/* Lisp parsing and input streams. Copyright (C) 1985-1989, 1993-1995, 1997-2013 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 #include #include #include #include #include /* For CHAR_BIT. */ #include #include "lisp.h" #include "intervals.h" #include "character.h" #include "buffer.h" #include "charset.h" #include "coding.h" #include #include "commands.h" #include "keyboard.h" #include "frame.h" #include "termhooks.h" #include "coding.h" #include "blockinput.h" #ifdef MSDOS #include "msdos.h" #endif #ifdef HAVE_NS #include "nsterm.h" #endif #include #ifdef HAVE_SETLOCALE #include #endif /* HAVE_SETLOCALE */ #include #ifdef HAVE_FSEEKO #define file_offset off_t #define file_tell ftello #else #define file_offset long #define file_tell ftell #endif /* Hash table read constants. */ static Lisp_Object Qhash_table, Qdata; static Lisp_Object Qtest, Qsize; static Lisp_Object Qweakness; static Lisp_Object Qrehash_size; static Lisp_Object Qrehash_threshold; static Lisp_Object Qread_char, Qget_file_char, Qcurrent_load_list; Lisp_Object Qstandard_input; Lisp_Object Qvariable_documentation; static Lisp_Object Qascii_character, Qload, Qload_file_name; Lisp_Object Qbackquote, Qcomma, Qcomma_at, Qcomma_dot, Qfunction; static Lisp_Object Qinhibit_file_name_operation; static Lisp_Object Qeval_buffer_list; Lisp_Object Qlexical_binding; static Lisp_Object Qfile_truename, Qdo_after_load_evaluation; /* ACM 2006/5/16 */ /* Used instead of Qget_file_char while loading *.elc files compiled by Emacs 21 or older. */ static Lisp_Object Qget_emacs_mule_file_char; static Lisp_Object Qload_force_doc_strings; static Lisp_Object Qload_in_progress; /* The association list of objects read with the #n=object form. Each member of the list has the form (n . object), and is used to look up the object for the corresponding #n# construct. It must be set to nil before all top-level calls to read0. */ static Lisp_Object read_objects; /* True means READCHAR should read bytes one by one (not character) when READCHARFUN is Qget_file_char or Qget_emacs_mule_file_char. This is set by read1 temporarily while handling #@NUMBER. */ static bool load_each_byte; /* List of descriptors now open for Fload. */ static Lisp_Object load_descriptor_list; /* File for get_file_char to read from. Use by load. */ static FILE *instream; /* For use within read-from-string (this reader is non-reentrant!!) */ static ptrdiff_t read_from_string_index; static ptrdiff_t read_from_string_index_byte; static ptrdiff_t read_from_string_limit; /* Number of characters read in the current call to Fread or Fread_from_string. */ static EMACS_INT readchar_count; /* This contains the last string skipped with #@. */ static char *saved_doc_string; /* Length of buffer allocated in saved_doc_string. */ static ptrdiff_t saved_doc_string_size; /* Length of actual data in saved_doc_string. */ static ptrdiff_t saved_doc_string_length; /* This is the file position that string came from. */ static file_offset saved_doc_string_position; /* This contains the previous string skipped with #@. We copy it from saved_doc_string when a new string is put in saved_doc_string. */ static char *prev_saved_doc_string; /* Length of buffer allocated in prev_saved_doc_string. */ static ptrdiff_t prev_saved_doc_string_size; /* Length of actual data in prev_saved_doc_string. */ static ptrdiff_t prev_saved_doc_string_length; /* This is the file position that string came from. */ static file_offset prev_saved_doc_string_position; /* True means inside a new-style backquote with no surrounding parentheses. Fread initializes this to false, so we need not specbind it or worry about what happens to it when there is an error. */ static bool new_backquote_flag; static Lisp_Object Qold_style_backquotes; /* A list of file names for files being loaded in Fload. Used to check for recursive loads. */ static Lisp_Object Vloads_in_progress; static int read_emacs_mule_char (int, int (*) (int, Lisp_Object), Lisp_Object); static void readevalloop (Lisp_Object, FILE *, Lisp_Object, bool, Lisp_Object, Lisp_Object, Lisp_Object, Lisp_Object); static Lisp_Object load_unwind (Lisp_Object); static Lisp_Object load_descriptor_unwind (Lisp_Object); /* Functions that read one byte from the current source READCHARFUN or unreads one byte. If the integer argument C is -1, it returns one read byte, or -1 when there's no more byte in the source. If C is 0 or positive, it unreads C, and the return value is not interesting. */ static int readbyte_for_lambda (int, Lisp_Object); static int readbyte_from_file (int, Lisp_Object); static int readbyte_from_string (int, Lisp_Object); /* Handle unreading and rereading of characters. Write READCHAR to read a character, UNREAD(c) to unread c to be read again. These macros correctly read/unread multibyte characters. */ #define READCHAR readchar (readcharfun, NULL) #define UNREAD(c) unreadchar (readcharfun, c) /* Same as READCHAR but set *MULTIBYTE to the multibyteness of the source. */ #define READCHAR_REPORT_MULTIBYTE(multibyte) readchar (readcharfun, multibyte) /* When READCHARFUN is Qget_file_char, Qget_emacs_mule_file_char, Qlambda, or a cons, we use this to keep an unread character because a file stream can't handle multibyte-char unreading. The value -1 means that there's no unread character. */ static int unread_char; static int readchar (Lisp_Object readcharfun, bool *multibyte) { Lisp_Object tem; register int c; int (*readbyte) (int, Lisp_Object); unsigned char buf[MAX_MULTIBYTE_LENGTH]; int i, len; bool emacs_mule_encoding = 0; if (multibyte) *multibyte = 0; readchar_count++; if (BUFFERP (readcharfun)) { register struct buffer *inbuffer = XBUFFER (readcharfun); ptrdiff_t pt_byte = BUF_PT_BYTE (inbuffer); if (pt_byte >= BUF_ZV_BYTE (inbuffer)) return -1; if (! NILP (BVAR (inbuffer, enable_multibyte_characters))) { /* Fetch the character code from the buffer. */ unsigned char *p = BUF_BYTE_ADDRESS (inbuffer, pt_byte); BUF_INC_POS (inbuffer, pt_byte); c = STRING_CHAR (p); if (multibyte) *multibyte = 1; } else { c = BUF_FETCH_BYTE (inbuffer, pt_byte); if (! ASCII_BYTE_P (c)) c = BYTE8_TO_CHAR (c); pt_byte++; } SET_BUF_PT_BOTH (inbuffer, BUF_PT (inbuffer) + 1, pt_byte); return c; } if (MARKERP (readcharfun)) { register struct buffer *inbuffer = XMARKER (readcharfun)->buffer; ptrdiff_t bytepos = marker_byte_position (readcharfun); if (bytepos >= BUF_ZV_BYTE (inbuffer)) return -1; if (! NILP (BVAR (inbuffer, enable_multibyte_characters))) { /* Fetch the character code from the buffer. */ unsigned char *p = BUF_BYTE_ADDRESS (inbuffer, bytepos); BUF_INC_POS (inbuffer, bytepos); c = STRING_CHAR (p); if (multibyte) *multibyte = 1; } else { c = BUF_FETCH_BYTE (inbuffer, bytepos); if (! ASCII_BYTE_P (c)) c = BYTE8_TO_CHAR (c); bytepos++; } XMARKER (readcharfun)->bytepos = bytepos; XMARKER (readcharfun)->charpos++; return c; } if (EQ (readcharfun, Qlambda)) { readbyte = readbyte_for_lambda; goto read_multibyte; } if (EQ (readcharfun, Qget_file_char)) { readbyte = readbyte_from_file; goto read_multibyte; } if (STRINGP (readcharfun)) { if (read_from_string_index >= read_from_string_limit) c = -1; else if (STRING_MULTIBYTE (readcharfun)) { if (multibyte) *multibyte = 1; FETCH_STRING_CHAR_ADVANCE_NO_CHECK (c, readcharfun, read_from_string_index, read_from_string_index_byte); } else { c = SREF (readcharfun, read_from_string_index_byte); read_from_string_index++; read_from_string_index_byte++; } return c; } if (CONSP (readcharfun)) { /* This is the case that read_vector is reading from a unibyte string that contains a byte sequence previously skipped because of #@NUMBER. The car part of readcharfun is that string, and the cdr part is a value of readcharfun given to read_vector. */ readbyte = readbyte_from_string; if (EQ (XCDR (readcharfun), Qget_emacs_mule_file_char)) emacs_mule_encoding = 1; goto read_multibyte; } if (EQ (readcharfun, Qget_emacs_mule_file_char)) { readbyte = readbyte_from_file; emacs_mule_encoding = 1; goto read_multibyte; } tem = call0 (readcharfun); if (NILP (tem)) return -1; return XINT (tem); read_multibyte: if (unread_char >= 0) { c = unread_char; unread_char = -1; return c; } c = (*readbyte) (-1, readcharfun); if (c < 0 || load_each_byte) return c; if (multibyte) *multibyte = 1; if (ASCII_BYTE_P (c)) return c; if (emacs_mule_encoding) return read_emacs_mule_char (c, readbyte, readcharfun); i = 0; buf[i++] = c; len = BYTES_BY_CHAR_HEAD (c); while (i < len) { c = (*readbyte) (-1, readcharfun); if (c < 0 || ! TRAILING_CODE_P (c)) { while (--i > 1) (*readbyte) (buf[i], readcharfun); return BYTE8_TO_CHAR (buf[0]); } buf[i++] = c; } return STRING_CHAR (buf); } /* Unread the character C in the way appropriate for the stream READCHARFUN. If the stream is a user function, call it with the char as argument. */ static void unreadchar (Lisp_Object readcharfun, int c) { readchar_count--; if (c == -1) /* Don't back up the pointer if we're unreading the end-of-input mark, since readchar didn't advance it when we read it. */ ; else if (BUFFERP (readcharfun)) { struct buffer *b = XBUFFER (readcharfun); ptrdiff_t charpos = BUF_PT (b); ptrdiff_t bytepos = BUF_PT_BYTE (b); if (! NILP (BVAR (b, enable_multibyte_characters))) BUF_DEC_POS (b, bytepos); else bytepos--; SET_BUF_PT_BOTH (b, charpos - 1, bytepos); } else if (MARKERP (readcharfun)) { struct buffer *b = XMARKER (readcharfun)->buffer; ptrdiff_t bytepos = XMARKER (readcharfun)->bytepos; XMARKER (readcharfun)->charpos--; if (! NILP (BVAR (b, enable_multibyte_characters))) BUF_DEC_POS (b, bytepos); else bytepos--; XMARKER (readcharfun)->bytepos = bytepos; } else if (STRINGP (readcharfun)) { read_from_string_index--; read_from_string_index_byte = string_char_to_byte (readcharfun, read_from_string_index); } else if (CONSP (readcharfun)) { unread_char = c; } else if (EQ (readcharfun, Qlambda)) { unread_char = c; } else if (EQ (readcharfun, Qget_file_char) || EQ (readcharfun, Qget_emacs_mule_file_char)) { if (load_each_byte) { block_input (); ungetc (c, instream); unblock_input (); } else unread_char = c; } else call1 (readcharfun, make_number (c)); } static int readbyte_for_lambda (int c, Lisp_Object readcharfun) { return read_bytecode_char (c >= 0); } static int readbyte_from_file (int c, Lisp_Object readcharfun) { if (c >= 0) { block_input (); ungetc (c, instream); unblock_input (); return 0; } block_input (); c = getc (instream); #ifdef EINTR /* Interrupted reads have been observed while reading over the network. */ while (c == EOF && ferror (instream) && errno == EINTR) { unblock_input (); QUIT; block_input (); clearerr (instream); c = getc (instream); } #endif unblock_input (); return (c == EOF ? -1 : c); } static int readbyte_from_string (int c, Lisp_Object readcharfun) { Lisp_Object string = XCAR (readcharfun); if (c >= 0) { read_from_string_index--; read_from_string_index_byte = string_char_to_byte (string, read_from_string_index); } if (read_from_string_index >= read_from_string_limit) c = -1; else FETCH_STRING_CHAR_ADVANCE (c, string, read_from_string_index, read_from_string_index_byte); return c; } /* Read one non-ASCII character from INSTREAM. The character is encoded in `emacs-mule' and the first byte is already read in C. */ static int read_emacs_mule_char (int c, int (*readbyte) (int, Lisp_Object), Lisp_Object readcharfun) { /* Emacs-mule coding uses at most 4-byte for one character. */ unsigned char buf[4]; int len = emacs_mule_bytes[c]; struct charset *charset; int i; unsigned code; if (len == 1) /* C is not a valid leading-code of `emacs-mule'. */ return BYTE8_TO_CHAR (c); i = 0; buf[i++] = c; while (i < len) { c = (*readbyte) (-1, readcharfun); if (c < 0xA0) { while (--i > 1) (*readbyte) (buf[i], readcharfun); return BYTE8_TO_CHAR (buf[0]); } buf[i++] = c; } if (len == 2) { charset = CHARSET_FROM_ID (emacs_mule_charset[buf[0]]); code = buf[1] & 