doc-src/IsarImplementation/Thy/Integration.thy

--- a/doc-src/IsarImplementation/Thy/Integration.thy	Mon Aug 27 16:48:41 2012 +0200
+++ /dev/null	Thu Jan 01 00:00:00 1970 +0000
@@ -1,307 +0,0 @@
-theory Integration
-imports Base
-begin
-
-chapter {* System integration *}
-
-section {* Isar toplevel \label{sec:isar-toplevel} *}
-
-text {* The Isar toplevel may be considered the centeral hub of the
-  Isabelle/Isar system, where all key components and sub-systems are
-  integrated into a single read-eval-print loop of Isar commands,
-  which also incorporates the underlying ML compiler.
-
-  Isabelle/Isar departs from the original ``LCF system architecture''
-  where ML was really The Meta Language for defining theories and
-  conducting proofs.  Instead, ML now only serves as the
-  implementation language for the system (and user extensions), while
-  the specific Isar toplevel supports the concepts of theory and proof
-  development natively.  This includes the graph structure of theories
-  and the block structure of proofs, support for unlimited undo,
-  facilities for tracing, debugging, timing, profiling etc.
-
-  \medskip The toplevel maintains an implicit state, which is
-  transformed by a sequence of transitions -- either interactively or
-  in batch-mode.  In interactive mode, Isar state transitions are
-  encapsulated as safe transactions, such that both failure and undo
-  are handled conveniently without destroying the underlying draft
-  theory (cf.~\secref{sec:context-theory}).  In batch mode,
-  transitions operate in a linear (destructive) fashion, such that
-  error conditions abort the present attempt to construct a theory or
-  proof altogether.
-
-  The toplevel state is a disjoint sum of empty @{text toplevel}, or
-  @{text theory}, or @{text proof}.  On entering the main Isar loop we
-  start with an empty toplevel.  A theory is commenced by giving a
-  @{text \<THEORY>} header; within a theory we may issue theory
-  commands such as @{text \<DEFINITION>}, or state a @{text
-  \<THEOREM>} to be proven.  Now we are within a proof state, with a
-  rich collection of Isar proof commands for structured proof
-  composition, or unstructured proof scripts.  When the proof is
-  concluded we get back to the theory, which is then updated by
-  storing the resulting fact.  Further theory declarations or theorem
-  statements with proofs may follow, until we eventually conclude the
-  theory development by issuing @{text \<END>}.  The resulting theory
-  is then stored within the theory database and we are back to the
-  empty toplevel.
-
-  In addition to these proper state transformations, there are also
-  some diagnostic commands for peeking at the toplevel state without
-  modifying it (e.g.\ \isakeyword{thm}, \isakeyword{term},
-  \isakeyword{print-cases}).
-*}
-
-text %mlref {*
-  \begin{mldecls}
-  @{index_ML_type Toplevel.state} \\
-  @{index_ML Toplevel.UNDEF: "exn"} \\
-  @{index_ML Toplevel.is_toplevel: "Toplevel.state -> bool"} \\
-  @{index_ML Toplevel.theory_of: "Toplevel.state -> theory"} \\
-  @{index_ML Toplevel.proof_of: "Toplevel.state -> Proof.state"} \\
-  @{index_ML Toplevel.debug: "bool Unsynchronized.ref"} \\
-  @{index_ML Toplevel.timing: "bool Unsynchronized.ref"} \\
-  @{index_ML Toplevel.profiling: "int Unsynchronized.ref"} \\
-  \end{mldecls}
-
-  \begin{description}
-
-  \item Type @{ML_type Toplevel.state} represents Isar toplevel
-  states, which are normally manipulated through the concept of
-  toplevel transitions only (\secref{sec:toplevel-transition}).  Also
-  note that a raw toplevel state is subject to the same linearity
-  restrictions as a theory context (cf.~\secref{sec:context-theory}).
-
-  \item @{ML Toplevel.UNDEF} is raised for undefined toplevel
-  operations.  Many operations work only partially for certain cases,
-  since @{ML_type Toplevel.state} is a sum type.
-
-  \item @{ML Toplevel.is_toplevel}~@{text "state"} checks for an empty
-  toplevel state.
-
-  \item @{ML Toplevel.theory_of}~@{text "state"} selects the
-  background theory of @{text "state"}, raises @{ML Toplevel.UNDEF}
-  for an empty toplevel state.
