author | wenzelm |
Sun, 05 Oct 2014 22:47:07 +0200 | |
changeset 58555 | 7975676c08c0 |
parent 56579 | 4c94f631c595 |
child 58618 | 782f0b662cae |
permissions | -rw-r--r-- |
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theory Proof |
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imports Base |
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begin |
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chapter {* Structured proofs *} |
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section {* Variables \label{sec:variables} *} |
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text {* |
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Any variable that is not explicitly bound by @{text "\<lambda>"}-abstraction |
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is considered as ``free''. Logically, free variables act like |
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outermost universal quantification at the sequent level: @{text |
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"A\<^sub>1(x), \<dots>, A\<^sub>n(x) \<turnstile> B(x)"} means that the result |
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holds \emph{for all} values of @{text "x"}. Free variables for |
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terms (not types) can be fully internalized into the logic: @{text |
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"\<turnstile> B(x)"} and @{text "\<turnstile> \<And>x. B(x)"} are interchangeable, provided |
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that @{text "x"} does not occur elsewhere in the context. |
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Inspecting @{text "\<turnstile> \<And>x. B(x)"} more closely, we see that inside the |
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quantifier, @{text "x"} is essentially ``arbitrary, but fixed'', |
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while from outside it appears as a place-holder for instantiation |
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(thanks to @{text "\<And>"} elimination). |
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The Pure logic represents the idea of variables being either inside |
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or outside the current scope by providing separate syntactic |
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categories for \emph{fixed variables} (e.g.\ @{text "x"}) vs.\ |
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\emph{schematic variables} (e.g.\ @{text "?x"}). Incidently, a |
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universal result @{text "\<turnstile> \<And>x. B(x)"} has the HHF normal form @{text |
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"\<turnstile> B(?x)"}, which represents its generality without requiring an |
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explicit quantifier. The same principle works for type variables: |
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@{text "\<turnstile> B(?\<alpha>)"} represents the idea of ``@{text "\<turnstile> \<forall>\<alpha>. B(\<alpha>)"}'' |
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without demanding a truly polymorphic framework. |
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\medskip Additional care is required to treat type variables in a |
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way that facilitates type-inference. In principle, term variables |
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depend on type variables, which means that type variables would have |
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to be declared first. For example, a raw type-theoretic framework |
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would demand the context to be constructed in stages as follows: |
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@{text "\<Gamma> = \<alpha>: type, x: \<alpha>, a: A(x\<^sub>\<alpha>)"}. |
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We allow a slightly less formalistic mode of operation: term |
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variables @{text "x"} are fixed without specifying a type yet |
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(essentially \emph{all} potential occurrences of some instance |
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@{text "x\<^sub>\<tau>"} are fixed); the first occurrence of @{text "x"} |
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within a specific term assigns its most general type, which is then |
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maintained consistently in the context. The above example becomes |
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@{text "\<Gamma> = x: term, \<alpha>: type, A(x\<^sub>\<alpha>)"}, where type @{text |
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"\<alpha>"} is fixed \emph{after} term @{text "x"}, and the constraint |
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@{text "x :: \<alpha>"} is an implicit consequence of the occurrence of |
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@{text "x\<^sub>\<alpha>"} in the subsequent proposition. |
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This twist of dependencies is also accommodated by the reverse |
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operation of exporting results from a context: a type variable |
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@{text "\<alpha>"} is considered fixed as long as it occurs in some fixed |
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term variable of the context. For example, exporting @{text "x: |