0x7F; } else if (len == 3) { if (buf[0] == EMACS_MULE_LEADING_CODE_PRIVATE_11 || buf[0] == EMACS_MULE_LEADING_CODE_PRIVATE_12) { charset = CHARSET_FROM_ID (emacs_mule_charset[buf[1]]); code = buf[2] & 0x7F; } else { charset = CHARSET_FROM_ID (emacs_mule_charset[buf[0]]); code = ((buf[1] << 8) | buf[2]) & 0x7F7F; } } else { charset = CHARSET_FROM_ID (emacs_mule_charset[buf[1]]); code = ((buf[2] << 8) | buf[3]) & 0x7F7F; } c = DECODE_CHAR (charset, code); if (c < 0) Fsignal (Qinvalid_read_syntax, Fcons (build_string ("invalid multibyte form"), Qnil)); return c; } static Lisp_Object read_internal_start (Lisp_Object, Lisp_Object, Lisp_Object); static Lisp_Object read0 (Lisp_Object); static Lisp_Object read1 (Lisp_Object, int *, bool); static Lisp_Object read_list (bool, Lisp_Object); static Lisp_Object read_vector (Lisp_Object, bool); static Lisp_Object substitute_object_recurse (Lisp_Object, Lisp_Object, Lisp_Object); static void substitute_object_in_subtree (Lisp_Object, Lisp_Object); static void substitute_in_interval (INTERVAL, Lisp_Object); /* Get a character from the tty. */ /* Read input events until we get one that's acceptable for our purposes. If NO_SWITCH_FRAME, switch-frame events are stashed until we get a character we like, and then stuffed into unread_switch_frame. If ASCII_REQUIRED, check function key events to see if the unmodified version of the symbol has a Qascii_character property, and use that character, if present. If ERROR_NONASCII, signal an error if the input we get isn't an ASCII character with modifiers. If it's false but ASCII_REQUIRED is true, just re-read until we get an ASCII character. If INPUT_METHOD, invoke the current input method if the character warrants that. If SECONDS is a number, wait that many seconds for input, and return Qnil if no input arrives within that time. */ static Lisp_Object read_filtered_event (bool no_switch_frame, bool ascii_required, bool error_nonascii, bool input_method, Lisp_Object seconds) { Lisp_Object val, delayed_switch_frame; EMACS_TIME end_time; #ifdef HAVE_WINDOW_SYSTEM if (display_hourglass_p) cancel_hourglass (); #endif delayed_switch_frame = Qnil; /* Compute timeout. */ if (NUMBERP (seconds)) { double duration = extract_float (seconds); EMACS_TIME wait_time = EMACS_TIME_FROM_DOUBLE (duration); end_time = add_emacs_time (current_emacs_time (), wait_time); } /* Read until we get an acceptable event. */ retry: do val = read_char (0, 0, 0, (input_method ? Qnil : Qt), 0, NUMBERP (seconds) ? &end_time : NULL); while (INTEGERP (val) && XINT (val) == -2); /* wrong_kboard_jmpbuf */ if (BUFFERP (val)) goto retry; /* switch-frame events are put off until after the next ASCII character. This is better than signaling an error just because the last characters were typed to a separate minibuffer frame, for example. Eventually, some code which can deal with switch-frame events will read it and process it. */ if (no_switch_frame && EVENT_HAS_PARAMETERS (val) && EQ (EVENT_HEAD_KIND (EVENT_HEAD (val)), Qswitch_frame)) { delayed_switch_frame = val; goto retry; } if (ascii_required && !(NUMBERP (seconds) && NILP (val))) { /* Convert certain symbols to their ASCII equivalents. */ if (SYMBOLP (val)) { Lisp_Object tem, tem1; tem = Fget (val, Qevent_symbol_element_mask); if (!NILP (tem)) { tem1 = Fget (Fcar (tem), Qascii_character); /* Merge this symbol's modifier bits with the ASCII equivalent of its basic code. */ if (!NILP (tem1)) XSETFASTINT (val, XINT (tem1) | XINT (Fcar (Fcdr (tem)))); } } /* If we don't have a character now, deal with it appropriately. */ if (!INTEGERP (val)) { if (error_nonascii) { Vunread_command_events = Fcons (val, Qnil); error ("Non-character input-event"); } else goto retry; } } if (! NILP (delayed_switch_frame)) unread_switch_frame = delayed_switch_frame; #if 0 #ifdef HAVE_WINDOW_SYSTEM if (display_hourglass_p) start_hourglass (); #endif #endif return val; } DEFUN ("read-char", Fread_char, Sread_char, 0, 3, 0, doc: /* Read a character from the command input (keyboard or macro). It is returned as a number. If the character has modifiers, they are resolved and reflected to the character code if possible (e.g. C-SPC -> 0). If the user generates an event which is not a character (i.e. a mouse click or function key event), `read-char' signals an error. As an exception, switch-frame events are put off until non-character events can be read. If you want to read non-character events, or ignore them, call `read-event' or `read-char-exclusive' instead. If the optional argument PROMPT is non-nil, display that as a prompt. If the optional argument INHERIT-INPUT-METHOD is non-nil and some input method is turned on in the current buffer, that input method is used for reading a character. If the optional argument SECONDS is non-nil, it should be a number specifying the maximum number of seconds to wait for input. If no input arrives in that time, return nil. SECONDS may be a floating-point value. */) (Lisp_Object prompt, Lisp_Object inherit_input_method, Lisp_Object seconds) { Lisp_Object val; if (! NILP (prompt)) message_with_string ("%s", prompt, 0); val = read_filtered_event (1, 1, 1, ! NILP (inherit_input_method), seconds); return (NILP (val) ? Qnil : make_number (char_resolve_modifier_mask (XINT (val)))); } DEFUN ("read-event", Fread_event, Sread_event, 0, 3, 0, doc: /* Read an event object from the input stream. If the optional argument PROMPT is non-nil, display that as a prompt. If the optional argument INHERIT-INPUT-METHOD is non-nil and some input method is turned on in the current buffer, that input method is used for reading a character. If the optional argument SECONDS is non-nil, it should be a number specifying the maximum number of seconds to wait for input. If no input arrives in that time, return nil. SECONDS may be a floating-point value. */) (Lisp_Object prompt, Lisp_Object inherit_input_method, Lisp_Object seconds) { if (! NILP (prompt)) message_with_string ("%s", prompt, 0); return read_filtered_event (0, 0, 0, ! NILP (inherit_input_method), seconds); } DEFUN ("read-char-exclusive", Fread_char_exclusive, Sread_char_exclusive, 0, 3, 0, doc: /* Read a character from the command input (keyboard or macro). It is returned as a number. Non-character events are ignored. If the character has modifiers, they are resolved and reflected to the character code if possible (e.g. C-SPC -> 0). If the optional argument PROMPT is non-nil, display that as a prompt. If the optional argument INHERIT-INPUT-METHOD is non-nil and some input method is turned on in the current buffer, that input method is used for reading a character. If the optional argument SECONDS is non-nil, it should be a number specifying the maximum number of seconds to wait for input. If no input arrives in that time, return nil. SECONDS may be a floating-point value. */) (Lisp_Object prompt, Lisp_Object inherit_input_method, Lisp_Object seconds) { Lisp_Object val; if (! NILP (prompt)) message_with_string ("%s", prompt, 0); val = read_filtered_event (1, 1, 0, ! NILP (inherit_input_method), seconds); return (NILP (val) ? Qnil : make_number (char_resolve_modifier_mask (XINT (val)))); } DEFUN ("get-file-char", Fget_file_char, Sget_file_char, 0, 0, 0, doc: /* Don't use this yourself. */) (void) { register Lisp_Object val; block_input (); XSETINT (val, getc (instream)); unblock_input (); return val; } /* Return true if the lisp code read using READCHARFUN defines a non-nil `lexical-binding' file variable. After returning, the stream is positioned following the first line, if it is a comment or #! line, otherwise nothing is read. */ static bool lisp_file_lexically_bound_p (Lisp_Object readcharfun) { int ch = READCHAR; if (ch == '#') { ch = READCHAR; if (ch != '!') { UNREAD (ch); UNREAD ('#'); return 0; } while (ch != '\n' && ch != EOF) ch = READCHAR; if (ch == '\n') ch = READCHAR; /* It is OK to leave the position after a #! line, since that is what read1 does. */ } if (ch != ';') /* The first line isn't a comment, just give up. */ { UNREAD (ch); return 0; } else /* Look for an appropriate file-variable in the first line. */ { bool rv = 0; enum { NOMINAL, AFTER_FIRST_DASH, AFTER_ASTERIX, } beg_end_state = NOMINAL; bool in_file_vars = 0; #define UPDATE_BEG_END_STATE(ch) \ if (beg_end_state == NOMINAL) \ beg_end_state = (ch == '-' ? AFTER_FIRST_DASH : NOMINAL); \ else if (beg_end_state == AFTER_FIRST_DASH) \ beg_end_state = (ch == '*' ? AFTER_ASTERIX : NOMINAL); \ else if (beg_end_state == AFTER_ASTERIX) \ { \ if (ch == '-') \ in_file_vars = !in_file_vars; \ beg_end_state = NOMINAL; \ } /* Skip until we get to the file vars, if any. */ do { ch = READCHAR; UPDATE_BEG_END_STATE (ch); } while (!in_file_vars && ch != '\n' && ch != EOF); while (in_file_vars) { char var[100], val[100]; unsigned i; ch = READCHAR; /* Read a variable name. */ while (ch == ' ' || ch == '\t') ch = READCHAR; i = 0; while (ch != ':' && ch != '\n' && ch != EOF && in_file_vars) { if (i < sizeof var - 1) var[i++] = ch; UPDATE_BEG_END_STATE (ch); ch = READCHAR; } /* Stop scanning if no colon was found before end marker. */ if (!in_file_vars || ch == '\n' || ch == EOF) break; while (i > 0 && (var[i - 1] == ' ' || var[i - 1] == '\t')) i--; var[i] = '\0'; if (ch == ':') { /* Read a variable value. */ ch = READCHAR; while (ch == ' ' || ch == '\t') ch = READCHAR; i = 0; while (ch != ';' && ch != '\n' && ch != EOF && in_file_vars) { if (i < sizeof val - 1) val[i++] = ch; UPDATE_BEG_END_STATE (ch); ch = READCHAR; } if (! in_file_vars) /* The value was terminated by an end-marker, which remove. */ i -= 3; while (i > 0 && (val[i - 1] == ' ' || val[i - 1] == '\t')) i--; val[i] = '\0'; if (strcmp (var, "lexical-binding") == 0) /* This is it... */ { rv = (strcmp (val, "nil") != 0); break; } } } while (ch != '\n' && ch != EOF) ch = READCHAR; return rv; } } /* Value is a version number of byte compiled code if the file associated with file descriptor FD is a compiled Lisp file that's safe to load. Only files compiled with Emacs are safe to load. Files compiled with XEmacs can lead to a crash in Fbyte_code because of an incompatible change in the byte compiler. */ static int safe_to_load_version (int fd) { char buf[512]; int nbytes, i; int version = 1; /* Read the first few bytes from the file, and look for a line specifying the byte compiler version used. */ nbytes = emacs_read (fd, buf, sizeof buf); if (nbytes > 0) { /* Skip to the next newline, skipping over the initial `ELC' with NUL bytes following it, but note the version. */ for (i = 0; i < nbytes && buf[i] != '\n'; ++i) if (i == 4) version = buf[i]; if (i >= nbytes || fast_c_string_match_ignore_case (Vbytecomp_version_regexp, buf + i, nbytes - i) < 0) version = 0; } lseek (fd, 0, SEEK_SET); return version; } /* Callback for record_unwind_protect. Restore the old load list OLD, after loading a file successfully. */ static Lisp_Object record_load_unwind (Lisp_Object old) { return Vloads_in_progress = old; } /* This handler function is used via internal_condition_case_1. */ static Lisp_Object load_error_handler (Lisp_Object data) { return Qnil; } static Lisp_Object load_warn_old_style_backquotes (Lisp_Object file) { if (!NILP (Vold_style_backquotes)) { Lisp_Object args[2]; args[0] = build_string ("Loading `%s': old-style backquotes detected!"); args[1] = file; Fmessage (2, args); } return Qnil; } DEFUN ("get-load-suffixes", Fget_load_suffixes, Sget_load_suffixes, 0, 0, 0, doc: /* Return the suffixes that `load' should try if a suffix is \ required. This uses the variables `load-suffixes' and `load-file-rep-suffixes'. */) (void) { Lisp_Object lst = Qnil, suffixes = Vload_suffixes, suffix, ext; while (CONSP (suffixes)) { Lisp_Object exts = Vload_file_rep_suffixes; suffix = XCAR (suffixes); suffixes = XCDR (suffixes); while (CONSP (exts)) { ext = XCAR (exts); exts = XCDR (exts); lst = Fcons (concat2 (suffix, ext), lst); } } return Fnreverse (lst); } DEFUN ("load", Fload, Sload, 1, 5, 0, doc: /* Execute a file of Lisp code named FILE. First try FILE with `.elc' appended, then try with `.el', then try FILE unmodified (the exact suffixes in the exact order are determined by `load-suffixes'). Environment variable references in FILE are replaced with their values by calling `substitute-in-file-name'. This function searches the directories in `load-path'. If optional second arg NOERROR is non-nil, report no error if FILE doesn't exist. Print messages at start and end of loading unless optional third arg NOMESSAGE is non-nil (but `force-load-messages' overrides that). If optional fourth arg NOSUFFIX is non-nil, don't try adding suffixes `.elc' or `.el' to the specified name FILE. If optional fifth arg MUST-SUFFIX is non-nil, insist on the suffix `.elc' or `.el'; don't accept just FILE unless it ends in one of those suffixes or includes a directory name. If NOSUFFIX is nil, then if a file could not be found, try looking for a different representation of the file by adding non-empty suffixes to its name, before trying another file. Emacs uses this feature to find compressed versions of files when Auto Compression mode is enabled. If NOSUFFIX is non-nil, disable this feature. The suffixes that this function tries out, when NOSUFFIX is nil, are given by the return value of `get-load-suffixes' and the values listed in `load-file-rep-suffixes'. If MUST-SUFFIX is non-nil, only the return value of `get-load-suffixes' is used, i.e. the file name is required to have a non-empty suffix. Loading a file records its definitions, and its `provide' and `require' calls, in an element of `load-history' whose car is the file name loaded. See `load-history'. While the file is in the process of being loaded, the variable `load-in-progress' is non-nil and the variable `load-file-name' is bound to the file's name. Return t if the file exists and loads successfully. */) (Lisp_Object file, Lisp_Object noerror, Lisp_Object nomessage, Lisp_Object nosuffix, Lisp_Object must_suffix) { register FILE *stream; register int fd = -1; ptrdiff_t count = SPECPDL_INDEX (); struct gcpro gcpro1, gcpro2, gcpro3; Lisp_Object found, efound, hist_file_name; /* True means we printed the ".el is newer" message. */ bool newer = 0; /* True means we are loading a compiled file. */ bool compiled = 0; Lisp_Object handler; bool safe_p = 1; const char *fmode = "r"; Lisp_Object tmp[2]; int version; #ifdef DOS_NT fmode = "rt"; #endif /* DOS_NT */ CHECK_STRING (file); /* If file name is magic, call the handler. */ /* This shouldn't be necessary any more now that `openp' handles it right. handler = Ffind_file_name_handler (file, Qload); if (!NILP (handler)) return call5 (handler, Qload, file, noerror, nomessage, nosuffix); */ /* Do this after the handler to avoid the need to gcpro noerror, nomessage and nosuffix. (Below here, we care only whether they are nil or not.) The presence of this call is the result of a historical accident: it used to be in every file-operation and when it got removed everywhere, it accidentally stayed here. Since then, enough people supposedly have things like (load "$PROJECT/foo.el") in their .emacs that it seemed risky to remove. */ if (! NILP (noerror)) { file = internal_condition_case_1 (Fsubstitute_in_file_name, file, Qt, load_error_handler); if (NILP (file)) return Qnil; } else file = Fsubstitute_in_file_name (file); /* Avoid weird lossage with null string as arg, since it would try to load a directory as a Lisp file. */ if (SBYTES (file) > 0) { ptrdiff_t size = SBYTES (file); found = Qnil; GCPRO2 (file, found); if (! NILP (must_suffix)) { /* Don't insist on adding a suffix if FILE already ends with one. */ if (size > 3 && !strcmp (SSDATA (file) + size - 3, ".el")) must_suffix = Qnil; else if (size > 4 && !strcmp (SSDATA (file) + size - 4, ".elc")) must_suffix = Qnil; /* Don't insist on adding a suffix if the argument includes a directory name. */ else if (! NILP (Ffile_name_directory (file))) must_suffix = Qnil; } fd = openp (Vload_path, file, (!NILP (nosuffix) ? Qnil : !NILP (must_suffix) ? Fget_load_suffixes () : Fappend (2, (tmp[0] = Fget_load_suffixes (), tmp[1] = Vload_file_rep_suffixes, tmp))), &found, Qnil); UNGCPRO; } if (fd == -1) { if (NILP (noerror)) xsignal2 (Qfile_error, build_string ("Cannot open load file"), file); return Qnil; } /* Tell startup.el whether or not we found the user's init file. */ if (EQ (Qt, Vuser_init_file)) Vuser_init_file = found; /* If FD is -2, that means openp found a magic file. */ if (fd == -2) { if (NILP (Fequal (found, file))) /* If FOUND is a different file name from FILE, find its handler even if we have already inhibited the `load' operation on FILE. */ handler = Ffind_file_name_handler (found, Qt); else handler = Ffind_file_name_handler (found, Qload); if (! NILP (handler)) return call5 (handler, Qload, found, noerror, nomessage, Qt); #ifdef DOS_NT /* Tramp has to deal with semi-broken packages that prepend drive letters to remote files. For that reason, Tramp catches file operations that test for file existence, which makes openp think X:/foo.elc files are remote. However, Tramp does not catch `load' operations for such files, so we end up with a nil as the `load' handler above. If we would continue with fd = -2, we will behave wrongly, and in particular try reading a .elc file in the "rt" mode instead of "rb". See bug #9311 for the results. To work around this, we try to open the file locally, and go with that if it succeeds. */ fd = emacs_open (SSDATA (ENCODE_FILE (found)), O_RDONLY, 0); if (fd == -1) fd = -2; #endif } /* Check if we're stuck in a recursive load cycle. 2000-09-21: It's not possible to just check for the file loaded being a member of Vloads_in_progress. This fails because of the way the byte compiler currently works; `provide's are not evaluated, see font-lock.el/jit-lock.el as an example. This leads to a certain amount of ``normal'' recursion. Also, just loading a file recursively is not always an error in the general case; the second load may do something different. */ { int load_count = 0; Lisp_Object tem; for (tem = Vloads_in_progress; CONSP (tem); tem = XCDR (tem)) if (!NILP (Fequal (found, XCAR (tem))) && (++load_count > 3)) { if (fd >= 0) emacs_close (fd); signal_error ("Recursive load", Fcons (found, Vloads_in_progress)); } record_unwind_protect (record_load_unwind, Vloads_in_progress); Vloads_in_progress = Fcons (found, Vloads_in_progress); } /* All loads are by default dynamic, unless the file itself specifies otherwise using a file-variable in the first line. This is bound here so that it takes effect whether or not we use Vload_source_file_function. */ specbind (Qlexical_binding, Qnil); /* Get the name for load-history. */ hist_file_name = (! NILP (Vpurify_flag) ? Fconcat (2, (tmp[0] = Ffile_name_directory (file), tmp[1] = Ffile_name_nondirectory (found), tmp)) : found) ; version = -1; /* Check for the presence of old-style quotes and warn about them. */ specbind (Qold_style_backquotes, Qnil); record_unwind_protect (load_warn_old_style_backquotes, file); if (!memcmp (SDATA (found) + SBYTES (found) - 4, ".elc", 4) || (fd >= 0 && (version = safe_to_load_version (fd)) > 0)) /* Load .elc files directly, but not when they are remote and have no handler! */ { if (fd != -2) { struct stat s1, s2; int result; GCPRO3 (file, found, hist_file_name); if (version < 0 && ! (version = safe_to_load_version (fd))) { safe_p = 0; if (!load_dangerous_libraries) { if (fd >= 0) emacs_close (fd); error ("File `%s' was not compiled in Emacs", SDATA (found)); } else if (!NILP (nomessage) && !force_load_messages) message_with_string ("File `%s' not compiled in Emacs", found, 1); } compiled = 1; efound = ENCODE_FILE (found); #ifdef DOS_NT fmode = "rb"; #endif /* DOS_NT */ result = stat (SSDATA (efound), &s1); if (result == 0) { SSET (efound, SBYTES (efound) - 1, 0); result = stat (SSDATA (efound), &s2); SSET (efound, SBYTES (efound) - 1, 'c'); } if (result == 0 && EMACS_TIME_LT (get_stat_mtime (&s1), get_stat_mtime (&s2))) { /* Make the progress messages mention that source is newer. */ newer = 1; /* If we won't print another message, mention this anyway. */ if (!NILP (nomessage) && !force_load_messages) { Lisp_Object msg_file; msg_file = Fsubstring (found, make_number (0), make_number (-1)); message_with_string ("Source file `%s' newer than byte-compiled file", msg_file, 1); } } UNGCPRO; } } else { /* We are loading a source file (*.el). */ if (!NILP (Vload_source_file_function)) { Lisp_Object val; if (fd >= 0) emacs_close (fd); val = call4 (Vload_source_file_function, found, hist_file_name, NILP (noerror) ? Qnil : Qt, (NILP (nomessage) || force_load_messages) ? Qnil : Qt); return unbind_to (count, val); } } GCPRO3 (file, found, hist_file_name); #ifdef WINDOWSNT efound = ENCODE_FILE (found); /* If we somehow got here with fd == -2, meaning the file is deemed to be remote, don't even try to reopen the file locally; just force a failure instead. */ if (fd >= 0) { emacs_close (fd); stream = fopen (SSDATA (efound), fmode); } else stream = NULL; #else /* not WINDOWSNT */ stream = fdopen (fd, fmode); #endif /* not WINDOWSNT */ if (stream == 0) { emacs_close (fd); error ("Failure to create stdio stream for %s", SDATA (file)); } if (! NILP (Vpurify_flag)) Vpreloaded_file_list = Fcons (Fpurecopy (file), Vpreloaded_file_list); if (NILP (nomessage) || force_load_messages) { if (!safe_p) message_with_string ("Loading %s (compiled; note unsafe, not compiled in Emacs)...", file, 1); else if (!compiled) message_with_string ("Loading %s (source)...", file, 1); else if (newer) message_with_string ("Loading %s (compiled; note, source file is newer)...", file, 1); else /* The typical case; compiled file newer than source file. */ message_with_string ("Loading %s...", file, 1); } record_unwind_protect (load_unwind, make_save_value (stream, 0)); record_unwind_protect (load_descriptor_unwind, load_descriptor_list); specbind (Qload_file_name, found); specbind (Qinhibit_file_name_operation, Qnil); load_descriptor_list = Fcons (make_number (fileno (stream)), load_descriptor_list); specbind (Qload_in_progress, Qt); instream = stream; if (lisp_file_lexically_bound_p (Qget_file_char)) Fset (Qlexical_binding, Qt); if (! version || version >= 22) readevalloop (Qget_file_char, stream, hist_file_name, 0, Qnil, Qnil, Qnil, Qnil); else { /* We can't handle a file which was compiled with byte-compile-dynamic by older version of Emacs. */ specbind (Qload_force_doc_strings, Qt); readevalloop (Qget_emacs_mule_file_char, stream, hist_file_name, 0, Qnil, Qnil, Qnil, Qnil); } unbind_to (count, Qnil); /* Run any eval-after-load forms for this file. */ if (!NILP (Ffboundp (Qdo_after_load_evaluation))) call1 (Qdo_after_load_evaluation, hist_file_name) ; UNGCPRO; xfree (saved_doc_string); saved_doc_string = 0; saved_doc_string_size = 0; xfree (prev_saved_doc_string); prev_saved_doc_string = 0; prev_saved_doc_string_size = 0; if (!noninteractive && (NILP (nomessage) || force_load_messages)) { if (!safe_p) message_with_string ("Loading %s (compiled; note unsafe, not compiled in Emacs)...done", file, 1); else if (!compiled) message_with_string ("Loading %s (source)...done", file, 1); else if (newer) message_with_string ("Loading %s (compiled; note, source file is newer)...done", file, 1); else /* The typical case; compiled file newer than source file. */ message_with_string ("Loading %s...done", file, 1); } return Qt; } static Lisp_Object load_unwind (Lisp_Object arg) /* Used as unwind-protect function in load. */ { FILE *stream = (FILE *) XSAVE_VALUE (arg)->pointer; if (stream != NULL) { block_input (); fclose (stream); unblock_input (); } return Qnil; } static Lisp_Object load_descriptor_unwind (Lisp_Object