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816 lines
29 KiB
EmacsLisp
816 lines
29 KiB
EmacsLisp
;;; semantic/scope.el --- Analyzer Scope Calculations
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;; Copyright (C) 2007, 2008, 2009, 2010 Free Software Foundation, Inc.
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;; Author: Eric M. Ludlam <eric@siege-engine.com>
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;; This file is part of GNU Emacs.
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;; GNU Emacs is free software: you can redistribute it and/or modify
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;; it under the terms of the GNU General Public License as published by
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;; the Free Software Foundation, either version 3 of the License, or
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;; (at your option) any later version.
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;; GNU Emacs is distributed in the hope that it will be useful,
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;; but WITHOUT ANY WARRANTY; without even the implied warranty of
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;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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;; GNU General Public License for more details.
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;; You should have received a copy of the GNU General Public License
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;; along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>.
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;;; Commentary:
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;;
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;; Calculate information about the current scope.
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;;
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;; Manages the current scope as a structure that can be cached on a
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;; per-file basis and recycled between different occurrences of
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;; analysis on different parts of a file.
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;;
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;; Pattern for Scope Calculation
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;;
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;; Step 1: Calculate DataTypes in Scope:
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;;
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;; a) What is in scope via using statements or local namespaces
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;; b) Lineage of current context. Some names drawn from step 1.
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;;
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;; Step 2: Convert type names into lists of concrete tags
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;;
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;; a) Convert each datatype into the real datatype tag
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;; b) Convert namespaces into the list of contents of the namespace.
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;; c) Merge all existing scopes together into one search list.
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;;
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;; Step 3: Local variables
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;;
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;; a) Local variables are in the master search list.
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;;
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(require 'semantic/db)
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(require 'semantic/analyze/fcn)
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(require 'semantic/ctxt)
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(eval-when-compile (require 'semantic/find))
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(declare-function data-debug-show "eieio-datadebug")
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(declare-function semantic-analyze-find-tag "semantic/analyze")
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(declare-function semantic-analyze-princ-sequence "semantic/analyze")
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(declare-function semanticdb-typecache-merge-streams "semantic/db-typecache")
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(declare-function semanticdb-typecache-add-dependant "semantic/db-typecache")
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;;; Code:
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(defclass semantic-scope-cache (semanticdb-abstract-cache)
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((tag :initform nil
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:documentation
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"The tag this scope was calculated for.")
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(scopetypes :initform nil
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:documentation
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"The list of types currently in scope.
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For C++, this would contain anonymous namespaces known, and
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anything labled by a `using' statement.")
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(parents :initform nil
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:documentation
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"List of parents in scope w/in the body of this function.
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Presumably, the members of these parent classes are available for access
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based on private:, or public: style statements.")
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(parentinheritance :initform nil
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:documentation "Alist of parents by inheritance.
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Each entry is ( PARENT . PROTECTION ), where PARENT is a type, and
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PROTECTION is a symbol representing the level of inheritance, such as 'private, or 'protected.")
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(scope :initform nil
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:documentation
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"Items in scope due to the scopetypes or parents.")
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(fullscope :initform nil
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:documentation
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"All the other stuff on one master list you can search.")
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(localargs :initform nil
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:documentation
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"The arguments to the function tag.")
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(localvar :initform nil
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:documentation
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"The local variables.")
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(typescope :initform nil
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:documentation
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"Slot to save intermediate scope while metatypes are dereferenced.")
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)
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"Cache used for storage of the current scope by the Semantic Analyzer.
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Saves scoping information between runs of the analyzer.")
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;;; METHODS
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;;
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;; Methods for basic management of the structure in semanticdb.
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;;
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(defmethod semantic-reset ((obj semantic-scope-cache))
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"Reset OBJ back to it's empty settings."
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(oset obj tag nil)
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(oset obj scopetypes nil)
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(oset obj parents nil)
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(oset obj parentinheritance nil)
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(oset obj scope nil)
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(oset obj fullscope nil)
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(oset obj localargs nil)
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(oset obj localvar nil)
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(oset obj typescope nil)
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)
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(defmethod semanticdb-synchronize ((cache semantic-scope-cache)
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new-tags)
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"Synchronize a CACHE with some NEW-TAGS."
