/* GNU Emacs routines to deal with syntax tables; also word and list parsing. Copyright (C) 1985, 1987, 1993-1995, 1997-1999, 2001-2017 Free Software Foundation, Inc. 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 . */ #include #include "lisp.h" #include "character.h" #include "buffer.h" #include "regex.h" #include "syntax.h" #include "intervals.h" #include "category.h" /* Make syntax table lookup grant data in gl_state. */ #define SYNTAX(c) syntax_property (c, 1) #define SYNTAX_ENTRY(c) syntax_property_entry (c, 1) #define SYNTAX_WITH_FLAGS(c) syntax_property_with_flags (c, 1) /* Eight single-bit flags have the following meanings: 1. This character is the first of a two-character comment-start sequence. 2. This character is the second of a two-character comment-start sequence. 3. This character is the first of a two-character comment-end sequence. 4. This character is the second of a two-character comment-end sequence. 5. This character is a prefix, for backward-prefix-chars. 6. The char is part of a delimiter for comments of style "b". 7. This character is part of a nestable comment sequence. 8. The char is part of a delimiter for comments of style "c". Note that any two-character sequence whose first character has flag 1 and whose second character has flag 2 will be interpreted as a comment start. Bits 6 and 8 discriminate among different comment styles. Languages such as C++ allow two orthogonal syntax start/end pairs and bit 6 determines whether a comment-end or Scommentend ends style a or b. Comment markers can start style a, b, c, or bc. Style a is always the default. For 2-char comment markers, the style b flag is looked up only on the second char of the comment marker and on the first char of the comment ender. For style c (like the nested flag), the flag can be placed on any of the chars. */ /* These functions extract specific flags from an integer that holds the syntax code and the flags. */ static bool SYNTAX_FLAGS_COMSTART_FIRST (int flags) { return (flags >> 16) & 1; } static bool SYNTAX_FLAGS_COMSTART_SECOND (int flags) { return (flags >> 17) & 1; } static bool SYNTAX_FLAGS_COMEND_FIRST (int flags) { return (flags >> 18) & 1; } static bool SYNTAX_FLAGS_COMEND_SECOND (int flags) { return (flags >> 19) & 1; } static bool SYNTAX_FLAGS_COMSTARTEND_FIRST (int flags) { return (flags & 0x50000) != 0; } static bool SYNTAX_FLAGS_PREFIX (int flags) { return (flags >> 20) & 1; } static bool SYNTAX_FLAGS_COMMENT_STYLEB (int flags) { return (flags >> 21) & 1; } static bool SYNTAX_FLAGS_COMMENT_STYLEC (int flags) { return (flags >> 23) & 1; } static int SYNTAX_FLAGS_COMMENT_STYLEC2 (int flags) { return (flags >> 22) & 2; /* SYNTAX_FLAGS_COMMENT_STYLEC (flags) * 2 */ } static bool SYNTAX_FLAGS_COMMENT_NESTED (int flags) { return (flags >> 22) & 1; } /* FLAGS should be the flags of the main char of the comment marker, e.g. the second for comstart and the first for comend. */ static int SYNTAX_FLAGS_COMMENT_STYLE (int flags, int other_flags) { return (SYNTAX_FLAGS_COMMENT_STYLEB (flags) | SYNTAX_FLAGS_COMMENT_STYLEC2 (flags) | SYNTAX_FLAGS_COMMENT_STYLEC2 (other_flags)); } /* Extract a particular flag for a given character. */ static bool SYNTAX_COMEND_FIRST (int c) { return SYNTAX_FLAGS_COMEND_FIRST (SYNTAX_WITH_FLAGS (c)); } /* We use these constants in place for comment-style and string-ender-char to distinguish comments/strings started by comment_fence and string_fence codes. */ enum { ST_COMMENT_STYLE = 256 + 1, ST_STRING_STYLE = 256 + 2 }; /* This is the internal form of the parse state used in parse-partial-sexp. */ struct lisp_parse_state { EMACS_INT depth; /* Depth at end of parsing. */ int instring; /* -1 if not within string, else desired terminator. */ EMACS_INT incomment; /* -1 if in unnestable comment else comment nesting */ int comstyle; /* comment style a=0, or b=1, or ST_COMMENT_STYLE. */ bool quoted; /* True if just after an escape char at end of parsing. */ EMACS_INT mindepth; /* Minimum depth seen while scanning. */ /* Char number of most recent start-of-expression at current level */ ptrdiff_t thislevelstart; /* Char number of start of containing expression */ ptrdiff_t prevlevelstart; ptrdiff_t location; /* Char number at which parsing stopped. */ ptrdiff_t location_byte; /* Corresponding byte position. */ ptrdiff_t comstr_start; /* Position of last comment/string starter. */ Lisp_Object levelstarts; /* Char numbers of starts-of-expression of levels (starting from outermost). */ int prev_syntax; /* Syntax of previous position scanned, when that position (potentially) holds the first char of a 2-char construct, i.e. comment delimiter or Sescape, etc. Smax otherwise. */ }; /* These variables are a cache for finding the start of a defun. find_start_pos is the place for which the defun start was found. find_start_value is the defun start position found for it. find_start_value_byte is the corresponding byte position. find_start_buffer is the buffer it was found in. find_start_begv is the BEGV value when it was found. find_start_modiff is the value of MODIFF when it was found. */ static ptrdiff_t find_start_pos; static ptrdiff_t find_start_value; static ptrdiff_t find_start_value_byte; static struct buffer *find_start_buffer; static ptrdiff_t find_start_begv; static EMACS_INT find_start_modiff; static Lisp_Object skip_chars (bool, Lisp_Object, Lisp_Object, bool); static Lisp_Object skip_syntaxes (bool, Lisp_Object, Lisp_Object); static Lisp_Object scan_lists (EMACS_INT, EMACS_INT, EMACS_INT, bool); static void scan_sexps_forward (struct lisp_parse_state *, ptrdiff_t, ptrdiff_t, ptrdiff_t, EMACS_INT, bool, int); static void internalize_parse_state (Lisp_Object, struct lisp_parse_state *); static bool in_classes (int, Lisp_Object); static void parse_sexp_propertize (ptrdiff_t charpos); static void check_syntax_table (Lisp_Object obj); /* This setter is used only in this file, so it can be private. */ static void bset_syntax_table (struct buffer *b, Lisp_Object val) { b->syntax_table_ = val; } /* Whether the syntax of the character C has the prefix flag set. */ bool syntax_prefix_flag_p (int c) { return SYNTAX_FLAGS_PREFIX (SYNTAX_WITH_FLAGS (c)); } struct gl_state_s gl_state; /* Global state of syntax parser. */ enum { INTERVALS_AT_ONCE = 10 }; /* 1 + max-number of intervals to scan to property-change. */ /* Set the syntax entry VAL for char C in table TABLE. */ static void SET_RAW_SYNTAX_ENTRY (Lisp_Object table, int c, Lisp_Object val) { CHAR_TABLE_SET (table, c, val); } /* Set the syntax entry VAL for char-range RANGE in table TABLE. RANGE is a cons (FROM . TO) specifying the range of characters. */ static void SET_RAW_SYNTAX_ENTRY_RANGE (Lisp_Object table, Lisp_Object range, Lisp_Object val) { Fset_char_table_range (table, range, val); } /* Extract the information from the entry for character C in the current syntax table. */ static Lisp_Object SYNTAX_MATCH (int c) { Lisp_Object ent = SYNTAX_ENTRY (c); return CONSP (ent) ? XCDR (ent) : Qnil; } /* This should be called with FROM at the start of forward search, or after the last position of the backward search. It makes sure that the first char is picked up with correct table, so one does not need to call UPDATE_SYNTAX_TABLE immediately after the call. Sign of COUNT gives the direction of the search. */ static void SETUP_SYNTAX_TABLE (ptrdiff_t from, ptrdiff_t count) { SETUP_BUFFER_SYNTAX_TABLE (); gl_state.b_property = BEGV; gl_state.e_property = ZV + 1; gl_state.object = Qnil; gl_state.offset = 0; if (parse_sexp_lookup_properties) { if (count > 0) update_syntax_table_forward (from, true, Qnil); else if (from > BEGV) { update_syntax_table (from - 1, count, true, Qnil); parse_sexp_propertize (from - 1); } } } /* Same as above, but in OBJECT. If OBJECT is nil, use current buffer. If it is t (which is only used in fast_c_string_match_ignore_case), ignore properties altogether. This is meant for regex.c to use. For buffers, regex.c passes arguments to the UPDATE_SYNTAX_TABLE functions which are relative to BEGV. So if it is a buffer, we set the offset field to BEGV. */ void SETUP_SYNTAX_TABLE_FOR_OBJECT (Lisp_Object object, ptrdiff_t from, ptrdiff_t count) { SETUP_BUFFER_SYNTAX_TABLE (); gl_state.object = object; if (BUFFERP (gl_state.object)) { struct buffer *buf = XBUFFER (gl_state.object); gl_state.b_property = 1; gl_state.e_property = BUF_ZV (buf) - BUF_BEGV (buf) + 1; gl_state.offset = BUF_BEGV (buf) - 1; } else if (NILP (gl_state.object)) { gl_state.b_property = 1; gl_state.e_property = ZV - BEGV + 1; gl_state.offset = BEGV - 1; } else if (EQ (gl_state.object, Qt)) { gl_state.b_property = 0; gl_state.e_property = PTRDIFF_MAX; gl_state.offset = 0; } else { gl_state.b_property = 0; gl_state.e_property = 1 + SCHARS (gl_state.object); gl_state.offset = 0; } if (parse_sexp_lookup_properties) update_syntax_table (from + gl_state.offset - (count <= 0), count, 1, gl_state.object); } /* Update gl_state to an appropriate interval which contains CHARPOS. The sign of COUNT give the relative position of CHARPOS wrt the previously valid interval. If INIT, only [be]_property fields of gl_state are valid at start, the rest is filled basing on OBJECT. `gl_state.*_i' are the intervals, and CHARPOS is further in the search direction than the intervals - or in an interval. We update the current syntax-table basing on the property of this interval, and update the interval to start further than CHARPOS - or be NULL. We also update lim_property to be the next value of charpos to call this subroutine again - or be before/after the start/end of OBJECT. */ void update_syntax_table (ptrdiff_t charpos, EMACS_INT count, bool init, Lisp_Object object) { Lisp_Object tmp_table; int cnt = 0; bool invalidate = true; INTERVAL i; if (init) { gl_state.old_prop = Qnil; gl_state.start = gl_state.b_property; gl_state.stop = gl_state.e_property; i = interval_of (charpos, object); gl_state.backward_i = gl_state.forward_i = i; invalidate = false; if (!i) return; /* interval_of updates only ->position of the return value, so update the parents manually to speed up update_interval. */ while (!NULL_PARENT (i)) { if (AM_RIGHT_CHILD (i)) INTERVAL_PARENT (i)->position = i->position - LEFT_TOTAL_LENGTH (i) + TOTAL_LENGTH (i) /* right end */ - TOTAL_LENGTH (INTERVAL_PARENT (i)) + LEFT_TOTAL_LENGTH (INTERVAL_PARENT (i)); else INTERVAL_PARENT (i)->position = i->position - LEFT_TOTAL_LENGTH (i) + TOTAL_LENGTH (i); i = INTERVAL_PARENT (i); } i = gl_state.forward_i; gl_state.b_property = i->position - gl_state.offset; gl_state.e_property = INTERVAL_LAST_POS (i) - gl_state.offset; goto update; } i = count > 0 ? gl_state.forward_i : gl_state.backward_i; /* We are guaranteed to be called with CHARPOS either in i, or further off. */ if (!i) error ("Error in syntax_table logic for to-the-end intervals"); else if (charpos < i->position) /* Move left. */ { if (count > 0) error ("Error in syntax_table logic for intervals <-"); /* Update the interval. */ i = update_interval (i, charpos); if (INTERVAL_LAST_POS (i) != gl_state.b_property) { invalidate = false; gl_state.forward_i = i; gl_state.e_property = INTERVAL_LAST_POS (i) - gl_state.offset; } } else if (charpos >= INTERVAL_LAST_POS (i)) /* Move right. */ { if (count < 0) error ("Error in syntax_table logic for intervals ->"); /* Update the interval. */ i = update_interval (i, charpos); if (i->position != gl_state.e_property) { invalidate = false; gl_state.backward_i = i; gl_state.b_property = i->position - gl_state.offset; } } update: tmp_table = textget (i->plist, Qsyntax_table); if (invalidate) invalidate = !EQ (tmp_table, gl_state.old_prop); /* Need to invalidate? */ if (invalidate) /* Did not get to adjacent interval. */ { /* with the same table => */ /* invalidate the old range. */ if (count > 0) { gl_state.backward_i = i; gl_state.b_property = i->position - gl_state.offset; } else { gl_state.forward_i = i; gl_state.e_property = INTERVAL_LAST_POS (i) - gl_state.offset; } } if (!EQ (tmp_table, gl_state.old_prop)) { gl_state.current_syntax_table = tmp_table; gl_state.old_prop = tmp_table; if (EQ (Fsyntax_table_p (tmp_table), Qt)) { gl_state.use_global = 0; } else if (CONSP (tmp_table)) { gl_state.use_global = 1; gl_state.global_code = tmp_table; } else { gl_state.use_global = 0; gl_state.current_syntax_table = BVAR (current_buffer, syntax_table); } } while (i) { if (cnt && !EQ (tmp_table, textget (i->plist, Qsyntax_table))) { if (count > 0) { gl_state.e_property = i->position - gl_state.offset; gl_state.forward_i = i; } else { gl_state.b_property = i->position + LENGTH (i) - gl_state.offset; gl_state.backward_i = i; } return; } else if (cnt == INTERVALS_AT_ONCE) { if (count > 0) { gl_state.e_property = i->position + LENGTH (i) - gl_state.offset /* e_property at EOB is not set to ZV but to ZV+1, so that we can do INC(from);UPDATE_SYNTAX_TABLE_FORWARD without having to check eob between the two. */ + (next_interval (i) ? 