oldlist) { load_descriptor_list = oldlist; return Qnil; } /* Close all descriptors in use for Floads. This is used when starting a subprocess. */ void close_load_descs (void) { #ifndef WINDOWSNT Lisp_Object tail; for (tail = load_descriptor_list; CONSP (tail); tail = XCDR (tail)) emacs_close (XFASTINT (XCAR (tail))); #endif } static bool complete_filename_p (Lisp_Object pathname) { const unsigned char *s = SDATA (pathname); return (IS_DIRECTORY_SEP (s[0]) || (SCHARS (pathname) > 2 && IS_DEVICE_SEP (s[1]) && IS_DIRECTORY_SEP (s[2]))); } DEFUN ("locate-file-internal", Flocate_file_internal, Slocate_file_internal, 2, 4, 0, doc: /* Search for FILENAME through PATH. Returns the file's name in absolute form, or nil if not found. If SUFFIXES is non-nil, it should be a list of suffixes to append to file name when searching. If non-nil, PREDICATE is used instead of `file-readable-p'. PREDICATE can also be an integer to pass to the access(2) function, in which case file-name-handlers are ignored. This function will normally skip directories, so if you want it to find directories, make sure the PREDICATE function returns `dir-ok' for them. */) (Lisp_Object filename, Lisp_Object path, Lisp_Object suffixes, Lisp_Object predicate) { Lisp_Object file; int fd = openp (path, filename, suffixes, &file, predicate); if (NILP (predicate) && fd > 0) close (fd); return file; } static Lisp_Object Qdir_ok; /* Search for a file whose name is STR, looking in directories in the Lisp list PATH, and trying suffixes from SUFFIX. On success, returns a file descriptor. On failure, returns -1. SUFFIXES is a list of strings containing possible suffixes. The empty suffix is automatically added if the list is empty. PREDICATE non-nil means don't open the files, just look for one that satisfies the predicate. In this case, returns 1 on success. The predicate can be a lisp function or an integer to pass to `access' (in which case file-name-handlers are ignored). If STOREPTR is nonzero, it points to a slot where the name of the file actually found should be stored as a Lisp string. nil is stored there on failure. If the file we find is remote, return -2 but store the found remote file name in *STOREPTR. */ int openp (Lisp_Object path, Lisp_Object str, Lisp_Object suffixes, Lisp_Object *storeptr, Lisp_Object predicate) { int fd; ptrdiff_t fn_size = 100; char buf[100]; char *fn = buf; bool absolute = 0; ptrdiff_t want_length; Lisp_Object filename; struct gcpro gcpro1, gcpro2, gcpro3, gcpro4, gcpro5, gcpro6; Lisp_Object string, tail, encoded_fn; ptrdiff_t max_suffix_len = 0; CHECK_STRING (str); for (tail = suffixes; CONSP (tail); tail = XCDR (tail)) { CHECK_STRING_CAR (tail); max_suffix_len = max (max_suffix_len, SBYTES (XCAR (tail))); } string = filename = encoded_fn = Qnil; GCPRO6 (str, string, filename, path, suffixes, encoded_fn); if (storeptr) *storeptr = Qnil; if (complete_filename_p (str)) absolute = 1; for (; CONSP (path); path = XCDR (path)) { filename = Fexpand_file_name (str, XCAR (path)); if (!complete_filename_p (filename)) /* If there are non-absolute elts in PATH (eg "."). */ /* Of course, this could conceivably lose if luser sets default-directory to be something non-absolute... */ { filename = Fexpand_file_name (filename, BVAR (current_buffer, directory)); if (!complete_filename_p (filename)) /* Give up on this path element! */ continue; } /* Calculate maximum length of any filename made from this path element/specified file name and any possible suffix. */ want_length = max_suffix_len + SBYTES (filename); if (fn_size <= want_length) fn = alloca (fn_size = 100 + want_length); /* Loop over suffixes. */ for (tail = NILP (suffixes) ? Fcons (empty_unibyte_string, Qnil) : suffixes; CONSP (tail); tail = XCDR (tail)) { ptrdiff_t fnlen, lsuffix = SBYTES (XCAR (tail)); Lisp_Object handler; bool exists; /* Concatenate path element/specified name with the suffix. If the directory starts with /:, remove that. */ int prefixlen = ((SCHARS (filename) > 2 && SREF (filename, 0) == '/' && SREF (filename, 1) == ':') ? 2 : 0); fnlen = SBYTES (filename) - prefixlen; memcpy (fn, SDATA (filename) + prefixlen, fnlen); memcpy (fn + fnlen, SDATA (XCAR (tail)), lsuffix + 1); fnlen += lsuffix; /* Check that the file exists and is not a directory. */ /* We used to only check for handlers on non-absolute file names: if (absolute) handler = Qnil; else handler = Ffind_file_name_handler (filename, Qfile_exists_p); It's not clear why that was the case and it breaks things like (load "/bar.el") where the file is actually "/bar.el.gz". */ string = make_string (fn, fnlen); handler = Ffind_file_name_handler (string, Qfile_exists_p); if ((!NILP (handler) || !NILP (predicate)) && !NATNUMP (predicate)) { if (NILP (predicate)) exists = !NILP (Ffile_readable_p (string)); else { Lisp_Object tmp = call1 (predicate, string); exists = !NILP (tmp) && (EQ (tmp, Qdir_ok) || NILP (Ffile_directory_p (string))); } if (exists) { /* We succeeded; return this descriptor and filename. */ if (storeptr) *storeptr = string; UNGCPRO; return -2; } } else { #ifndef WINDOWSNT struct stat st; #endif const char *pfn; encoded_fn = ENCODE_FILE (string); pfn = SSDATA (encoded_fn); #ifdef WINDOWSNT exists = access (pfn, F_OK) == 0 && access (pfn, D_OK) < 0; #else exists = (stat (pfn, &st) == 0 && ! S_ISDIR (st.st_mode)); #endif if (exists) { /* Check that we can access or open it. */ if (NATNUMP (predicate)) fd = (((XFASTINT (predicate) & ~INT_MAX) == 0 && access (pfn, XFASTINT (predicate)) == 0) ? 1 : -1); else fd = emacs_open (pfn, O_RDONLY, 0); if (fd >= 0) { /* We succeeded; return this descriptor and filename. */ if (storeptr) *storeptr = string; UNGCPRO; return fd; } } } } if (absolute) break; } UNGCPRO; return -1; } /* Merge the list we've accumulated of globals from the current input source into the load_history variable. The details depend on whether the source has an associated file name or not. FILENAME is the file name that we are loading from. ENTIRE is true if loading that entire file, false if evaluating part of it. */ static void build_load_history (Lisp_Object filename, bool entire) { Lisp_Object tail, prev, newelt; Lisp_Object tem, tem2; bool foundit = 0; tail = Vload_history; prev = Qnil; while (CONSP (tail)) { tem = XCAR (tail); /* Find the feature's previous assoc list... */ if (!NILP (Fequal (filename, Fcar (tem)))) { foundit = 1; /* If we're loading the entire file, remove old data. */ if (entire) { if (NILP (prev)) Vload_history = XCDR (tail); else Fsetcdr (prev, XCDR (tail)); } /* Otherwise, cons on new symbols that are not already members. */ else { tem2 = Vcurrent_load_list; while (CONSP (tem2)) { newelt = XCAR (tem2); if (NILP (Fmember (newelt, tem))) Fsetcar (tail, Fcons (XCAR (tem), Fcons (newelt, XCDR (tem)))); tem2 = XCDR (tem2); QUIT; } } } else prev = tail; tail = XCDR (tail); QUIT; } /* If we're loading an entire file, cons the new assoc onto the front of load-history, the most-recently-loaded position. Also do this if we didn't find an existing member for the file. */ if (entire || !foundit) Vload_history = Fcons (Fnreverse (Vcurrent_load_list), Vload_history); } static Lisp_Object readevalloop_1 (Lisp_Object old) { load_convert_to_unibyte = ! NILP (old); return Qnil; } /* Signal an `end-of-file' error, if possible with file name information. */ static _Noreturn void end_of_file_error (void) { if (STRINGP (Vload_file_name)) xsignal1 (Qend_of_file, Vload_file_name); xsignal0 (Qend_of_file); } /* UNIBYTE specifies how to set load_convert_to_unibyte for this invocation. READFUN, if non-nil, is used instead of `read'. START, END specify region to read in current buffer (from eval-region). If the input is not from a buffer, they must be nil. */ static void readevalloop (Lisp_Object readcharfun, FILE *stream, Lisp_Object sourcename, bool printflag, Lisp_Object unibyte, Lisp_Object readfun, Lisp_Object start, Lisp_Object end) { register int c; register Lisp_Object val; ptrdiff_t count = SPECPDL_INDEX (); struct gcpro gcpro1, gcpro2, gcpro3, gcpro4; struct buffer *b = 0; bool continue_reading_p; Lisp_Object lex_bound; /* True if reading an entire buffer. */ bool whole_buffer = 0; /* True on the first time around. */ bool first_sexp = 1; Lisp_Object macroexpand = intern ("internal-macroexpand-for-load"); if (NILP (Ffboundp (macroexpand)) /* Don't macroexpand in .elc files, since it should have been done already. We actually don't know whether we're in a .elc file or not, so we use circumstantial evidence: .el files normally go through Vload_source_file_function -> load-with-code-conversion -> eval-buffer. */ || EQ (readcharfun, Qget_file_char) || EQ (readcharfun, Qget_emacs_mule_file_char)) macroexpand = Qnil; if (MARKERP (readcharfun)) { if (NILP (start)) start = readcharfun; } if (BUFFERP (readcharfun)) b = XBUFFER (readcharfun); else if (MARKERP (readcharfun)) b = XMARKER (readcharfun)->buffer; /* We assume START is nil when input is not from a buffer. */ if (! NILP (start) && !b) emacs_abort (); specbind (Qstandard_input, readcharfun); /* GCPROs readcharfun. */ specbind (Qcurrent_load_list, Qnil); record_unwind_protect (readevalloop_1, load_convert_to_unibyte ? Qt : Qnil); load_convert_to_unibyte = !NILP (unibyte); /* If lexical binding is active (either because it was specified in the file's header, or via a buffer-local variable), create an empty lexical environment, otherwise, turn off lexical binding. */ lex_bound = find_symbol_value (Qlexical_binding); specbind (Qinternal_interpreter_environment, NILP (lex_bound) || EQ (lex_bound, Qunbound) ? Qnil : Fcons (Qt, Qnil)); GCPRO4 (sourcename, readfun, start, end); /* Try to ensure sourcename is a truename, except whilst preloading. */ if (NILP (Vpurify_flag) && !NILP (sourcename) && !NILP (Ffile_name_absolute_p (sourcename)) && !NILP (Ffboundp (Qfile_truename))) sourcename = call1 (Qfile_truename, sourcename) ; LOADHIST_ATTACH (sourcename); continue_reading_p = 1; while (continue_reading_p) { ptrdiff_t count1 = SPECPDL_INDEX (); if (b != 0 && !BUFFER_LIVE_P (b)) error ("Reading from killed buffer"); if (!NILP (start)) { /* Switch to the buffer we are reading from. */ record_unwind_protect (save_excursion_restore, save_excursion_save ()); set_buffer_internal (b); /* Save point in it. */ record_unwind_protect (save_excursion_restore, save_excursion_save ()); /* Save ZV in it. */ record_unwind_protect (save_restriction_restore, save_restriction_save ()); /* Those get unbound after we read one expression. */ /* Set point and ZV around stuff to be read. */ Fgoto_char (start); if (!NILP (end)) Fnarrow_to_region (make_number (BEGV), end); /* Just for cleanliness, convert END to a marker if it is an integer. */ if (INTEGERP (end)) end = Fpoint_max_marker (); } /* On the first cycle, we can easily test here whether we are reading the whole buffer. */ if (b && first_sexp) whole_buffer = (PT == BEG && ZV == Z); instream = stream; read_next: c = READCHAR; if (c == ';') { while ((c = READCHAR) != '\n' && c != -1); goto read_next; } if (c < 0) { unbind_to (count1, Qnil); break; } /* Ignore whitespace here, so we can detect eof. */ if (c == ' ' || c == '\t' || c == '\n' || c == '\f' || c == '\r' || c == 0xa0) /* NBSP */ goto read_next; if (!NILP (Vpurify_flag) && c == '(') { val = read_list (0, readcharfun); } else { UNREAD (c); read_objects = Qnil; if (!NILP (readfun)) { val = call1 (readfun, readcharfun); /* If READCHARFUN has set point to ZV, we should stop reading, even if the form read sets point to a different value when evaluated. */ if (BUFFERP (readcharfun)) { struct buffer *buf = XBUFFER (readcharfun); if (BUF_PT (buf) == BUF_ZV (buf)) continue_reading_p = 0; } } else if (! NILP (Vload_read_function)) val = call1 (Vload_read_function, readcharfun); else val = read_internal_start (readcharfun, Qnil, Qnil); } if (!NILP (start) && continue_reading_p) start = Fpoint_marker (); /* Restore saved point and BEGV. */ unbind_to (count1, Qnil); /* Now eval what we just read. */ if (!NILP (macroexpand)) val = call1 (macroexpand, val); val = eval_sub (val); if (printflag) { Vvalues = Fcons (val, Vvalues); if (EQ (Vstandard_output, Qt)) Fprin1 (val, Qnil); else Fprint (val, Qnil); } first_sexp = 0; } build_load_history (sourcename, stream || whole_buffer); UNGCPRO; unbind_to (count, Qnil); } DEFUN ("eval-buffer", Feval_buffer, Seval_buffer, 0, 5, "", doc: /* Execute the current buffer as Lisp code. When called from a Lisp program (i.e., not interactively), this function accepts up to five optional arguments: BUFFER is the buffer to evaluate (nil means use current buffer). PRINTFLAG controls printing of output: A value of nil means discard it; anything else is stream for print. FILENAME specifies the file name to use for `load-history'. UNIBYTE, if non-nil, specifies `load-convert-to-unibyte' for this invocation. DO-ALLOW-PRINT, if non-nil, specifies that `print' and related functions should work normally even if PRINTFLAG is nil. This function preserves the position of point. */) (Lisp_Object buffer, Lisp_Object printflag, Lisp_Object filename, Lisp_Object unibyte, Lisp_Object do_allow_print) { ptrdiff_t count = SPECPDL_INDEX (); Lisp_Object tem, buf; if (NILP (buffer)) buf = Fcurrent_buffer (); else buf = Fget_buffer (buffer); if (NILP (buf)) error ("No such buffer"); if (NILP (printflag) && NILP (do_allow_print)) tem = Qsymbolp; else tem = printflag; if (NILP (filename)) filename = BVAR (XBUFFER (buf), filename); specbind (Qeval_buffer_list, Fcons (buf, Veval_buffer_list)); specbind (Qstandard_output, tem); record_unwind_protect (save_excursion_restore, save_excursion_save ()); BUF_TEMP_SET_PT (XBUFFER (buf), BUF_BEGV (XBUFFER (buf))); specbind (Qlexical_binding, lisp_file_lexically_bound_p (buf) ? Qt : Qnil); readevalloop (buf, 0, filename, !NILP (printflag), unibyte, Qnil, Qnil, Qnil); unbind_to (count, Qnil); return Qnil; } DEFUN ("eval-region", Feval_region, Seval_region, 2, 4, "r", doc: /* Execute the region as Lisp code. When called from programs, expects two arguments, giving starting and ending indices in the current buffer of the text to be executed. Programs can pass third argument PRINTFLAG which controls output: A value of nil means discard it; anything else is stream for printing it. Also the fourth argument READ-FUNCTION, if non-nil, is used instead of `read' to read each expression. It gets one argument which is the input stream for reading characters. This function does not move point. */) (Lisp_Object start, Lisp_Object end, Lisp_Object printflag, Lisp_Object read_function) { /* FIXME: Do the eval-sexp-add-defvars dance! */ ptrdiff_t count = SPECPDL_INDEX (); Lisp_Object tem, cbuf; cbuf = Fcurrent_buffer (); if (NILP (printflag)) tem = Qsymbolp; else tem = printflag; specbind (Qstandard_output, tem); specbind (Qeval_buffer_list, Fcons (cbuf, Veval_buffer_list)); /* `readevalloop' calls functions which check the type of start and end. */ readevalloop (cbuf, 0, BVAR (XBUFFER (cbuf), filename), !NILP (printflag), Qnil, read_function, start, end); return unbind_to (count, Qnil); } DEFUN ("read", Fread, Sread, 0, 1, 0, doc: /* Read one Lisp expression as text from STREAM, return as Lisp object. If STREAM is nil, use the value of `standard-input' (which see). STREAM or the value of `standard-input' may be: a buffer (read from point and advance it) a marker (read from where it points and advance it) a function (call it with no arguments for each character, call it with a char as argument to push a char back) a string (takes text from string, starting at the beginning) t (read text line using minibuffer and use it, or read from standard input in batch mode). */) (Lisp_Object stream) { if (NILP (stream)) stream = Vstandard_input; if (EQ (stream, Qt)) stream = Qread_char; if (EQ (stream, Qread_char)) return Fread_minibuffer (build_string ("Lisp expression: "), Qnil); return read_internal_start (stream, Qnil, Qnil); } DEFUN ("read-from-string", Fread_from_string, Sread_from_string, 1, 3, 0, doc: /* Read one Lisp expression which is represented as text by STRING. Returns a cons: (OBJECT-READ . FINAL-STRING-INDEX). FINAL-STRING-INDEX is an integer giving the position of the next remaining character in STRING. START and END optionally delimit a substring of STRING from which to read; they default to 0 and (length STRING) respectively. */) (Lisp_Object string, Lisp_Object start, Lisp_Object end) { Lisp_Object ret; CHECK_STRING (string); /* `read_internal_start' sets `read_from_string_index'. */ ret = read_internal_start (string, start, end); return Fcons (ret, make_number (read_from_string_index)); } /* Function to set up the global context we need in toplevel read calls. */ static Lisp_Object read_internal_start (Lisp_Object stream, Lisp_Object start, Lisp_Object end) /* `start', `end' only used when stream is a string. */ { Lisp_Object retval; readchar_count = 0; new_backquote_flag = 0; read_objects = Qnil; if (EQ (Vread_with_symbol_positions, Qt) || EQ (Vread_with_symbol_positions, stream)) Vread_symbol_positions_list = Qnil; if (STRINGP (stream) || ((CONSP (stream) && STRINGP (XCAR (stream))))) { ptrdiff_t startval, endval; Lisp_Object string; if (STRINGP (stream)) string = stream; else string = XCAR (stream); if (NILP (end)) endval = SCHARS (string); else { CHECK_NUMBER (end); if (! (0 <= XINT (end) && XINT (end) <= SCHARS (string))) args_out_of_range (string, end); endval = XINT (end); } if (NILP (start)) startval = 0; else { CHECK_NUMBER (start); if (! (0 <= XINT (start) && XINT (start) <= endval)) args_out_of_range (string, start); startval = XINT (start); } read_from_string_index = startval; read_from_string_index_byte = string_char_to_byte (string, startval); read_from_string_limit = endval; } retval = read0 (stream); if (EQ (Vread_with_symbol_positions, Qt) || EQ (Vread_with_symbol_positions, stream)) Vread_symbol_positions_list = Fnreverse (Vread_symbol_positions_list); return retval; } /* Signal Qinvalid_read_syntax error. S is error string of length N (if > 0) */ static _Noreturn void invalid_syntax (const char *s) { xsignal1 (Qinvalid_read_syntax, build_string (s)); } /* Use this for recursive reads, in contexts where internal tokens are not allowed. */ static Lisp_Object read0 (Lisp_Object readcharfun) { register Lisp_Object val; int c; val = read1 (readcharfun, &c, 0); if (!c) return val; xsignal1 (Qinvalid_read_syntax, Fmake_string (make_number (1), make_number (c))); } static ptrdiff_t read_buffer_size; static char *read_buffer; /* Read a \-escape sequence, assuming we already read the `\'. If the escape sequence forces unibyte, return eight-bit char. */ static int read_escape (Lisp_Object readcharfun, bool stringp) { int c = READCHAR; /* \u allows up to four hex digits, \U up to eight. Default to the behavior for \u, and change this value in the case that \U is seen. */ int unicode_hex_count = 4; switch (c) { case -1: end_of_file_error (); case 'a': return '\007'; case 'b': return '\b'; case 'd': return 0177; case 'e': return 033; case 'f': return '\f'; case 'n': return '\n'; case 'r': return '\r'; case 't': return '\t'; case 'v': return '\v'; case '\n': return -1; case ' ': if (stringp) return -1; return ' '; case 'M': c = READCHAR; if (c != '-') error ("Invalid escape character syntax"); c = READCHAR; if (c == '\\') c = read_escape (readcharfun, 0); return c | meta_modifier; case 'S': c = READCHAR; if (c != '-') error ("Invalid escape character syntax"); c = READCHAR; if (c == '\\') c = read_escape (readcharfun, 0); return c | shift_modifier; case 'H': c = READCHAR; if (c != '-') error ("Invalid escape character syntax"); c = READCHAR; if (c == '\\') c = read_escape (readcharfun, 0); return c | hyper_modifier; case 'A': c = READCHAR; if (c != '-') error ("Invalid escape character syntax"); c = READCHAR; if (c == '\\') c = read_escape (readcharfun, 0); return c | alt_modifier; case 's': c = READCHAR; if (stringp || c != '-') { UNREAD (c); return ' '; } c = READCHAR; if (c == '\\') c = read_escape (readcharfun, 0); return c | super_modifier; case 'C': c = READCHAR; if (c != '-') error ("Invalid escape character syntax"); case '^': c = READCHAR; if (c == '\\') c = read_escape (readcharfun, 0); if ((c & ~CHAR_MODIFIER_MASK) == '?') return 0177 | (c & CHAR_MODIFIER_MASK); else if (! SINGLE_BYTE_CHAR_P ((c & ~CHAR_MODIFIER_MASK))) return c | ctrl_modifier; /* ASCII control chars are made from letters (both cases), as well as the non-letters within 0100...0137. */ else if ((c & 0137) >= 0101 && (c & 0137) <= 0132) return (c & (037 | ~0177)); else if ((c & 0177) >= 0100 && (c & 0177) <= 0137) return (c & (037 | ~0177)); else return c | ctrl_modifier; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': /* An octal escape, as in ANSI C. */ { register int i = c - '0'; register int count = 0; while (++count < 3) { if ((c = READCHAR) >= '0' && c <= '7') { i *= 8; i += c - '0'; } else { UNREAD (c); break; } } if (i >= 0x80 && i < 0x100) i = BYTE8_TO_CHAR (i); return i; } case 'x': /* A hex escape, as in ANSI C. */ { unsigned int i = 0; int count = 0; while (1) { c = READCHAR; if (c >= '0' && c <= '9') { i *= 16; i += c - '0'; } else if ((c >= 'a' && c <= 'f') || (c >= 'A' && c <= 'F')) { i *= 16; if (c >= 'a' && c <= 'f') i += c - 'a' + 10; else i += c - 'A' + 10; } else { UNREAD (c); break; } /* Allow hex escapes as large as ?\xfffffff, because some packages use them to denote characters with modifiers. */ if ((CHAR_META | (CHAR_META - 1)) < i) error ("Hex character out of range: \\x%x...", i); count += count < 3; } if (count < 3 && i >= 0x80) return BYTE8_TO_CHAR (i); return i; } case 'U': /* Post-Unicode-2.0: Up to eight hex chars. */ unicode_hex_count = 8; case 'u': /* A Unicode escape. We only permit them in strings and characters, not arbitrarily in the source code, as in some other languages. */ { unsigned int i = 0; int count = 0; while (++count <= unicode_hex_count) { c = READCHAR; /* `isdigit' and `isalpha' may be locale-specific, which we don't want. */ if (c >= '0' && c <= '9') i = (i << 4) + (c - '0'); else if (c >= 'a' && c <= 'f') i = (i << 4) + (c - 'a') + 10; else if (c >= 'A' && c <= 'F') i = (i << 4) + (c - 'A') + 10; else error ("Non-hex digit used for Unicode escape"); } if (i > 0x10FFFF) error ("Non-Unicode character: 0x%x", i); return i; } default: return c; } } /* Return the digit that CHARACTER stands for in the given BASE. Return -1 if CHARACTER is out of range for BASE, and -2 if CHARACTER is not valid for any supported BASE. */ static int digit_to_number (int character, int base) { int digit; if ('0' <= character && character <= '9') digit = character - '0'; else if ('a' <= character && character <= 'z') digit = character - 'a' + 10; else if ('A' <= character && character <= 'Z') digit = character - 'A' + 10; else return -2; return digit < base ? digit : -1; } /* Read an integer in radix RADIX using READCHARFUN to read characters. RADIX must be in the interval [2..36]; if it isn't, a read error is signaled . Value is the integer read. Signals an error if encountering invalid read syntax or if RADIX is out of range. */ static Lisp_Object read_integer (Lisp_Object readcharfun, EMACS_INT radix) { /* Room for sign, leading 0, other digits, trailing null byte. Also, room for invalid syntax diagnostic. */ char buf[max (1 + 1 + sizeof (uintmax_t) * CHAR_BIT + 1, sizeof "integer, radix " + INT_STRLEN_BOUND (EMACS_INT))]; int valid = -1; /* 1 if valid, 0 if not, -1 if incomplete. */ if (radix < 2 || radix > 36) valid = 0; else { char *p = buf; int c, digit; c = READCHAR; if (c == '-' || c == '+') { *p++ = c; c = READCHAR; } if (c == '0') { *p++ = c; valid = 1; /* Ignore redundant leading zeros, so the