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(semantic-reset cache))
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(defmethod semanticdb-partial-synchronize ((cache semantic-scope-cache)
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new-tags)
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"Synchronize a CACHE with some changed NEW-TAGS."
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;; If there are any includes or datatypes changed, then clear.
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(if (or (semantic-find-tags-by-class 'include new-tags)
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(semantic-find-tags-by-class 'type new-tags)
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(semantic-find-tags-by-class 'using new-tags))
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(semantic-reset cache))
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)
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(defun semantic-scope-reset-cache ()
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"Get the current cached scope, and reset it."
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(when semanticdb-current-table
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(let ((co (semanticdb-cache-get semanticdb-current-table
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semantic-scope-cache)))
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(semantic-reset co))))
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(defmethod semantic-scope-set-typecache ((cache semantic-scope-cache)
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types-in-scope)
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"Set the :typescope property on CACHE to some types.
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TYPES-IN-SCOPE is a list of type tags whos members are
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currently in scope. For each type in TYPES-IN-SCOPE,
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add those members to the types list.
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If nil, then the typescope is reset."
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(let ((newts nil)) ;; New Type Scope
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(dolist (onetype types-in-scope)
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(setq newts (append (semantic-tag-type-members onetype)
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newts))
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)
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(oset cache typescope newts)))
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;;; TAG SCOPES
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;;
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;; These fcns should be used by search routines that return a single
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;; tag which, in turn, may have come from a deep scope. The scope
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;; will be attached to the tag. Thus, in future scope based calls, a
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;; tag can be passed in and a scope derived from it.
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(defun semantic-scope-tag-clone-with-scope (tag scopetags)
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"Close TAG, and return it. Add SCOPETAGS as a tag-local scope.
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Stores the SCOPETAGS as a set of tag properties on the cloned tag."
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(let ((clone (semantic-tag-clone tag))
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)
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(semantic--tag-put-property clone 'scope scopetags)
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))
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(defun semantic-scope-tag-get-scope (tag)
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"Get from TAG the list of tags comprising the scope from TAG."
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(semantic--tag-get-property tag 'scope))
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;;; SCOPE UTILITIES
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;;
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;; Functions that do the main scope calculations
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(define-overloadable-function semantic-analyze-scoped-types (position)
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"Return a list of types currently in scope at POSITION.
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This is based on what tags exist at POSITION, and any associated
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types available.")
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(defun semantic-analyze-scoped-types-default (position)
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"Return a list of types currently in scope at POSITION.
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Use `semantic-ctxt-scoped-types' to find types."
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(require 'semantic/db-typecache)
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(save-excursion
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(goto-char position)
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(let ((code-scoped-types nil))
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;; Lets ask if any types are currently scoped. Scoped
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;; classes and types provide their public methods and types
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;; in source code, but are unrelated hierarchically.
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(let ((sp (semantic-ctxt-scoped-types)))
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(while sp
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;; Get this thing as a tag
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(let ((tmp (cond
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((stringp (car sp))
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(semanticdb-typecache-find (car sp)))
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;(semantic-analyze-find-tag (car sp) 'type))
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((semantic-tag-p (car sp))
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(if (semantic-analyze-tag-prototype-p (car sp))
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(semanticdb-typecache-find (semantic-tag-name (car sp)))
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;;(semantic-analyze-find-tag (semantic-tag-name (car sp)) 'type)
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(car sp)))
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(t nil))))
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(when tmp
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(setq code-scoped-types
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(cons tmp code-scoped-types))))
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(setq sp (cdr sp))))
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(setq code-scoped-types (nreverse code-scoped-types))
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(when code-scoped-types
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(semanticdb-typecache-merge-streams code-scoped-types nil))
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)))
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;;------------------------------------------------------------
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(define-overloadable-function semantic-analyze-scope-nested-tags (position scopedtypes)
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"Return a list of types in order of nesting for the context of POSITION.
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If POSITION is in a method with a named parent, find that parent, and
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identify it's scope via overlay instead.