0 : 1); gl_state.forward_i = i; } else { gl_state.b_property = i->position - gl_state.offset; gl_state.backward_i = i; } return; } cnt++; i = count > 0 ? next_interval (i) : previous_interval (i); } eassert (i == NULL); /* This property goes to the end. */ if (count > 0) { gl_state.e_property = gl_state.stop; gl_state.forward_i = i; } else gl_state.b_property = gl_state.start; } static void parse_sexp_propertize (ptrdiff_t charpos) { EMACS_INT zv = ZV; if (syntax_propertize__done <= charpos && syntax_propertize__done < zv) { EMACS_INT modiffs = CHARS_MODIFF; safe_call1 (Qinternal__syntax_propertize, make_number (min (zv, 1 + charpos))); if (modiffs != CHARS_MODIFF) error ("parse-sexp-propertize-function modified the buffer!"); if (syntax_propertize__done <= charpos && syntax_propertize__done < zv) error ("parse-sexp-propertize-function did not move" " syntax-propertize--done"); SETUP_SYNTAX_TABLE (charpos, 1); } else if (gl_state.e_property > syntax_propertize__done) { gl_state.e_property = syntax_propertize__done; gl_state.e_property_truncated = true; } else if (gl_state.e_property_truncated && gl_state.e_property < syntax_propertize__done) { /* When moving backward, e_property might be set without resetting e_property_truncated, so the e_property_truncated flag may occasionally be left raised spuriously. This should be rare. */ gl_state.e_property_truncated = false; update_syntax_table_forward (charpos, false, Qnil); } } void update_syntax_table_forward (ptrdiff_t charpos, bool init, Lisp_Object object) { if (gl_state.e_property_truncated) { eassert (NILP (object)); eassert (charpos >= gl_state.e_property); parse_sexp_propertize (charpos); } else { update_syntax_table (charpos, 1, init, object); if (NILP (object) && gl_state.e_property > syntax_propertize__done) parse_sexp_propertize (charpos); } } /* Returns true if char at CHARPOS is quoted. Global syntax-table data should be set up already to be good at CHARPOS or after. On return global syntax data is good for lookup at CHARPOS. */ static bool char_quoted (ptrdiff_t charpos, ptrdiff_t bytepos) { enum syntaxcode code; ptrdiff_t beg = BEGV; bool quoted = 0; ptrdiff_t orig = charpos; while (charpos > beg) { int c; DEC_BOTH (charpos, bytepos); UPDATE_SYNTAX_TABLE_BACKWARD (charpos); c = FETCH_CHAR_AS_MULTIBYTE (bytepos); code = SYNTAX (c); if (! (code == Scharquote || code == Sescape)) break; quoted = !quoted; } UPDATE_SYNTAX_TABLE (orig); return quoted; } /* Return the bytepos one character before BYTEPOS. We assume that BYTEPOS is not at the start of the buffer. */ static ptrdiff_t dec_bytepos (ptrdiff_t bytepos) { if (NILP (BVAR (current_buffer, enable_multibyte_characters))) return bytepos - 1; DEC_POS (bytepos); return bytepos; } /* Return the SYNTAX_COMEND_FIRST of the character before POS, POS_BYTE. */ static bool prev_char_comend_first (ptrdiff_t pos, ptrdiff_t pos_byte) { int c; bool val; DEC_BOTH (pos, pos_byte); UPDATE_SYNTAX_TABLE_BACKWARD (pos); c = FETCH_CHAR (pos_byte); val = SYNTAX_COMEND_FIRST (c); UPDATE_SYNTAX_TABLE_FORWARD (pos + 1); return val; } /* `literal-cache' text properties ------------------------------- These are applied to all text between BOB and `literal-cache-hwm' which is in literals. They record what type of literal the current character is in. On a buffer change (when `inhibit-modification-hooks' is nil), any buffer change (including changing text-properties) will reduce `literal-cache-hwm' to the change position, if it is higher. When `inhibit-modification-hooks' is non-nil, only changes to the `syntax-table' text property (possibly via a `category' text property) which affect the scanning of literals cause the setting of `literal-cache-hwm'. The `literal-cache' text property for a literal is applied on the text between just after its opening delimiter and just after its closing delimiter. The value of the `literal-cache' text property is a cons. For a string, its car is the symbol `string' and its cdr is the expected closing delimiter (or ST_STRING_STYLE in the case of a string fence string). For a comment, the car is -1 for a non-nestable comment, or the current nesting depth for a nestable comment. When not in a literal, no `literal-cache' text property exists at that place. These values match the internal values used in `scan_sexps_forward. */ DEFUN ("trim-literal-cache", Ftrim_literal_cache, Strim_literal_cache, 0, 1, 0, doc: /* Mark the selected buffer's "comment cache" as invalid from POS. By default, POS is the beginning of the buffer (position 1). If the cache is already invalid from an earlier position than POS, this function has no effect. The return value is the new bound. */) (Lisp_Object pos) { ptrdiff_t position, cache_limit; if (!NILP (pos)) { CHECK_NUMBER (pos); position = max (XINT (pos), 1); } else position = 1; cache_limit = XINT (BVAR (current_buffer, literal_cache_hwm)); BVAR (current_buffer, literal_cache_hwm) = make_number (min (cache_limit, position)); return BVAR (current_buffer, literal_cache_hwm); } /* Empty the literal-cache of every buffer whose syntax table is currently set to SYNTAB. */ void empty_syntax_tables_buffers_literal_caches (Lisp_Object syntab) { Lisp_Object buf, buf_list; Lisp_Object one = make_number (1); struct buffer *b; buf_list = Fbuffer_list (Qnil); while (!NILP (buf_list)) { buf = XCAR (buf_list); b = XBUFFER (buf); if (EQ (BVAR (b, syntax_table), syntab)) BVAR (b, literal_cache_hwm) = one; buf_list = XCDR (buf_list); } } #define LITERAL_MASK ((1 << Sstring) \ | (1 << Sescape) \ | (1 << Scharquote) \ | (1 << Scomment) \ | (1 << Sendcomment) \ | (1 << Scomment_fence) \ | (1 << Sstring_fence)) /* The following returns true if ELT (which will be a raw syntax descriptor (see page "Syntax Table Internals" in the Elisp manual) or nil) represents a syntax which is (potentially) relevant to strings or comments. */ INLINE bool SYNTAB_LITERAL (Lisp_Object elt) { int ielt; if (!CONSP (elt)) return false; ielt = XINT (XCAR (elt)); return (ielt & 0xF0000) /* a comment flag is set */ || ((1 << (ielt & 0xFF)) & LITERAL_MASK); /* One of Sstring, .... */ } static bool syntax_table_value_is_interesting_for_literals (Lisp_Object val) { ptrdiff_t syntax, code; if (!CONSP (val) || !INTEGERP (XCAR (val))) return false; return SYNTAB_LITERAL (XCAR (val)); } /* The text property PROP is having its value VAL at position POS in buffer BUF either set or cleared. If this value is relevant to the syntax of literals, reduce the BUF's value of literal_cache_hwm to POS. */ void check_literal_cache_hwm_for_prop (ptrdiff_t pos, Lisp_Object prop, Lisp_Object val, Lisp_Object buffer) { struct buffer *b; ptrdiff_t hwm; Lisp_Object plist; if (!BUFFERP (buffer)) return; b = XBUFFER (buffer); hwm = XINT (BVAR (b, literal_cache_hwm)); if (pos >= hwm) return; if (EQ (prop, Qcategory) && SYMBOLP (val)) { plist = Fsymbol_plist (val); while (CONSP (plist)) { prop = XCAR (plist); plist = XCDR (plist); if (!CONSP (plist)) return; val = XCAR (plist); if (EQ (prop, Qsyntax_table)) break; plist = XCDR (plist); } } if (EQ (prop, Qsyntax_table) && syntax_table_value_is_interesting_for_literals (val)) BVAR (b, literal_cache_hwm) = make_number (pos); } /* Scan forward over the innards of a containing comment, marking nested comments. FROM/FROM_BYTE, TO delimit the region to be marked. LITERAL_CACHE_VALUE is the value of the `literal-cache' property that was applied to the containing comment. */ static void scan_nested_comments_forward (ptrdiff_t from, ptrdiff_t from_byte, ptrdiff_t to, Lisp_Object literal_cache_value) { Lisp_Object tem; int comstyle = XINT (XCDR (literal_cache_value)); struct lisp_parse_state state; /* Increment the nesting depth. */ literal_cache_value = Fcons (make_number (XINT (XCAR (literal_cache_value)) + 1), XCDR (literal_cache_value)); /* Make sure our text property value is `eq' to other values which are `equal'. */ tem = Fmember (literal_cache_value, Vliteral_cache_values); if (CONSP (tem)) literal_cache_value = XCAR (tem); else Vliteral_cache_values = Fcons (literal_cache_value, Vliteral_cache_values); UPDATE_SYNTAX_TABLE_BACKWARD (from); internalize_parse_state (Qnil, &state); while (from < to) { scan_sexps_forward (&state, from, from_byte, to, TYPE_MINIMUM (EMACS_INT), false, -1); /* Stop after literal boundary. */ from = state.location; from_byte = state.location_byte; if (state.instring != -1) state.instring = -1; /* Ignore string delim we've passed. */ else if (state.incomment <= 0 || state.comstyle != comstyle) state.incomment = 0; /* Ignore a wrong type comment opener we've passed. */ else if (from < to) { /* We're at the start of the innards of a nested comment of the right type. We know the next scan will stop at the end of this comment. */ scan_sexps_forward (&state, from, from_byte, to, TYPE_MINIMUM (EMACS_INT), false, -1); Fput_text_property (make_number (from), make_number (state.location), Qliteral_cache, literal_cache_value, Qnil); scan_nested_comments_forward (from, from_byte, state.location, literal_cache_value); from = state.location; from_byte = state.location_byte; } } } /* Scan forward over all text between literal-cache-hwm and TO, marking literals (strings and comments) with the `literal-cache' text property. `literal-cache-hwm' is updated to TO. */ static void scan_comments_forward_to (ptrdiff_t to, ptrdiff_t to_byte) { ptrdiff_t count = SPECPDL_INDEX (); ptrdiff_t hwm, hwm_byte; struct lisp_parse_state state; ptrdiff_t orig_begv = BEGV, orig_begv_byte = BEGV_BYTE; ptrdiff_t tmp, tmp_byte; int c, syntax; enum syntaxcode code; Lisp_Object depth; Lisp_Object literal_cache_value; Lisp_Object tem; hwm = XINT (BVAR (current_buffer, literal_cache_hwm)); if (hwm < to) { record_unwind_protect (save_restriction_restore, save_restriction_save ()); BEGV = BEG; BEGV_BYTE = BEG_BYTE; hwm_byte = CHAR_TO_BYTE (hwm); /* We mustn't start scanning just after the first half of a double character comment starter or ender. */ if (hwm > BEG) { tmp = hwm; tmp_byte = hwm_byte; do { DEC_BOTH (tmp, tmp_byte); UPDATE_SYNTAX_TABLE_BACKWARD (tmp); c = FETCH_CHAR_AS_MULTIBYTE (tmp_byte); syntax = SYNTAX_WITH_FLAGS (c); code = SYNTAX (c); } while (tmp > BEG && (code == Sescape || (syntax & 0xF0000))); /* Flags `1', `2', `3', `4'. */ if (tmp > BEG) INC_BOTH (tmp, tmp_byte); hwm = tmp; hwm_byte = tmp_byte; } internalize_parse_state (Qnil, &state); if (hwm > BEG) /* Initialize STATE with the current value of the `literal-cache' text property. */ { depth = Fget_text_property (make_number (hwm - 1), Qliteral_cache, Qnil); if (CONSP (depth)) { if (EQ (Fcar (depth), Qstring)) { state.instring = XINT (Fcdr (depth)); state.incomment = 0; } else { state.instring = -1; state.incomment = XINT (Fcar (depth)); state.comstyle = XINT (Fcdr (depth)); } } } { /* Setup the buffer to write text properties discreetly. */ Lisp_Object modified = Fbuffer_modified_p (Qnil); ptrdiff_t count1 = SPECPDL_INDEX (); specbind (Qinhibit_modification_hooks, Qt); specbind (intern ("buffer-undo-list"), Qt); specbind (Qinhibit_read_only, Qt); specbind (Qdeactivate_mark, Qnil); if (NILP (modified)) record_unwind_protect ((void (*) (Lisp_Object))Frestore_buffer_modified_p, Qnil); while (hwm < to) { /* For each literal we scan, we apply the `literal-cache' property on its innards and closing delimiter. Calculate the value we will use first. */ literal_cache_value = (state.instring != -1) ? Fcons (Qstring, make_number (state.instring)) : (state.incomment ? Fcons (make_number (state.incomment), make_number (state.comstyle)) : Qnil); /* Ensure all `equal' values of literal-cache-value are also `eq'. */ if (!NILP (literal_cache_value)) { tem = Fmember (literal_cache_value, Vliteral_cache_values); if (CONSP (tem)) literal_cache_value = XCAR (tem); else Vliteral_cache_values = Fcons (literal_cache_value, Vliteral_cache_values); } scan_sexps_forward (&state, hwm, hwm_byte, to, TYPE_MINIMUM (EMACS_INT), false, -1); /* stop after literal boundary */ if (!NILP (literal_cache_value)) Fput_text_property (make_number (hwm), make_number (state.location), Qliteral_cache, literal_cache_value, Qnil); else Fremove_list_of_text_properties (make_number (hwm), make_number (state.location), Fcons (Qliteral_cache, Qnil), Qnil); if (!NILP (literal_cache_value) && NUMBERP (XCAR (literal_cache_value)) && XINT (XCAR (literal_cache_value)) > 0) scan_nested_comments_forward (hwm, hwm_byte, state.location, literal_cache_value); hwm = state.location; hwm_byte = state.location_byte; } unbind_to (count1, Qnil); if (NILP (modified)) /* Frestore_buffer_modified_p overwrites gl_state, hence: */ SETUP_SYNTAX_TABLE (to, -1); } BVAR (current_buffer, literal_cache_hwm) = make_number (hwm); unbind_to (count, Qnil); } } /* Check whether charpos FROM is at the end of a comment. FROM_BYTE is the bytepos corresponding to FROM. Do not move back before STOP. Return true if we find a comment ending at FROM/FROM_BYTE. If successful, store the charpos of the comment's beginning into *CHARPOS_PTR, and the bytepos into *BYTEPOS_PTR. Global syntax data remains valid for backward search starting at the returned value (or at FROM, if the search was not successful). */ static bool back_comment (ptrdiff_t from, ptrdiff_t from_byte, ptrdiff_t stop, bool comnested, int comstyle, ptrdiff_t *charpos_ptr, ptrdiff_t *bytepos_ptr) { Lisp_Object depth; ptrdiff_t literal_cache, target_depth, comment_style; Lisp_Object temp; int c; int syntax, code; scan_comments_forward_to (from, from_byte); if (from <= stop) return false; depth = Fget_text_property (make_number (from - 1), Qliteral_cache, Qnil); if (!CONSP (depth) /* nil, not in a literal. */ || !INTEGERP (XCAR (depth))) /* A string. */ return false; literal_cache = XINT (XCAR (depth)); comment_style = XINT (XCDR (depth)); if (comment_style != comstyle) /* Wrong sort of comment. This can happen with "*|" at the end of a "||" line comment. */ return false; /* literal_cache: -1 is a non-nested comment, otherwise it's the depth of nesting of nested comments. */ target_depth = literal_cache < 0 ? 