buffer doesn't fill up with them. */ do c = READCHAR; while (c == '0'); } while (-1 <= (digit = digit_to_number (c, radix))) { if (digit == -1) valid = 0; if (valid < 0) valid = 1; if (p < buf + sizeof buf - 1) *p++ = c; else valid = 0; c = READCHAR; } UNREAD (c); *p = '\0'; } if (! valid) { sprintf (buf, "integer, radix %"pI"d", radix); invalid_syntax (buf); } return string_to_number (buf, radix, 0); } /* If the next token is ')' or ']' or '.', we store that character in *PCH and the return value is not interesting. Else, we store zero in *PCH and we read and return one lisp object. FIRST_IN_LIST is true if this is the first element of a list. */ static Lisp_Object read1 (Lisp_Object readcharfun, int *pch, bool first_in_list) { int c; bool uninterned_symbol = 0; bool multibyte; *pch = 0; load_each_byte = 0; retry: c = READCHAR_REPORT_MULTIBYTE (&multibyte); if (c < 0) end_of_file_error (); switch (c) { case '(': return read_list (0, readcharfun); case '[': return read_vector (readcharfun, 0); case ')': case ']': { *pch = c; return Qnil; } case '#': c = READCHAR; if (c == 's') { c = READCHAR; if (c == '(') { /* Accept extended format for hashtables (extensible to other types), e.g. #s(hash-table size 2 test equal data (k1 v1 k2 v2)) */ Lisp_Object tmp = read_list (0, readcharfun); Lisp_Object head = CAR_SAFE (tmp); Lisp_Object data = Qnil; Lisp_Object val = Qnil; /* The size is 2 * number of allowed keywords to make-hash-table. */ Lisp_Object params[10]; Lisp_Object ht; Lisp_Object key = Qnil; int param_count = 0; if (!EQ (head, Qhash_table)) error ("Invalid extended read marker at head of #s list " "(only hash-table allowed)"); tmp = CDR_SAFE (tmp); /* This is repetitive but fast and simple. */ params[param_count] = QCsize; params[param_count + 1] = Fplist_get (tmp, Qsize); if (!NILP (params[param_count + 1])) param_count += 2; params[param_count] = QCtest; params[param_count + 1] = Fplist_get (tmp, Qtest); if (!NILP (params[param_count + 1])) param_count += 2; params[param_count] = QCweakness; params[param_count + 1] = Fplist_get (tmp, Qweakness); if (!NILP (params[param_count + 1])) param_count += 2; params[param_count] = QCrehash_size; params[param_count + 1] = Fplist_get (tmp, Qrehash_size); if (!NILP (params[param_count + 1])) param_count += 2; params[param_count] = QCrehash_threshold; params[param_count + 1] = Fplist_get (tmp, Qrehash_threshold); if (!NILP (params[param_count + 1])) param_count += 2; /* This is the hashtable data. */ data = Fplist_get (tmp, Qdata); /* Now use params to make a new hashtable and fill it. */ ht = Fmake_hash_table (param_count, params); while (CONSP (data)) { key = XCAR (data); data = XCDR (data); if (!CONSP (data)) error ("Odd number of elements in hashtable data"); val = XCAR (data); data = XCDR (data); Fputhash (key, val, ht); } return ht; } UNREAD (c); invalid_syntax ("#"); } if (c == '^') { c = READCHAR; if (c == '[') { Lisp_Object tmp; tmp = read_vector (readcharfun, 0); if (ASIZE (tmp) < CHAR_TABLE_STANDARD_SLOTS) error ("Invalid size char-table"); XSETPVECTYPE (XVECTOR (tmp), PVEC_CHAR_TABLE); return tmp; } else if (c == '^') { c = READCHAR; if (c == '[') { Lisp_Object tmp; int depth; ptrdiff_t size; tmp = read_vector (readcharfun, 0); size = ASIZE (tmp); if (size == 0) error ("Invalid size char-table"); if (! RANGED_INTEGERP (1, AREF (tmp, 0), 3)) error ("Invalid depth in char-table"); depth = XINT (AREF (tmp, 0)); if (chartab_size[depth] != size - 2) error ("Invalid size char-table"); XSETPVECTYPE (XVECTOR (tmp), PVEC_SUB_CHAR_TABLE); return tmp; } invalid_syntax ("#^^"); } invalid_syntax ("#^"); } if (c == '&') { Lisp_Object length; length = read1 (readcharfun, pch, first_in_list); c = READCHAR; if (c == '"') { Lisp_Object tmp, val; EMACS_INT size_in_chars = ((XFASTINT (length) + BOOL_VECTOR_BITS_PER_CHAR - 1) / BOOL_VECTOR_BITS_PER_CHAR); UNREAD (c); tmp = read1 (readcharfun, pch, first_in_list); if (STRING_MULTIBYTE (tmp) || (size_in_chars != SCHARS (tmp) /* We used to print 1 char too many when the number of bits was a multiple of 8. Accept such input in case it came from an old version. */ && ! (XFASTINT (length) == (SCHARS (tmp) - 1) * BOOL_VECTOR_BITS_PER_CHAR))) invalid_syntax ("#&..."); val = Fmake_bool_vector (length, Qnil); memcpy (XBOOL_VECTOR (val)->data, SDATA (tmp), size_in_chars); /* Clear the extraneous bits in the last byte. */ if (XINT (length) != size_in_chars * BOOL_VECTOR_BITS_PER_CHAR) XBOOL_VECTOR (val)->data[size_in_chars - 1] &= (1 << (XINT (length) % BOOL_VECTOR_BITS_PER_CHAR)) - 1; return val; } invalid_syntax ("#&..."); } if (c == '[') { /* Accept compiled functions at read-time so that we don't have to build them using function calls. */ Lisp_Object tmp; tmp = read_vector (readcharfun, 1); make_byte_code (XVECTOR (tmp)); return tmp; } if (c == '(') { Lisp_Object tmp; struct gcpro gcpro1; int ch; /* Read the string itself. */ tmp = read1 (readcharfun, &ch, 0); if (ch != 0 || !STRINGP (tmp)) invalid_syntax ("#"); GCPRO1 (tmp); /* Read the intervals and their properties. */ while (1) { Lisp_Object beg, end, plist; beg = read1 (readcharfun, &ch, 0); end = plist = Qnil; if (ch == ')') break; if (ch == 0) end = read1 (readcharfun, &ch, 0); if (ch == 0) plist = read1 (readcharfun, &ch, 0); if (ch) invalid_syntax ("Invalid string property list"); Fset_text_properties (beg, end, plist, tmp); } UNGCPRO; return tmp; } /* #@NUMBER is used to skip NUMBER following characters. That's used in .elc files to skip over doc strings and function definitions. */ if (c == '@') { enum { extra = 100 }; ptrdiff_t i, nskip = 0; load_each_byte = 1; /* Read a decimal integer. */ while ((c = READCHAR) >= 0 && c >= '0' && c <= '9') { if ((STRING_BYTES_BOUND - extra) / 10 <= nskip) string_overflow (); nskip *= 10; nskip += c - '0'; } UNREAD (c); if (load_force_doc_strings && (EQ (readcharfun, Qget_file_char) || EQ (readcharfun, Qget_emacs_mule_file_char))) { /* If we are supposed to force doc strings into core right now, record the last string that we skipped, and record where in the file it comes from. */ /* But first exchange saved_doc_string with prev_saved_doc_string, so we save two strings. */ { char *temp = saved_doc_string; ptrdiff_t temp_size = saved_doc_string_size; file_offset temp_pos = saved_doc_string_position; ptrdiff_t temp_len = saved_doc_string_length; saved_doc_string = prev_saved_doc_string; saved_doc_string_size = prev_saved_doc_string_size; saved_doc_string_position = prev_saved_doc_string_position; saved_doc_string_length = prev_saved_doc_string_length; prev_saved_doc_string = temp; prev_saved_doc_string_size = temp_size; prev_saved_doc_string_position = temp_pos; prev_saved_doc_string_length = temp_len; } if (saved_doc_string_size == 0) { saved_doc_string = xmalloc (nskip + extra); saved_doc_string_size = nskip + extra; } if (nskip > saved_doc_string_size) { saved_doc_string = xrealloc (saved_doc_string, nskip + extra); saved_doc_string_size = nskip + extra; } saved_doc_string_position = file_tell (instream); /* Copy that many characters into saved_doc_string. */ for (i = 0; i < nskip && c >= 0; i++) saved_doc_string[i] = c = READCHAR; saved_doc_string_length = i; } else { /* Skip that many characters. */ for (i = 0; i < nskip && c >= 0; i++) c = READCHAR; } load_each_byte = 0; goto retry; } if (c == '!') { /* #! appears at the beginning of an executable file. Skip the first line. */ while (c != '\n' && c >= 0) c = READCHAR; goto retry; } if (c == '$') return Vload_file_name; if (c == '\'') return Fcons (Qfunction, Fcons (read0 (readcharfun), Qnil)); /* #:foo is the uninterned symbol named foo. */ if (c == ':') { uninterned_symbol = 1; c = READCHAR; if (!(c > 040 && c != 0xa0 /* NBSP */ && (c >= 0200 || strchr ("\"';()[]#`,", c) == NULL))) { /* No symbol character follows, this is the empty symbol. */ UNREAD (c); return Fmake_symbol (empty_unibyte_string); } goto read_symbol; } /* ## is the empty symbol. */ if (c == '#') return Fintern (empty_unibyte_string, Qnil); /* Reader forms that can reuse previously read objects. */ if (c >= '0' && c <= '9') { EMACS_INT n = 0; Lisp_Object tem; /* Read a non-negative integer. */ while (c >= '0' && c <= '9') { if (MOST_POSITIVE_FIXNUM / 10 < n || MOST_POSITIVE_FIXNUM < n * 10 + c - '0') n = MOST_POSITIVE_FIXNUM + 1; else n = n * 10 + c - '0'; c = READCHAR; } if (n <= MOST_POSITIVE_FIXNUM) { if (c == 'r' || c == 'R') return read_integer (readcharfun, n); if (! NILP (Vread_circle)) { /* #n=object returns object, but associates it with n for #n#. */ if (c == '=') { /* Make a placeholder for #n# to use temporarily. */ Lisp_Object placeholder; Lisp_Object cell; placeholder = Fcons (Qnil, Qnil); cell = Fcons (make_number (n), placeholder); read_objects = Fcons (cell, read_objects); /* Read the object itself. */ tem = read0 (readcharfun); /* Now put it everywhere the placeholder was... */ substitute_object_in_subtree (tem, placeholder); /* ...and #n# will use the real value from now on. */ Fsetcdr (cell, tem); return tem; } /* #n# returns a previously read object. */ if (c == '#') { tem = Fassq (make_number (n), read_objects); if (CONSP (tem)) return XCDR (tem); } } } /* Fall through to error message. */ } else if (c == 'x' || c == 'X') return read_integer (readcharfun, 16); else if (c == 'o' || c == 'O') return read_integer (readcharfun, 8); else if (c == 'b' || c == 'B') return read_integer (readcharfun, 2); UNREAD (c); invalid_syntax ("#"); case ';': while ((c = READCHAR) >= 0 && c != '\n'); goto retry; case '\'': { return Fcons (Qquote, Fcons (read0 (readcharfun), Qnil)); } case '`': { int next_char = READCHAR; UNREAD (next_char); /* Transition from old-style to new-style: If we see "(`" it used to mean old-style, which usually works fine because ` should almost never appear in such a position for new-style. But occasionally we need "(`" to mean new style, so we try to distinguish the two by the fact that we can either write "( `foo" or "(` foo", where the first intends to use new-style whereas the second intends to use old-style. For Emacs-25, we should completely remove this first_in_list exception (old-style can still be obtained via "(\`" anyway). */ if (!new_backquote_flag && first_in_list && next_char == ' ') { Vold_style_backquotes = Qt; goto default_label; } else { Lisp_Object value; bool saved_new_backquote_flag = new_backquote_flag; new_backquote_flag = 1; value = read0 (readcharfun); new_backquote_flag = saved_new_backquote_flag; return Fcons (Qbackquote, Fcons (value, Qnil)); } } case ',': { int next_char = READCHAR; UNREAD (next_char); /* Transition from old-style to new-style: It used to be impossible to have a new-style , other than within a new-style `. This is sufficient when ` and , are used in the normal way, but ` and , can also appear in args to macros that will not interpret them in the usual way, in which case , may be used without any ` anywhere near. So we now use the same heuristic as for backquote: old-style unquotes are only recognized when first on a list, and when followed by a space. Because it's more difficult to peek 2 chars ahead, a new-style ,@ can still not be used outside of a `, unless it's in the middle of a list. */ if (new_backquote_flag || !first_in_list || (next_char != ' ' && next_char != '@')) { Lisp_Object comma_type = Qnil; Lisp_Object value; int ch = READCHAR; if (ch == '@') comma_type = Qcomma_at; else if (ch == '.') comma_type = Qcomma_dot; else { if (ch >= 0) UNREAD (ch); comma_type = Qcomma; } value = read0 (readcharfun); return Fcons (comma_type, Fcons (value, Qnil)); } else { Vold_style_backquotes = Qt; goto default_label; } } case '?': { int modifiers; int next_char; bool ok; c = READCHAR; if (c < 0) end_of_file_error (); /* Accept `single space' syntax like (list ? x) where the whitespace character is SPC or TAB. Other literal whitespace like NL, CR, and FF are not accepted, as there are well-established escape sequences for these. */ if (c == ' ' || c == '\t') return make_number (c); if (c == '\\') c = read_escape (readcharfun, 0); modifiers = c & CHAR_MODIFIER_MASK; c &= ~CHAR_MODIFIER_MASK; if (CHAR_BYTE8_P (c)) c = CHAR_TO_BYTE8 (c); c |= modifiers; next_char = READCHAR; ok = (next_char <= 040 || (next_char < 0200 && strchr ("\"';()[]#?