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Optional SCOPETYPES are additional scoped entities in which our parent might
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be found.")
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(defun semantic-analyze-scope-nested-tags-default (position scopetypes)
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"Return a list of types in order of nesting for the context of POSITION.
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If POSITION is in a method with a named parent, find that parent, and
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identify it's scope via overlay instead.
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Optional SCOPETYPES are additional scoped entities in which our parent might
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be found.
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This only finds ONE immediate parent by name. All other parents returned
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are from nesting data types."
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(require 'semantic/analyze)
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(save-excursion
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(if position (goto-char position))
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(let* ((stack (reverse (semantic-find-tag-by-overlay (point))))
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(tag (car stack))
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(pparent (car (cdr stack)))
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(returnlist nil)
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)
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;; In case of arg lists or some-such, throw out non-types.
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(while (and stack (not (semantic-tag-of-class-p pparent 'type)))
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(setq stack (cdr stack)
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pparent (car (cdr stack))))
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;; Step 1:
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;; Analyze the stack of tags we are nested in as parents.
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;;
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;; If we have a pparent tag, lets go there
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;; an analyze that stack of tags.
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(when (and pparent (semantic-tag-with-position-p pparent))
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(semantic-go-to-tag pparent)
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(setq stack (semantic-find-tag-by-overlay (point)))
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;; Step one, find the merged version of stack in the typecache.
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(let* ((stacknames (reverse (mapcar 'semantic-tag-name stack)))
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(tc nil)
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)
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;; @todo - can we use the typecache ability to
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;; put a scope into a tag to do this?
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(while (and stacknames
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(setq tc (semanticdb-typecache-find
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(reverse stacknames))))
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(setq returnlist (cons tc returnlist)
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stacknames (cdr stacknames)))
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(when (not returnlist)
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;; When there was nothing from the typecache, then just
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;; use what's right here.
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(setq stack (reverse stack))
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;; Add things to STACK until we cease finding tags of class type.
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(while (and stack (eq (semantic-tag-class (car stack)) 'type))
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;; Otherwise, just add this to the returnlist.
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(setq returnlist (cons (car stack) returnlist))
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(setq stack (cdr stack)))
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(setq returnlist (nreverse returnlist))
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))
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)
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;; Only do this level of analysis for functions.
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(when (eq (semantic-tag-class tag) 'function)
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;; Step 2:
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;; If the function tag itself has a "parent" by name, then that
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;; parent will exist in the scope we just calculated, so look it
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;; up now.
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;;
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(let ((p (semantic-tag-function-parent tag)))
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(when p
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;; We have a parent, search for it.
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(let* ((searchnameraw (cond ((stringp p) p)
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((semantic-tag-p p)
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(semantic-tag-name p))
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((and (listp p) (stringp (car p)))
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(car p))))
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(searchname (semantic-analyze-split-name searchnameraw))
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(snlist (if (consp searchname)
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searchname
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(list searchname)))
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(fullsearchname nil)
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(miniscope (semantic-scope-cache "mini"))
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ptag)
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;; Find the next entry in the refereneced type for
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;; our function, and append to return list till our
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;; returnlist is empty.
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(while snlist
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(setq fullsearchname
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(append (mapcar 'semantic-tag-name returnlist)
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(list (car snlist)))) ;; Next one
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(setq ptag
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(semanticdb-typecache-find fullsearchname))
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(when (or (not ptag)
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(not (semantic-tag-of-class-p ptag 'type)))
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(let ((rawscope
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(apply 'append
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(mapcar 'semantic-tag-type-members
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(cons (car returnlist) scopetypes)
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)))
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)
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(oset miniscope parents returnlist) ;; Not really accurate, but close
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(oset miniscope scope rawscope)
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(oset miniscope fullscope rawscope)
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(setq ptag
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(semantic-analyze-find-tag searchnameraw
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'type
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miniscope
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))
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))
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(when ptag
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(when (and (not (semantic-tag-p ptag))
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(semantic-tag-p (car ptag)))
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(setq ptag (car ptag)))
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(setq returnlist (append returnlist (list ptag)))
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)
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(setq snlist (cdr snlist)))
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(setq returnlist returnlist)
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)))
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)
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returnlist
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)))
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(define-overloadable-function semantic-analyze-scope-lineage-tags (parents scopedtypes)
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"Return the full lineage of tags from PARENTS.