0 : literal_cache - 1; do { temp = Fprevious_single_property_change (make_number (from), Qliteral_cache, Qnil, Qnil); if (NILP (temp)) return false; from = XINT (temp); } while (from > stop && (depth = Fget_text_property (make_number (from - 1), Qliteral_cache, Qnil), !NILP (depth)) && XINT (XCAR (depth)) > target_depth); if (from <= stop) return false; from_byte = CHAR_TO_BYTE (from); /* Having passed back over the body of the comment, we should now find a comment opener. */ DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); syntax = SYNTAX_WITH_FLAGS (c); code = SYNTAX (c); if (code != Scomment && code != Scomment_fence) { if (from <= stop) return false; if (!SYNTAX_FLAGS_COMSTART_SECOND (syntax)) return false; DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); syntax = SYNTAX_WITH_FLAGS (c); if (!SYNTAX_FLAGS_COMSTART_FIRST (syntax)) return false; } *charpos_ptr = from; *bytepos_ptr = from_byte; return true; } /* If the two syntax entries OLD_SYN and NEW_SYN would parse strings or comments differently return true, otherwise return nil. */ INLINE bool literally_different (Lisp_Object old_syn, Lisp_Object new_syn) { bool old_literality = SYNTAB_LITERAL (old_syn), new_literality = SYNTAB_LITERAL (new_syn); return (old_literality != new_literality) || (old_literality && (!EQ (XCAR (old_syn), XCAR (new_syn)))); } /* If there is a character position in the range [START, END] for whose syntaxes in syntax tables OLD and NEW strings or comments might be parsed differently, return the lowest character for which this holds. Otherwise, return -1. */ int syntax_table_ranges_differ_literally_p (Lisp_Object old, Lisp_Object new, int start, int end) { int old_from, new_from, old_to, new_to; Lisp_Object old_syn, new_syn; bool old_literality, new_literality; new_from = old_from = start; new_to = old_to = -1; while ((old_from < end) && (new_from < end)) { if (old_from == new_from) { old_syn = char_table_ref_and_range_with_parents (old, old_from, &old_from, &old_to); new_syn = char_table_ref_and_range_with_parents (new, new_from, &new_from, &new_to); if (literally_different (old_syn, new_syn)) return old_from; old_from = old_to + 1; new_from = new_to + 1; old_to = -1; new_to = -1; } else if (old_from < new_from) { old_syn = char_table_ref_and_range_with_parents (old, old_from, &old_from, &old_to); if (literally_different (old_syn, new_syn)) return old_from; old_from = old_to + 1; old_to = -1; } else { new_syn = char_table_ref_and_range_with_parents (new, new_from, &new_from, &new_to); if (literally_different (old_syn, new_syn)) return new_from; new_from = new_to + 1; new_to = -1; } } return -1; } DEFUN ("least-literal-difference-between-syntax-tables", Fleast_literal_difference_between_syntax_tables, Sleast_literal_difference_between_syntax_tables, 2, 2, 0, doc: /* Lowest char whose different syntaxes in OLD and NEW parse literals differently. OLD and NEW are syntax tables. */) (Lisp_Object old, Lisp_Object new) { int c; check_syntax_table (old); check_syntax_table (new); c = syntax_table_ranges_differ_literally_p (old, new, 0, MAX_CHAR + 1); if (c >= 0) return make_number (c); return Qnil; } DEFUN ("syntax-tables-literally-different-p", Fsyntax_tables_literally_different_p, Ssyntax_tables_literally_different_p, 2, 2, 0, doc: /* Will syntax tables OLD and NEW parse literals differently? Return t when OLD and NEW might parse comments and strings differently, otherwise nil. (Use `least-literal-difference-between-syntax-tables' to locate a character position where the tables differ.) */) (Lisp_Object old, Lisp_Object new) { Lisp_Object extra; check_syntax_table (old); check_syntax_table (new); /* Check to see if there is a cached relationship between the tables. */ if (Fmemq (new, XCHAR_TABLE (old)->extras[0])) return Qnil; if (Fmemq (new, XCHAR_TABLE (old)->extras[1])) return Qt; /* the two tables have no known relationship, so we'll have laboriously to compare them. */ if (syntax_table_ranges_differ_literally_p (old, new, 0, MAX_CHAR + 1) >= 0) { /* mark the "literally different" relationship between the OLD and NEW syntax tables. */ extra = Fcons (new, XCHAR_TABLE (old)->extras[1]); XCHAR_TABLE (old)->extras[1] = extra; extra = Fcons (old, XCHAR_TABLE (new)->extras[1]); XCHAR_TABLE (new)->extras[1] = extra; return Qt; } else { /* mark the "not literally different" relationship between the OLD and NEW syntax tables. */ extra = Fcons (new, XCHAR_TABLE (old)->extras[0]); XCHAR_TABLE (old)->extras[0] = extra; extra = Fcons (old, XCHAR_TABLE (new)->extras[0]); XCHAR_TABLE (new)->extras[0] = extra; return Qnil; } } /* If any character in the range [START, END) has an entry in syntax table SYNTAB which is relevant to literal parsing, return true, else return false. */ bool syntax_table_value_range_is_interesting_for_literals (Lisp_Object syntab, int start, int end) { int from, to; Lisp_Object syn; from = start; to = end; while (from < to) { syn = char_table_ref_and_range_with_parents (syntab, from, &from, &to); if (SYNTAB_LITERAL (syn)) return true; from = to + 1; to = end; } return false; } /* In the syntax table SYNTAB, in the 0th and 1st extra slots are lists of other syntax tables which are known to be "literally the same" and "literally different" respectively. Those other tables will each contain SYNTAB in their extra slots. Remove all these syntax tables from all these extra slots; this will leave both of the slots on SYNTAB nil. */ void break_off_syntax_tables_literal_relations (Lisp_Object syntab) { struct Lisp_Char_Table *c = XCHAR_TABLE (syntab); Lisp_Object remote_tab; struct Lisp_Char_Table *r; Lisp_Object syntab_extra, remote_extra; syntab_extra = c->extras[0]; while (!NILP (syntab_extra)) { remote_tab = XCAR (syntab_extra); r = XCHAR_TABLE (remote_tab); remote_extra = r->extras[0]; r->extras[0] = Fdelq (syntab, remote_extra); syntab_extra = XCDR (syntab_extra); } c->extras[0] = Qnil; syntab_extra = c->extras[1]; while (!NILP (syntab_extra)) { remote_tab = XCAR (syntab_extra); r = XCHAR_TABLE (remote_tab); remote_extra = r->extras[1]; r->extras[1] = Fdelq (syntab, remote_extra); syntab_extra = XCDR (syntab_extra); } c->extras[1] = Qnil; } DEFUN ("syntax-table-p", Fsyntax_table_p, Ssyntax_table_p, 1, 1, 0, doc: /* Return t if OBJECT is a syntax table. Currently, any char-table counts as a syntax table. */) (Lisp_Object object) { if (CHAR_TABLE_P (object) && EQ (XCHAR_TABLE (object)->purpose, Qsyntax_table)) return Qt; return Qnil; } static void check_syntax_table (Lisp_Object obj) { CHECK_TYPE (CHAR_TABLE_P (obj) && EQ (XCHAR_TABLE (obj)->purpose, Qsyntax_table), Qsyntax_table_p, obj); } DEFUN ("syntax-table", Fsyntax_table, Ssyntax_table, 0, 0, 0, doc: /* Return the current syntax table. This is the one specified by the current buffer. */) (void) { return BVAR (current_buffer, syntax_table); } DEFUN ("standard-syntax-table", Fstandard_syntax_table, Sstandard_syntax_table, 0, 0, 0, doc: /* Return the standard syntax table. This is the one used for new buffers. */) (void) { return Vstandard_syntax_table; } DEFUN ("copy-syntax-table", Fcopy_syntax_table, Scopy_syntax_table, 0, 1, 0, doc: /* Construct a new syntax table and return it. It is a copy of the TABLE, which defaults to the standard syntax table. */) (Lisp_Object table) { Lisp_Object copy; if (!NILP (table)) check_syntax_table (table); else table = Vstandard_syntax_table; copy = Fcopy_sequence (table); /* Only the standard syntax table should have a default element. Other syntax tables should inherit from parents instead. */ set_char_table_defalt (copy, Qnil); /* Copied syntax tables should all have parents. If we copied one with no parent, such as the standard syntax table, use the standard syntax table as the copy's parent. */ if (NILP (XCHAR_TABLE (copy)->parent)) Fset_char_table_parent (copy, Vstandard_syntax_table); return copy; } DEFUN ("set-syntax-table", Fset_syntax_table, Sset_syntax_table, 1, 1, 0, doc: /* Select a new syntax table for the current buffer. One argument, a syntax table. */) (Lisp_Object table) { int idx; check_syntax_table (table); if (Fsyntax_table_p (BVAR (current_buffer, syntax_table)) && !NILP (Fsyntax_tables_literally_different_p (BVAR (current_buffer, syntax_table), table))) Ftrim_literal_cache (Qnil); bset_syntax_table (current_buffer, table); /* Indicate that this buffer now has a specified syntax table. */ idx = PER_BUFFER_VAR_IDX (syntax_table); SET_PER_BUFFER_VALUE_P (current_buffer, idx, 1); return table; } /* Convert a letter which signifies a syntax code into the code it signifies. This is used by modify-syntax-entry, and other things. */ unsigned char const syntax_spec_code[0400] = { 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, Swhitespace, Scomment_fence, Sstring, 0377, Smath, 0377, 0377, Squote, Sopen, Sclose, 0377, 0377, 0377, Swhitespace, Spunct, Scharquote, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, Scomment, 0377, Sendcomment, 0377, Sinherit, 0377, 0377, 0377, 0377, 0377, 0377, 0377, /* @, A ... */ 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, Sword, 0377, 0377, 0377, 0377, Sescape, 0377, 0377, Ssymbol, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, /* `, a, ... */ 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, 0377, Sword, 0377, 0377, 0377, 0377, Sstring_fence, 0377, 0377, 0377 }; /* Indexed by syntax code, give the letter that describes it. */ char const syntax_code_spec[16] = { ' ', '.', 'w', '_', '(', ')', '\'', '\"', '$', '\\', '/', '<', '>', '@', '!', '|' }; /* Indexed by syntax code, give the object (cons of syntax code and nil) to be stored in syntax table. Since these objects can be shared among syntax tables, we generate them in advance. By sharing objects, the function `describe-syntax' can give a more compact listing. */ static Lisp_Object Vsyntax_code_object; DEFUN ("char-syntax", Fchar_syntax, Schar_syntax, 1, 1, 0, doc: /* Return the syntax code of CHARACTER, described by a character. For example, if CHARACTER is a word constituent, the character `w' (119) is returned. The characters that correspond to various syntax codes are listed in the documentation of `modify-syntax-entry'. */) (Lisp_Object character) { int char_int; CHECK_CHARACTER (character); char_int = XINT (character); SETUP_BUFFER_SYNTAX_TABLE (); return make_number (syntax_code_spec[SYNTAX (char_int)]); } DEFUN ("matching-paren", Fmatching_paren, Smatching_paren, 1, 1, 0, doc: /* Return the matching parenthesis of CHARACTER, or nil if none. */) (Lisp_Object character) { int char_int; enum syntaxcode code; CHECK_CHARACTER (character); char_int = XINT (character); SETUP_BUFFER_SYNTAX_TABLE (); code = SYNTAX (char_int); if (code == Sopen || code == Sclose) return SYNTAX_MATCH (char_int); return Qnil; } DEFUN ("string-to-syntax", Fstring_to_syntax, Sstring_to_syntax, 1, 1, 0, doc: /* Convert a syntax descriptor STRING into a raw syntax descriptor. STRING should be a string of the form allowed as argument of `modify-syntax-entry'. The return value is a raw syntax descriptor: a cons cell (CODE . MATCHING-CHAR) which can be used, for example, as the value of a `syntax-table' text property. */) (Lisp_Object string) { const unsigned char *p; int val; Lisp_Object match; CHECK_STRING (string); p = SDATA (string); val = syntax_spec_code[*p++]; if (val == 0377) error ("Invalid syntax description letter: %c", p[-1]); if (val == Sinherit) return Qnil; if (*p) { int len; int character = STRING_CHAR_AND_LENGTH (p, len); XSETINT (match, character); if (XFASTINT (match) == ' ') match = Qnil; p += len; } else match = Qnil; while (*p) switch (*p++) { case '1': val |= 1 << 16; break; case '2': val |= 1 << 17; break; case '3': val |= 1 << 18; break; case '4': val |= 1 << 19; break; case 'p': val |= 1 << 20; break; case 'b': val |= 1 << 21; break; case 'n': val |= 1 << 22; break; case 'c': val |= 1 << 23; break; } if (val < ASIZE (Vsyntax_code_object) && NILP (match)) return AREF (Vsyntax_code_object, val); else /* Since we can't use a shared object, let's make a new one. */ return Fcons (make_number (val), match); } /* I really don't know why this is interactive help-form should at least be made useful whilst reading the second arg. */ DEFUN ("modify-syntax-entry", Fmodify_syntax_entry, Smodify_syntax_entry, 2, 3, "cSet syntax for character: \nsSet syntax for %s to: ", doc: /* Set syntax for character CHAR according to string NEWENTRY. The syntax is changed only for table SYNTAX-TABLE, which defaults to the current buffer's syntax table. CHAR may be a cons (MIN . MAX), in which case, syntaxes of all characters in the range MIN to MAX are changed. The first character of NEWENTRY should be one of the following: Space or - whitespace syntax. w word constituent. _ symbol constituent. . punctuation. ( open-parenthesis. ) close-parenthesis. " string quote. \\ escape. $ paired delimiter. \\=' expression quote or prefix operator. < comment starter. > comment ender. / character-quote. @ inherit from parent table. | generic string fence. ! generic comment fence. Only single-character comment start and end sequences are represented thus. Two-character sequences are represented as described below. The second character of NEWENTRY is the matching parenthesis, used only if the first character is `(' or `)'. Any additional characters are flags. Defined flags are the characters 1, 2, 3, 4, b, p, and n. 1 means CHAR is the start of a two-char comment start sequence. 