-
-  \item @{ML Toplevel.proof_of}~@{text "state"} selects the Isar proof
-  state if available, otherwise raises @{ML Toplevel.UNDEF}.
-
-  \item @{ML "Toplevel.debug := true"} makes the toplevel print further
-  details about internal error conditions, exceptions being raised
-  etc.
-
-  \item @{ML "Toplevel.timing := true"} makes the toplevel print timing
-  information for each Isar command being executed.
-
-  \item @{ML Toplevel.profiling}~@{ML_text ":="}~@{text "n"} controls
-  low-level profiling of the underlying ML runtime system.  For
-  Poly/ML, @{text "n = 1"} means time and @{text "n = 2"} space
-  profiling.
-
-  \end{description}
-*}
-
-text %mlantiq {*
-  \begin{matharray}{rcl}
-  @{ML_antiquotation_def "Isar.state"} & : & @{text ML_antiquotation} \\
-  \end{matharray}
-
-  \begin{description}
-
-  \item @{text "@{Isar.state}"} refers to Isar toplevel state at that
-  point --- as abstract value.
-
-  This only works for diagnostic ML commands, such as @{command
-  ML_val} or @{command ML_command}.
-
-  \end{description}
-*}
-
-
-subsection {* Toplevel transitions \label{sec:toplevel-transition} *}
-
-text {*
-  An Isar toplevel transition consists of a partial function on the
-  toplevel state, with additional information for diagnostics and
-  error reporting: there are fields for command name, source position,
-  optional source text, as well as flags for interactive-only commands
-  (which issue a warning in batch-mode), printing of result state,
-  etc.
-
-  The operational part is represented as the sequential union of a
-  list of partial functions, which are tried in turn until the first
-  one succeeds.  This acts like an outer case-expression for various
-  alternative state transitions.  For example, \isakeyword{qed} works
-  differently for a local proofs vs.\ the global ending of the main
-  proof.
-
-  Toplevel transitions are composed via transition transformers.
-  Internally, Isar commands are put together from an empty transition
-  extended by name and source position.  It is then left to the
-  individual command parser to turn the given concrete syntax into a
-  suitable transition transformer that adjoins actual operations on a
-  theory or proof state etc.
-*}
-
-text %mlref {*
-  \begin{mldecls}
-  @{index_ML Toplevel.print: "Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.no_timing: "Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.keep: "(Toplevel.state -> unit) ->
-  Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.theory: "(theory -> theory) ->
-  Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.theory_to_proof: "(theory -> Proof.state) ->
-  Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.proof: "(Proof.state -> Proof.state) ->
-  Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.proofs: "(Proof.state -> Proof.state Seq.seq) ->
-  Toplevel.transition -> Toplevel.transition"} \\
-  @{index_ML Toplevel.end_proof: "(bool -> Proof.state -> Proof.context) ->
-  Toplevel.transition -> Toplevel.transition"} \\
-  \end{mldecls}
-
-  \begin{description}
-
-  \item @{ML Toplevel.print}~@{text "tr"} sets the print flag, which
-  causes the toplevel loop to echo the result state (in interactive
-  mode).
-
-  \item @{ML Toplevel.no_timing}~@{text "tr"} indicates that the
-  transition should never show timing information, e.g.\ because it is
-  a diagnostic command.
-
-  \item @{ML Toplevel.keep}~@{text "tr"} adjoins a diagnostic
-  function.
-
-  \item @{ML Toplevel.theory}~@{text "tr"} adjoins a theory
-  transformer.
-
-  \item @{ML Toplevel.theory_to_proof}~@{text "tr"} adjoins a global
-  goal function, which turns a theory into a proof state.  The theory
-  may be changed before entering the proof; the generic Isar goal
-  setup includes an argument that specifies how to apply the proven
-  result to the theory, when the proof is finished.
-
-  \item @{ML Toplevel.proof}~@{text "tr"} adjoins a deterministic
-  proof command, with a singleton result.
-
-  \item @{ML Toplevel.proofs}~@{text "tr"} adjoins a general proof
-  command, with zero or more result states (represented as a lazy
-  list).
-
-  \item @{ML Toplevel.end_proof}~@{text "tr"} adjoins a concluding
-  proof command, that returns the resulting theory, after storing the
-  resulting facts in the context etc.
-
-  \end{description}
-*}
-
-
-section {* Theory database \label{sec:theory-database} *}
-
-text {*
-  The theory database maintains a collection of theories, together
-  with some administrative information about their original sources,
-  which are held in an external store (i.e.\ some directory within the
-  regular file system).