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The return list is of the form ( TAG . PROTECTION ), where TAG is a tag,
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and PROTECTION is the level of protection offered by the relationship.
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Optional SCOPETYPES are additional scoped entities in which our parent might
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be found.")
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(defun semantic-analyze-scope-lineage-tags-default (parents scopetypes)
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"Return the full lineage of tags from PARENTS.
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The return list is of the form ( TAG . PROTECTION ), where TAG is a tag,
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and PROTECTION is the level of protection offered by the relationship.
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Optional SCOPETYPES are additional scoped entities in which our parent might
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be found."
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(let ((lineage nil)
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(miniscope (semantic-scope-cache "mini"))
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)
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(oset miniscope parents parents)
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(oset miniscope scope scopetypes)
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(oset miniscope fullscope scopetypes)
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(dolist (slp parents)
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(semantic-analyze-scoped-inherited-tag-map
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slp (lambda (newparent)
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(let* ((pname (semantic-tag-name newparent))
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(prot (semantic-tag-type-superclass-protection slp pname))
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(effectiveprot (cond ((eq prot 'public)
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;; doesn't provide access to private slots?
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'protected)
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(t prot))))
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(push (cons newparent effectiveprot) lineage)
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))
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miniscope))
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lineage))
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;;------------------------------------------------------------
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(define-overloadable-function semantic-analyze-scoped-tags (typelist parentlist)
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"Return accessable tags when TYPELIST and PARENTLIST is in scope.
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Tags returned are not in the global name space, but are instead
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scoped inside a class or namespace. Such items can be referenced
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without use of \"object.function()\" style syntax due to an
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implicit \"object\".")
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(defun semantic-analyze-scoped-tags-default (typelist halfscope)
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"Return accessible tags when TYPELIST and HALFSCOPE is in scope.
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HALFSCOPE is the current scope partially initialized.
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Tags returned are not in the global name space, but are instead
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scoped inside a class or namespace. Such items can be referenced
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without use of \"object.function()\" style syntax due to an
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implicit \"object\"."
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(let ((typelist2 nil)
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(currentscope nil)
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(parentlist (oref halfscope parents))
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(miniscope halfscope)
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)
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;; Loop over typelist, and find and merge all namespaces matching
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;; the names in typelist.
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(while typelist
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(let ((tt (semantic-tag-type (car typelist))))
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(when (and (stringp tt) (string= tt "namespace"))
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;; By using the typecache, our namespaces are pre-merged.
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(setq typelist2 (cons (car typelist) typelist2))
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))
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(setq typelist (cdr typelist)))
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;; Loop over the types (which should be sorted by postion
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;; adding to the scopelist as we go, and using the scopelist
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;; for additional searching!
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(while typelist2
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(oset miniscope scope currentscope)
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(oset miniscope fullscope currentscope)
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(setq currentscope (append
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(semantic-analyze-scoped-type-parts (car typelist2)
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miniscope)
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currentscope))
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(setq typelist2 (cdr typelist2)))
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;; Collect all the types (class, etc) that are in our heratage.
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;; These are types that we can extract members from, not those
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;; delclared in using statements, or the like.
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;; Get the PARENTS including nesting scope for this location.
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(while parentlist
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(oset miniscope scope currentscope)
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(oset miniscope fullscope currentscope)
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(setq currentscope (append
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(semantic-analyze-scoped-type-parts (car parentlist)
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miniscope)
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currentscope))
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(setq parentlist (cdr parentlist)))
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;; Loop over all the items, and collect any type constants.
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(let ((constants nil))
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(dolist (T currentscope)
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(setq constants (append constants
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(semantic-analyze-type-constants T)))
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)
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(setq currentscope (append currentscope constants)))
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currentscope))
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;;------------------------------------------------------------
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(define-overloadable-function semantic-analyze-scope-calculate-access (type scope)
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"Calculate the access class for TYPE as defined by the current SCOPE.
