;;; org-element-ast.el --- Abstract syntax tree for Org  -*- lexical-binding: t; -*-

;; Copyright (C) 2023-2023 Free Software Foundation, Inc.

;; Author: Ihor Radchenko <yantar92 at posteo dot net>
;; Keywords: data, lisp

;; 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 <https://www.gnu.org/licenses/>.

;;; Commentary:

;; This file implements Org abstract syntax tree (AST) data structure.
;;
;; Only the most generic aspect of the syntax tree are considered
;; below.  The fine details of Org syntax are implemented elsewhere.
;;
;; Org AST is composed of nested syntax nodes.
;; Within actual Org syntax, the nodes can be either headings,
;; elements, or objects.  However, historically, we often call syntax
;; nodes simply "elements", unless the context requires clarification
;; about the node type.  In particular, many functions below will have
;; naming pattern `org-element-X', implying `org-element-node-X' --
;; they will apply to all the node types, not just to elements.
;;
;; 1. Syntax nodes
;; ------------------
;; Each Org syntax node can be represented as a string or list.
;;
;; The main node representation follows the pattern
;; (TYPE PROPERTIES CONTENTS), where
;;   TYPE is a symbol describing the node type.
;;   PROPERTIES is the property list attached to it.
;;   CONTENTS is a list of child syntax nodes contained within the
;;            current node, when applicable.
;;
;;; For example, "*bold text*  " node can be represented as
;;
;;    (bold (:begin 1 :end 14 :post-blank 2 ...) "bold text")
;;
;; TYPE can be any symbol, including symbol not explicitly defined by
;; Org syntax.  If TYPE is not a part of the syntax, the syntax
;; node is called "pseudo element/object", but otherwise considered a
;; valid part of Org syntax tree.  Search "Pseudo objects and
;; elements" in lisp/ox-latex.el for an example of using pseudo
;; elements.
;;
;; PROPERTIES is a property list (:property1 value1 :property2 value2 ...)
;; holding properties and value.
;;
;; `:standard-properties', `:parent', `:deferred', and `:secondary'
;; properties are treated specially in the code below.
;;
;; `:standard-properties' holds an array with
;; `org-element--standard-properties' values, in the same order.  The
;; values in the array have priority over the same properties
;; specified in the property list.  You should not rely on the value
;; of `org-element--standard-properties' in the code.
;; `:standard-properties' may or may not be actually present in
;; PROPERTIES.  It is mostly used to speed up property access in
;; performance-critical code, as most of the code requesting property
;; values by constant name is inlined.
;;
;; The previous example can also be presented in more compact form as:
;;
;;    (bold (:standard-properties [1 10 ... 2 ...]) "bold text")
;;
;; Using an array allows faster access to frequently used properties.
;;
;; `:parent' holds the containing node, for a child node within the
;; AST.  It may or may not be present in PROPERTIES.
;;
;; `:secondary' holds a list of properties that may contain extra AST
;; nodes, in addition to the node contents.
;;
;; `deferred' property describes how to update not-yet-calculated
;; properties on request.
;;
;;
;; Syntax node can also be represented by a string.  Strings always
;; represent syntax node of `plain-text' type with contents being nil
;; and properties represented as string properties at position 0.
;; `:standard-properties' are not considered for `plain-text' nodes as
;; `plain-text' nodes tend to hold much fewer properties.
;;
;; In the above example, `plain-text' node "bold text" is more
;; accurately represented as
;;
;;    #("bold text" 0 9 (:parent (bold ...)))
;;
;; with :parent property value pointing back to the containing `bold'
;; node.
;;
;; `anonymous' syntax node is represented as a list with `car'
;; containing another syntax node.  Such node has nil type, does not
;; have properties, and its contents is a list of the contained syntax
;; node.  `:parent' property of the contained nodes point back to the
;; list itself, except when `anonymous' node holds secondary value
;; (see below), in which case the `:parent' property is set to be the
;; containing node in the AST.
;;
;; Any node representation other then described above is not
;; considered as Org syntax node.
;;
;; 2. Deferred values
;; ------------------
;; Sometimes, it is computationally expensive or even not possible to
;; calculate property values when creating an AST node.  The value
;; calculation can be deferred to the time the value is requested.
;;
;; Property values and contained nodes may have a special value of
;; `org-element-deferred' type.  Such values are computed dynamically.
;; Either every time the property value is requested or just the first
;; time.  In the latter case, the `org-element-deferred' property
;; value is auto-replaced with the dynamically computed result.
;;
;; Sometimes, even property names (not just property values) cannot, or
;; should not be computed in advance.  If a special property
;; `:deferred' has the value of `org-element-deferred-type', it is
;; first resolved for side effects of setting the missing properties.
;; The resolved value is re-assigned to the `:deferred' property.
;;
;; Note that `org-element-copy' unconditionally resolves deferred
;; properties.  This is useful to generate pure (in functional sense)
;; AST.
;;
;; The properties listed in `org-element--standard-properties', except
;; `:deferred' and `:parent' are never considered to have deferred value.
;; This constraint makes org-element API significantly faster.
;;
;; 3. Org document representation
;; ------------------------------
;; Document AST is represented by nested Org syntax nodes.
;;
;; Each node in the AST can hold the contained node in its CONTENTS or
;; as values of properties.
;;
;; For example, (bold (...) "bold text") `bold' node contains
;; `plain-text' node in CONTENTS.
;;
;; The containing node is called "parent node".
;;
;; The contained nodes held inside CONTENTS are called "child nodes".
;; They must have their `:parent' property set to the containing
;; parent node.
;;
;; The contained nodes can also be held as property values.  Such
;; nodes are called "secondary nodes".  Only certain properties
;; can contribute to AST - the property names listed as the value of
;; special property `:secondary'
;;
;; For example,
;;
;;   (headline ((:secondary (:title)
;;               :title (#("text" 0 4 (:parent (headline ...)))))))
;;
;; is a parent headline node containing "text" secondary string node
;; inside `:title' property.  Note that `:title' is listed in
;; `:secondary' value.
;;
;; The following example illustrates an example AST for Org document:
;;
;; ---- Org document --------
;; * Heading with *bold* text
;; Paragraph.
;; ---- end -----------------
;;
;; (org-data (...) ; `org-data' node.
;;   (headline
;;     (
;;      ;; `:secondary' property lists property names that contain other
;;      ;; syntax tree nodes.
;;
;;      :secondary (:title)
;;
;;      ;; `:title' property is set to anonymous node containing:
;;      ;; `plain-text', `bold', `plain-text'.
;;
;;      :title ("Heading with " (bold (:post-blank 1 ...) "bold") "text"))
;;
;;      ;; `headline' contents
;;     (section (...)
;;       (paragraph
;;         ;; `:parent' property set to the containing section.
;;         (:parent (section ...))
;;         ;; paragraph contents is a `plain-text' node.
;;         "Paragraph1."))))
;;
;; Try calling M-: (org-element-parse-buffer) on the above example Org
;; document to explore a more complete version of Org AST.