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term, \<alpha>: type \<turnstile> x\<^sub>\<alpha> \<equiv> x\<^sub>\<alpha>"} produces in the first step @{text "x: term |
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\<turnstile> x\<^sub>\<alpha> \<equiv> x\<^sub>\<alpha>"} for fixed @{text "\<alpha>"}, and only in the second step |
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@{text "\<turnstile> ?x\<^sub>?\<^sub>\<alpha> \<equiv> ?x\<^sub>?\<^sub>\<alpha>"} for schematic @{text "?x"} and @{text "?\<alpha>"}. |
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The following Isar source text illustrates this scenario. |
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*} |
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notepad |
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begin |
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{ |
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fix x -- {* all potential occurrences of some @{text "x::\<tau>"} are fixed *} |
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{ |
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have "x::'a \<equiv> x" -- {* implicit type assignment by concrete occurrence *} |
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by (rule reflexive) |
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} |
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thm this -- {* result still with fixed type @{text "'a"} *} |
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} |
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thm this -- {* fully general result for arbitrary @{text "?x::?'a"} *} |
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end |
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text {* The Isabelle/Isar proof context manages the details of term |
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vs.\ type variables, with high-level principles for moving the |
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frontier between fixed and schematic variables. |
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The @{text "add_fixes"} operation explicitly declares fixed |
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variables; the @{text "declare_term"} operation absorbs a term into |
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a context by fixing new type variables and adding syntactic |
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constraints. |
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The @{text "export"} operation is able to perform the main work of |
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generalizing term and type variables as sketched above, assuming |
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that fixing variables and terms have been declared properly. |
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There @{text "import"} operation makes a generalized fact a genuine |
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part of the context, by inventing fixed variables for the schematic |
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ones. The effect can be reversed by using @{text "export"} later, |
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potentially with an extended context; the result is equivalent to |
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the original modulo renaming of schematic variables. |
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The @{text "focus"} operation provides a variant of @{text "import"} |
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for nested propositions (with explicit quantification): @{text |
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"\<And>x\<^sub>1 \<dots> x\<^sub>n. B(x\<^sub>1, \<dots>, x\<^sub>n)"} is |
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decomposed by inventing fixed variables @{text "x\<^sub>1, \<dots>, |
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x\<^sub>n"} for the body. |
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*} |
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text %mlref {* |
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\begin{mldecls} |
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@{index_ML Variable.add_fixes: " |
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string list -> Proof.context -> string list * Proof.context"} \\ |
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@{index_ML Variable.variant_fixes: " |
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string list -> Proof.context -> string list * Proof.context"} \\ |
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@{index_ML Variable.declare_term: "term -> Proof.context -> Proof.context"} \\ |
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@{index_ML Variable.declare_constraints: "term -> Proof.context -> Proof.context"} \\ |
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@{index_ML Variable.export: "Proof.context -> Proof.context -> thm list -> thm list"} \\ |
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@{index_ML Variable.polymorphic: "Proof.context -> term list -> term list"} \\ |
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@{index_ML Variable.import: "bool -> thm list -> Proof.context -> |
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(((ctyp * ctyp) list * (cterm * cterm) list) * thm list) * Proof.context"} \\ |
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@{index_ML Variable.focus: "term -> Proof.context -> |
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((string * (string * typ)) list * term) * Proof.context"} \\ |