`,.", next_char) != NULL)); UNREAD (next_char); if (ok) return make_number (c); invalid_syntax ("?"); } case '"': { char *p = read_buffer; char *end = read_buffer + read_buffer_size; int ch; /* True if we saw an escape sequence specifying a multibyte character. */ bool force_multibyte = 0; /* True if we saw an escape sequence specifying a single-byte character. */ bool force_singlebyte = 0; bool cancel = 0; ptrdiff_t nchars = 0; while ((ch = READCHAR) >= 0 && ch != '\"') { if (end - p < MAX_MULTIBYTE_LENGTH) { ptrdiff_t offset = p - read_buffer; if (min (PTRDIFF_MAX, SIZE_MAX) / 2 < read_buffer_size) memory_full (SIZE_MAX); read_buffer = xrealloc (read_buffer, read_buffer_size * 2); read_buffer_size *= 2; p = read_buffer + offset; end = read_buffer + read_buffer_size; } if (ch == '\\') { int modifiers; ch = read_escape (readcharfun, 1); /* CH is -1 if \ newline has just been seen. */ if (ch == -1) { if (p == read_buffer) cancel = 1; continue; } modifiers = ch & CHAR_MODIFIER_MASK; ch = ch & ~CHAR_MODIFIER_MASK; if (CHAR_BYTE8_P (ch)) force_singlebyte = 1; else if (! ASCII_CHAR_P (ch)) force_multibyte = 1; else /* I.e. ASCII_CHAR_P (ch). */ { /* Allow `\C- ' and `\C-?'. */ if (modifiers == CHAR_CTL) { if (ch == ' ') ch = 0, modifiers = 0; else if (ch == '?') ch = 127, modifiers = 0; } if (modifiers & CHAR_SHIFT) { /* Shift modifier is valid only with [A-Za-z]. */ if (ch >= 'A' && ch <= 'Z') modifiers &= ~CHAR_SHIFT; else if (ch >= 'a' && ch <= 'z') ch -= ('a' - 'A'), modifiers &= ~CHAR_SHIFT; } if (modifiers & CHAR_META) { /* Move the meta bit to the right place for a string. */ modifiers &= ~CHAR_META; ch = BYTE8_TO_CHAR (ch | 0x80); force_singlebyte = 1; } } /* Any modifiers remaining are invalid. */ if (modifiers) error ("Invalid modifier in string"); p += CHAR_STRING (ch, (unsigned char *) p); } else { p += CHAR_STRING (ch, (unsigned char *) p); if (CHAR_BYTE8_P (ch)) force_singlebyte = 1; else if (! ASCII_CHAR_P (ch)) force_multibyte = 1; } nchars++; } if (ch < 0) end_of_file_error (); /* If purifying, and string starts with \ newline, return zero instead. This is for doc strings that we are really going to find in etc/DOC.nn.nn. */ if (!NILP (Vpurify_flag) && NILP (Vdoc_file_name) && cancel) return make_number (0); if (! force_multibyte && force_singlebyte) { /* READ_BUFFER contains raw 8-bit bytes and no multibyte forms. Convert it to unibyte. */ nchars = str_as_unibyte ((unsigned char *) read_buffer, p - read_buffer); p = read_buffer + nchars; } return make_specified_string (read_buffer, nchars, p - read_buffer, (force_multibyte || (p - read_buffer != nchars))); } case '.': { int next_char = READCHAR; UNREAD (next_char); if (next_char <= 040 || (next_char < 0200 && strchr ("\"';([#?`,", next_char) != NULL)) { *pch = c; return Qnil; } /* Otherwise, we fall through! Note that the atom-reading loop below will now loop at least once, assuring that we will not try to UNREAD two characters in a row. */ } default: default_label: if (c <= 040) goto retry; if (c == 0xa0) /* NBSP */ goto retry; read_symbol: { char *p = read_buffer; bool quoted = 0; EMACS_INT start_position = readchar_count - 1; { char *end = read_buffer + read_buffer_size; do { if (end - p < MAX_MULTIBYTE_LENGTH) { ptrdiff_t offset = p - read_buffer; if (min (PTRDIFF_MAX, SIZE_MAX) / 2 < read_buffer_size) memory_full (SIZE_MAX); read_buffer = xrealloc (read_buffer, read_buffer_size * 2); read_buffer_size *= 2; p = read_buffer + offset; end = read_buffer + read_buffer_size; } if (c == '\\') { c = READCHAR; if (c == -1) end_of_file_error (); quoted = 1; } if (multibyte) p += CHAR_STRING (c, (unsigned char *) p); else *p++ = c; c = READCHAR; } while (c > 040 && c != 0xa0 /* NBSP */ && (c >= 0200 || strchr ("\"';()[]#`,", c) == NULL)); if (p == end) { ptrdiff_t offset = p - read_buffer; if (min (PTRDIFF_MAX, SIZE_MAX) / 2 < read_buffer_size) memory_full (SIZE_MAX); read_buffer = xrealloc (read_buffer, read_buffer_size * 2); read_buffer_size *= 2; p = read_buffer + offset; end = read_buffer + read_buffer_size; } *p = 0; UNREAD (c); } if (!quoted && !uninterned_symbol) { Lisp_Object result = string_to_number (read_buffer, 10, 0); if (! NILP (result)) return result; } { Lisp_Object name, result; ptrdiff_t nbytes = p - read_buffer; ptrdiff_t nchars = (multibyte ? multibyte_chars_in_text ((unsigned char *) read_buffer, nbytes) : nbytes); name = ((uninterned_symbol && ! NILP (Vpurify_flag) ? make_pure_string : make_specified_string) (read_buffer, nchars, nbytes, multibyte)); result = (uninterned_symbol ? Fmake_symbol (name) : Fintern (name, Qnil)); if (EQ (Vread_with_symbol_positions, Qt) || EQ (Vread_with_symbol_positions, readcharfun)) Vread_symbol_positions_list = Fcons (Fcons (result, make_number (start_position)), Vread_symbol_positions_list); return result; } } } } /* List of nodes we've seen during substitute_object_in_subtree. */ static Lisp_Object seen_list; static void substitute_object_in_subtree (Lisp_Object object, Lisp_Object placeholder) { Lisp_Object check_object; /* We haven't seen any objects when we start. */ seen_list = Qnil; /* Make all the substitutions. */ check_object = substitute_object_recurse (object, placeholder, object); /* Clear seen_list because we're done with it. */ seen_list = Qnil; /* The returned object here is expected to always eq the original. */ if (!EQ (check_object, object)) error ("Unexpected mutation error in reader"); } /* Feval doesn't get called from here, so no gc protection is needed. */ #define SUBSTITUTE(get_val, set_val) \ do { \ Lisp_Object old_value = get_val; \ Lisp_Object true_value \ = substitute_object_recurse (object, placeholder, \ old_value); \ \ if (!EQ (old_value, true_value)) \ { \ set_val; \ } \ } while (0) static Lisp_Object substitute_object_recurse (Lisp_Object object, Lisp_Object placeholder, Lisp_Object subtree) { /* If we find the placeholder, return the target object. */ if (EQ (placeholder, subtree)) return object; /* If we've been to this node before, don't explore it again. */ if (!EQ (Qnil, Fmemq (subtree, seen_list))) return subtree; /* If this node can be the entry point to a cycle, remember that we've seen it. It can only be such an entry point if it was made by #n=, which means that we can find it as a value in read_objects. */ if (!EQ (Qnil, Frassq (subtree, read_objects))) seen_list = Fcons (subtree, seen_list); /* Recurse according to subtree's type. Every branch must return a Lisp_Object. */ switch (XTYPE (subtree)) { case Lisp_Vectorlike: { ptrdiff_t i, length = 0; if (BOOL_VECTOR_P (subtree)) return subtree; /* No sub-objects anyway. */ else if (CHAR_TABLE_P (subtree) || SUB_CHAR_TABLE_P (subtree) || COMPILEDP (subtree)) length = ASIZE (subtree) & PSEUDOVECTOR_SIZE_MASK; else if (VECTORP (subtree)) length = ASIZE (subtree); else /* An unknown pseudovector may contain non-Lisp fields, so we can't just blindly traverse all its fields. We used to call `Flength' which signaled `sequencep', so I just preserved this behavior. */ wrong_type_argument (Qsequencep, subtree); for (i = 0; i < length; i++) SUBSTITUTE (AREF (subtree, i), ASET (subtree, i, true_value)); return subtree; } case Lisp_Cons: { SUBSTITUTE (XCAR (subtree), XSETCAR (subtree, true_value)); SUBSTITUTE (XCDR (subtree), XSETCDR (subtree, true_value)); return subtree; } case Lisp_String: { /* Check for text properties in each interval. substitute_in_interval contains part of the logic. */ INTERVAL root_interval = string_intervals (subtree); Lisp_Object arg = Fcons (object, placeholder); traverse_intervals_noorder (root_interval, &substitute_in_interval, arg); return subtree; } /* Other types don't recurse any further. */ default: return subtree; } } /* Helper function for substitute_object_recurse. */ static void substitute_in_interval (INTERVAL interval, Lisp_Object arg) { Lisp_Object object = Fcar (arg); Lisp_Object placeholder = Fcdr (arg); SUBSTITUTE (interval->plist, set_interval_plist (interval, true_value)); } #define LEAD_INT 1 #define DOT_CHAR 2 #define TRAIL_INT 4 #define E_EXP 16 /* Convert STRING to a number, assuming base BASE. Return a fixnum if CP has integer syntax and fits in a fixnum, else return the nearest float if CP has either floating point or integer syntax and BASE is 10, else return nil. If IGNORE_TRAILING, consider just the longest prefix of CP that has valid floating point syntax. Signal an overflow if BASE is not 10 and the number has integer syntax but does not fit. */ Lisp_Object string_to_number (char const *string, int base, bool ignore_trailing) { int state; char const *cp = string; int leading_digit; bool float_syntax = 0; double value = 0; /* Compute NaN and infinities using a variable, to cope with compilers that think they are smarter than we are. */ double zero = 0; /* Negate the value ourselves. This treats 0, NaNs, and infinity properly on IEEE floating point hosts, and works around a formerly-common bug where atof ("-0.0") drops the sign. */ bool negative = *cp == '-'; bool signedp = negative || *cp == '+'; cp += signedp; state = 0; leading_digit = digit_to_number (*cp, base); if (0 <= leading_digit) { state |= LEAD_INT; do ++cp; while (0 <= digit_to_number (*cp, base)); } if (*cp == '.') { state |= DOT_CHAR; cp++; } if (base == 10) { if ('0' <= *cp && *cp <= '9') { state |= TRAIL_INT; do cp++; while ('0' <= *cp && *cp <= '9'); } if (*cp == 'e' || *cp == 'E') { char const *ecp = cp; cp++; if (*cp == '+' || *cp == '-') cp++; if ('0' <= *cp && *cp <= '9') { state |= E_EXP; do cp++; while ('0' <= *cp && *cp <= '9'); } else if (cp[-1] == '+' && cp[0] == 'I' && cp[1] == 'N' && cp[2] == 'F') { state |= E_EXP; cp += 3; value = 1.0 / zero; } else if (cp[-1] == '+' && cp[0] == 'N' && cp[1] == 'a' && cp[2] == 'N') { state |= E_EXP; cp += 3; value = zero / zero; /* If that made a "negative" NaN, negate it. */ { int i; union { double d; char c[sizeof (double)]; } u_data, u_minus_zero; u_data.d = value; u_minus_zero.d = -0.0; for (i = 0; i < sizeof (double); i++) if (u_data.c[i] & u_minus_zero.c[i]) { value = -value; break; } } /* Now VALUE is a positive NaN. */ } else cp = ecp; } float_syntax = ((state & (DOT_CHAR|TRAIL_INT)) == (DOT_CHAR|TRAIL_INT) || state == (LEAD_INT|E_EXP)); } /* Return nil if the number uses invalid syntax. If IGNORE_TRAILING, accept any prefix that matches. Otherwise, the entire string must match. */ if (! (ignore_trailing ? ((state & LEAD_INT) != 0 || float_syntax) : (!