;;; Code:

(require 'org-macs)
(require 'inline) ; load indentation rules

;;;; Syntax node type

(defun org-element-type (node &optional anonymous)
  "Return type of NODE.

The function returns the type of the node provided.
It can also return the following special value:
  `plain-text'       for a string
  nil                in any other case.

When optional argument ANONYMOUS is non-nil, return symbol `anonymous'
when NODE is an anonymous node."
  (declare (pure t))
  (cond
   ((stringp node) 'plain-text)
   ((null node) nil)
   ((not (consp node)) nil)
   ((symbolp (car node)) (car node))
   ((and anonymous (car node) (org-element-type (car node) t))
    'anonymous)
   (t nil)))

(define-inline org-element-type-p (node types)
  "Return non-nil when NODE type is one of TYPES.
TYPES can be a type symbol or a list of symbols."
  (if (inline-const-p types)
      (if (listp (inline-const-val types))
          (inline-quote (memq (org-element-type ,node t) ,types))
        (inline-quote (eq (org-element-type ,node t) ,types)))
    (inline-letevals (node types)
      (inline-quote
       (if (listp ,types)
           (memq (org-element-type ,node t) ,types)
         (eq (org-element-type ,node t) ,types))))))

(defun org-element-secondary-p (node)
  "Non-nil when NODE directly belongs to a secondary node.
Return value is the containing property name, as a keyword, or nil."
  (declare (pure t))
  (let* ((parent (org-element-property :parent node))
	 (properties (org-element-property :secondary parent))
         val)
    (catch 'exit
      (dolist (p properties)
        (setq val (org-element-property-raw p parent))
	(when (or (eq node val) (memq node val))
	  (throw 'exit p))))))

;;;; Deferred values

(cl-defstruct (org-element-deferred
               (:constructor nil)
               (:constructor org-element-deferred-create
                             ( auto-undefer-p function &rest arg-value
                               &aux (args arg-value)))
               (:constructor org-element-deferred-create-alias
                             ( keyword &optional auto-undefer-p
                               &aux
                               (function #'org-element-property-2)
                               (args (list keyword))))
               (:constructor org-element-deferred-create-list
                             ( args &optional auto-undefer-p
                               &aux
                               (function #'org-element--deferred-resolve-list)))
               (:type vector) :named)
  "Dynamically computed value.

The value can be obtained by calling FUNCTION with containing syntax
node as first argument and ARGS list as remainting arguments.

If the function throws `:org-element-deferred-retry' signal, assume
that the syntax node has been modified by side effect and retry
retrieving the value that was previously deferred.

AUTO-UNDEFER slot flags if the property value should be replaced upon
resolution.  Some functions may ignore this flag."
  function args auto-undefer-p)

(defsubst org-element--deferred-resolve-once (deferred-value &optional node)
  "Resolve DEFERRED-VALUE for NODE.
Throw `:org-element-deferred-retry' if NODE has been modified and we
need to re-read the value again."
  (apply (org-element-deferred-function deferred-value)
         node
         (org-element-deferred-args deferred-value)))

(defsubst org-element--deferred-resolve (value &optional node force-undefer)
  "Resolve VALUE for NODE recursively.
Return a cons cell of the resolved value and the value to store.
When no value should be stored, return `org-element-ast--nil' as cdr.
When FORCE-UNDEFER is non-nil, resolve all the deferred values, ignoring
their `auto-undefer-p' slot.

Throw `:org-element-deferred-retry' if NODE has been modified and we
need to re-read the value again."
  (let ((value-to-store 'org-element-ast--nil) undefer)
    (while (org-element-deferred-p value)
      (setq undefer (or force-undefer (org-element-deferred-auto-undefer-p value))
            value (org-element--deferred-resolve-once value node))
      (when undefer (setq value-to-store value)))
    (cons value value-to-store)))

(defsubst org-element--deferred-resolve-force (value &optional node)
  "Resolve VALUE for NODE recursively, ignoring `auto-undefer-p'.
Return the resolved value.

