sZZ3 ProductSet(Integers, Integers, Integers) sage: (1, 2, 3) in sZZ3 sage: NN = NonNegativeIntegers() sage: NN._sympy_() Naturals0 sage: (RealSet(1, 2).union(RealSet.closed(3, 4)))._sympy_() Union(Interval.open(1, 2), Interval(3, 4)) }}} See [[https://trac.sagemath.org/ticket/31926|Meta-ticket #31926: Connect Sage sets to SymPy sets]] == Convex geometry == === ABC for convex sets === Sage 9.4 has added an abstract base class `ConvexSet_base` (as well as abstract subclasses `ConvexSet_closed`, `ConvexSet_compact`, `ConvexSet_relatively_open`, `ConvexSet_open`) for convex subsets of finite-dimensional vector spaces. The abstract methods and default implementations of methods provide a unifying API to the existing classes `Polyhedron_base`, `ConvexRationalPolyhedralCone`, `LatticePolytope`, and `PolyhedronFace`. [[https://trac.sagemath.org/ticket/31919|#31919]], [[https://trac.sagemath.org/ticket/31959|#31959]], [[https://trac.sagemath.org/ticket/31990|#31990]] As part of the API, there are new methods for point-set topology such as `is_open`, `relative_interior`, and `closure`. For example, taking the `relative_interior` of a polyhedron constructs an instance of `RelativeInterior`, a simple object that provides a `__contains__` method and all other methods of the `ConvexSet_base` API. [[https://trac.sagemath.org/ticket/31916|#31916]] {{{ sage: P = Polyhedron(vertices=[(1,0), (-1,0)]) sage: ri_P = P.relative_interior(); ri_P Relative interior of a 1-dimensional polyhedron in ZZ^2 defined as the convex hull of 2 vertices sage: (0, 0) in ri_P True sage: (1, 0) in ri_P False }}} === Polyhedral geometry === == Manifolds == == Configuration changes == === Support for system Python 3.6 dropped === It was already deprecated in Sage 9.3. [[https://trac.sagemath.org/ticket/30551|#30551]] It is still possible to build the Sage distribution on systems with old Python versions, but Sage will build its own copy of Python 3.9.x in this case. === ./configure --prefix=SAGE_LOCAL --with-sage-venv=SAGE_VENV === [[https://trac.sagemath.org/ticket/29013|#29013]] == Package upgrades == |
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| The 9.4 series has not been started yet. | The first beta of the 9.4 series, 9.4.beta0, was tagged on 2021-05-26. |
Sage 9.4 Release Tour
current development cycle (2021)
Contents
Goals and tickets
- Add support for gcc 11
- Add support for macOS Big Sur that does not depend on homebrew's gcc@10
- packages upgrades
- https://repology.org/projects/?inrepo=sagemath_develop - many upgrades enabled by dropping support for Python 3.6
- Drop support for optional packages with system gcc 4.x
Symbolics
Extended interface with SymPy
The SymPy package has been updated to version 1.8.
SageMath has a bidirectional interface with SymPy. Symbolic expressions in Sage provide a _sympy_ method, which converts to SymPy; also, Sage attaches _sage_ methods to various SymPy classes, which provide the opposite conversion.
In Sage 9.4, several conversions have been added. Now there is a bidirectional interface as well for matrices and vectors. #31942
sage: M = matrix([[sin(x), cos(x)], [-cos(x), sin(x)]]); M [ sin(x) cos(x)] [-cos(x) sin(x)] sage: sM = M._sympy_(); sM Matrix([ [ sin(x), cos(x)], [-cos(x), sin(x)]]) sage: sM.subs(x, pi/4) # computation in SymPy Matrix([ [ sqrt(2)/2, sqrt(2)/2], [-sqrt(2)/2, sqrt(2)/2]])
Work is underway to make SymPy's symbolic linear algebra methods available in Sage via this route.
Sage has added a formal set membership function element_of for use in symbolic expressions; it converts to a SymPy's Contains expression. #24171
Moreover, all sets and algebraic structures (Parents) of SageMath are now accessible to SymPy by way of a wrapper class, which implements the SymPy Set API. #31938
sage: F = Family([2, 3, 5, 7]); F Family (2, 3, 5, 7) sage: sF = F._sympy_(); sF SageSet(Family (2, 3, 5, 7)) # this is how the wrapper prints sage: sF._sage_() is F True # bidirectional sage: bool(sF) True sage: len(sF) 4 sage: sF.is_finite_set # SymPy property True
Finite or infinite, we can wrap it:
sage: W = WeylGroup(["A",1,1]) sage: sW = W._sympy_(); sW SageSet(Weyl Group of type ['A', 1, 1] (as a matrix group acting on the root space)) sage: sW.is_finite_set False sage: sW.is_iterable True sage: sB3 = WeylGroup(["B", 3])._sympy_(); sB3 SageSet(Weyl Group of type ['B', 3] (as a matrix group acting on the ambient space)) sage: len(sB3) 48
Some parents or constructions have a more specific conversion to SymPy #31931.
sage: ZZ3 = cartesian_product([ZZ, ZZ, ZZ]) sage: sZZ3 = ZZ3._sympy_(); sZZ3 ProductSet(Integers, Integers, Integers) sage: (1, 2, 3) in sZZ3 sage: NN = NonNegativeIntegers() sage: NN._sympy_() Naturals0 sage: (RealSet(1, 2).union(RealSet.closed(3, 4)))._sympy_() Union(Interval.open(1, 2), Interval(3, 4))
See Meta-ticket #31926: Connect Sage sets to SymPy sets
Convex geometry
ABC for convex sets
Sage 9.4 has added an abstract base class ConvexSet_base (as well as abstract subclasses ConvexSet_closed, ConvexSet_compact, ConvexSet_relatively_open, ConvexSet_open) for convex subsets of finite-dimensional vector spaces. The abstract methods and default implementations of methods provide a unifying API to the existing classes Polyhedron_base, ConvexRationalPolyhedralCone, LatticePolytope, and PolyhedronFace. #31919, #31959, #31990
As part of the API, there are new methods for point-set topology such as is_open, relative_interior, and closure. For example, taking the relative_interior of a polyhedron constructs an instance of RelativeInterior, a simple object that provides a __contains__ method and all other methods of the ConvexSet_base API. #31916
sage: P = Polyhedron(vertices=[(1,0), (-1,0)]) sage: ri_P = P.relative_interior(); ri_P Relative interior of a 1-dimensional polyhedron in ZZ^2 defined as the convex hull of 2 vertices sage: (0, 0) in ri_P True sage: (1, 0) in ri_P False
Polyhedral geometry
Manifolds
Configuration changes
Support for system Python 3.6 dropped
It was already deprecated in Sage 9.3. #30551
It is still possible to build the Sage distribution on systems with old Python versions, but Sage will build its own copy of Python 3.9.x in this case.
./configure --prefix=SAGE_LOCAL --with-sage-venv=SAGE_VENV
Package upgrades
Availability of Sage 9.4 and installation help
The first beta of the 9.4 series, 9.4.beta0, was tagged on 2021-05-26.
See sage-devel for development discussions and sage-release for announcements of beta versions and release candidates.