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Access is related to the :parents in SCOPE. If type is a member of SCOPE
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then access would be 'private. If TYPE is inherited by a member of SCOPE,
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the access would be 'protected. Otherwise, access is 'public")
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(defun semantic-analyze-scope-calculate-access-default (type scope)
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"Calculate the access class for TYPE as defined by the current SCOPE."
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(cond ((semantic-scope-cache-p scope)
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(let ((parents (oref scope parents))
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(parentsi (oref scope parentinheritance))
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)
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(catch 'moose
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;; Investigate the parent, and see how it relates to type.
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;; If these tags are basically the same, then we have full access.
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(dolist (p parents)
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(when (semantic-tag-similar-p type p)
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(throw 'moose 'private))
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)
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;; Look to see if type is in our list of inherited parents.
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(dolist (pi parentsi)
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;; pi is a cons cell ( PARENT . protection)
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(let ((pip (car pi))
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(piprot (cdr pi)))
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(when (semantic-tag-similar-p type pip)
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(throw 'moose
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;; protection via inheritance means to pull out different
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;; bits based on protection labels in an opposite way.
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(cdr (assoc piprot
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'((public . private)
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(protected . protected)
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(private . public))))
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)))
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)
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;; Not in our parentage. Is type a FRIEND?
|
|
(let ((friends (semantic-find-tags-by-class 'friend (semantic-tag-type-members type))))
|
|
(dolist (F friends)
|
|
(dolist (pi parents)
|
|
(if (string= (semantic-tag-name F) (semantic-tag-name pi))
|
|
(throw 'moose 'private))
|
|
)))
|
|
;; Found nothing, return public
|
|
'public)
|
|
))
|
|
(t 'public)))
|
|
|
|
(defun semantic-completable-tags-from-type (type)
|
|
"Return a list of slots that are valid completions from the list of SLOTS.
|
|
If a tag in SLOTS has a named parent, then that implies that the
|
|
tag is not something you can complete from within TYPE."
|
|
(let ((allslots (semantic-tag-components type))
|
|
(leftover nil)
|
|
)
|
|
(dolist (S allslots)
|
|
(when (or (not (semantic-tag-of-class-p S 'function))
|
|
(not (semantic-tag-function-parent S)))
|
|
(setq leftover (cons S leftover)))
|
|
)
|
|
(nreverse leftover)))
|
|
|
|
(defun semantic-analyze-scoped-type-parts (type &optional scope noinherit protection)
|
|
"Return all parts of TYPE, a tag representing a TYPE declaration.
|
|
SCOPE is the scope object.
|
|
NOINHERIT turns off searching of inherited tags.
|
|
PROTECTION specifies the type of access requested, such as 'public or 'private."
|
|
(if (not type)
|
|
nil
|
|
(let* ((access (semantic-analyze-scope-calculate-access type scope))
|
|
;; SLOTS are the slots directly a part of TYPE.
|
|
(allslots (semantic-completable-tags-from-type type))
|
|
(slots (semantic-find-tags-by-scope-protection
|
|
access
|
|
type allslots))
|
|
(fname (semantic-tag-file-name type))
|
|
;; EXTMETH are externally defined methods that are still
|
|
;; a part of this class.
|
|
|
|
;; @TODO - is this line needed?? Try w/out for a while
|
|
;; @note - I think C++ says no. elisp might, but methods
|
|
;; look like defuns, so it makes no difference.
|
|
(extmeth nil) ; (semantic-tag-external-member-children type t))
|
|
|
|
;; INHERITED are tags found in classes that our TYPE tag
|
|
;; inherits from. Do not do this if it was not requested.
|
|
(inherited (when (not noinherit)
|
|
(semantic-analyze-scoped-inherited-tags type scope
|
|
access)))
|
|
)
|
|
(when (not (semantic-tag-in-buffer-p type))
|
|
(let ((copyslots nil))
|
|
(dolist (TAG slots)
|
|
;;(semantic--tag-put-property TAG :filename fname)
|
|
(if (semantic-tag-file-name TAG)
|
|
;; If it has a filename, just go with it...
|
|
(setq copyslots (cons TAG copyslots))
|
|
;; Otherwise, copy the tag w/ the guessed filename.