Throw `:org-element-deferred-retry' if NODE has been modified and we
need to re-read the value again."
  (car (org-element--deferred-resolve value node 'force)))

(defsubst org-element--deferred-resolve-list (node &rest list)
  "Unconditionally resolve all the deferred values in LIST for NODE.
Return a new list with all the values resolved.

Throw `:org-element-deferred-retry' if NODE has been modified and we
need to re-read the value again."
  (mapcar
   (lambda (value)
     (if (org-element-deferred-p value)
         (org-element--deferred-resolve-force value node)
       value))
   list))

;;;; Object properties

(eval-and-compile ; make available during inline expansion

  (defconst org-element--standard-properties
    '( :begin :post-affiliated :contents-begin :contents-end :end :post-blank
       :secondary :mode :granularity
       :cached :org-element--cache-sync-key
       :robust-begin :robust-end
       :true-level
       :buffer :deferred
       :structure :parent)
    "Standard properties stored in every syntax node structure.
These properties are stored in an array pre-allocated every time a new
object is created.  Two exceptions are `anonymous' and `plain-text'
node types.")

  (defconst org-element--standard-properties-idxs
    (let (plist)
      (seq-do-indexed
       (lambda (property idx)
         (setq plist (plist-put plist property idx)))
       org-element--standard-properties)
      plist)
    "Property list holding standard indexes for `org-element--standard-properties'."))

(define-inline org-element--property-idx (property)
  "Return standard property index or nil."
  (declare (pure t))
  (if (inline-const-p property)
      (plist-get
       org-element--standard-properties-idxs
       (inline-const-val property))
    (inline-quote (plist-get
                   org-element--standard-properties-idxs
                   ,property))))

(define-inline org-element--parray (node)
  "Return standard property array for NODE."
  (declare (pure t))
  (inline-letevals (node)
    (inline-quote
     (pcase (org-element-type ,node)
       (`nil nil)
       ;; Do not use property array for strings - they usually hold
       ;; `:parent' property and nothing more.
       (`plain-text nil)
       (_
        ;; (type (:standard-properties val ...) ...)
        (if (eq :standard-properties (car (nth 1 ,node)))
            (cadr (nth 1 ,node))
          ;; Non-standard order.  Go long way.
          (plist-get (nth 1 ,node) :standard-properties)))))))

(define-inline org-element--plist-property (property node &optional dflt)
  "Extract the value for PROPERTY from NODE's property list.
Ignore standard property array."
  (declare (pure t))
  (inline-letevals (property node dflt)
    (inline-quote
     (pcase (org-element-type ,node)
       (`nil ,dflt)
       (`plain-text
        (or (get-text-property 0 ,property ,node)
            (when ,dflt
              (if
                  ;; FIXME: Byte-compiler throws false positives in Emacs 27.
                  (with-no-warnings
                    (plist-member (text-properties-at 0 ,node) ,property))
                  nil ,dflt))))
       (_
        (or (plist-get (nth 1 ,node) ,property)
            (when ,dflt
              (if
                  ;; FIXME: Byte-compiler throws false positives in Emacs 27.
                  (with-no-warnings
                    (plist-member (nth 1 ,node) ,property))
                  nil ,dflt))))))))

(define-inline org-element-property-raw (property node &optional dflt)
  "Extract the value for PROPERTY of an NODE.
Do not resolve deferred values.
If PROPERTY is not present, return DFLT."
  (declare (pure t))
  (let ((idx (and (inline-const-p property)
                  (org-element--property-idx property))))
    (if idx
        (inline-letevals (node)
          (inline-quote
           (if-let ((parray (org-element--parray ,node)))
               (pcase (aref parray ,idx)
                 (`org-element-ast--nil ,dflt)
                 (val val))
             ;; No property array exists.  Fall back to `plist-get'.
             (org-element--plist-property ,property ,node ,dflt))))
      (inline-letevals (node property)
        (inline-quote
         (let ((idx (org-element--property-idx ,property)))
           (if-let ((parray (and idx (org-element--parray ,node))))
               (pcase (aref parray idx)
                 (`org-element-ast--nil ,dflt)
                 (val val))
             ;; No property array exists.  Fall back to `plist-get'.
             (org-element--plist-property ,property ,node ,dflt))))))))

(define-inline org-element--put-parray (node &optional parray)
  "Initialize standard property array in NODE.
Return the array or nil when NODE is `plain-text'."
  (inline-letevals (node parray)
    (inline-quote
     (let ((parray ,parray))
       (unless (or parray (memq (org-element-type ,node) '(plain-text nil)))
         (setq parray (make-vector ,(length org-element--standard-properties) nil))
         ;; Copy plist standard properties back to parray.
         (let ((stdplist org-element--standard-properties-idxs))
           (while stdplist
             (aset parray (cadr stdplist)
                   (org-element--plist-property (car stdplist) ,node))
             (setq stdplist (cddr stdplist))))
         (setcar (cdr ,node)
                 (nconc (list :standard-properties parray)
                        (cadr ,node)))
         parray)))))

