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;;; semantic/analyze/fcn.el --- Analyzer support functions.
;; Copyright (C) 2007-2013 Free Software Foundation, Inc.
;; Author: Eric M. Ludlam <zappo@gnu.org>
;; This file is part of GNU Emacs.
;; GNU Emacs is free software: you can redistribute it and/or modify
;; it under the terms of the GNU General Public License as published by
;; the Free Software Foundation, either version 3 of the License, or
;; (at your option) any later version.
;; GNU Emacs is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;; GNU General Public License for more details.
;; You should have received a copy of the GNU General Public License
;; along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>.
;;; Commentary:
;;
;; Analyzer support functions.
;;; Code:
(require 'semantic)
(eval-when-compile (require 'semantic/find))
(declare-function semanticdb-typecache-merge-streams "semantic/db-typecache")
(declare-function semantic-scope-find "semantic/scope")
(declare-function semantic-scope-set-typecache "semantic/scope")
(declare-function semantic-scope-tag-get-scope "semantic/scope")
;;; Small Mode Specific Options
;;
;; These queries allow a major mode to help the analyzer make decisions.
;;
(define-overloadable-function semantic-analyze-split-name (name)
"Split a tag NAME into a sequence.
Sometimes NAMES are gathered from the parser that are compounded,
such as in C++ where foo::bar means:
\"The class BAR in the namespace FOO.\"
Return the string NAME for no change, or a list if it needs to be split.")
(defun semantic-analyze-split-name-default (name)
"Don't split up NAME by default."
name)
(define-overloadable-function semantic-analyze-unsplit-name (namelist)
"Assemble a NAMELIST into a string representing a compound name.
Return the string representing the compound name.")
(defun semantic-analyze-unsplit-name-default (namelist)
"Concatenate the names in NAMELIST with a . between."
(mapconcat 'identity namelist "."))
;;; SELECTING
;;
;; If you narrow things down to a list of tags that all mean
;; the same thing, how to you pick one? Select or merge.
;;
(defun semantic-analyze-select-best-tag (sequence &optional tagclass)
"For a SEQUENCE of tags, all with good names, pick the best one.
If SEQUENCE is made up of namespaces, merge the namespaces together.
If SEQUENCE has several prototypes, find the non-prototype.
If SEQUENCE has some items w/ no type information, find the one with a type.
If SEQUENCE is all prototypes, or has no prototypes, get the first one.
Optional TAGCLASS indicates to restrict the return to only
tags of TAGCLASS."
;; If there is a srew up and we get just one tag.. massage over it.
(when (semantic-tag-p sequence)
(setq sequence (list sequence)))
;; Filter out anything not of TAGCLASS
(when tagclass
(setq sequence (semantic-find-tags-by-class tagclass sequence)))
(if (< (length sequence) 2)
;; If the remaining sequence is 1 tag or less, just return it
;; and skip the rest of this mumbo-jumbo.
(car sequence)
;; 1)
;; This step will eliminate a vast majority of the types,
;; in addition to merging namespaces together.
;;
;; 2)
;; It will also remove prototypes.
(require 'semantic/db-typecache)
(setq sequence (semanticdb-typecache-merge-streams sequence nil))
(if (< (length sequence) 2)
;; If the remaining sequence after the merge is 1 tag or less,
;; just return it and skip the rest of this mumbo-jumbo.
(car sequence)
(let ((best nil)
(notypeinfo nil)
)
(while (and (not best) sequence)
;; 3) select a non-prototype.
(if (not (semantic-tag-type (car sequence)))
(setq notypeinfo (car sequence))
(setq best (car sequence))
)
(setq sequence (cdr sequence)))
;; Select the best, or at least the prototype.
(or best notypeinfo)))))
;;; Tag Finding
;;
;; Mechanism for lookup up tags by name.
;;
(defun semantic-analyze-find-tags-by-prefix (prefix)
;; @todo - only used in semantic-complete. Find something better?
"Attempt to find a tag with PREFIX.
This is a wrapper on top of semanticdb, and semantic search functions.
Almost all searches use the same arguments."
(if (and (fboundp 'semanticdb-minor-mode-p)
(semanticdb-minor-mode-p))
;; Search the database & concatenate all matches together.
(semanticdb-strip-find-results
(semanticdb-find-tags-for-completion prefix)
'name)
;; Search just this file because there is no DB available.
(semantic-find-tags-for-completion
prefix (current-buffer))))
;;; Finding Datatypes
;;
(define-overloadable-function semantic-analyze-dereference-metatype (type scope &optional type-declaration)
;; todo - move into typecache!!
"Return a concrete type tag based on input TYPE tag.
A concrete type is an actual declaration of a memory description,
such as a structure, or class. A meta type is an alias,
or a typedef in C or C++. If TYPE is concrete, it
is returned. If it is a meta type, it will return the concrete
type defined by TYPE.
The default behavior always returns TYPE.
Override functions need not return a real semantic tag.
Just a name, or short tag will be ok. It will be expanded here.
SCOPE is the scope object with additional items in which to search for names."
(catch 'default-behavior
(let* ((ans-tuple (:override
;; Nothing fancy, just return type by default.
(throw 'default-behavior (list type type-declaration))))
(ans-type (car ans-tuple))
(ans-type-declaration (cadr ans-tuple)))
(list (semantic-analyze-dereference-metatype-1 ans-type scope) ans-type-declaration))))
;; Finding a data type by name within a project.
;;
(defun semantic-analyze-type-to-name (type)
"Get the name of TAG's type.
The TYPE field in a tag can be nil (return nil)
or a string, or a non-positional tag."