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\end{mldecls} |
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\begin{description} |
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\item @{ML Variable.add_fixes}~@{text "xs ctxt"} fixes term |
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variables @{text "xs"}, returning the resulting internal names. By |
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default, the internal representation coincides with the external |
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one, which also means that the given variables must not be fixed |
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already. There is a different policy within a local proof body: the |
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given names are just hints for newly invented Skolem variables. |
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\item @{ML Variable.variant_fixes} is similar to @{ML |
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Variable.add_fixes}, but always produces fresh variants of the given |
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names. |
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\item @{ML Variable.declare_term}~@{text "t ctxt"} declares term |
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@{text "t"} to belong to the context. This automatically fixes new |
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type variables, but not term variables. Syntactic constraints for |
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type and term variables are declared uniformly, though. |
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\item @{ML Variable.declare_constraints}~@{text "t ctxt"} declares |
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syntactic constraints from term @{text "t"}, without making it part |
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of the context yet. |
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\item @{ML Variable.export}~@{text "inner outer thms"} generalizes |
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fixed type and term variables in @{text "thms"} according to the |
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difference of the @{text "inner"} and @{text "outer"} context, |
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following the principles sketched above. |
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\item @{ML Variable.polymorphic}~@{text "ctxt ts"} generalizes type |
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variables in @{text "ts"} as far as possible, even those occurring |
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in fixed term variables. The default policy of type-inference is to |
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fix newly introduced type variables, which is essentially reversed |
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with @{ML Variable.polymorphic}: here the given terms are detached |
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from the context as far as possible. |
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\item @{ML Variable.import}~@{text "open thms ctxt"} invents fixed |
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type and term variables for the schematic ones occurring in @{text |
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"thms"}. The @{text "open"} flag indicates whether the fixed names |
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should be accessible to the user, otherwise newly introduced names |
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are marked as ``internal'' (\secref{sec:names}). |
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\item @{ML Variable.focus}~@{text B} decomposes the outermost @{text |
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"\<And>"} prefix of proposition @{text "B"}. |
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\end{description} |
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*} |
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text %mlex {* The following example shows how to work with fixed term |
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and type parameters and with type-inference. *} |
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ML {* |
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(*static compile-time context -- for testing only*) |
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val ctxt0 = @{context}; |
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(*locally fixed parameters -- no type assignment yet*) |
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val ([x, y], ctxt1) = ctxt0 |> Variable.add_fixes ["x", "y"]; |
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(*t1: most general fixed type; t1': most general arbitrary type*) |
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val t1 = Syntax.read_term ctxt1 "x"; |
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val t1' = singleton (Variable.polymorphic ctxt1) t1; |
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(*term u enforces specific type assignment*) |
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val u = Syntax.read_term ctxt1 "(x::nat) \<equiv> y"; |
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(*official declaration of u -- propagates constraints etc.*) |
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val ctxt2 = ctxt1 |> Variable.declare_term u; |
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val t2 = Syntax.read_term ctxt2 "x"; (*x::nat is enforced*) |
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*} |