(define-inline org-element-put-property (node property value)
  "In NODE, set PROPERTY to VALUE.
Return modified NODE."
  (let ((idx (and (inline-const-p property)
                  (org-element--property-idx property))))
    (if idx
        (inline-letevals (node value)
          (inline-quote
           (if (org-element-type-p ,node 'plain-text)
               ;; Special case: Do not use parray for plain-text.
               (org-add-props ,node nil ,property ,value)
             (let ((parray
                    (or (org-element--parray ,node)
                        (org-element--put-parray ,node))))
               (when parray (aset parray ,idx ,value))
               ,node))))
      (inline-letevals (node property value)
        (inline-quote
         (let ((idx (org-element--property-idx ,property)))
           (if (and idx (not (org-element-type-p ,node 'plain-text)))
               (when-let
                   ((parray
                     (or (org-element--parray ,node)
                         (org-element--put-parray ,node))))
                 (aset parray idx ,value))
             (pcase (org-element-type ,node)
               (`nil nil)
               (`plain-text
                (org-add-props ,node nil ,property ,value))
               (_
                ;; Note that `plist-put' adds new elements at the end,
                ;; thus keeping `:standard-properties' as the first element.
                (setcar (cdr ,node) (plist-put (nth 1 ,node) ,property ,value)))))
           ,node))))))

(define-inline org-element-put-property-2 (property value node)
  "Like `org-element-put-property', but NODE is the last argument.
See `org-element-put-property' for the meaning of PROPERTY and VALUE."
  (inline-quote (org-element-put-property ,node ,property ,value)))

(defun org-element--property (property node &optional dflt force-undefer)
  "Extract the value from the PROPERTY of a NODE.
Return DFLT when PROPERTY is not present.
When FORCE-UNDEFER is non-nil, unconditionally resolve deferred
properties, replacing their values in NODE."
  (let ((value (org-element-property-raw property node 'org-element-ast--nil)))
    ;; PROPERTY not present.
    (when (and (eq 'org-element-ast--nil value)
               (org-element-deferred-p
                (org-element-property-raw :deferred node)))
      ;; If :deferred has `org-element-deferred' type, resolve it for
      ;; side-effects, and re-assign the new value.
      (org-element--property :deferred node nil 'force-undefer)
      ;; Try to retrieve the value again.
      (setq value (org-element-property-raw property node dflt)))
    ;; Deferred property.  Resolve it recursively.
    (when (org-element-deferred-p value)
      (let ((retry t) (firstiter t))
        (while retry
          (if firstiter (setq firstiter nil) ; avoid extra call to `org-element-property-raw'.
            (setq value (org-element-property-raw property node 'org-element-ast--nil)))
          (catch :org-element-deferred-retry
            (pcase-let
                ((`(,resolved . ,value-to-store)
                  (org-element--deferred-resolve value node force-undefer)))
              (setq value resolved)
              ;; Store the resolved property value, if needed.
              (unless (eq value-to-store 'org-element-ast--nil)
                (org-element-put-property node property value-to-store)))
            ;; Finished resolving.
            (setq retry nil)))))
    ;; Return the resolved value.
    (if (eq value 'org-element-ast--nil) dflt value)))

(define-inline org-element-property (property node &optional dflt force-undefer)
  "Extract the value from the PROPERTY of a NODE.
Return DFLT when PROPERTY is not present.
When FORCE-UNDEFER is non-nil and the property value is computed
dynamically, unconditionally replace the dynamic deferred value,
modifying NODE by side effect.

Note: The properties listed in `org-element--standard-properties',
except `:deferred', may not be resolved."
  (if (and (inline-const-p property)
           (not (memq (inline-const-val property) '(:deferred :parent)))
           (org-element--property-idx (inline-const-val property)))
      ;; This is an important optimization, making common org-element
      ;; API calls much faster.
      (inline-quote (org-element-property-raw ,property ,node ,dflt))
    (inline-quote (org-element--property ,property ,node ,dflt ,force-undefer))))

(define-inline org-element-property-2 (node property &optional dflt force-undefer)
  "Like `org-element-property', but reverse the order of NODE and PROPERTY."
  (inline-quote (org-element-property ,property ,node ,dflt ,force-undefer)))

(defsubst org-element-parent (node)
  "Return `:parent' property of NODE."
  (org-element-property :parent node))

(gv-define-setter org-element-parent (value node)
  `(org-element-put-property ,node :parent ,value))

(gv-define-setter org-element-property (value property node &optional _)
  `(org-element-put-property ,node ,property ,value))

(gv-define-setter org-element-property-raw (value property node &optional _)
  `(org-element-put-property ,node ,property ,value))

(defun org-element--properties-mapc (fun node &optional collect no-standard)
  "Apply FUN for each property of NODE.
FUN will be called with three arguments: property name, property
value, and node.  If FUN accepts only 2 arguments, it will be called
with two arguments: property name and property value.  If FUN accepts
only a single argument, it will be called with a single argument -
property value.

Do not resolve deferred values, except `:deferred'.
`:standard-properties' internal property will be skipped.

When NO-STANDARD is non-nil, do no map over
`org-element--standard-properties'.