2 means CHAR is the second character of such a sequence. 3 means CHAR is the start of a two-char comment end sequence. 4 means CHAR is the second character of such a sequence. There can be several orthogonal comment sequences. This is to support language modes such as C++. By default, all comment sequences are of style a, but you can set the comment sequence style to b (on the second character of a comment-start, and the first character of a comment-end sequence) and/or c (on any of its chars) using this flag: b means CHAR is part of comment sequence b. c means CHAR is part of comment sequence c. n means CHAR is part of a nestable comment sequence. p means CHAR is a prefix character for `backward-prefix-chars'; such characters are treated as whitespace when they occur between expressions. usage: (modify-syntax-entry CHAR NEWENTRY &optional SYNTAX-TABLE) */) (Lisp_Object c, Lisp_Object newentry, Lisp_Object syntax_table) { if (CONSP (c)) { CHECK_CHARACTER_CAR (c); CHECK_CHARACTER_CDR (c); } else CHECK_CHARACTER (c); if (NILP (syntax_table)) syntax_table = BVAR (current_buffer, syntax_table); else check_syntax_table (syntax_table); newentry = Fstring_to_syntax (newentry); if (SYNTAB_LITERAL (newentry) || (CONSP (c) ? syntax_table_value_range_is_interesting_for_literals (syntax_table, XINT (XCAR(c)), XINT (XCDR (c))) : (SYNTAB_LITERAL (c)))) { empty_syntax_tables_buffers_literal_caches (syntax_table); break_off_syntax_tables_literal_relations (syntax_table); } if (CONSP (c)) SET_RAW_SYNTAX_ENTRY_RANGE (syntax_table, c, newentry); else SET_RAW_SYNTAX_ENTRY (syntax_table, XINT (c), newentry); /* We clear the regexp cache, since character classes can now have different values from those in the compiled regexps.*/ clear_regexp_cache (); return Qnil; } /* Dump syntax table to buffer in human-readable format */ DEFUN ("internal-describe-syntax-value", Finternal_describe_syntax_value, Sinternal_describe_syntax_value, 1, 1, 0, doc: /* Insert a description of the internal syntax description SYNTAX at point. */) (Lisp_Object syntax) { int code, syntax_code; bool start1, start2, end1, end2, prefix, comstyleb, comstylec, comnested; char str[2]; Lisp_Object first, match_lisp, value = syntax; if (NILP (value)) { insert_string ("default"); return syntax; } if (CHAR_TABLE_P (value)) { insert_string ("deeper char-table ..."); return syntax; } if (!CONSP (value)) { insert_string ("invalid"); return syntax; } first = XCAR (value); match_lisp = XCDR (value); if (!INTEGERP (first) || !(NILP (match_lisp) || CHARACTERP (match_lisp))) { insert_string ("invalid"); return syntax; } syntax_code = XINT (first) & INT_MAX; code = syntax_code & 0377; start1 = SYNTAX_FLAGS_COMSTART_FIRST (syntax_code); start2 = SYNTAX_FLAGS_COMSTART_SECOND (syntax_code); end1 = SYNTAX_FLAGS_COMEND_FIRST (syntax_code); end2 = SYNTAX_FLAGS_COMEND_SECOND (syntax_code); prefix = SYNTAX_FLAGS_PREFIX (syntax_code); comstyleb = SYNTAX_FLAGS_COMMENT_STYLEB (syntax_code); comstylec = SYNTAX_FLAGS_COMMENT_STYLEC (syntax_code); comnested = SYNTAX_FLAGS_COMMENT_NESTED (syntax_code); if (Smax <= code) { insert_string ("invalid"); return syntax; } str[0] = syntax_code_spec[code], str[1] = 0; insert (str, 1); if (NILP (match_lisp)) insert (" ", 1); else insert_char (XINT (match_lisp)); if (start1) insert ("1", 1); if (start2) insert ("2", 1); if (end1) insert ("3", 1); if (end2) insert ("4", 1); if (prefix) insert ("p", 1); if (comstyleb) insert ("b", 1); if (comstylec) insert ("c", 1); if (comnested) insert ("n", 1); insert_string ("\twhich means: "); switch (code) { case Swhitespace: insert_string ("whitespace"); break; case Spunct: insert_string ("punctuation"); break; case Sword: insert_string ("word"); break; case Ssymbol: insert_string ("symbol"); break; case Sopen: insert_string ("open"); break; case Sclose: insert_string ("close"); break; case Squote: insert_string ("prefix"); break; case Sstring: insert_string ("string"); break; case Smath: insert_string ("math"); break; case Sescape: insert_string ("escape"); break; case Scharquote: insert_string ("charquote"); break; case Scomment: insert_string ("comment"); break; case Sendcomment: insert_string ("endcomment"); break; case Sinherit: insert_string ("inherit"); break; case Scomment_fence: insert_string ("comment fence"); break; case Sstring_fence: insert_string ("string fence"); break; default: insert_string ("invalid"); return syntax; } if (!NILP (match_lisp)) { insert_string (", matches "); insert_char (XINT (match_lisp)); } if (start1) insert_string (",\n\t is the first character of a comment-start sequence"); if (start2) insert_string (",\n\t is the second character of a comment-start sequence"); if (end1) insert_string (",\n\t is the first character of a comment-end sequence"); if (end2) insert_string (",\n\t is the second character of a comment-end sequence"); if (comstyleb) insert_string (" (comment style b)"); if (comstylec) insert_string (" (comment style c)"); if (comnested) insert_string (" (nestable)"); if (prefix) { AUTO_STRING (prefixdoc, ",\n\t is a prefix character for `backward-prefix-chars'"); insert1 (Fsubstitute_command_keys (prefixdoc)); } return syntax; } /* Return the position across COUNT words from FROM. If that many words cannot be found before the end of the buffer, return 0. COUNT negative means scan backward and stop at word beginning. */ ptrdiff_t scan_words (ptrdiff_t from, EMACS_INT count) { ptrdiff_t beg = BEGV; ptrdiff_t end = ZV; ptrdiff_t from_byte = CHAR_TO_BYTE (from); enum syntaxcode code; int ch0, ch1; Lisp_Object func, pos; SETUP_SYNTAX_TABLE (from, count); while (count > 0) { while (true) { if (from == end) return 0; UPDATE_SYNTAX_TABLE_FORWARD (from); ch0 = FETCH_CHAR_AS_MULTIBYTE (from_byte); code = SYNTAX (ch0); INC_BOTH (from, from_byte); if (words_include_escapes && (code == Sescape || code == Scharquote)) break; if (code == Sword) break; rarely_quit (from); } /* Now CH0 is a character which begins a word and FROM is the position of the next character. */ func = CHAR_TABLE_REF (Vfind_word_boundary_function_table, ch0); if (! NILP (Ffboundp (func))) { pos = call2 (func, make_number (from - 1), make_number (end)); if (INTEGERP (pos) && from < XINT (pos) && XINT (pos) <= ZV) { from = XINT (pos); from_byte = CHAR_TO_BYTE (from); } } else { while (1) { if (from == end) break; UPDATE_SYNTAX_TABLE_FORWARD (from); ch1 = FETCH_CHAR_AS_MULTIBYTE (from_byte); code = SYNTAX (ch1); if ((code != Sword && (! words_include_escapes || (code != Sescape && code != Scharquote))) || word_boundary_p (ch0, ch1)) break; INC_BOTH (from, from_byte); ch0 = ch1; rarely_quit (from); } } count--; } while (count < 0) { while (true) { if (from == beg) return 0; DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); ch1 = FETCH_CHAR_AS_MULTIBYTE (from_byte); code = SYNTAX (ch1); if (words_include_escapes && (code == Sescape || code == Scharquote)) break; if (code == Sword) break; rarely_quit (from); } /* Now CH1 is a character which ends a word and FROM is the position of it. */ func = CHAR_TABLE_REF (Vfind_word_boundary_function_table, ch1); if (! NILP (Ffboundp (func))) { pos = call2 (func, make_number (from), make_number (beg)); if (INTEGERP (pos) && BEGV <= XINT (pos) && XINT (pos) < from) { from = XINT (pos); from_byte = CHAR_TO_BYTE (from); } } else { while (1) { if (from == beg) break; DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); ch0 = FETCH_CHAR_AS_MULTIBYTE (from_byte); code = SYNTAX (ch0); if ((code != Sword && (! words_include_escapes || (code != Sescape && code != Scharquote))) || word_boundary_p (ch0, ch1)) { INC_BOTH (from, from_byte); break; } ch1 = ch0; rarely_quit (from); } } count++; } return from; } DEFUN ("forward-word", Fforward_word, Sforward_word, 0, 1, "^p", doc: /* Move point forward ARG words (backward if ARG is negative). If ARG is omitted or nil, move point forward one word. Normally returns t. If an edge of the buffer or a field boundary is reached, point is left there and the function returns nil. Field boundaries are not noticed if `inhibit-field-text-motion' is non-nil. The word boundaries are normally determined by the buffer's syntax table, but `find-word-boundary-function-table', such as set up by `subword-mode', can change that. If a Lisp program needs to move by words determined strictly by the syntax table, it should use `forward-word-strictly' instead. */) (Lisp_Object arg) { Lisp_Object tmp; ptrdiff_t orig_val, val; if (NILP (arg)) XSETFASTINT (arg, 1); else CHECK_NUMBER (arg); val = orig_val = scan_words (PT, XINT (arg)); if (! orig_val) val = XINT (arg) > 0 ? ZV : BEGV; /* Avoid jumping out of an input field. */ tmp = Fconstrain_to_field (make_number (val), make_number (PT), Qnil, Qnil, Qnil); val = XFASTINT (tmp); SET_PT (val); return val == orig_val ? Qt : Qnil; } DEFUN ("skip-chars-forward", Fskip_chars_forward, Sskip_chars_forward, 1, 2, 0, doc: /* Move point forward, stopping before a char not in STRING, or at pos LIM. STRING is like the inside of a `[...]' in a regular expression except that `]' is never special and `\\' quotes `^', `-' or `\\' (but not at the end of a range; quoting is never needed there). Thus, with arg "a-zA-Z", this skips letters stopping before first nonletter. With arg "^a-zA-Z", skips nonletters stopping before first letter. Char classes, e.g. `[:alpha:]', are supported. Returns the distance traveled, either zero or positive. */) (Lisp_Object string, Lisp_Object lim) { return skip_chars (1, string, lim, 1); } DEFUN ("skip-chars-backward", Fskip_chars_backward, Sskip_chars_backward, 1, 2, 0, doc: /* Move point backward, stopping after a char not in STRING, or at pos LIM. See `skip-chars-forward' for details. Returns the distance traveled, either zero or negative. */) (Lisp_Object string, Lisp_Object lim) { return skip_chars (0, string, lim, 1); } DEFUN ("skip-syntax-forward", Fskip_syntax_forward, Sskip_syntax_forward, 1, 2, 0, doc: /* Move point forward across chars in specified syntax classes. SYNTAX is a string of syntax code characters. Stop before a char whose syntax is not in SYNTAX, or at position LIM. If SYNTAX starts with ^, skip characters whose syntax is NOT in SYNTAX. This function returns the distance traveled, either zero or positive. */) (Lisp_Object syntax, Lisp_Object lim) { return skip_syntaxes (1, syntax, lim); } DEFUN ("skip-syntax-backward", Fskip_syntax_backward, Sskip_syntax_backward, 1, 2, 0, doc: /* Move point backward across chars in specified syntax classes. SYNTAX is a string of syntax code characters. Stop on reaching a char whose syntax is not in SYNTAX, or at position LIM. If SYNTAX starts with ^, skip characters whose syntax is NOT in SYNTAX. This function returns either zero or a negative number, and the absolute value of this is the distance traveled. */) (Lisp_Object syntax, Lisp_Object lim) { return skip_syntaxes (0, syntax, lim); } static Lisp_Object skip_chars (bool forwardp, Lisp_Object string, Lisp_Object lim, bool handle_iso_classes) { int c; char fastmap[0400]; /* Store the ranges of non-ASCII characters. */ int *char_ranges UNINIT; int n_char_ranges = 0; bool negate = 0; ptrdiff_t i, i_byte; /* True if the current buffer is multibyte and the region contains non-ASCII chars. */ bool multibyte; /* True if STRING is multibyte and it contains non-ASCII chars. */ bool string_multibyte; ptrdiff_t size_byte; const unsigned char *str; int len; Lisp_Object iso_classes; USE_SAFE_ALLOCA; CHECK_STRING (string); iso_classes = Qnil; if (NILP (lim)) XSETINT (lim, forwardp ? ZV : BEGV); else CHECK_NUMBER_COERCE_MARKER (lim); /* In any case, don't allow scan outside bounds of buffer. */ if (XINT (lim) > ZV) XSETFASTINT (lim, ZV); if (XINT (lim) < BEGV) XSETFASTINT (lim, BEGV); multibyte = (!NILP (BVAR (current_buffer, enable_multibyte_characters)) && (XINT (lim) - PT != CHAR_TO_BYTE (XINT (lim)) - PT_BYTE)); string_multibyte = SBYTES (string) > SCHARS (string); memset (fastmap, 0, sizeof fastmap); str = SDATA (string); size_byte = SBYTES (string); i_byte = 0; if (i_byte < size_byte && SREF (string, 0) == '^') { negate = 1; i_byte++; } /* Find the characters specified and set their elements of fastmap. Handle backslashes and ranges specially. If STRING contains non-ASCII characters, setup char_ranges for them and use fastmap only for their leading codes. */ if (! string_multibyte) { bool string_has_eight_bit = 0; /* At first setup fastmap. */ while (i_byte < size_byte) { if (handle_iso_classes) { const unsigned char *ch = str + i_byte; re_wctype_t cc = re_wctype_parse (&ch, size_byte - i_byte); if (cc == 0) error ("Invalid ISO C character class"); if (cc != -1) { iso_classes = Fcons (make_number (cc), iso_classes); i_byte = ch - str; continue; } } c = str[i_byte++]; if (c == '\\') { if (i_byte == size_byte) break; c = str[i_byte++]; } /* Treat `-' as range character only if another character follows. */ if (i_byte + 1 < size_byte && str[i_byte] == '-') { int c2; /* Skip over the dash. */ i_byte++; /* Get the end of the range. */ c2 = str[i_byte++]; if (c2 == '\\' && i_byte < size_byte) c2 = str[i_byte++]; if (c <= c2) { int lim2 = c2 + 1; while (c < lim2) fastmap[c++] = 1; if (! ASCII_CHAR_P (c2)) string_has_eight_bit = 1; } } else { fastmap[c] = 1; if (! ASCII_CHAR_P (c)) string_has_eight_bit = 1; } } /* If the current range is multibyte and STRING contains eight-bit chars, arrange fastmap and setup char_ranges for the corresponding multibyte chars. */ if (multibyte && string_has_eight_bit) { char *p1; char himap[0200 + 1]; memcpy (himap, fastmap + 0200, 0200); himap[0200] = 0; memset (fastmap + 0200, 0, 0200); SAFE_NALLOCA (char_ranges, 2, 128); i = 0; while ((p1 = memchr (himap + i, 1, 0200 - i))) { /* Deduce the next range C..C2 from the next clump of 1s in HIMAP starting with &HIMAP[I]. HIMAP is the high order half of the old FASTMAP. */ int c2, leading_code; i = p1 - himap; c = BYTE8_TO_CHAR (i + 0200); i += strlen (p1); c2 = BYTE8_TO_CHAR (i + 0200 - 1); char_ranges[n_char_ranges++] = c; char_ranges[n_char_ranges++] = c2; leading_code = CHAR_LEADING_CODE (c); memset (fastmap + leading_code, 1, CHAR_LEADING_CODE (c2) - leading_code + 1); } } } else /* STRING is multibyte */ { SAFE_NALLOCA (char_ranges, 2, SCHARS (string)); while (i_byte < size_byte) { int leading_code = str[i_byte]; if (handle_iso_classes) { const unsigned char *ch = str + i_byte; re_wctype_t cc = re_wctype_parse (&ch, size_byte - i_byte); if (cc == 0) error ("Invalid ISO C character class"); if (cc != -1) { iso_classes = Fcons (make_number (cc), iso_classes); i_byte = ch - str; continue; } } if (leading_code== '\\') { if (++i_byte == size_byte) break; leading_code = str[i_byte]; } c = STRING_CHAR_AND_LENGTH (str + i_byte, len); i_byte += len; /* Treat `-' as range character only if another character follows. */ if (i_byte + 1 < size_byte && str[i_byte] == '-') { int c2, leading_code2; /* Skip over the dash. */ i_byte++; /* Get the end of the range. */ leading_code2 = str[i_byte]; c2 = STRING_CHAR_AND_LENGTH (str + i_byte, len); i_byte += len; if (c2 == '\\' && i_byte < size_byte) { leading_code2 = str[i_byte]; c2 = STRING_CHAR_AND_LENGTH (str + i_byte, len); i_byte += len; } if (c > c2) continue; if (ASCII_CHAR_P (c)) { while (c <= c2 && c < 0x80) fastmap[c++] = 1; leading_code = CHAR_LEADING_CODE (c); } if (! ASCII_CHAR_P (c)) { int lim2 = leading_code2 + 1; while (leading_code < lim2) fastmap[leading_code++] = 1; if (c <= c2) { char_ranges[n_char_ranges++] = c; char_ranges[n_char_ranges++] = c2; } } } else { if (ASCII_CHAR_P (c)) fastmap[c] = 1; else { fastmap[leading_code] = 1; char_ranges[n_char_ranges++] = c; char_ranges[n_char_ranges++] = c; } } } /* If the current range is unibyte and STRING contains non-ASCII chars, arrange fastmap for the corresponding unibyte chars. */ if (! multibyte && n_char_ranges > 0) { memset (fastmap + 0200, 0, 0200); for (i = 0; i < n_char_ranges; i += 2) { int c1 = char_ranges[i]; int lim2 = char_ranges[i + 1] + 1; for (; c1 < lim2; c1++) { int b = CHAR_TO_BYTE_SAFE (c1); if (b >= 0) fastmap[b] = 1; } } } } /* If ^ was the first character, complement the fastmap. */ if (negate) { if (! multibyte) for (i = 0; i < sizeof fastmap; i++) fastmap[i] ^= 1; else { for (i = 0; i < 0200; i++) fastmap[i] ^= 1; /* All non-ASCII chars possibly match. */ for (; i < sizeof fastmap; i++) fastmap[i] = 1; } } { ptrdiff_t start_point = PT; ptrdiff_t pos = PT; ptrdiff_t pos_byte = PT_BYTE; unsigned char *p = PT_ADDR, *endp, *stop; if (forwardp) { endp = (XINT (lim) == GPT) ? GPT_ADDR : CHAR_POS_ADDR (XINT (lim)); stop = (pos < GPT && GPT < XINT (lim)) ? GPT_ADDR : endp; } else { endp = CHAR_POS_ADDR (XINT (lim)); stop = (pos >= GPT && GPT > XINT (lim)) ? GAP_END_ADDR : endp; } /* This code may look up syntax tables using functions that rely on the gl_state object. To make sure this object is not out of date, let's initialize it manually. We ignore syntax-table text-properties for now, since that's what we've done in the past. */ SETUP_BUFFER_SYNTAX_TABLE (); if (forwardp) { if (multibyte) while (1) { int nbytes; if (p >= stop) { if (p >= endp) break; p = GAP_END_ADDR; stop = endp; } c = STRING_CHAR_AND_LENGTH (p, nbytes); if (! NILP (iso_classes) && in_classes (c, iso_classes)) { if (negate) break; else goto fwd_ok; } if (! fastmap[*p]) break; if (! ASCII_CHAR_P (c)) { /* As we are looking at a multibyte character, we must look up the character in the table CHAR_RANGES. If there's no data in the table, that character is not what we want to skip. */ /* The following code do the right thing even if n_char_ranges is zero (i.e. no data in CHAR_RANGES). */ for (i = 0; i < n_char_ranges; i += 2) if (c >= char_ranges[i] && c <= char_ranges[i + 1]) break; if (!(negate ^ (i < n_char_ranges))) break; } fwd_ok: p += nbytes, pos++, pos_byte += nbytes; rarely_quit (pos); } else while (true) { if (p >= stop) { if (p >= endp) break; p = GAP_END_ADDR; stop = endp; } if (!NILP (iso_classes) && in_classes (*p, iso_classes)) { if (negate) break; else goto fwd_unibyte_ok; } if (!fastmap[*p]) break; fwd_unibyte_ok: p++, pos++, pos_byte++; rarely_quit (pos); } } else { if (multibyte) while (true) { if (p <= stop) { if (p <= endp) break; p = GPT_ADDR; stop = endp; } unsigned char *prev_p = p; do p--; while (stop <= p && ! CHAR_HEAD_P (*p)); c = STRING_CHAR (p); if (! NILP (iso_classes) && in_classes (c, iso_classes)) { if (negate) break; else goto back_ok; } if (! fastmap[*p]) break; if (! ASCII_CHAR_P (c)) { /* See the comment in the previous similar code. */ for (i = 0; i < n_char_ranges; i += 2) if (c >= char_ranges[i] && c <= char_ranges[i + 1]) break; if (!(negate ^ (i < n_char_ranges))) break; } back_ok: pos--, pos_byte -= prev_p - p; rarely_quit (pos); } else while (true) { if (p <= stop) { if (p <= endp) break; p = GPT_ADDR; stop = endp; } if (! NILP (iso_classes) && in_classes (p[-1], iso_classes)) { if (negate) break; else goto back_unibyte_ok; } if (!fastmap[p[-1]]) break; back_unibyte_ok: p--, pos--, pos_byte--; rarely_quit (pos); } } SET_PT_BOTH (pos, pos_byte); SAFE_FREE (); return make_number (PT - start_point); } } static Lisp_Object skip_syntaxes (bool forwardp, Lisp_Object string, Lisp_Object lim) { int c; unsigned char fastmap[0400]; bool negate = 0; ptrdiff_t i, i_byte; bool multibyte; ptrdiff_t size_byte; unsigned char *str; CHECK_STRING (string); if (NILP (lim)) XSETINT (lim, forwardp ? ZV : BEGV); else CHECK_NUMBER_COERCE_MARKER (lim); /* In any case, don't allow scan outside bounds of buffer. */ if (XINT (lim) > ZV) XSETFASTINT (lim, ZV); if (XINT (lim) < BEGV) XSETFASTINT (lim, BEGV); if (forwardp ? (PT >= XFASTINT (lim)) : (PT <= XFASTINT (lim))) return make_number (0); multibyte = (!NILP (BVAR (current_buffer, enable_multibyte_characters)) && (XINT (lim) - PT != CHAR_TO_BYTE (XINT (lim)) - PT_BYTE)); memset (fastmap, 0, sizeof fastmap); if (SBYTES (string) > SCHARS (string)) /* As this is very rare case (syntax spec is ASCII only), don't consider efficiency. */ string = string_make_unibyte (string); str = SDATA (string); size_byte = SBYTES (string); i_byte = 0; if (i_byte < size_byte && SREF (string, 0) == '^') { negate = 1; i_byte++; } /* Find the syntaxes specified and set their elements of fastmap. */ while (i_byte < size_byte) { c = str[i_byte++]; fastmap[syntax_spec_code[c]] = 1; } /* If ^ was the first character, complement the fastmap. */ if (negate) for (i = 0; i < sizeof fastmap; i++) fastmap[i] ^= 1; { ptrdiff_t start_point = PT; ptrdiff_t pos = PT; ptrdiff_t pos_byte = PT_BYTE; unsigned char *p, *endp, *stop; SETUP_SYNTAX_TABLE (pos, forwardp ? 1 : -1); if (forwardp) { while (true) { p = BYTE_POS_ADDR (pos_byte); endp = XINT (lim) == GPT ? GPT_ADDR : CHAR_POS_ADDR (XINT (lim)); stop = pos < GPT && GPT < XINT (lim) ? GPT_ADDR : endp; do { int nbytes; if (p >= stop) { if (p >= endp) goto done; p = GAP_END_ADDR; stop = endp; } if (multibyte) c = STRING_CHAR_AND_LENGTH (p, nbytes); else c = *p, nbytes = 1; if (! fastmap[SYNTAX (c)]) goto done; p += nbytes, pos++, pos_byte += nbytes; rarely_quit (pos); } while (!parse_sexp_lookup_properties || pos < gl_state.e_property); update_syntax_table_forward (pos + gl_state.offset, false, gl_state.object); } } else { p = BYTE_POS_ADDR (pos_byte); endp = CHAR_POS_ADDR (XINT (lim)); stop = pos >= GPT && GPT > XINT (lim) ? GAP_END_ADDR : endp; if (multibyte) { while (true) { if (p <= stop) { if (p <= endp) break; p = GPT_ADDR; stop = endp; } UPDATE_SYNTAX_TABLE_BACKWARD (pos - 1); unsigned char *prev_p = p; do p--; while (stop <= p && ! CHAR_HEAD_P (*p)); c = STRING_CHAR (p); if (! fastmap[SYNTAX (c)]) break; pos--, pos_byte -= prev_p - p; rarely_quit (pos); } } else { while (true) { if (p <= stop) { if (p <= endp) break; p = GPT_ADDR; stop = endp; } UPDATE_SYNTAX_TABLE_BACKWARD (pos - 1); if (! fastmap[SYNTAX (p[-1])]) break; p--, pos--, pos_byte--; rarely_quit (pos); } } } done: SET_PT_BOTH (pos, pos_byte); return make_number (PT - start_point); } } /* Return true if character C belongs to one of the ISO classes in the list ISO_CLASSES. Each class is represented by an integer which is its type according to re_wctype. */ static bool in_classes (int c, Lisp_Object iso_classes) { bool fits_class = 0; while (CONSP (iso_classes)) { Lisp_Object elt; elt = XCAR (iso_classes); iso_classes = XCDR (iso_classes); if (re_iswctype (c, XFASTINT (elt))) fits_class = 1; } return fits_class; } /* Jump over a comment, assuming we are at the beginning of one. FROM is the current position. FROM_BYTE is the bytepos corresponding to FROM. Do not move past STOP (a charpos). The comment over which we have to jump is of style STYLE (either SYNTAX_FLAGS_COMMENT_STYLE (foo) or ST_COMMENT_STYLE). NESTING should be positive to indicate the nesting at the beginning for nested comments and should be zero or negative else. ST_COMMENT_STYLE cannot be nested. PREV_SYNTAX is the SYNTAX_WITH_FLAGS of the previous character (or 0 If the search cannot start in the middle of a two-character). If successful, return true and store the charpos of the comment's end into *CHARPOS_PTR and the corresponding bytepos into *BYTEPOS_PTR. Else, return false and store the charpos STOP into *CHARPOS_PTR, the corresponding bytepos into *BYTEPOS_PTR and the current nesting (as defined for state->incomment) in *INCOMMENT_PTR. Should the last character scanned in an incomplete comment be a possible first character of a two character construct, we store its SYNTAX_WITH_FLAGS into *last_syntax_ptr. Otherwise, we store Smax into *last_syntax_ptr. The comment end is the last character of the comment rather than the character just after the comment. Global syntax data is assumed to initially be valid for FROM and remains valid for forward search starting at the returned position. */ static bool forw_comment (ptrdiff_t from, ptrdiff_t from_byte, ptrdiff_t stop, EMACS_INT nesting, int style, int prev_syntax, ptrdiff_t *charpos_ptr, ptrdiff_t *bytepos_ptr, EMACS_INT *incomment_ptr, int *last_syntax_ptr) { unsigned short int quit_count = 0; int c, c1; enum syntaxcode code; int syntax, other_syntax; if (nesting <= 0) nesting = -1; /* Enter the loop in the middle so that we find a 2-char comment ender if we start in the middle of it. */ syntax = prev_syntax; code = syntax & 0xff; if (syntax != 0 && from < stop) goto forw_incomment; while (1) { if (from == stop) { *incomment_ptr = nesting; *charpos_ptr = from; *bytepos_ptr = from_byte; *last_syntax_ptr = (code == Sescape || code == Scharquote || SYNTAX_FLAGS_COMEND_FIRST (syntax) || (nesting > 0 && SYNTAX_FLAGS_COMSTART_FIRST (syntax))) ? syntax : Smax ; return 0; } c = FETCH_CHAR_AS_MULTIBYTE (from_byte); syntax = SYNTAX_WITH_FLAGS (c); code = syntax & 0xff; if (code == Sendcomment && SYNTAX_FLAGS_COMMENT_STYLE (syntax, 0) == style && (SYNTAX_FLAGS_COMMENT_NESTED (syntax) ? (nesting > 0 && --nesting == 0) : nesting < 0) && !