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text {* In the above example, the starting context is derived from the |
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toplevel theory, which means that fixed variables are internalized |
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literally: @{text "x"} is mapped again to @{text "x"}, and |
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attempting to fix it again in the subsequent context is an error. |
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Alternatively, fixed parameters can be renamed explicitly as |
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follows: *} |
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ML {* |
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val ctxt0 = @{context}; |
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val ([x1, x2, x3], ctxt1) = |
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ctxt0 |> Variable.variant_fixes ["x", "x", "x"]; |
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*} |
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text {* The following ML code can now work with the invented names of |
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@{text x1}, @{text x2}, @{text x3}, without depending on |
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the details on the system policy for introducing these variants. |
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Recall that within a proof body the system always invents fresh |
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``Skolem constants'', e.g.\ as follows: *} |
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notepad |
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begin |
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ML_prf %"ML" {* |
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val ctxt0 = @{context}; |
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val ([x1], ctxt1) = ctxt0 |> Variable.add_fixes ["x"]; |
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val ([x2], ctxt2) = ctxt1 |> Variable.add_fixes ["x"]; |
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val ([x3], ctxt3) = ctxt2 |> Variable.add_fixes ["x"]; |
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val ([y1, y2], ctxt4) = |
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ctxt3 |> Variable.variant_fixes ["y", "y"]; |
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*} |
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end |
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text {* In this situation @{ML Variable.add_fixes} and @{ML |
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Variable.variant_fixes} are very similar, but identical name |
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proposals given in a row are only accepted by the second version. |
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*} |
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section {* Assumptions \label{sec:assumptions} *} |
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text {* |
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An \emph{assumption} is a proposition that it is postulated in the |
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current context. Local conclusions may use assumptions as |
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additional facts, but this imposes implicit hypotheses that weaken |
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the overall statement. |
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Assumptions are restricted to fixed non-schematic statements, i.e.\ |
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all generality needs to be expressed by explicit quantifiers. |
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Nevertheless, the result will be in HHF normal form with outermost |
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quantifiers stripped. For example, by assuming @{text "\<And>x :: \<alpha>. P |
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x"} we get @{text "\<And>x :: \<alpha>. P x \<turnstile> P ?x"} for schematic @{text "?x"} |
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of fixed type @{text "\<alpha>"}. Local derivations accumulate more and |
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more explicit references to hypotheses: @{text "A\<^sub>1, \<dots>, |
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A\<^sub>n \<turnstile> B"} where @{text "A\<^sub>1, \<dots>, A\<^sub>n"} needs to |
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be covered by the assumptions of the current context. |
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\medskip The @{text "add_assms"} operation augments the context by |
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local assumptions, which are parameterized by an arbitrary @{text |
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"export"} rule (see below). |
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The @{text "export"} operation moves facts from a (larger) inner |
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context into a (smaller) outer context, by discharging the |
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difference of the assumptions as specified by the associated export |
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rules. Note that the discharged portion is determined by the |
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difference of contexts, not the facts being exported! There is a |
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separate flag to indicate a goal context, where the result is meant |