When COLLECT is symbol `set', set the property values to the return
values (except the values equal to `org-element-ast--nil') and finally
return nil.  When COLLECT is non-nil and not symbol `set', collect the
return values into a list and return it.
Otherwise, return nil."
  (let ( acc rtn (fun-arity (cdr (func-arity fun)))
         (type (org-element-type node)))
    (when type
      ;; Compute missing properties.
      (org-element-property :deferred node)
      ;; Map over parray.
      (unless no-standard
        (let ((standard-idxs
               org-element--standard-properties-idxs)
              (parray (org-element--parray node)))
          (when parray
            (while standard-idxs
              (setq
               rtn
               (pcase fun-arity
                 (1 (funcall fun (aref parray (cadr standard-idxs))))
                 (2 (funcall
                     fun
                     (car standard-idxs)
                     (aref parray (cadr standard-idxs))))
                 (_ (funcall
                     fun
                     (car standard-idxs)
                     (aref parray (cadr standard-idxs))
                     node))))
              (when collect
                (unless (eq rtn (aref parray (cadr standard-idxs)))
                  (if (and (eq collect 'set) (not (eq rtn 'org-element-ast--nil)))
                      (setf (aref parray (cadr standard-idxs)) rtn)
                    (push rtn acc))))
              (setq standard-idxs (cddr standard-idxs))))))
      ;; Map over plist.
      (let ((props
             (if (eq type 'plain-text)
                 (text-properties-at 0 node)
               (nth 1 node))))
        (while props
          (unless (eq :standard-properties (car props))
            (setq rtn
                  (pcase fun-arity
                    (1 (funcall fun (cadr props)))
                    (2 (funcall fun (car props) (cadr props)))
                    (_ (funcall fun (car props) (cadr props) node))))
            (when collect
              (if (and (eq collect 'set)
                       (not (eq rtn 'org-element-ast--nil)))
                  (unless (eq rtn (cadr props))
                    (if (eq type 'plain-text)
                        (org-add-props node nil (car props) rtn)
                      (setf (cadr props) rtn)))
                (push rtn acc))))
          (setq props (cddr props)))))
    ;; Return.
    (when collect (nreverse acc))))

(defun org-element--deferred-resolve-force-rec (property val node)
  "Resolve deferred PROPERTY VAL in NODE recursively.  Force undefer."
  (catch :found
    (catch :org-element-deferred-retry
      (throw :found (org-element--deferred-resolve-force val node)))
    ;; Caught `:org-element-deferred-retry'.  Go long way.
    (org-element-property property node nil t)))

(defun org-element--deferred-resolve-rec (property val node)
  "Resolve deferred PROPERTY VAL in NODE recursively.
Return the value to be stored."
  (catch :found
    (catch :org-element-deferred-retry
      (throw :found (cdr (org-element--deferred-resolve val node))))
    ;; Caught `:org-element-deferred-retry'.  Go long way.
    (org-element-property property node)))

(defsubst org-element-properties-resolve (node &optional force-undefer)
  "Resolve all the deferred properties in NODE, modifying the NODE.
When FORCE-UNDEFER is non-nil, resolve unconditionally.
Return the modified NODE."
  ;; Compute all the available properties.
  (org-element-property :deferred node nil force-undefer)
  (org-element--properties-mapc
   (if force-undefer
       #'org-element--deferred-resolve-force-rec
     #'org-element--deferred-resolve-rec)
   node 'set 'no-standard)
  node)

(defsubst org-element-properties-mapc (fun node &optional undefer)
  "Apply FUN for each property of NODE for side effect.
FUN will be called with three arguments: property name, property
value, and node.  If FUN accepts only 2 arguments, it will be called
with two arguments: property name and property value.  If FUN accepts
only a single argument, it will be called with a single argument -
property value.

When UNDEFER is non-nil, undefer deferred properties.
When UNDEFER is symbol `force', unconditionally replace the property
values with undeferred values.

Return nil."
  (when undefer
    (org-element-properties-resolve node (eq 'force undefer)))
  (org-element--properties-mapc fun node))

(defsubst org-element-properties-map (fun node &optional undefer)
  "Apply FUN for each property of NODE and return a list of the results.
FUN will be called with three arguments: property name, property
value, and node.  If FUN accepts only 2 arguments, it will be called
with two arguments: property name and property value.  If FUN accepts
only a single argument, it will be called with a single argument -
property value.

When UNDEFER is non-nil, undefer deferred properties unconditionally.
When UNDEFER is symbol `force', unconditionally replace the property
values with undeferred values."
  (when undefer
    (org-element-properties-resolve node (eq 'force undefer)))
  (org-element--properties-mapc fun node 'collect))

;;;; Node contents.

(defsubst org-element-contents (node)
  "Extract contents from NODE.
Do not resolve deferred values."
  (declare (pure t))
  (cond ((not (consp node)) nil)
	((symbolp (car node)) (nthcdr 2 node))
	(t node)))

(defsubst org-element-set-contents (node &rest contents)
  "Set NODE's contents to CONTENTS.
Return modified NODE.
If NODE cannot have contents, return CONTENTS."
  (pcase (org-element-type node t)
    (`plain-text contents)
    ((guard (null node)) contents)
    ;; Anonymous node.
    (`anonymous
     (setcar node (car contents))
     (setcdr node (cdr contents))
     node)
    ;; Node with type.
    (_ (setf (cddr node) contents)
       node)))

(defalias 'org-element-resolve-deferred #'org-element-properties-resolve)

;;;; Constructor and copier

(defun org-element-create (type &optional props &rest children)
  "Create a new syntax node of TYPE.
Optional argument PROPS, when non-nil, is a plist defining the
properties of the node.  CHILDREN can be elements, objects or
strings.