(Vcomment_end_can_be_escaped && char_quoted (from, from_byte))) /* We have encountered a comment end of the same style as the comment sequence which began this comment section. */ break; if (code == Scomment_fence && style == ST_COMMENT_STYLE) /* We have encountered a comment end of the same style as the comment sequence which began this comment section. */ break; if (nesting > 0 && code == Scomment && SYNTAX_FLAGS_COMMENT_NESTED (syntax) && SYNTAX_FLAGS_COMMENT_STYLE (syntax, 0) == style) /* We have encountered a nested comment of the same style as the comment sequence which began this comment section. */ nesting++; INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); forw_incomment: if (from < stop && SYNTAX_FLAGS_COMEND_FIRST (syntax) && (c1 = FETCH_CHAR_AS_MULTIBYTE (from_byte), other_syntax = SYNTAX_WITH_FLAGS (c1), SYNTAX_FLAGS_COMEND_SECOND (other_syntax)) && SYNTAX_FLAGS_COMMENT_STYLE (syntax, other_syntax) == style && ((SYNTAX_FLAGS_COMMENT_NESTED (syntax) || SYNTAX_FLAGS_COMMENT_NESTED (other_syntax)) ? nesting > 0 : nesting < 0)) { syntax = Smax; /* So that "|#" (lisp) can not return the syntax of "#" in *last_syntax_ptr. */ if (--nesting <= 0) /* We have encountered a comment end of the same style as the comment sequence which began this comment section. */ break; else { INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); } } if (nesting > 0 && from < stop && SYNTAX_FLAGS_COMSTART_FIRST (syntax) && (c1 = FETCH_CHAR_AS_MULTIBYTE (from_byte), other_syntax = SYNTAX_WITH_FLAGS (c1), SYNTAX_FLAGS_COMMENT_STYLE (other_syntax, syntax) == style && SYNTAX_FLAGS_COMSTART_SECOND (other_syntax)) && (SYNTAX_FLAGS_COMMENT_NESTED (syntax) || SYNTAX_FLAGS_COMMENT_NESTED (other_syntax))) /* We have encountered a nested comment of the same style as the comment sequence which began this comment section. */ { syntax = Smax; /* So that "#|#" isn't also a comment ender. */ INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); nesting++; } rarely_quit (++quit_count); } *charpos_ptr = from; *bytepos_ptr = from_byte; *last_syntax_ptr = Smax; /* Any syntactic power the last byte had is used up. */ return 1; } DEFUN ("forward-comment", Fforward_comment, Sforward_comment, 1, 1, 0, doc: /* Move forward across up to COUNT comments. If COUNT is negative, move backward. Stop scanning if we find something other than a comment or whitespace. Set point to where scanning stops. If COUNT comments are found as expected, with nothing except whitespace between them, return t; otherwise return nil. */) (Lisp_Object count) { ptrdiff_t from, from_byte, stop; int c, c1; enum syntaxcode code; int comstyle = 0; /* style of comment encountered */ bool comnested = 0; /* whether the comment is nestable or not */ bool found; EMACS_INT count1; ptrdiff_t out_charpos, out_bytepos; EMACS_INT dummy; int dummy2; unsigned short int quit_count = 0; CHECK_NUMBER (count); count1 = XINT (count); stop = count1 > 0 ? ZV : BEGV; from = PT; from_byte = PT_BYTE; SETUP_SYNTAX_TABLE (from, count1); while (count1 > 0) { do { bool comstart_first; int syntax, other_syntax; if (from == stop) { SET_PT_BOTH (from, from_byte); return Qnil; } c = FETCH_CHAR_AS_MULTIBYTE (from_byte); syntax = SYNTAX_WITH_FLAGS (c); code = SYNTAX (c); comstart_first = SYNTAX_FLAGS_COMSTART_FIRST (syntax); comnested = SYNTAX_FLAGS_COMMENT_NESTED (syntax); comstyle = SYNTAX_FLAGS_COMMENT_STYLE (syntax, 0); INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); if (from < stop && comstart_first && (c1 = FETCH_CHAR_AS_MULTIBYTE (from_byte), other_syntax = SYNTAX_WITH_FLAGS (c1), SYNTAX_FLAGS_COMSTART_SECOND (other_syntax))) { /* We have encountered a comment start sequence and we are ignoring all text inside comments. We must record the comment style this sequence begins so that later, only a comment end of the same style actually ends the comment section. */ code = Scomment; comstyle = SYNTAX_FLAGS_COMMENT_STYLE (other_syntax, syntax); comnested |= SYNTAX_FLAGS_COMMENT_NESTED (other_syntax); INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); } rarely_quit (++quit_count); } while (code == Swhitespace || (code == Sendcomment && c == '\n')); if (code == Scomment_fence) comstyle = ST_COMMENT_STYLE; else if (code != Scomment) { DEC_BOTH (from, from_byte); SET_PT_BOTH (from, from_byte); return Qnil; } /* We're at the start of a comment. */ found = forw_comment (from, from_byte, stop, comnested, comstyle, 0, &out_charpos, &out_bytepos, &dummy, &dummy2); from = out_charpos; from_byte = out_bytepos; if (!found) { SET_PT_BOTH (from, from_byte); return Qnil; } INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); /* We have skipped one comment. */ count1--; } while (count1 < 0) { while (true) { if (from <= stop) { SET_PT_BOTH (BEGV, BEGV_BYTE); return Qnil; } DEC_BOTH (from, from_byte); /* char_quoted does UPDATE_SYNTAX_TABLE_BACKWARD (from). */ bool quoted = char_quoted (from, from_byte); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); int syntax = SYNTAX_WITH_FLAGS (c); code = SYNTAX (c); comstyle = 0; comnested = SYNTAX_FLAGS_COMMENT_NESTED (syntax); if (code == Sendcomment) comstyle = SYNTAX_FLAGS_COMMENT_STYLE (syntax, 0); if (from > stop && SYNTAX_FLAGS_COMEND_SECOND (syntax) && prev_char_comend_first (from, from_byte) && !char_quoted (from - 1, dec_bytepos (from_byte))) { int other_syntax; /* We must record the comment style encountered so that later, we can match only the proper comment begin sequence of the same style. */ DEC_BOTH (from, from_byte); code = Sendcomment; /* Calling char_quoted, above, set up global syntax position at the new value of FROM. */ c1 = FETCH_CHAR_AS_MULTIBYTE (from_byte); other_syntax = SYNTAX_WITH_FLAGS (c1); comstyle = SYNTAX_FLAGS_COMMENT_STYLE (other_syntax, syntax); comnested |= SYNTAX_FLAGS_COMMENT_NESTED (other_syntax); } if (code == Scomment_fence) { /* Skip until first preceding unquoted comment_fence. */ bool fence_found = 0; ptrdiff_t ini = from, ini_byte = from_byte; while (1) { DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); if (SYNTAX (c) == Scomment_fence && !char_quoted (from, from_byte)) { fence_found = 1; break; } else if (from == stop) break; rarely_quit (++quit_count); } if (fence_found == 0) { from = ini; /* Set point to ini + 1. */ from_byte = ini_byte; goto leave; } else /* We have skipped one comment. */ break; } else if (code == Sendcomment) { found = back_comment (from, from_byte, stop, comnested, comstyle, &out_charpos, &out_bytepos); if (!found) { if (c == '\n') /* This end-of-line is not an end-of-comment. Treat it like a whitespace. CC-mode (and maybe others) relies on this behavior. */ ; else { /* Failure: we should go back to the end of this not-quite-endcomment. */ if (SYNTAX (c) != code) /* It was a two-char Sendcomment. */ INC_BOTH (from, from_byte); goto leave; } } else { /* We have skipped one comment. */ from = out_charpos, from_byte = out_bytepos; break; } } else if (code != Swhitespace || quoted) { leave: INC_BOTH (from, from_byte); SET_PT_BOTH (from, from_byte); return Qnil; } rarely_quit (++quit_count); } count1++; } SET_PT_BOTH (from, from_byte); return Qt; } /* Return syntax code of character C if C is an ASCII character or if MULTIBYTE_SYMBOL_P is false. Otherwise, return Ssymbol. */ static enum syntaxcode syntax_multibyte (int c, bool multibyte_symbol_p) { return ASCII_CHAR_P (c) || !multibyte_symbol_p ? SYNTAX (c) : Ssymbol; } static Lisp_Object scan_lists (EMACS_INT from, EMACS_INT count, EMACS_INT depth, bool sexpflag) { Lisp_Object val; ptrdiff_t stop = count > 0 ? ZV : BEGV; int c, c1; int stringterm; bool quoted; bool mathexit = 0; enum syntaxcode code; EMACS_INT min_depth = depth; /* Err out if depth gets less than this. */ int comstyle = 0; /* Style of comment encountered. */ bool comnested = 0; /* Whether the comment is nestable or not. */ ptrdiff_t temp_pos; EMACS_INT last_good = from; bool found; ptrdiff_t from_byte; ptrdiff_t out_bytepos, out_charpos; EMACS_INT dummy; int dummy2; bool multibyte_symbol_p = sexpflag && multibyte_syntax_as_symbol; unsigned short int quit_count = 0; if (depth > 0) min_depth = 0; if (from > ZV) from = ZV; if (from < BEGV) from = BEGV; from_byte = CHAR_TO_BYTE (from); maybe_quit (); SETUP_SYNTAX_TABLE (from, count); while (count > 0) { while (from < stop) { rarely_quit (++quit_count); bool comstart_first, prefix; int syntax, other_syntax; UPDATE_SYNTAX_TABLE_FORWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); syntax = SYNTAX_WITH_FLAGS (c); code = syntax_multibyte (c, multibyte_symbol_p); comstart_first = SYNTAX_FLAGS_COMSTART_FIRST (syntax); comnested = SYNTAX_FLAGS_COMMENT_NESTED (syntax); comstyle = SYNTAX_FLAGS_COMMENT_STYLE (syntax, 0); prefix = SYNTAX_FLAGS_PREFIX (syntax); if (depth == min_depth) last_good = from; INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); if (from < stop && comstart_first && (c = FETCH_CHAR_AS_MULTIBYTE (from_byte), other_syntax = SYNTAX_WITH_FLAGS (c), SYNTAX_FLAGS_COMSTART_SECOND (other_syntax)) && parse_sexp_ignore_comments) { /* We have encountered a comment start sequence and we are ignoring all text inside comments. We must record the comment style this sequence begins so that later, only a comment end of the same style actually ends the comment section. */ code = Scomment; comstyle = SYNTAX_FLAGS_COMMENT_STYLE (other_syntax, syntax); comnested |= SYNTAX_FLAGS_COMMENT_NESTED (other_syntax); INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); } if (prefix) continue; switch (code) { case Sescape: case Scharquote: if (from == stop) goto lose; INC_BOTH (from, from_byte); /* Treat following character as a word constituent. */ case Sword: case Ssymbol: if (depth || !sexpflag) break; /* This word counts as a sexp; return at end of it. */ while (from < stop) { UPDATE_SYNTAX_TABLE_FORWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); switch (syntax_multibyte (c, multibyte_symbol_p)) { case Scharquote: case Sescape: INC_BOTH (from, from_byte); if (from == stop) goto lose; break; case Sword: case Ssymbol: case Squote: break; default: goto done; } INC_BOTH (from, from_byte); rarely_quit (++quit_count); } goto done; case Scomment_fence: comstyle = ST_COMMENT_STYLE; /* FALLTHROUGH */ case Scomment: if (!parse_sexp_ignore_comments) break; UPDATE_SYNTAX_TABLE_FORWARD (from); found = forw_comment (from, from_byte, stop, comnested, comstyle, 0, &out_charpos, &out_bytepos, &dummy, &dummy2); from = out_charpos, from_byte = out_bytepos; if (!found) { if (depth == 0) goto done; goto lose; } INC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_FORWARD (from); break; case Smath: if (!sexpflag) break; if (from != stop && c == FETCH_CHAR_AS_MULTIBYTE (from_byte)) { INC_BOTH (from, from_byte); } if (mathexit) { mathexit = 0; goto close1; } mathexit = 1; case Sopen: if (!++depth) goto done; break; case Sclose: close1: if (!--depth) goto done; if (depth < min_depth) xsignal3 (Qscan_error, build_string ("Containing expression ends prematurely"), make_number (last_good), make_number (from)); break; case Sstring: case Sstring_fence: temp_pos = dec_bytepos (from_byte); stringterm = FETCH_CHAR_AS_MULTIBYTE (temp_pos); while (1) { enum syntaxcode c_code; if (from >= stop) goto lose; UPDATE_SYNTAX_TABLE_FORWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); c_code = syntax_multibyte (c, multibyte_symbol_p); if (code == Sstring ? c == stringterm && c_code == Sstring : c_code == Sstring_fence) break; if (c_code == Scharquote || c_code == Sescape) INC_BOTH (from, from_byte); INC_BOTH (from, from_byte); rarely_quit (++quit_count); } INC_BOTH (from, from_byte); if (!depth && sexpflag) goto done; break; default: /* Ignore whitespace, punctuation, quote, endcomment. */ break; } } /* Reached end of buffer. Error if within object, return nil if between */ if (depth) goto lose; return Qnil; /* End of object reached */ done: count--; } while (count < 0) { while (from > stop) { rarely_quit (++quit_count); DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); c = FETCH_CHAR_AS_MULTIBYTE (from_byte); int syntax = SYNTAX_WITH_FLAGS (c); code = syntax_multibyte (c, multibyte_symbol_p); if (depth == min_depth) last_good = from; comstyle = 0; comnested = SYNTAX_FLAGS_COMMENT_NESTED (syntax); if (code == Sendcomment) comstyle = SYNTAX_FLAGS_COMMENT_STYLE (syntax, 0); if (from > stop && SYNTAX_FLAGS_COMEND_SECOND (syntax) && prev_char_comend_first (from, from_byte) && parse_sexp_ignore_comments) { /* We must record the comment style encountered so that later, we can match only the proper comment begin sequence of the same style. */ int c2, other_syntax; DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); code = Sendcomment; c2 = FETCH_CHAR_AS_MULTIBYTE (from_byte); other_syntax = SYNTAX_WITH_FLAGS (c2); comstyle = SYNTAX_FLAGS_COMMENT_STYLE (other_syntax, syntax); comnested |= SYNTAX_FLAGS_COMMENT_NESTED (other_syntax); } /* Quoting turns anything except a comment-ender into a word character. Note that this cannot be true if we decremented FROM in the if-statement above. */ if (code != Sendcomment && char_quoted (from, from_byte)) { DEC_BOTH (from, from_byte); code = Sword; } else if (SYNTAX_FLAGS_PREFIX (syntax)) continue; switch (code) { case Sword: case Ssymbol: case Sescape: case Scharquote: if (depth || !sexpflag) break; /* This word counts as a sexp; count object finished after passing it. */ while (from > stop) { temp_pos = from_byte; if (! NILP (BVAR (current_buffer, enable_multibyte_characters))) DEC_POS (temp_pos); else temp_pos--; UPDATE_SYNTAX_TABLE_BACKWARD (from - 1); c1 = FETCH_CHAR_AS_MULTIBYTE (temp_pos); /* Don't allow comment-end to be quoted. */ if (syntax_multibyte (c1, multibyte_symbol_p) == Sendcomment) goto done2; quoted = char_quoted (from - 1, temp_pos); if (quoted) { DEC_BOTH (from, from_byte); temp_pos = dec_bytepos (temp_pos); UPDATE_SYNTAX_TABLE_BACKWARD (from - 1); } c1 = FETCH_CHAR_AS_MULTIBYTE (temp_pos); if (! quoted) switch (syntax_multibyte (c1, multibyte_symbol_p)) { case Sword: case Ssymbol: case Squote: break; default: goto done2; } DEC_BOTH (from, from_byte); rarely_quit (++quit_count); } goto done2; case Smath: if (!sexpflag) break; if (from > BEGV) { temp_pos = dec_bytepos (from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from - 1); if (from != stop && c == FETCH_CHAR_AS_MULTIBYTE (temp_pos)) DEC_BOTH (from, from_byte); } if (mathexit) { mathexit = 0; goto open2; } mathexit = 1; case Sclose: if (!