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to refine an enclosing sub-goal of a structured proof state. |
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\medskip The most basic export rule discharges assumptions directly |
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by means of the @{text "\<Longrightarrow>"} introduction rule: |
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\[ |
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\infer[(@{text "\<Longrightarrow>\<hyphen>intro"})]{@{text "\<Gamma> - A \<turnstile> A \<Longrightarrow> B"}}{@{text "\<Gamma> \<turnstile> B"}} |
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\] |
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The variant for goal refinements marks the newly introduced |
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premises, which causes the canonical Isar goal refinement scheme to |
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enforce unification with local premises within the goal: |
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\[ |
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\infer[(@{text "#\<Longrightarrow>\<hyphen>intro"})]{@{text "\<Gamma> - A \<turnstile> #A \<Longrightarrow> B"}}{@{text "\<Gamma> \<turnstile> B"}} |
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\] |
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\medskip Alternative versions of assumptions may perform arbitrary |
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transformations on export, as long as the corresponding portion of |
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hypotheses is removed from the given facts. For example, a local |
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definition works by fixing @{text "x"} and assuming @{text "x \<equiv> t"}, |
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with the following export rule to reverse the effect: |
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\[ |
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\infer[(@{text "\<equiv>\<hyphen>expand"})]{@{text "\<Gamma> - (x \<equiv> t) \<turnstile> B t"}}{@{text "\<Gamma> \<turnstile> B x"}} |
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\] |
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This works, because the assumption @{text "x \<equiv> t"} was introduced in |
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a context with @{text "x"} being fresh, so @{text "x"} does not |
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occur in @{text "\<Gamma>"} here. |
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*} |
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text %mlref {* |
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\begin{mldecls} |
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@{index_ML_type Assumption.export} \\ |
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@{index_ML Assumption.assume: "Proof.context -> cterm -> thm"} \\ |
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@{index_ML Assumption.add_assms: |
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"Assumption.export -> |
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cterm list -> Proof.context -> thm list * Proof.context"} \\ |
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@{index_ML Assumption.add_assumes: " |
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cterm list -> Proof.context -> thm list * Proof.context"} \\ |
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@{index_ML Assumption.export: "bool -> Proof.context -> Proof.context -> thm -> thm"} \\ |
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\end{mldecls} |
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\begin{description} |
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\item Type @{ML_type Assumption.export} represents arbitrary export |
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rules, which is any function of type @{ML_type "bool -> cterm list |
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-> thm -> thm"}, where the @{ML_type "bool"} indicates goal mode, |
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and the @{ML_type "cterm list"} the collection of assumptions to be |
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discharged simultaneously. |
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\item @{ML Assumption.assume}~@{text "ctxt A"} turns proposition @{text |
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"A"} into a primitive assumption @{text "A \<turnstile> A'"}, where the |
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conclusion @{text "A'"} is in HHF normal form. |
|
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|
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\item @{ML Assumption.add_assms}~@{text "r As"} augments the context |
304 |
by assumptions @{text "As"} with export rule @{text "r"}. The |
|
305 |
resulting facts are hypothetical theorems as produced by the raw |
|
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@{ML Assumption.assume}. |
|
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|
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\item @{ML Assumption.add_assumes}~@{text "As"} is a special case of |
|
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@{ML Assumption.add_assms} where the export rule performs @{text |
|
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"\<Longrightarrow>\<hyphen>intro"} or @{text "#\<Longrightarrow>\<hyphen>intro"}, depending on goal |
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mode. |
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|