(cond ((semantic-tag-p type)
(if (semantic-tag-named-parent type)
(semantic-analyze-unsplit-name `(,(semantic-tag-named-parent type)
,(semantic-tag-name type)))
(semantic-tag-name type)))
((stringp type)
type)
((listp type)
(car type))
(t nil)))
(defun semantic-analyze-tag-type (tag &optional scope nometaderef)
"Return the semantic tag for a type within the type of TAG.
TAG can be a variable, function or other type of tag.
The behavior of TAG's type is defined by `semantic-analyze-type'.
Optional SCOPE represents a calculated scope in which the
types might be found. This can be nil.
If NOMETADEREF, then do not dereference metatypes. This is
used by the analyzer debugger."
(semantic-analyze-type (semantic-tag-type tag) scope nometaderef))
(defun semantic-analyze-type (type-declaration &optional scope nometaderef)
"Return the semantic tag for TYPE-DECLARATION.
TAG can be a variable, function or other type of tag.
The type of tag (such as a class or struct) is a name.
Lookup this name in database, and return all slots/fields
within that types field. Also handles anonymous types.
Optional SCOPE represents a calculated scope in which the
types might be found. This can be nil.
If NOMETADEREF, then do not dereference metatypes. This is
used by the analyzer debugger."
(require 'semantic/scope)
(let ((name nil)
(typetag nil)
)
;; Is it an anonymous type?
(if (and type-declaration
(semantic-tag-p type-declaration)
(semantic-tag-of-class-p type-declaration 'type)
(not (semantic-tag-prototype-p type-declaration))
)
;; We have an anonymous type for TAG with children.
;; Use this type directly.
(if nometaderef
type-declaration
(semantic-analyze-dereference-metatype-stack
type-declaration scope type-declaration))
;; Not an anonymous type. Look up the name of this type
;; elsewhere, and report back.
(setq name (semantic-analyze-type-to-name type-declaration))
(if (and name (not (string= name "")))
(progn
;; Find a type of that name in scope.
(setq typetag (and scope (semantic-scope-find name 'type scope)))
;; If no typetag, try the typecache
(when (not typetag)
(setq typetag (semanticdb-typecache-find name))))
;; No name to look stuff up with.
(error "Semantic tag %S has no type information"
(semantic-tag-name type-declaration)))
;; Handle lists of tags.
(when (and (consp typetag) (semantic-tag-p (car typetag)))
(setq typetag (semantic-analyze-select-best-tag typetag 'type))
)
;; We now have a tag associated with the type. We need to deref it.
;;
;; If we were asked not to (ie - debugger) push the typecache anyway.
(if nometaderef
typetag
(unwind-protect
(progn
(semantic-scope-set-typecache
scope (semantic-scope-tag-get-scope typetag))
(semantic-analyze-dereference-metatype-stack typetag scope type-declaration)
)
(semantic-scope-set-typecache scope nil)
)))))
(autoload 'semantic-tag-similar-p "semantic/tag-ls")
(defun semantic-analyze-dereference-metatype-stack (type scope &optional type-declaration)
"Dereference metatypes repeatedly until we hit a real TYPE.
Uses `semantic-analyze-dereference-metatype'.
Argument SCOPE is the scope object with additional items in which to search.
Optional argument TYPE-DECLARATION is how TYPE was found referenced."
(let ((lasttype type)
(lasttypedeclaration type-declaration)
(nexttype (semantic-analyze-dereference-metatype type scope type-declaration))
(idx 0))
(catch 'metatype-recursion
(while (and nexttype (not (semantic-tag-similar-p (car nexttype) lasttype)))
(setq lasttype (car nexttype)
lasttypedeclaration (cadr nexttype))
(setq nexttype (semantic-analyze-dereference-metatype lasttype scope lasttypedeclaration))
(setq idx (1+ idx))
(when (> idx 20) (message "Possible metatype recursion for %S"
(semantic-tag-name lasttype))
(throw 'metatype-recursion nil))
))
lasttype))
;; @ TODO - the typecache can also return a stack of scope names.
(defun semantic-analyze-dereference-metatype-1 (ans scope)
"Do extra work after dereferencing a metatype.
ANS is the answer from the language specific query.
SCOPE is the current scope."
(require 'semantic/scope)
;; If ANS is a string, or if ANS is a short tag, we
;; need to do some more work to look it up.
(if (stringp ans)
;; The metatype is just a string... look it up.
(or (and scope (car-safe
;; @todo - should this be `find the best one'?
(semantic-scope-find ans 'type scope)))
(let ((tcsans nil))
(prog1
(setq tcsans
(semanticdb-typecache-find ans))
;; While going through the metatype, if we have
;; a scope, push our new cache in.
(when scope
(semantic-scope-set-typecache
scope (semantic-scope-tag-get-scope tcsans))
))
))
(when (and (semantic-tag-p ans)
(eq (semantic-tag-class ans) 'type))
;; We have a tag.
(if (semantic-tag-prototype-p ans)
;; It is a prototype.. find the real one.
(or (and scope
(car-safe
(semantic-scope-find (semantic-tag-name ans)
'type scope)))
(let ((tcsans nil))
(prog1
(setq tcsans
(semanticdb-typecache-find (semantic-tag-name ans)))
;; While going through the metatype, if we have
;; a scope, push our new cache in.
(when scope
(semantic-scope-set-typecache
scope (semantic-scope-tag-get-scope tcsans))
))))
;; We have a tag, and it is not a prototype.
ans))
))
(provide 'semantic/analyze/fcn)
;;; semantic/analyze/fcn.el ends here
|