When CHILDREN is a single anonymous node, use its contents as children
nodes.  This way,
   (org-element-create \\='section nil (org-element-contents node))
will yield expected results with contents of another node adopted into
a newly created one.

When TYPE is `plain-text', CHILDREN must contain a single node -
string.  Alternatively, TYPE can be a string.  When TYPE is nil or
`anonymous', PROPS must be nil."
  (cl-assert
   ;; FIXME: Just use `plistp' from Emacs 29 when available.
   (let ((len (proper-list-p props)))
     (and len (zerop (% len 2)))))
  ;; Assign parray.
  (when (and props (not (stringp type)) (not (eq type 'plain-text)))
    (let ((node (list 'dummy props)))
      (org-element--put-parray node)
      (setq props (nth 1 node))
      ;; Remove standard properties from PROPS plist by side effect.
      (let ((ptail props))
        (while ptail
          (if (not (and (keywordp (car ptail))
                        (org-element--property-idx (car ptail))))
              (setq ptail (cddr ptail))
            (if (null (cddr ptail)) ; last property
                (setq props (nbutlast props 2)
                      ptail nil)
              (setcar ptail (nth 2 ptail))
              (setcdr ptail (seq-drop ptail 3))))))))
  (pcase type
    ((or `nil `anonymous)
     (cl-assert (null props))
     (apply #'org-element-adopt nil children))
    (`plain-text
     (cl-assert (= (length children) 1))
     (org-add-props (car children) props))
    ((pred stringp)
     (if props (org-add-props type props) type))
    (_
     (if (and (= 1 (length children))
              (org-element-type-p (car children) 'anonymous))
         (apply #'org-element-adopt (list type props) (car children))
       (apply #'org-element-adopt (list type props) children)))))

(defun org-element-copy (datum &optional keep-contents)
  "Return a copy of DATUM.
DATUM is an element, object, string or nil.  `:parent' property
is cleared and contents are removed in the process.
Secondary objects are also copied and their `:parent' is re-assigned.

When optional argument KEEP-CONTENTS is non-nil, do not remove the
contents.  Instead, copy the children recursively, updating their
`:parent' property.

As a special case, `anonymous' nodes do not have their contents
removed.  The contained children are copied recursively, updating
their `:parent' property to the copied `anonymous' node.

When DATUM is `plain-text', all the properties are removed."
  (pcase (org-element-type datum t)
    ((guard (null datum)) nil)
    (`plain-text (substring-no-properties datum))
    (`nil (error "Not an Org syntax node: %S" datum))
    (`anonymous
     (let* ((node-copy (copy-sequence datum))
            (tail node-copy))
       (while tail
         (setcar tail (org-element-copy (car tail) t))
         (org-element-put-property (car tail) :parent node-copy)
         (setq tail (cdr tail)))
       node-copy))
    (_
     (let ((node-copy (copy-sequence datum)))
       ;; Copy `:standard-properties'
       (when-let ((parray (org-element-property-raw :standard-properties node-copy)))
         (org-element-put-property node-copy :standard-properties (copy-sequence parray)))
       ;; Clear `:parent'.
       (org-element-put-property node-copy :parent nil)
       ;; We cannot simply return the copied property list.  When
       ;; DATUM is i.e. a headline, it's property list `:title' can
       ;; contain parsed objects.  The objects will contain
       ;; `:parent' property set to the DATUM itself.  When copied,
       ;; these inner `:parent' property values will contain
       ;; incorrect object decoupled from DATUM.  Changes to the
       ;; DATUM copy will no longer be reflected in the `:parent'
       ;; properties.  So, we need to reassign inner `:parent'
       ;; properties to the DATUM copy explicitly.
       (dolist (secondary-prop (org-element-property :secondary node-copy))
         (when-let ((secondary-value (org-element-property secondary-prop node-copy)))
           (setq secondary-value (org-element-copy secondary-value t))
           (if (org-element-type secondary-value)
               (org-element-put-property secondary-value :parent node-copy)
             (dolist (el secondary-value)
               (org-element-put-property el :parent node-copy)))
           (org-element-put-property node-copy secondary-prop secondary-value)))
       (when keep-contents
         (let ((contents (org-element-contents node-copy)))
           (while contents
             (setcar contents (org-element-copy (car contents) t))
             (setq contents (cdr contents)))))
       node-copy))))

;;;; AST queries

(defun org-element-ast-map
    ( data types fun
      &optional
      ignore first-match no-recursion
      with-properties no-secondary no-undefer)
  "Map a function on selected syntax nodes.

DATA is a syntax tree.  TYPES is a symbol or list of symbols of
node types.  FUN is the function called on the matching nodes.
It has to accept one argument: the node itself.

When TYPES is t, call FUN for all the node types.

FUN can also be a Lisp form.  The form will be evaluated as function
with symbol `node' bound to the current node.

When optional argument IGNORE is non-nil, it should be a list holding
nodes to be skipped.  In that case, the listed nodes and their
contents will be skipped.

When optional argument FIRST-MATCH is non-nil, stop at the first
match for which FUN doesn't return nil, and return that value.

Optional argument NO-RECURSION is a symbol or a list of symbols
representing node types.  `org-element-map' won't enter any recursive
element or object whose type belongs to that list.  Though, FUN can
still be applied on them.