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\item @{ML Assumption.export}~@{text "is_goal inner outer thm"} |
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exports result @{text "thm"} from the the @{text "inner"} context |
|
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back into the @{text "outer"} one; @{text "is_goal = true"} means |
316 |
this is a goal context. The result is in HHF normal form. Note |
|
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that @{ML "Proof_Context.export"} combines @{ML "Variable.export"} |
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and @{ML "Assumption.export"} in the canonical way. |
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|
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\end{description} |
|
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*} |
|
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|
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text %mlex {* The following example demonstrates how rules can be |
324 |
derived by building up a context of assumptions first, and exporting |
|
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some local fact afterwards. We refer to @{theory Pure} equality |
|
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here for testing purposes. |
|
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*} |
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||
329 |
ML {* |
|
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(*static compile-time context -- for testing only*) |
|
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val ctxt0 = @{context}; |
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||
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val ([eq], ctxt1) = |
|
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ctxt0 |> Assumption.add_assumes [@{cprop "x \<equiv> y"}]; |
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val eq' = Thm.symmetric eq; |
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||
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(*back to original context -- discharges assumption*) |
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val r = Assumption.export false ctxt1 ctxt0 eq'; |
|
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*} |
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||
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text {* Note that the variables of the resulting rule are not |
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|
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generalized. This would have required to fix them properly in the |
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|
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context beforehand, and export wrt.\ variables afterwards (cf.\ @{ML |
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Variable.export} or the combined @{ML "Proof_Context.export"}). *} |
34932 | 345 |
|
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|
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section {* Structured goals and results \label{sec:struct-goals} *} |
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|
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text {* |
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Local results are established by monotonic reasoning from facts |
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within a context. This allows common combinations of theorems, |
352 |
e.g.\ via @{text "\<And>/\<Longrightarrow>"} elimination, resolution rules, or equational |
|
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reasoning, see \secref{sec:thms}. Unaccounted context manipulations |
|
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should be avoided, notably raw @{text "\<And>/\<Longrightarrow>"} introduction or ad-hoc |
|
20472 | 355 |
references to free variables or assumptions not present in the proof |
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context. |
|
18537 | 357 |
|
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\medskip The @{text "SUBPROOF"} combinator allows to structure a |
359 |
tactical proof recursively by decomposing a selected sub-goal: |
|
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@{text "(\<And>x. A(x) \<Longrightarrow> B(x)) \<Longrightarrow> \<dots>"} is turned into @{text "B(x) \<Longrightarrow> \<dots>"} |
|
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after fixing @{text "x"} and assuming @{text "A(x)"}. This means |
|
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the tactic needs to solve the conclusion, but may use the premise as |
|
363 |
a local fact, for locally fixed variables. |
|
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|
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The family of @{text "FOCUS"} combinators is similar to @{text |
366 |
"SUBPROOF"}, but allows to retain schematic variables and pending |
|
367 |
subgoals in the resulting goal state. |
|
368 |
||
20491 | 369 |
The @{text "prove"} operation provides an interface for structured |
370 |
backwards reasoning under program control, with some explicit sanity |
|
371 |
checks of the result. The goal context can be augmented by |
|
372 |
additional fixed variables (cf.\ \secref{sec:variables}) and |
|
373 |
assumptions (cf.\ \secref{sec:assumptions}), which will be available |
|
374 |
as local facts during the proof and discharged into implications in |
|
375 |
the result. Type and term variables are generalized as usual, |
|
376 |
according to the context. |
|
18537 | 377 |
|
20491 | 378 |
The @{text "obtain"} operation produces results by eliminating |
379 |