++depth) goto done2; break; case Sopen: open2: if (!--depth) goto done2; if (depth < min_depth) xsignal3 (Qscan_error, build_string ("Containing expression ends prematurely"), make_number (last_good), make_number (from)); break; case Sendcomment: if (!parse_sexp_ignore_comments) break; found = back_comment (from, from_byte, stop, comnested, comstyle, &out_charpos, &out_bytepos); /* FIXME: if !found, it really wasn't a comment-end. For single-char Sendcomment, we can't do much about it apart from skipping the char. For 2-char endcomments, we could try again, taking both chars as separate entities, but it's a lot of trouble for very little gain, so we don't bother either. -sm */ if (found) from = out_charpos, from_byte = out_bytepos; break; case Scomment_fence: case Sstring_fence: while (1) { if (from == stop) goto lose; DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); if (!char_quoted (from, from_byte)) { c = FETCH_CHAR_AS_MULTIBYTE (from_byte); if (syntax_multibyte (c, multibyte_symbol_p) == code) break; } rarely_quit (++quit_count); } if (code == Sstring_fence && !depth && sexpflag) goto done2; break; case Sstring: stringterm = FETCH_CHAR_AS_MULTIBYTE (from_byte); while (true) { if (from == stop) goto lose; DEC_BOTH (from, from_byte); UPDATE_SYNTAX_TABLE_BACKWARD (from); if (!char_quoted (from, from_byte)) { c = FETCH_CHAR_AS_MULTIBYTE (from_byte); if (c == stringterm && (syntax_multibyte (c, multibyte_symbol_p) == Sstring)) break; } rarely_quit (++quit_count); } if (!depth && sexpflag) goto done2; break; default: /* Ignore whitespace, punctuation, quote, endcomment. */ break; } } /* Reached start of buffer. Error if within object, return nil if between */ if (depth) goto lose; return Qnil; done2: count++; } XSETFASTINT (val, from); return val; lose: xsignal3 (Qscan_error, build_string ("Unbalanced parentheses"), make_number (last_good), make_number (from)); } DEFUN ("scan-lists", Fscan_lists, Sscan_lists, 3, 3, 0, doc: /* Scan from character number FROM by COUNT lists. Scan forward if COUNT is positive, backward if COUNT is negative. Return the character number of the position thus found. A \"list", in this context, refers to a balanced parenthetical grouping, as determined by the syntax table. If DEPTH is nonzero, treat that as the nesting depth of the starting point (i.e. the starting point is DEPTH parentheses deep). This function scans over parentheses until the depth goes to zero COUNT times. Hence, positive DEPTH moves out that number of levels of parentheses, while negative DEPTH moves to a deeper level. Comments are ignored if `parse-sexp-ignore-comments' is non-nil. If we reach the beginning or end of the accessible part of the buffer before we have scanned over COUNT lists, return nil if the depth at that point is zero, and signal a error if the depth is nonzero. */) (Lisp_Object from, Lisp_Object count, Lisp_Object depth) { CHECK_NUMBER (from); CHECK_NUMBER (count); CHECK_NUMBER (depth); return scan_lists (XINT (from), XINT (count), XINT (depth), 0); } DEFUN ("scan-sexps", Fscan_sexps, Sscan_sexps, 2, 2, 0, doc: /* Scan from character number FROM by COUNT balanced expressions. If COUNT is negative, scan backwards. Returns the character number of the position thus found. Comments are ignored if `parse-sexp-ignore-comments' is non-nil. If the beginning or end of (the accessible part of) the buffer is reached in the middle of a parenthetical grouping, an error is signaled. If the beginning or end is reached between groupings but before count is used up, nil is returned. */) (Lisp_Object from, Lisp_Object count) { CHECK_NUMBER (from); CHECK_NUMBER (count); return scan_lists (XINT (from), XINT (count), 0, 1); } DEFUN ("backward-prefix-chars", Fbackward_prefix_chars, Sbackward_prefix_chars, 0, 0, 0, doc: /* Move point backward over any number of chars with prefix syntax. This includes chars with expression prefix syntax class (\\=') and those with the prefix syntax flag (p). */) (void) { ptrdiff_t beg = BEGV; ptrdiff_t opoint = PT; ptrdiff_t opoint_byte = PT_BYTE; ptrdiff_t pos = PT; ptrdiff_t pos_byte = PT_BYTE; int c; if (pos <= beg) { SET_PT_BOTH (opoint, opoint_byte); return Qnil; } SETUP_SYNTAX_TABLE (pos, -1); DEC_BOTH (pos, pos_byte); while (!char_quoted (pos, pos_byte) /* Previous statement updates syntax table. */ && ((c = FETCH_CHAR_AS_MULTIBYTE (pos_byte), SYNTAX (c) == Squote) || syntax_prefix_flag_p (c))) { opoint = pos; opoint_byte = pos_byte; if (pos <= beg) break; DEC_BOTH (pos, pos_byte); rarely_quit (pos); } SET_PT_BOTH (opoint, opoint_byte); return Qnil; } /* If the character at FROM_BYTE is the second part of a 2-character comment opener based on PREV_FROM_SYNTAX, update STATE and return true. */ static bool in_2char_comment_start (struct lisp_parse_state *state, int prev_from_syntax, ptrdiff_t prev_from, ptrdiff_t from_byte) { int c1, syntax; if (SYNTAX_FLAGS_COMSTART_FIRST (prev_from_syntax) && (c1 = FETCH_CHAR_AS_MULTIBYTE (from_byte), syntax = SYNTAX_WITH_FLAGS (c1), SYNTAX_FLAGS_COMSTART_SECOND (syntax))) { /* Record the comment style we have entered so that only the comment-end sequence of the same style actually terminates the comment section. */ state->comstyle = SYNTAX_FLAGS_COMMENT_STYLE (syntax, prev_from_syntax); bool comnested = (SYNTAX_FLAGS_COMMENT_NESTED (prev_from_syntax) | SYNTAX_FLAGS_COMMENT_NESTED (syntax)); state->incomment = comnested ? 1 : -1; state->comstr_start = prev_from; return true; } return false; } /* Parse forward from FROM / FROM_BYTE to END, assuming that FROM has state STATE, and return a description of the state of the parse at END. If STOPBEFORE, stop at the start of an atom. If COMMENTSTOP is 1, stop at the start of a comment. If COMMENTSTOP is -1, stop at the start or end of a comment, after the beginning of a string, or after the end of a string. */ static void scan_sexps_forward (struct lisp_parse_state *state, ptrdiff_t from, ptrdiff_t from_byte, ptrdiff_t end, EMACS_INT targetdepth, bool stopbefore, int commentstop) { enum syntaxcode code; struct level { ptrdiff_t last, prev; }; struct level levelstart[100]; struct level *curlevel = levelstart; struct level *endlevel = levelstart + 100; EMACS_INT depth; /* Paren depth of current scanning location. level - levelstart equals this except when the depth becomes negative. */ EMACS_INT mindepth; /* Lowest DEPTH value seen. */ bool start_quoted = 0; /* True means starting after a char quote. */ Lisp_Object tem; ptrdiff_t prev_from; /* Keep one character before FROM. */ ptrdiff_t prev_from_byte; int prev_from_syntax, prev_prev_from_syntax; bool boundary_stop = commentstop == -1; bool nofence; bool found; ptrdiff_t out_bytepos, out_charpos; int temp; unsigned short int quit_count = 0; prev_from = from; prev_from_byte = from_byte; if (from != BEGV) DEC_BOTH (prev_from, prev_from_byte); /* Use this macro instead of `from++'. */ #define INC_FROM \ do { prev_from = from; \ prev_from_byte = from_byte; \ temp = FETCH_CHAR_AS_MULTIBYTE (prev_from_byte); \ prev_prev_from_syntax = prev_from_syntax; \ prev_from_syntax = SYNTAX_WITH_FLAGS (temp); \ INC_BOTH (from, from_byte); \ if (from < end) \ UPDATE_SYNTAX_TABLE_FORWARD (from); \ } while (0) maybe_quit (); depth = state->depth; start_quoted = state->quoted; prev_prev_from_syntax = Smax; prev_from_syntax = state->prev_syntax; tem = state->levelstarts; while (!NILP (tem)) /* >= second enclosing sexps. */ { Lisp_Object temhd = Fcar (tem); if (RANGED_INTEGERP (PTRDIFF_MIN, temhd, PTRDIFF_MAX)) curlevel->last = XINT (temhd); if (++curlevel == endlevel) curlevel--; /* error ("Nesting too deep for parser"); */ curlevel->prev = -1; curlevel->last = -1; tem = Fcdr (tem); } curlevel->prev = -1; curlevel->last = -1; state->quoted = 0; mindepth = depth; SETUP_SYNTAX_TABLE (from, 1); /* Enter the loop at a place appropriate for initial state. */ if (state->incomment) goto startincomment; if (state->instring >= 0) { nofence = state->instring != ST_STRING_STYLE; if (start_quoted) goto startquotedinstring; goto startinstring; } else if (start_quoted) goto startquoted; else if ((from < end) && (in_2char_comment_start (state, prev_from_syntax, prev_from, from_byte))) { INC_FROM; prev_from_syntax = Smax; /* the syntax has already been "used up". */ goto atcomment; } while (from < end) { rarely_quit (++quit_count); INC_FROM; if ((from < end) && (in_2char_comment_start (state, prev_from_syntax, prev_from, from_byte))) { INC_FROM; prev_from_syntax = Smax; /* the syntax has already been "used up". */ goto atcomment; } if (SYNTAX_FLAGS_PREFIX (prev_from_syntax)) continue; code = prev_from_syntax & 0xff; switch (code) { case Sescape: case Scharquote: if (stopbefore) goto stop; /* this arg means stop at sexp start */ curlevel->last = prev_from; startquoted: if (from == end) goto endquoted; INC_FROM; goto symstarted; /* treat following character as a word constituent */ case Sword: case Ssymbol: if (stopbefore) goto stop; /* this arg means stop at sexp start */ curlevel->last = prev_from; symstarted: while (from < end) { if (in_2char_comment_start (state, prev_from_syntax, prev_from, from_byte)) { INC_FROM; prev_from_syntax = Smax; /* the syntax has already been "used up". */ goto atcomment; } int symchar = FETCH_CHAR_AS_MULTIBYTE (from_byte); switch (SYNTAX (symchar)) { case Scharquote: case Sescape: INC_FROM; if (from == end) goto endquoted; break; case Sword: case Ssymbol: case Squote: break; default: goto symdone; } INC_FROM; rarely_quit (++quit_count); } symdone: curlevel->prev = curlevel->last; break; case Scomment_fence: /* Record the comment style we have entered so that only the comment-end sequence of the same style actually terminates the comment section. */ state->comstyle = ST_COMMENT_STYLE; state->incomment = -1; state->comstr_start = prev_from; goto atcomment; case Scomment: state->comstyle = SYNTAX_FLAGS_COMMENT_STYLE (prev_from_syntax, 0); state->incomment = (SYNTAX_FLAGS_COMMENT_NESTED (prev_from_syntax) ? 1 : -1); state->comstr_start = prev_from; atcomment: if (commentstop || boundary_stop) goto done; startincomment: /* The (from == BEGV) test was to enter the loop in the middle so that we find a 2-char comment ender even if we start in the middle of it. We don't want to do that if we're just at the beginning of the comment (think of (*) ... (*)). */ found = forw_comment (from, from_byte, end, state->incomment, state->comstyle, from == BEGV ? 0 : prev_from_syntax, &out_charpos, &out_bytepos, &state->incomment, &prev_from_syntax); from = out_charpos; from_byte = out_bytepos; /* Beware! prev_from and friends (except prev_from_syntax) are invalid now. Luckily, the `done' doesn't use them and the INC_FROM sets them to a sane value without looking at them. */ if (!found) goto done; INC_FROM; state->incomment = 0; state->comstyle = 0; /* reset the comment style */ prev_from_syntax = Smax; /* For the comment closer */ if (boundary_stop) goto done; break; case Sopen: if (stopbefore) goto stop; /* this arg means stop at sexp start */ depth++; /* curlevel++->last ran into compiler bug on Apollo */ curlevel->last = prev_from; if (++curlevel == endlevel) curlevel--; /* error ("Nesting too deep for parser"); */ curlevel->prev = -1; curlevel->last = -1; if (targetdepth == depth) goto done; break; case Sclose: depth--; if (depth < mindepth) mindepth = depth; if (curlevel != levelstart) curlevel--; curlevel->prev = curlevel->last; if (targetdepth == depth) goto done; break; case Sstring: case Sstring_fence: state->comstr_start = from - 1; if (stopbefore) goto stop; /* this arg means stop at sexp start */ curlevel->last = prev_from; state->instring = (code == Sstring ? (FETCH_CHAR_AS_MULTIBYTE (prev_from_byte)) : ST_STRING_STYLE); if (boundary_stop) goto done; startinstring: { nofence = state->instring != ST_STRING_STYLE; while (1) { int c; enum syntaxcode c_code; if (from >= end) goto done; c = FETCH_CHAR_AS_MULTIBYTE (from_byte); c_code = SYNTAX (c); /* Check C_CODE here so that if the char has a syntax-table property which says it is NOT a string character, it does not end the string. */ if (nofence && c == state->instring && c_code == Sstring) break; switch (c_code) { case Sstring_fence: if (!nofence) goto string_end; break; case Scharquote: case Sescape: INC_FROM; startquotedinstring: if (from >= end) goto endquoted; break; default: break; } INC_FROM; rarely_quit (++quit_count); } } string_end: state->instring = -1; curlevel->prev = curlevel->last; INC_FROM; if (boundary_stop) goto done; break; case Smath: /* FIXME: We should do something with it. */ break; default: /* Ignore