|
|
(setq copyslots (cons (semantic-tag-copy TAG nil fname)
|
|
copyslots)))
|
|
)
|
|
(setq slots (nreverse copyslots))
|
|
))
|
|
;; Flatten the database output.
|
|
(append slots extmeth inherited)
|
|
)))
|
|
|
|
(defun semantic-analyze-scoped-inherited-tags (type scope access)
|
|
"Return all tags that TYPE inherits from.
|
|
Argument SCOPE specify additional tags that are in scope
|
|
whose tags can be searched when needed, OR it may be a scope object.
|
|
ACCESS is the level of access we filter on child supplied tags.
|
|
For languages with protection on specific methods or slots,
|
|
it should strip out those not accessible by methods of TYPE.
|
|
An ACCESS of 'public means not in a method of a subclass of type.
|
|
A value of 'private means we can access private parts of the originating
|
|
type."
|
|
(let ((ret nil))
|
|
(semantic-analyze-scoped-inherited-tag-map
|
|
type (lambda (p)
|
|
(let* ((pname (semantic-tag-name p))
|
|
(protection (semantic-tag-type-superclass-protection
|
|
type pname))
|
|
)
|
|
(if (and (eq access 'public) (not (eq protection 'public)))
|
|
nil ;; Don't do it.
|
|
|
|
;; We can get some parts of this type.
|
|
(setq ret (nconc ret
|
|
;; Do not pull in inherited parts here. Those
|
|
;; will come via the inherited-tag-map fcn
|
|
(semantic-analyze-scoped-type-parts
|
|
p scope t protection))
|
|
))))
|
|
scope)
|
|
ret))
|
|
|
|
(defun semantic-analyze-scoped-inherited-tag-map (type fcn scope)
|
|
"Map all parents of TYPE to FCN. Return tags of all the types.
|
|
Argument SCOPE specify additional tags that are in scope
|
|
whose tags can be searched when needed, OR it may be a scope object."
|
|
(require 'semantic/analyze)
|
|
(let* (;; PARENTS specifies only the superclasses and not
|
|
;; interfaces. Inheriting from an interfaces implies
|
|
;; you have a copy of all methods locally. I think.
|
|
(parents (semantic-tag-type-superclasses type))
|
|
ps pt
|
|
(tmpscope scope)
|
|
)
|
|
(save-excursion
|
|
|
|
;; Create a SCOPE just for looking up the parent based on where
|
|
;; the parent came from.
|
|
;;
|
|
;; @TODO - Should we cache these mini-scopes around in Emacs
|
|
;; for recycling later? Should this become a helpful
|
|
;; extra routine?
|
|
(when (and parents (semantic-tag-with-position-p type))
|
|
(save-excursion
|
|
;; If TYPE has a position, go there and get the scope.
|
|
(semantic-go-to-tag type)
|
|
|
|
;; We need to make a mini scope, and only include the misc bits
|
|
;; that will help in finding the parent. We don't really need
|
|
;; to do any of the stuff related to variables and what-not.
|
|
(setq tmpscope (semantic-scope-cache "mini"))
|
|
(let* ( ;; Step 1:
|
|
(scopetypes (semantic-analyze-scoped-types (point)))
|
|
(parents (semantic-analyze-scope-nested-tags (point) scopetypes))
|
|
;;(parentinherited (semantic-analyze-scope-lineage-tags parents scopetypes))
|
|
(lscope nil)
|
|
)
|
|
(oset tmpscope scopetypes scopetypes)
|
|
(oset tmpscope parents parents)
|
|
;;(oset tmpscope parentinheritance parentinherited)
|
|
|
|
(when (or scopetypes parents)
|
|
(setq lscope (semantic-analyze-scoped-tags scopetypes tmpscope))
|
|
(oset tmpscope scope lscope))
|
|
(oset tmpscope fullscope (append scopetypes lscope parents))
|
|
)))
|
|
;; END creating tmpscope
|
|
|
|
;; Look up each parent one at a time.