When optional argument WITH-PROPERTIES is non-nil, it should hold a list
of property names.  These properties will be treated as additional
secondary properties.

When optional argument NO-SECONDARY is non-nil, do not recurse into
secondary strings.

When optional argument NO-UNDEFER is non-nil, do not resolve deferred
values.

FUN may also throw `:org-element-skip' signal.  Then,
`org-element-ast-map' will not recurse into the current node.

Nil values returned from FUN do not appear in the results."
  (declare (indent 2))
  ;; Ensure TYPES and NO-RECURSION are a list, even of one node.
  (when types
    (let* ((types (pcase types
                    ((pred listp) types)
                    (`t t)
                    (_ (list types))))
	   (no-recursion (if (listp no-recursion) no-recursion
			   (list no-recursion)))
           (fun (if (functionp fun) fun `(lambda (node) ,fun)))
	   --acc)
      (letrec ((--walk-tree
	        (lambda (--data)
		  ;; Recursively walk DATA.  INFO, if non-nil, is a plist
		  ;; holding contextual information.
		  (let ((--type (org-element-type --data t))
                        recurse)
		    (cond
		     ((not --data))
                     ((not --type))
		     ;; Ignored node in an export context.
		     ((and ignore (memq --data ignore)))
		     ;; List of elements or objects.
		     ((eq --type 'anonymous)
                      (mapc --walk-tree (org-element-contents --data)))
		     (t
		      ;; Check if TYPE is matching among TYPES.  If so,
		      ;; apply FUN to --DATA and accumulate return value
		      ;; into --ACC (or exit if FIRST-MATCH is non-nil).
                      (setq recurse t)
		      (when (or (eq types t) (memq --type types))
		        (let ((result
                               (catch :org-element-skip
                                 (setq recurse nil)
                                 (prog1 (funcall fun --data)
                                   (setq recurse t)))))
			  (cond ((not result))
			        (first-match (throw :--map-first-match result))
			        (t (push result --acc)))))
		      ;; Determine if a recursion into --DATA is possible.
		      (cond
                       ;; No recursion requested.
                       ((not recurse))
		       ;; --TYPE is explicitly removed from recursion.
		       ((memq --type no-recursion))
		       ;; In any other case, map secondary, affiliated, and contents.
		       (t
		        (when with-properties
		          (dolist (p with-properties)
                            (funcall
                             --walk-tree
                             (if no-undefer
                                 (org-element-property-raw p --data)
                               (org-element-property p --data)))))
                        (unless no-secondary
		          (dolist (p (org-element-property :secondary --data))
			    (funcall
                             --walk-tree
                             (if no-undefer
                                 (org-element-property-raw p --data)
                               (org-element-property p --data)))))
                        (mapc --walk-tree (org-element-contents --data))))))))))
        (catch :--map-first-match
	  (funcall --walk-tree data)
	  ;; Return value in a proper order.
	  (nreverse --acc))))))

(defun org-element-lineage (datum &optional types with-self)
  "List all ancestors of a given element or object.

DATUM is an object or element.

Return ancestors from the closest to the farthest.  When optional
argument TYPES is a symbol or a list of symbols, return the first
element or object in the lineage whose type equals or belongs to that
list instead.

When optional argument WITH-SELF is non-nil, lineage includes
DATUM itself as the first element, and TYPES, if provided, also
apply to it.

When DATUM is obtained through `org-element-context' or
`org-element-at-point', and org-element-cache is disabled, only
ancestors from its section can be found.  There is no such limitation
when DATUM belongs to a full parse tree."
  (when (and types (not (listp types))) (setq types (list types)))
  (let ((up (if with-self datum (org-element-parent datum)))
	ancestors)
    (while (and up (not (org-element-type-p up types)))
      (unless types (push up ancestors))
      (setq up (org-element-parent up)))
    (if types up (nreverse ancestors))))

(defun org-element-lineage-map (datum fun &optional types with-self first-match)
  "Map FUN across ancestors of DATUM, from closest to furthest.
Return a list of results.  Nil values returned from FUN do not appear
in the results.

DATUM is an object or element.

FUN is a function accepting a single argument: syntax node.
FUN can also be a Lisp form.  The form will be evaluated as function
with symbol `node' bound to the current node.

When optional argument TYPES is a list of symbols, only map across
nodes with the listed types.

When optional argument WITH-SELF is non-nil, lineage includes
DATUM itself as the first element, and TYPES, if provided, also
apply to it.

When optional argument FIRST-MATCH is non-nil, stop at the first
match for which FUN doesn't return nil, and return that value."
  (declare (indent 2))
  (setq fun (if (functionp fun) fun `(lambda (node) ,fun)))
  (let ((up (if with-self datum (org-element-parent datum)))
	acc rtn)
    (catch :--first-match
      (while up
        (when (or (not types) (org-element-type-p up types))
          (setq rtn (funcall fun up))
          (if (and first-match rtn)
              (throw :--first-match rtn)
            (when rtn (push rtn acc))))
        (setq up (org-element-parent up)))
      (nreverse acc))))

(defun org-element-property-inherited (property node &optional with-self accumulate literal-nil include-nil)
  "Extract non-nil value from the PROPERTY of a NODE and/or its parents.

PROPERTY is a single property or a list of properties to be considered.

When WITH-SELF is non-nil, consider PROPERTY in the NODE itself.
Otherwise, only start from the immediate parent.