whitespace, punctuation, quote, endcomment. */ break; } } goto done; stop: /* Here if stopping before start of sexp. */ from = prev_from; /* We have just fetched the char that starts it; */ from_byte = prev_from_byte; prev_from_syntax = prev_prev_from_syntax; goto done; /* but return the position before it. */ endquoted: state->quoted = 1; done: state->depth = depth; state->mindepth = mindepth; state->thislevelstart = curlevel->prev; state->prevlevelstart = (curlevel == levelstart) ? -1 : (curlevel - 1)->last; state->location = from; state->location_byte = from_byte; state->levelstarts = Qnil; while (curlevel > levelstart) state->levelstarts = Fcons (make_number ((--curlevel)->last), state->levelstarts); state->prev_syntax = (SYNTAX_FLAGS_COMSTARTEND_FIRST (prev_from_syntax) || state->quoted) ? prev_from_syntax : Smax; } /* Convert a (lisp) parse state to the internal form used in scan_sexps_forward. */ static void internalize_parse_state (Lisp_Object external, struct lisp_parse_state *state) { Lisp_Object tem; if (NILP (external)) { state->depth = 0; state->instring = -1; state->incomment = 0; state->quoted = 0; state->comstyle = 0; /* comment style a by default. */ state->comstr_start = -1; /* no comment/string seen. */ state->levelstarts = Qnil; state->prev_syntax = Smax; } else { tem = Fcar (external); if (!NILP (tem)) state->depth = XINT (tem); else state->depth = 0; external = Fcdr (external); external = Fcdr (external); external = Fcdr (external); tem = Fcar (external); /* Check whether we are inside string_fence-style string: */ state->instring = (!NILP (tem) ? (CHARACTERP (tem) ? XFASTINT (tem) : ST_STRING_STYLE) : -1); external = Fcdr (external); tem = Fcar (external); state->incomment = (!NILP (tem) ? (INTEGERP (tem) ? XINT (tem) : -1) : 0); external = Fcdr (external); tem = Fcar (external); state->quoted = !NILP (tem); /* if the eighth element of the list is nil, we are in comment style a. If it is non-nil, we are in comment style b */ external = Fcdr (external); external = Fcdr (external); tem = Fcar (external); state->comstyle = (NILP (tem) ? 0 : (RANGED_INTEGERP (0, tem, ST_COMMENT_STYLE) ? XINT (tem) : ST_COMMENT_STYLE)); external = Fcdr (external); tem = Fcar (external); state->comstr_start = RANGED_INTEGERP (PTRDIFF_MIN, tem, PTRDIFF_MAX) ? XINT (tem) : -1; external = Fcdr (external); tem = Fcar (external); state->levelstarts = tem; external = Fcdr (external); tem = Fcar (external); state->prev_syntax = NILP (tem) ? Smax : XINT (tem); } } DEFUN ("parse-partial-sexp", Fparse_partial_sexp, Sparse_partial_sexp, 2, 6, 0, doc: /* Parse Lisp syntax starting at FROM until TO; return status of parse at TO. Parsing stops at TO or when certain criteria are met; point is set to where parsing stops. If fifth arg OLDSTATE is omitted or nil, parsing assumes that FROM is the beginning of a function. Value is a list of elements describing final state of parsing: 0. depth in parens. 1. character address of start of innermost containing list; nil if none. 2. character address of start of last complete sexp terminated. 3. non-nil if inside a string. (it is the character that will terminate the string, or t if the string should be terminated by a generic string delimiter.) 4. nil if outside a comment, t if inside a non-nestable comment, else an integer (the current comment nesting). 5. t if following a quote character. 6. the minimum paren-depth encountered during this scan. 7. style of comment, if any. 8. character address of start of comment or string; nil if not in one. 9. List of positions of currently open parens, outermost first. 10. When the last position scanned holds the first character of a (potential) two character construct, the syntax of that position, otherwise nil. That construct can be a two character comment delimiter or an Escaped or Char-quoted character. 11..... Possible further internal information used by `parse-partial-sexp'. If third arg TARGETDEPTH is non-nil, parsing stops if the depth in parentheses becomes equal to TARGETDEPTH. Fourth arg STOPBEFORE non-nil means stop when we come to any character that starts a sexp. Fifth arg OLDSTATE is a list like what this function returns. It is used to initialize the state of the parse. Elements number 1, 2, 6 are ignored. Sixth arg COMMENTSTOP non-nil means stop after the start of a comment. If it is the symbol `syntax-table', stop after the start of a comment or a string, or after end of a comment or a string. */) (Lisp_Object from, Lisp_Object to, Lisp_Object targetdepth, Lisp_Object stopbefore, Lisp_Object oldstate, Lisp_Object commentstop) { struct lisp_parse_state state; EMACS_INT target; if (!NILP (targetdepth)) { CHECK_NUMBER (targetdepth); target = XINT (targetdepth); } else target = TYPE_MINIMUM (EMACS_INT); /* We won't reach this depth. */ validate_region (&from, &to); internalize_parse_state (oldstate, &state); scan_sexps_forward (&state, XINT (from), CHAR_TO_BYTE (XINT (from)), XINT (to), target, !NILP (stopbefore), (NILP (commentstop) ? 0 : (EQ (commentstop, Qsyntax_table) ? -1 : 1))); SET_PT_BOTH (state.location, state.location_byte); return Fcons (make_number (state.depth), Fcons (state.prevlevelstart < 0 ? Qnil : make_number (state.prevlevelstart), Fcons (state.thislevelstart < 0 ? Qnil : make_number (state.thislevelstart), Fcons (state.instring >= 0 ? (state.instring == ST_STRING_STYLE ? Qt : make_number (state.instring)) : Qnil, Fcons (state.incomment < 0 ? Qt : (state.incomment == 0 ? Qnil : make_number (state.incomment)), Fcons (state.quoted ? Qt : Qnil, Fcons (make_number (state.mindepth), Fcons ((state.comstyle ? (state.comstyle == ST_COMMENT_STYLE ? Qsyntax_table : make_number (state.comstyle)) : Qnil), Fcons (((state.incomment || (state.instring >= 0)) ? make_number (state.comstr_start) : Qnil), Fcons (state.levelstarts, Fcons (state.prev_syntax == Smax ? Qnil : make_number (state.prev_syntax), Qnil))))))))))); } void init_syntax_once (void) { register int i, c; Lisp_Object temp; /* This has to be done here, before we call Fmake_char_table. */ DEFSYM (Qsyntax_table, "syntax-table"); Fput (Qsyntax_table, Qchar_table_extra_slots, make_number (2)); /* Create objects which can be shared among syntax tables. */ Vsyntax_code_object = make_uninit_vector (Smax); for (i = 0; i < Smax; i++) ASET (Vsyntax_code_object, i, Fcons (make_number (i), Qnil)); /* Now we are ready to set up this property, so we can create syntax tables. */ /* Fput (Qsyntax_table, Qchar_table_extra_slots, make_number (0)); */ temp = AREF (Vsyntax_code_object, Swhitespace); Vstandard_syntax_table = Fmake_char_table (Qsyntax_table, temp); /* Control characters should not be whitespace. */ temp = AREF (Vsyntax_code_object, Spunct); for (i = 0; i <= ' ' - 1; i++) SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, i, temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, 0177, temp); /* Except that a few really are whitespace. */ temp = AREF (Vsyntax_code_object, Swhitespace); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, ' ', temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '\t', temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '\n', temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, 015, temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, 014, temp); temp = AREF (Vsyntax_code_object, Sword); for (i = 'a'; i <= 'z'; i++) SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, i, temp); for (i = 'A'; i <= 'Z'; i++) SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, i, temp); for (i = '0'; i <= '9'; i++) SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, i, temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '$', temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '%', temp); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '(', Fcons (make_number (Sopen), make_number (')'))); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, ')', Fcons (make_number (Sclose), make_number ('('))); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '[', Fcons (make_number (Sopen), make_number (']'))); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, ']', Fcons (make_number (Sclose), make_number ('['))); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '{', Fcons (make_number (Sopen), make_number ('}'))); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '}', Fcons (make_number (Sclose), make_number ('{'))); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '"', Fcons (make_number (Sstring), Qnil)); SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, '\\', Fcons (make_number (Sescape), Qnil)); temp = AREF (Vsyntax_code_object, Ssymbol); for (i = 0; i < 10; i++) { c = "_-+*/&|<>="[i]; SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, c, temp); } temp = AREF (Vsyntax_code_object, Spunct); for (i = 0; i < 12; i++) { c = ".,;:?!#@~^'`"[i]; SET_RAW_SYNTAX_ENTRY (Vstandard_syntax_table, c, temp); } /* All multibyte characters have syntax `word' by default. */ temp = AREF (Vsyntax_code_object, Sword); char_table_set_range (Vstandard_syntax_table, 0x80, MAX_CHAR, temp); } void syms_of_syntax (void) { DEFSYM (Qsyntax_table_p, "syntax-table-p"); staticpro (&Vsyntax_code_object); staticpro (&gl_state.object); staticpro (&gl_state.global_code); staticpro (&gl_state.current_syntax_table); staticpro (&gl_state.old_prop); /* Defined in regex.c. */ staticpro (&re_match_object); DEFSYM (Qscan_error, "scan-error"); Fput (Qscan_error, Qerror_conditions, listn (CONSTYPE_PURE, 2, Qscan_error, Qerror)); Fput (Qscan_error, Qerror_message, build_pure_c_string ("Scan error")); DEFSYM (Qliteral_cache, "literal-cache"); DEFVAR_LISP ("literal-cache-values", Vliteral_cache_values, doc: /* A list of values which the text property `literal-cache' can assume. This is to ensure that any values which are `equal' are also `eq', as required by the text property functions. The list starts off empty, and any time a new value is needed, it is pushed onto the list. The second time a value is needed, it is found by `member', and the canonical equivalent used. */); Vliteral_cache_values = Qnil; DEFVAR_BOOL ("parse-sexp-ignore-comments", parse_sexp_ignore_comments, doc: /* Non-nil means `forward-sexp', etc., should treat comments as whitespace. */); DEFVAR_BOOL ("parse-sexp-lookup-properties", parse_sexp_lookup_properties, doc: /* Non-nil means `forward-sexp', etc., obey `syntax-table' property. Otherwise, that text property is simply ignored. See the info node `(elisp)Syntax Properties' for a description of the `syntax-table' property. */); DEFVAR_INT ("syntax-propertize--done", syntax_propertize__done, doc: /* Position up to which syntax-table properties have been set. */); syntax_propertize__done = -1; DEFSYM (Qinternal__syntax_propertize, "internal--syntax-propertize"); Fmake_variable_buffer_local (intern ("syntax-propertize--done")); words_include_escapes = 0; DEFVAR_BOOL ("words-include-escapes", words_include_escapes, doc: /* Non-nil means `forward-word', etc., should treat escape chars part of words. */); DEFVAR_BOOL ("multibyte-syntax-as-symbol", multibyte_syntax_as_symbol, doc: /* Non-nil means `scan-sexps' treats all multibyte characters as symbol. */); multibyte_syntax_as_symbol = 0; DEFVAR_BOOL ("open-paren-in-column-0-is-defun-start", open_paren_in_column_0_is_defun_start, doc: /* Non-nil means an open paren in column 0 denotes the start of a defun. */); open_paren_in_column_0_is_defun_start = 1; DEFVAR_LISP ("find-word-boundary-function-table", Vfind_word_boundary_function_table, doc: /* Char table of functions to search for the word boundary. Each function is called with two arguments; POS and LIMIT. POS and LIMIT are character positions in the current buffer. If POS is less than LIMIT, POS is at the first character of a word, and the return value of a function should be a position after the last character of that word. If POS is not less than LIMIT, POS is at the last character of a word, and the return value of a function should be a position at the first character of that word. In both cases, LIMIT bounds the search. */); Vfind_word_boundary_function_table = Fmake_char_table (Qnil, Qnil); DEFVAR_BOOL ("comment-end-can-be-escaped", Vcomment_end_can_be_escaped, doc: /* Non-nil means an escaped ender inside a comment doesn't end the comment. */); Vcomment_end_can_be_escaped = 0; DEFSYM (Qcomment_end_can_be_escaped, "comment-end-can-be-escaped"); Fmake_variable_buffer_local (Qcomment_end_can_be_escaped); defsubr (&Strim_literal_cache); defsubr (&Sleast_literal_difference_between_syntax_tables); defsubr (&Ssyntax_tables_literally_different_p); defsubr (&Ssyntax_table_p); defsubr (&Ssyntax_table); defsubr (&Sstandard_syntax_table); defsubr (&Scopy_syntax_table); defsubr (&Sset_syntax_table); defsubr (&Schar_syntax); defsubr (&Smatching_paren); defsubr (&Sstring_to_syntax); defsubr (&Smodify_syntax_entry); defsubr (&Sinternal_describe_syntax_value); defsubr (&Sforward_word); defsubr (&Sskip_chars_forward); defsubr (&Sskip_chars_backward); defsubr (&Sskip_syntax_forward); defsubr (&Sskip_syntax_backward); defsubr (&Sforward_comment); defsubr (&Sscan_lists); defsubr (&Sscan_sexps); defsubr (&Sbackward_prefix_chars); defsubr (&Sparse_partial_sexp); }