|
|
(dolist (p parents)
|
|
(setq ps (cond ((stringp p) p)
|
|
((and (semantic-tag-p p) (semantic-tag-prototype-p p))
|
|
(semantic-tag-name p))
|
|
((and (listp p) (stringp (car p)))
|
|
p))
|
|
pt (condition-case nil
|
|
(or (semantic-analyze-find-tag ps 'type tmpscope)
|
|
;; A backup hack.
|
|
(semantic-analyze-find-tag ps 'type scope))
|
|
(error nil)))
|
|
|
|
(when pt
|
|
(funcall fcn pt)
|
|
;; Note that we pass the original SCOPE in while recursing.
|
|
;; so that the correct inheritance model is passed along.
|
|
(semantic-analyze-scoped-inherited-tag-map pt fcn scope)
|
|
)))
|
|
nil))
|
|
|
|
;;; ANALYZER
|
|
;;
|
|
;; Create the scope structure for use in the Analyzer.
|
|
;;
|
|
;;;###autoload
|
|
(defun semantic-calculate-scope (&optional point)
|
|
"Calculate the scope at POINT.
|
|
If POINT is not provided, then use the current location of point.
|
|
The class returned from the scope calculation is variable
|
|
`semantic-scope-cache'."
|
|
(interactive)
|
|
(if (not (and (featurep 'semantic/db) semanticdb-current-database))
|
|
nil ;; Don't do anything...
|
|
(require 'semantic/db-typecache)
|
|
(if (not point) (setq point (point)))
|
|
(when (called-interactively-p 'any)
|
|
(semantic-fetch-tags)
|
|
(semantic-scope-reset-cache))
|
|
(save-excursion
|
|
(goto-char point)
|
|
(let* ((TAG (semantic-current-tag))
|
|
(scopecache
|
|
(semanticdb-cache-get semanticdb-current-table
|
|
semantic-scope-cache))
|
|
)
|
|
(when (not (semantic-equivalent-tag-p TAG (oref scopecache tag)))
|
|
(semantic-reset scopecache))
|
|
(if (oref scopecache tag)
|
|
;; Even though we can recycle most of the scope, we
|
|
;; need to redo the local variables since those change
|
|
;; as you move about the tag.
|
|
(condition-case nil
|
|
(oset scopecache localvar (semantic-get-all-local-variables))
|
|
(error nil))
|
|
|
|
(let* (;; Step 1:
|
|
(scopetypes (semantic-analyze-scoped-types point))
|
|
(parents (semantic-analyze-scope-nested-tags point scopetypes))
|
|
(parentinherited (semantic-analyze-scope-lineage-tags
|
|
parents scopetypes))
|
|
)
|
|
(oset scopecache tag TAG)
|
|
(oset scopecache scopetypes scopetypes)
|
|
(oset scopecache parents parents)
|
|
(oset scopecache parentinheritance parentinherited)
|
|
|
|
(let* (;; Step 2:
|
|
(scope (when (or scopetypes parents)
|
|
(semantic-analyze-scoped-tags scopetypes scopecache))
|
|
)
|
|
;; Step 3:
|
|
(localargs (semantic-get-local-arguments))
|
|
(localvar (condition-case nil
|
|
(semantic-get-all-local-variables)
|
|
(error nil)))
|
|
)
|
|
|
|
;; Try looking for parents again.
|
|
(when (not parentinherited)
|
|
(setq parentinherited (semantic-analyze-scope-lineage-tags
|
|
parents (append scopetypes scope)))
|
|
(when parentinherited
|
|
(oset scopecache parentinheritance parentinherited)
|
|
;; Try calculating the scope again with the new inherited parent list.
|
|
(setq scope (when (or scopetypes parents)
|
|
(semantic-analyze-scoped-tags scopetypes scopecache))
|
|
)))
|
|
|
|
;; Fill out the scope.
|
|
(oset scopecache scope scope)
|
|
(oset scopecache fullscope (append scopetypes scope parents))
|
|
(oset scopecache localargs localargs)
|
|
(oset scopecache localvar localvar)
|
|
)))
|
|
;; Make sure we become dependant on the typecache.
|
|
(semanticdb-typecache-add-dependant scopecache)
|
|
;; Handy debug output.