existing facts by means of a given tactic. This acts like a dual |
|
380 |
conclusion: the proof demonstrates that the context may be augmented |
|
34930 | 381 |
by parameters and assumptions, without affecting any conclusions |
382 |
that do not mention these parameters. See also |
|
58555 | 383 |
@{cite "isabelle-isar-ref"} for the user-level @{command obtain} and |
39851 | 384 |
@{command guess} elements. Final results, which may not refer to |
20491 | 385 |
the parameters in the conclusion, need to exported explicitly into |
39851 | 386 |
the original context. *} |
18537 | 387 |
|
20472 | 388 |
text %mlref {* |
389 |
\begin{mldecls} |
|
39821 | 390 |
@{index_ML SUBPROOF: "(Subgoal.focus -> tactic) -> |
391 |
Proof.context -> int -> tactic"} \\ |
|
392 |
@{index_ML Subgoal.FOCUS: "(Subgoal.focus -> tactic) -> |
|
393 |
Proof.context -> int -> tactic"} \\ |
|
394 |
@{index_ML Subgoal.FOCUS_PREMS: "(Subgoal.focus -> tactic) -> |
|
395 |
Proof.context -> int -> tactic"} \\ |
|
396 |
@{index_ML Subgoal.FOCUS_PARAMS: "(Subgoal.focus -> tactic) -> |
|
397 |
Proof.context -> int -> tactic"} \\ |
|
39853 | 398 |
@{index_ML Subgoal.focus: "Proof.context -> int -> thm -> Subgoal.focus * thm"} \\ |
399 |
@{index_ML Subgoal.focus_prems: "Proof.context -> int -> thm -> Subgoal.focus * thm"} \\ |
|
400 |
@{index_ML Subgoal.focus_params: "Proof.context -> int -> thm -> Subgoal.focus * thm"} \\ |
|
20547 | 401 |
\end{mldecls} |
34930 | 402 |
|
20547 | 403 |
\begin{mldecls} |
20472 | 404 |
@{index_ML Goal.prove: "Proof.context -> string list -> term list -> term -> |
405 |
({prems: thm list, context: Proof.context} -> tactic) -> thm"} \\ |
|
406 |
@{index_ML Goal.prove_multi: "Proof.context -> string list -> term list -> term list -> |
|
407 |
({prems: thm list, context: Proof.context} -> tactic) -> thm list"} \\ |
|
20547 | 408 |
\end{mldecls} |
409 |
\begin{mldecls} |
|
39821 | 410 |
@{index_ML Obtain.result: "(Proof.context -> tactic) -> thm list -> |
411 |
Proof.context -> ((string * cterm) list * thm list) * Proof.context"} \\ |
|
20472 | 412 |
\end{mldecls} |
18537 | 413 |
|
20472 | 414 |
\begin{description} |
18537 | 415 |
|
29761 | 416 |
\item @{ML SUBPROOF}~@{text "tac ctxt i"} decomposes the structure |
417 |
of the specified sub-goal, producing an extended context and a |
|
418 |
reduced goal, which needs to be solved by the given tactic. All |
|
419 |
schematic parameters of the goal are imported into the context as |
|
420 |
fixed ones, which may not be instantiated in the sub-proof. |
|
20491 | 421 |
|
34930 | 422 |
\item @{ML Subgoal.FOCUS}, @{ML Subgoal.FOCUS_PREMS}, and @{ML |
423 |
Subgoal.FOCUS_PARAMS} are similar to @{ML SUBPROOF}, but are |
|
424 |
slightly more flexible: only the specified parts of the subgoal are |
|
425 |
imported into the context, and the body tactic may introduce new |
|
426 |
subgoals and schematic variables. |
|
427 |
||
39853 | 428 |
\item @{ML Subgoal.focus}, @{ML Subgoal.focus_prems}, @{ML |
429 |
Subgoal.focus_params} extract the focus information from a goal |
|
430 |
state in the same way as the corresponding tacticals above. This is |
|
431 |
occasionally useful to experiment without writing actual tactics |
|
432 |
yet. |
|
433 |
||
20472 | 434 |
\item @{ML Goal.prove}~@{text "ctxt xs As C tac"} states goal @{text |
20474 | 435 |
"C"} in the context augmented by fixed variables @{text "xs"} and |
436 |
assumptions @{text "As"}, and applies tactic @{text "tac"} to solve |
|
437 |
it. The latter may depend on the local assumptions being presented |
|
438 |
as facts. The result is in HHF normal form. |
|
18537 | 439 |
|
56579 | 440 |
\item @{ML Goal.prove_multi} is similar to @{ML Goal.prove}, but |
20491 | 441 |
states several conclusions simultaneously. The goal is encoded by |
21827 | 442 |
means of Pure conjunction; @{ML Goal.conjunction_tac} will turn this |
443 |
into a collection of individual subgoals. |
|
20472 | 444 |
|
20491 | 445 |
\item @{ML Obtain.result}~@{text "tac thms ctxt"} eliminates the |
446 |
given facts using a tactic, which results in additional fixed |
|
447 |
variables and assumptions in the context. Final results need to be |
|
448 |
exported explicitly. |
|
20472 | 449 |
|
450 |
\end{description} |
|
451 |
*} |
|
30272 | 452 |
|
39853 | 453 |
text %mlex {* The following minimal example illustrates how to access |
454 |
the focus information of a structured goal state. *} |
|
455 |
||
40964 | 456 |
notepad |
457 |
begin |
|
39853 | 458 |
fix A B C :: "'a \<Rightarrow> bool" |
459 |
||
460 |
have "\<And>x. A x \<Longrightarrow> B x \<Longrightarrow> C x" |
|
461 |
ML_val |
|
462 |
{* |
|
463 |
val {goal, context = goal_ctxt, ...} = @{Isar.goal}; |
|
464 |
val (focus as {params, asms, concl, ...}, goal') = |
|
465 |
Subgoal.focus goal_ctxt 1 goal; |
|
466 |
val [A, B] = #prems focus; |
|
467 |
val [(_, x)] = #params focus; |
|
468 |
*} |
|
469 |
oops |
|
470 |
||
471 |
text {* \medskip The next example demonstrates forward-elimination in |
|
472 |
a local context, using @{ML Obtain.result}. *} |
|
39851 | 473 |
|
40964 | 474 |
notepad |
475 |
begin |
|
39851 | 476 |
assume ex: "\<exists>x. B x" |
477 |
||
478 |
ML_prf %"ML" {* |
|
479 |
val ctxt0 = @{context}; |
|
480 |
val (([(_, x)], [B]), ctxt1) = ctxt0 |
|
481 |
|> Obtain.result (fn _ => etac @{thm exE} 1) [@{thm ex}]; |
|
482 |
*} |
|
483 |
ML_prf %"ML" {* |
|
42361 | 484 |
singleton (Proof_Context.export ctxt1 ctxt0) @{thm refl}; |
39851 | 485 |
*} |
486 |
ML_prf %"ML" {* |
|
42361 | 487 |
Proof_Context.export ctxt1 ctxt0 [Thm.reflexive x] |
39851 | 488 |
handle ERROR msg => (warning msg; []); |
489 |
*} |
|
40964 | 490 |
end |
39851 | 491 |
|
18537 | 492 |
end |