Source: ssreflect Priority: optional Maintainer: Debian OCaml Maintainers Uploaders: Stéphane Glondu , Julien Puydt , Ralf Treinen Build-Depends: debhelper-compat (= 13), dh-coq, coq (>= 8.11), libcoq-stdlib, lua5.4 Rules-Requires-Root: no Standards-Version: 4.6.1 Section: math Homepage: https://math-comp.github.io/math-comp/ Vcs-Browser: https://salsa.debian.org/ocaml-team/ssreflect Vcs-Git: https://salsa.debian.org/ocaml-team/ssreflect.git Package: libcoq-mathcomp-algebra Architecture: any Depends: libcoq-mathcomp-fingroup (= ${binary:Version}), ${misc:Depends}, ${coq:Depends} Provides: ${coq:Provides} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Description: Mathematical Components library for Coq (algebra) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the algebra part of the library (ring, fields, ordered fields, real fields, modules, algebras, integers, rationals, polynomials, matrices, vector spaces...). Package: libcoq-mathcomp-character Architecture: any Depends: libcoq-mathcomp-field (= ${binary:Version}), ${misc:Depends}, ${coq:Depends} Provides: ${coq:Provides} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Description: Mathematical Components library for Coq (character) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the character theory part of the library (group representations, characters and class functions). Package: libcoq-mathcomp-field Architecture: any Depends: libcoq-mathcomp-solvable (= ${binary:Version}), ${misc:Depends}, ${coq:Depends} Provides: ${coq:Provides} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Description: Mathematical Components library for Coq (field) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the field theory part of the library (field extensions, Galois theory, algebraic numbers, cyclotomic polynomials). Package: libcoq-mathcomp-fingroup Architecture: any Depends: libcoq-mathcomp-ssreflect (= ${binary:Version}), ${misc:Depends}, ${coq:Depends} Provides: ${coq:Provides} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Description: Mathematical Components library for Coq (finite groups) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the finite groups theory part of the library (finite groups, group quotients, group morphisms, group presentation, group action...). Package: libcoq-mathcomp-solvable Architecture: any Depends: libcoq-mathcomp-algebra (= ${binary:Version}), ${misc:Depends}, ${coq:Depends} Provides: ${coq:Provides} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Description: Mathematical Components library for Coq (finite groups II) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the second finite groups theory part of the library (abelian groups, center, commutator, Jordan-Holder series, Sylow theorems...). Package: libcoq-mathcomp-ssreflect Architecture: any Depends: libcoq-core-ocaml, ${misc:Depends}, ${coq:Depends} Provides: ${coq:Provides} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Description: Mathematical Components library for Coq (small scale reflection) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the small scale reflection language extension and the minimal set of libraries to take advantage of it (sequences, booleans and boolean predicates, natural numbers and types with decidable equality, finite types, finite sets, finite functions, finite graphs, basic arithmetics and prime numbers, big operators...). Package: libcoq-mathcomp Architecture: any Depends: libcoq-mathcomp-algebra (= ${binary:Version}), libcoq-mathcomp-character (= ${binary:Version}), libcoq-mathcomp-field (= ${binary:Version}), libcoq-mathcomp-fingroup (= ${binary:Version}), libcoq-mathcomp-solvable (= ${binary:Version}), libcoq-mathcomp-ssreflect (= ${binary:Version}), ${misc:Depends} Breaks: libssreflect-coq (<= ${binary:Version}) Replaces: libssreflect-coq Provides: ssreflect, libmathcomp-coq, libssreflect-coq Description: Mathematical Components library for Coq (all) The Mathematical Components Library is an extensive and coherent repository of formalized mathematical theories. It is based on the Coq proof assistant, powered with the Coq/SSReflect language. . These formal theories cover a wide spectrum of topics, ranging from the formal theory of general-purpose data structures like lists, prime numbers or finite graphs, to advanced topics in algebra. . The formalization technique adopted in the library, called "small scale reflection", leverages the higher-order nature of Coq's underlying logic to provide effective automation for many small, clerical proof steps. This is often accomplished by restating ("reflecting") problems in a more concrete form, hence the name. For example, arithmetic comparison is not an abstract predicate, but rather a function computing a Boolean. . This package installs the full Mathematical Components library.