|
|
(when (called-interactively-p 'any)
|
|
(require 'eieio-datadebug)
|
|
(data-debug-show scopecache))
|
|
;; Return ourselves
|
|
scopecache))))
|
|
|
|
(defun semantic-scope-find (name &optional class scope-in)
|
|
"Find the tag with NAME, and optional CLASS in the current SCOPE-IN.
|
|
Searches various elements of the scope for NAME. Return ALL the
|
|
hits in order, with the first tag being in the closest scope."
|
|
(let ((scope (or scope-in (semantic-calculate-scope)))
|
|
(ans nil))
|
|
;; Is the passed in scope really a scope? if so, look through
|
|
;; the options in that scope.
|
|
(if (semantic-scope-cache-p scope)
|
|
(let* ((la
|
|
;; This should be first, but bugs in the
|
|
;; C parser will turn function calls into
|
|
;; assumed int return function prototypes. Yuck!
|
|
(semantic-find-tags-by-name name (oref scope localargs)))
|
|
(lv
|
|
(semantic-find-tags-by-name name (oref scope localvar)))
|
|
(fullscoperaw (oref scope fullscope))
|
|
(sc (semantic-find-tags-by-name name fullscoperaw))
|
|
(typescoperaw (oref scope typescope))
|
|
(tsc (semantic-find-tags-by-name name typescoperaw))
|
|
)
|
|
(setq ans
|
|
(if class
|
|
;; Scan out things not of the right class.
|
|
(semantic-find-tags-by-class class (append la lv sc tsc))
|
|
(append la lv sc tsc))
|
|
)
|
|
|
|
(when (and (not ans) (or typescoperaw fullscoperaw))
|
|
(let ((namesplit (semantic-analyze-split-name name)))
|
|
(when (consp namesplit)
|
|
;; It may be we need to hack our way through type typescope.
|
|
(while namesplit
|
|
(setq ans (append
|
|
(semantic-find-tags-by-name (car namesplit)
|
|
typescoperaw)
|
|
(semantic-find-tags-by-name (car namesplit)
|
|
fullscoperaw)
|
|
))
|
|
(if (not ans)
|
|
(setq typescoperaw nil)
|
|
(when (cdr namesplit)
|
|
(setq typescoperaw (semantic-tag-type-members
|
|
(car ans)))))
|
|
|
|
(setq namesplit (cdr namesplit)))
|
|
;; Once done, store the current typecache lookup
|
|
(oset scope typescope
|
|
(append typescoperaw (oref scope typescope)))
|
|
)))
|
|
;; Return it.
|
|
ans)
|
|
;; Not a real scope. Our scope calculation analyze parts of
|
|
;; what it finds, and needs to pass lists through to do it's work.
|
|
;; Tread that list as a singly entry.
|
|
(if class
|
|
(semantic-find-tags-by-class class scope)
|
|
scope)
|
|
)))
|
|
|
|
;;; DUMP
|
|
;;
|
|
(defmethod semantic-analyze-show ((context semantic-scope-cache))
|
|
"Insert CONTEXT into the current buffer in a nice way."
|
|
(require 'semantic/analyze)
|
|
(semantic-analyze-princ-sequence (oref context scopetypes) "-> ScopeTypes: " )
|
|
(semantic-analyze-princ-sequence (oref context parents) "-> Parents: " )
|
|
(semantic-analyze-princ-sequence (oref context scope) "-> Scope: " )
|
|
;;(semantic-analyze-princ-sequence (oref context fullscope) "Fullscope: " )
|
|
(semantic-analyze-princ-sequence (oref context localargs) "-> Local Args: " )
|
|
(semantic-analyze-princ-sequence (oref context localvar) "-> Local Vars: " )
|
|
)
|
|
|
|
(provide 'semantic/scope)
|
|
|
|
;; Local variables:
|
|
;; generated-autoload-file: "loaddefs.el"
|
|
;; generated-autoload-load-name: "semantic/scope"
|
|
;; End:
|
|
|
|
;; arch-tag: 056ab514-3e28-4d6e-84ed-9283dce5a01e
|
|
;;; semantic/scope.el ends here
|