When optional argument ACCUMULATE is nil, return the first non-nil value
\(properties when PROPERTY is a list are considered one by one).
When ACCUMULATE is non-nil, extract all the values, starting from the
outermost ancestor and accumulate them into a single list.  The values
that are lists are appended.

When LITERAL-NIL is non-nil, treat property values \"nil\" and nil.

When INCLUDE-NIL is non-nil, do not skip properties with value nil.  The
properties that are missing from the property list will still be
skipped."
  (unless (listp property) (setq property (list property)))
  (let (acc local val)
    (catch :found
      (unless with-self (setq node (org-element-parent node)))
      (while node
        (setq local nil)
        (dolist (prop property)
          (setq val (org-element-property prop node 'org-element-ast--nil))
          (unless (eq val 'org-element-ast--nil) ; not present
            (when literal-nil (setq val (org-not-nil val)))
            (when (and (not accumulate) (or val include-nil))
              (throw :found val))
            ;; Append to the end.
            (if (and include-nil (not val))
                (setq local (append local '(nil)))
              (setq local (append local (if (listp val) val (list val)))))))
        ;; Append parent to front.
        (setq acc (append local acc))
        (setq node (org-element-parent node)))
      acc)))

;;;; AST modification

(defalias 'org-element-adopt-elements #'org-element-adopt)
(defun org-element-adopt (parent &rest children)
  "Append CHILDREN to the contents of PARENT.

PARENT is a syntax node.  CHILDREN can be elements, objects, or
strings.

If PARENT is nil, create a new anonymous node containing CHILDREN.

The function takes care of setting `:parent' property for each child.
Return the modified PARENT."
  (declare (indent 1))
  (if (not children) parent
    ;; Link every child to PARENT. If PARENT is nil, it is a secondary
    ;; string: parent is the list itself.
    (dolist (child children)
      (when child
        (org-element-put-property child :parent (or parent children))))
    ;; Add CHILDREN at the end of PARENT contents.
    (when parent
      (apply #'org-element-set-contents
	     parent
	     (nconc (org-element-contents parent) children)))
    ;; Return modified PARENT element.
    (or parent children)))

(defalias 'org-element-extract-element #'org-element-extract)
(defun org-element-extract (node)
  "Extract NODE from parse tree.
Remove NODE from the parse tree by side-effect, and return it
with its `:parent' property stripped out."
  (let ((parent (org-element-parent node))
	(secondary (org-element-secondary-p node)))
    (if secondary
        (org-element-put-property
	 parent secondary
	 (delq node (org-element-property secondary parent)))
      (apply #'org-element-set-contents
	     parent
	     (delq node (org-element-contents parent))))
    ;; Return NODE with its :parent removed.
    (org-element-put-property node :parent nil)))

(defun org-element-insert-before (node location)
  "Insert NODE before LOCATION in parse tree.
LOCATION is an element, object or string within the parse tree.
Parse tree is modified by side effect."
  (let* ((parent (org-element-parent location))
	 (property (org-element-secondary-p location))
	 (siblings (if property (org-element-property property parent)
		     (org-element-contents parent)))
	 ;; Special case: LOCATION is the first element of an
	 ;; independent secondary string (e.g. :title property).  Add
	 ;; NODE in-place.
	 (specialp (and (not property)
			(eq siblings parent)
			(eq (car parent) location))))
    ;; Install NODE at the appropriate LOCATION within SIBLINGS.
    (cond (specialp)
	  ((or (null siblings) (eq (car siblings) location))
	   (push node siblings))
	  ((null location) (nconc siblings (list node)))
	  (t
	   (let ((index (cl-position location siblings)))
	     (unless index (error "No location found to insert node"))
	     (push node (cdr (nthcdr (1- index) siblings))))))
    ;; Store SIBLINGS at appropriate place in parse tree.
    (cond
     (specialp (setcdr parent (copy-sequence parent)) (setcar parent node))
     (property (org-element-put-property parent property siblings))
     (t (apply #'org-element-set-contents parent siblings)))
    ;; Set appropriate :parent property.
    (org-element-put-property node :parent parent)))

(defalias 'org-element-set-element #'org-element-set)
(defun org-element-set (old new &optional keep-props)
  "Replace element or object OLD with element or object NEW.
When KEEP-PROPS is non-nil, keep OLD values of the listed property
names.

Return the modified element.

The function takes care of setting `:parent' property for NEW."
  ;; Ensure OLD and NEW have the same parent.
  (org-element-put-property new :parent (org-element-property :parent old))
  ;; Handle KEEP-PROPS.
  (dolist (p keep-props)
    (org-element-put-property new p (org-element-property p old)))
  (let ((old-type (org-element-type old))
        (new-type (org-element-type new)))
    (if (or (eq old-type 'plain-text)
	    (eq new-type 'plain-text))
        ;; We cannot replace OLD with NEW since strings are not mutable.
        ;; We take the long path.
        (progn (org-element-insert-before new old)
	       (org-element-extract old))
      ;; Since OLD is going to be changed into NEW by side-effect, first
      ;; make sure that every element or object within NEW has OLD as
      ;; parent.
      (dolist (blob (org-element-contents new))
        (org-element-put-property blob :parent old))
      ;; Both OLD and NEW are lists.
      (setcar old (car new))
      (setcdr old (cdr new))))
  old)

(provide 'org-element-ast)
;;; org-element-ast.el ends here