-
-  The theory database is organized as a directed acyclic graph;
-  entries are referenced by theory name.  Although some additional
-  interfaces allow to include a directory specification as well, this
-  is only a hint to the underlying theory loader.  The internal theory
-  name space is flat!
-
-  Theory @{text A} is associated with the main theory file @{text
-  A}\verb,.thy,, which needs to be accessible through the theory
-  loader path.  Any number of additional ML source files may be
-  associated with each theory, by declaring these dependencies in the
-  theory header as @{text \<USES>}, and loading them consecutively
-  within the theory context.  The system keeps track of incoming ML
-  sources and associates them with the current theory.
-
-  The basic internal actions of the theory database are @{text
-  "update"} and @{text "remove"}:
-
-  \begin{itemize}
-
-  \item @{text "update A"} introduces a link of @{text "A"} with a
-  @{text "theory"} value of the same name; it asserts that the theory
-  sources are now consistent with that value;
-
-  \item @{text "remove A"} deletes entry @{text "A"} from the theory
-  database.
-  
-  \end{itemize}
-
-  These actions are propagated to sub- or super-graphs of a theory
-  entry as expected, in order to preserve global consistency of the
-  state of all loaded theories with the sources of the external store.
-  This implies certain causalities between actions: @{text "update"}
-  or @{text "remove"} of an entry will @{text "remove"} all
-  descendants.
-
-  \medskip There are separate user-level interfaces to operate on the
-  theory database directly or indirectly.  The primitive actions then
-  just happen automatically while working with the system.  In
-  particular, processing a theory header @{text "\<THEORY> A
-  \<IMPORTS> B\<^sub>1 \<dots> B\<^sub>n \<BEGIN>"} ensures that the
-  sub-graph of the collective imports @{text "B\<^sub>1 \<dots> B\<^sub>n"}
-  is up-to-date, too.  Earlier theories are reloaded as required, with
-  @{text update} actions proceeding in topological order according to
-  theory dependencies.  There may be also a wave of implied @{text
-  remove} actions for derived theory nodes until a stable situation
-  is achieved eventually.
-*}
-
-text %mlref {*
-  \begin{mldecls}
-  @{index_ML use_thy: "string -> unit"} \\
-  @{index_ML use_thys: "string list -> unit"} \\
-  @{index_ML Thy_Info.get_theory: "string -> theory"} \\
-  @{index_ML Thy_Info.remove_thy: "string -> unit"} \\[1ex]
-  @{index_ML Thy_Info.register_thy: "theory -> unit"} \\[1ex]
-  @{ML_text "datatype action = Update | Remove"} \\
-  @{index_ML Thy_Info.add_hook: "(Thy_Info.action -> string -> unit) -> unit"} \\
-  \end{mldecls}
-
-  \begin{description}
-
-  \item @{ML use_thy}~@{text A} ensures that theory @{text A} is fully
-  up-to-date wrt.\ the external file store, reloading outdated
-  ancestors as required.  In batch mode, the simultaneous @{ML
-  use_thys} should be used exclusively.
-
-  \item @{ML use_thys} is similar to @{ML use_thy}, but handles
-  several theories simultaneously.  Thus it acts like processing the
-  import header of a theory, without performing the merge of the
-  result.  By loading a whole sub-graph of theories like that, the
-  intrinsic parallelism can be exploited by the system, to speedup
-  loading.
-
-  \item @{ML Thy_Info.get_theory}~@{text A} retrieves the theory value
-  presently associated with name @{text A}.  Note that the result
-  might be outdated.
-
-  \item @{ML Thy_Info.remove_thy}~@{text A} deletes theory @{text A} and all
-  descendants from the theory database.
-
-  \item @{ML Thy_Info.register_thy}~@{text "text thy"} registers an
-  existing theory value with the theory loader database and updates
-  source version information according to the current file-system
-  state.
-
-  \item @{ML "Thy_Info.add_hook"}~@{text f} registers function @{text
-  f} as a hook for theory database actions.  The function will be
-  invoked with the action and theory name being involved; thus derived
-  actions may be performed in associated system components, e.g.\
-  maintaining the state of an editor for the theory sources.
-
-  The kind and order of actions occurring in practice depends both on
-  user interactions and the internal process of resolving theory
-  imports.  Hooks should not rely on a particular policy here!  Any
-  exceptions raised by the hook are ignored.
-
-  \end{description}
-*}
-
-end