*cp && ((state & ~DOT_CHAR) == LEAD_INT || float_syntax)))) return Qnil; /* If the number uses integer and not float syntax, and is in C-language range, use its value, preferably as a fixnum. */ if (0 <= leading_digit && ! float_syntax) { uintmax_t n; /* Fast special case for single-digit integers. This also avoids a glitch when BASE is 16 and IGNORE_TRAILING, because in that case some versions of strtoumax accept numbers like "0x1" that Emacs does not allow. */ if (digit_to_number (string[signedp + 1], base) < 0) return make_number (negative ? -leading_digit : leading_digit); errno = 0; n = strtoumax (string + signedp, NULL, base); if (errno == ERANGE) { /* Unfortunately there's no simple and accurate way to convert non-base-10 numbers that are out of C-language range. */ if (base != 10) xsignal1 (Qoverflow_error, build_string (string)); } else if (n <= (negative ? -MOST_NEGATIVE_FIXNUM : MOST_POSITIVE_FIXNUM)) { EMACS_INT signed_n = n; return make_number (negative ? -signed_n : signed_n); } else value = n; } /* Either the number uses float syntax, or it does not fit into a fixnum. Convert it from string to floating point, unless the value is already known because it is an infinity, a NAN, or its absolute value fits in uintmax_t. */ if (! value) value = atof (string + signedp); return make_float (negative ? -value : value); } static Lisp_Object read_vector (Lisp_Object readcharfun, bool bytecodeflag) { ptrdiff_t i, size; Lisp_Object *ptr; Lisp_Object tem, item, vector; struct Lisp_Cons *otem; Lisp_Object len; tem = read_list (1, readcharfun); len = Flength (tem); vector = Fmake_vector (len, Qnil); size = ASIZE (vector); ptr = XVECTOR (vector)->contents; for (i = 0; i < size; i++) { item = Fcar (tem); /* If `load-force-doc-strings' is t when reading a lazily-loaded bytecode object, the docstring containing the bytecode and constants values must be treated as unibyte and passed to Fread, to get the actual bytecode string and constants vector. */ if (bytecodeflag && load_force_doc_strings) { if (i == COMPILED_BYTECODE) { if (!STRINGP (item)) error ("Invalid byte code"); /* Delay handling the bytecode slot until we know whether it is lazily-loaded (we can tell by whether the constants slot is nil). */ ASET (vector, COMPILED_CONSTANTS, item); item = Qnil; } else if (i == COMPILED_CONSTANTS) { Lisp_Object bytestr = ptr[COMPILED_CONSTANTS]; if (NILP (item)) { /* Coerce string to unibyte (like string-as-unibyte, but without generating extra garbage and guaranteeing no change in the contents). */ STRING_SET_CHARS (bytestr, SBYTES (bytestr)); STRING_SET_UNIBYTE (bytestr); item = Fread (Fcons (bytestr, readcharfun)); if (!CONSP (item)) error ("Invalid byte code"); otem = XCONS (item); bytestr = XCAR (item); item = XCDR (item); free_cons (otem); } /* Now handle the bytecode slot. */ ASET (vector, COMPILED_BYTECODE, bytestr); } else if (i == COMPILED_DOC_STRING && STRINGP (item) && ! STRING_MULTIBYTE (item)) { if (EQ (readcharfun, Qget_emacs_mule_file_char)) item = Fdecode_coding_string (item, Qemacs_mule, Qnil, Qnil); else item = Fstring_as_multibyte (item); } } ASET (vector, i, item); otem = XCONS (tem); tem = Fcdr (tem); free_cons (otem); } return vector; } /* FLAG means check for ] to terminate rather than ) and . */ static Lisp_Object read_list (bool flag, Lisp_Object readcharfun) { Lisp_Object val, tail; Lisp_Object elt, tem; struct gcpro gcpro1, gcpro2; /* 0 is the normal case. 1 means this list is a doc reference; replace it with the number 0. 2 means this list is a doc reference; replace it with the doc string. */ int doc_reference = 0; /* Initialize this to 1 if we are reading a list. */ bool first_in_list = flag <= 0; val = Qnil; tail = Qnil; while (1) { int ch; GCPRO2 (val, tail); elt = read1 (readcharfun, &ch, first_in_list); UNGCPRO; first_in_list = 0; /* While building, if the list starts with #$, treat it specially. */ if (EQ (elt, Vload_file_name) && ! NILP (elt) && !NILP (Vpurify_flag)) { if (NILP (Vdoc_file_name)) /* We have not yet called Snarf-documentation, so assume this file is described in the DOC-MM.NN file and Snarf-documentation will fill in the right value later. For now, replace the whole list with 0. */ doc_reference = 1; else /* We have already called Snarf-documentation, so make a relative file name for this file, so it can be found properly in the installed Lisp directory. We don't use Fexpand_file_name because that would make the directory absolute now. */ elt = concat2 (build_string ("../lisp/"), Ffile_name_nondirectory (elt)); } else if (EQ (elt, Vload_file_name) && ! NILP (elt) && load_force_doc_strings) doc_reference = 2; if (ch) { if (flag > 0) { if (ch == ']') return val; invalid_syntax (") or . in a vector"); } if (ch == ')') return val; if (ch == '.') { GCPRO2 (val, tail); if (!NILP (tail)) XSETCDR (tail, read0 (readcharfun)); else val = read0 (readcharfun); read1 (readcharfun, &ch, 0); UNGCPRO; if (ch == ')') { if (doc_reference == 1) return make_number (0); if (doc_reference == 2) { /* Get a doc string from the file we are loading. If it's in saved_doc_string, get it from there. Here, we don't know if the string is a bytecode string or a doc string. As a bytecode string must be unibyte, we always return a unibyte string. If it is actually a doc string, caller must make it multibyte. */ EMACS_INT pos = XINT (XCDR (val)); /* Position is negative for user variables. */ if (pos < 0) pos = -pos; if (pos >= saved_doc_string_position && pos < (saved_doc_string_position + saved_doc_string_length)) { ptrdiff_t start = pos - saved_doc_string_position; ptrdiff_t from, to; /* Process quoting with ^A, and find the end of the string, which is marked with ^_ (037). */ for (from = start, to = start; saved_doc_string[from] != 037;) { int c = saved_doc_string[from++]; if (c == 1) { c = saved_doc_string[from++]; if (c == 1) saved_doc_string[to++] = c; else if (c == '0') saved_doc_string[to++] = 0; else if (c == '_') saved_doc_string[to++] = 037; } else saved_doc_string[to++] = c; } return make_unibyte_string (saved_doc_string + start, to - start); } /* Look in prev_saved_doc_string the same way. */ else if (pos >= prev_saved_doc_string_position && pos < (prev_saved_doc_string_position + prev_saved_doc_string_length)) { ptrdiff_t start = pos - prev_saved_doc_string_position; ptrdiff_t from, to; /* Process quoting with ^A, and find the end of the string, which is marked with ^_ (037). */ for (from = start, to = start; prev_saved_doc_string[from] != 037;) { int c = prev_saved_doc_string[from++]; if (c == 1) { c = prev_saved_doc_string[from++]; if (c == 1) prev_saved_doc_string[to++] = c; else if (c == '0') prev_saved_doc_string[to++] = 0; else if (c == '_') prev_saved_doc_string[to++] = 037; } else prev_saved_doc_string[to++] = c; } return make_unibyte_string (prev_saved_doc_string + start, to - start); } else return get_doc_string (val, 1, 0); } return val; } invalid_syntax (". in wrong context"); } invalid_syntax ("] in a list"); } tem = Fcons (elt, Qnil); if (!NILP (tail)) XSETCDR (tail, tem); else val = tem; tail = tem; } } static Lisp_Object initial_obarray; /* `oblookup' stores the bucket number here, for the sake of Funintern. */ static size_t oblookup_last_bucket_number; /* Get an error if OBARRAY is not an obarray. If it is one, return it. */ Lisp_Object check_obarray (Lisp_Object obarray) { if (!VECTORP (obarray) || ASIZE (obarray) == 0) { /* If Vobarray is now invalid, force it to be valid. */ if (EQ (Vobarray, obarray)) Vobarray = initial_obarray; wrong_type_argument (Qvectorp, obarray); } return obarray; } /* Intern the C string STR: return a symbol with that name, interned in the current obarray. */ Lisp_Object intern_1 (const char *str, ptrdiff_t len) { Lisp_Object obarray = check_obarray (Vobarray); Lisp_Object tem = oblookup (obarray, str, len, len); return SYMBOLP (tem) ? tem : Fintern (make_string (str, len), obarray); } Lisp_Object intern_c_string_1 (const char *str, ptrdiff_t len) { Lisp_Object obarray = check_obarray (Vobarray); Lisp_Object tem = oblookup (obarray, str, len, len); if (SYMBOLP (tem)) return tem; if (NILP (Vpurify_flag)) /* Creating a non-pure string from a string literal not implemented yet. We could just use make_string here and live with the extra copy. */ emacs_abort (); return Fintern (make_pure_c_string (str, len), obarray); } DEFUN ("intern", Fintern, Sintern, 1, 2, 0, doc: /* Return the canonical symbol whose name is STRING. If there is none, one is created by this function and returned. A second optional argument specifies the obarray to use; it defaults to the value of `obarray'. */) (Lisp_Object string, Lisp_Object obarray) { register Lisp_Object tem, sym, *ptr; if (NILP (obarray)) obarray = Vobarray; obarray = check_obarray (obarray); CHECK_STRING (string); tem = oblookup (obarray, SSDATA (string), SCHARS (string), SBYTES (string)); if (!INTEGERP (tem)) return tem; if (!NILP (Vpurify_flag)) string = Fpurecopy (string); sym = Fmake_symbol (string); if (EQ (obarray, initial_obarray)) XSYMBOL (sym)->interned = SYMBOL_INTERNED_IN_INITIAL_OBARRAY; else XSYMBOL (sym)->interned = SYMBOL_INTERNED; if ((SREF (string, 0) == ':') && EQ (obarray, initial_obarray)) { XSYMBOL (sym)->constant = 1; XSYMBOL (sym)->redirect = SYMBOL_PLAINVAL; SET_SYMBOL_VAL (XSYMBOL (sym), sym); } ptr = aref_addr (obarray, XINT(tem)); if (SYMBOLP (*ptr)) set_symbol_next (sym, XSYMBOL (*ptr)); else set_symbol_next (sym, NULL); *ptr = sym; return sym; } DEFUN ("intern-soft", Fintern_soft, Sintern_soft, 1, 2, 0, doc: /* Return the canonical symbol named NAME, or nil if none exists. NAME may be a string or a symbol. If it is a symbol, that exact symbol is searched for. A second optional argument specifies the obarray to use; it defaults to the value of `obarray'. */) (Lisp_Object name, Lisp_Object obarray) { register Lisp_Object tem, string; if (NILP (obarray)) obarray = Vobarray; obarray = check_obarray (obarray); if (!SYMBOLP (name)) { CHECK_STRING (name); string = name; } else string = SYMBOL_NAME (name); tem = oblookup (obarray, SSDATA (string), SCHARS (string), SBYTES (string)); if (INTEGERP (tem) || (SYMBOLP (name) && !EQ (name, tem))) return Qnil; else return tem; } DEFUN ("unintern", Funintern, Sunintern, 1, 2, 0, doc: /* Delete the symbol named NAME, if any, from OBARRAY. The value is t if a symbol was found and deleted, nil otherwise. NAME may be a string or a symbol. If it is a symbol, that symbol is deleted, if it belongs to OBARRAY--no other symbol is deleted. OBARRAY defaults to the value of the variable `obarray'. */) (Lisp_Object name, Lisp_Object obarray) { register Lisp_Object string, tem; size_t hash; if (NILP (obarray)) obarray = Vobarray; obarray = check_obarray (obarray); if (SYMBOLP (name)) string = SYMBOL_NAME (name); else { CHECK_STRING (name); string = name; } tem = oblookup (obarray, SSDATA (string), SCHARS (string), SBYTES (string)); if (INTEGERP (tem)) return Qnil; /* If arg was a symbol, don't delete anything but that symbol itself. */ if (SYMBOLP (name) && !EQ (name, tem)) return Qnil; /* There are plenty of other symbols which will screw up the Emacs session if we unintern them, as well as even more ways to use `setq' or `fset' or whatnot to make the Emacs session unusable. Let's not go down this silly road. --Stef */ /* if (EQ (tem, Qnil) || EQ (tem, Qt)) error ("Attempt to unintern t or nil"); */ XSYMBOL (tem)->interned = SYMBOL_UNINTERNED; hash = oblookup_last_bucket_number; if (EQ (AREF (obarray, hash), tem)) { if (XSYMBOL (tem)->next) { Lisp_Object sym; XSETSYMBOL (sym, XSYMBOL (tem)->next); ASET (obarray, hash, sym); } else ASET (obarray, hash, make_number (0)); } else { Lisp_Object tail, following; for (tail = AREF (obarray, hash); XSYMBOL (tail)->next; tail = following) { XSETSYMBOL (following, XSYMBOL (tail)->next); if (EQ (following, tem)) { set_symbol_next (tail, XSYMBOL (following)->next); break; } } } return Qt; } /* Return the symbol in OBARRAY whose names matches the string of SIZE characters (SIZE_BYTE bytes) at PTR. If there is no such symbol in OBARRAY, return nil. Also store the bucket number in oblookup_last_bucket_number. */ Lisp_Object oblookup (Lisp_Object obarray, register const char *ptr, ptrdiff_t size, ptrdiff_t size_byte) { size_t hash; size_t obsize; register Lisp_Object tail; Lisp_Object bucket, tem; obarray = check_obarray (obarray); obsize = ASIZE (obarray); /* This is sometimes needed in the middle of GC. */ obsize &= ~ARRAY_MARK_FLAG; hash = hash_string (ptr, size_byte) % obsize; bucket = AREF (obarray, hash); oblookup_last_bucket_number = hash; if (EQ (bucket, make_number (0))) ; else if (!SYMBOLP (bucket)) error ("Bad data in guts of obarray"); /* Like CADR error message. */ else for (tail = bucket; ; XSETSYMBOL (tail, XSYMBOL (tail)->next)) { if (SBYTES (SYMBOL_NAME (tail)) == size_byte && SCHARS (SYMBOL_NAME (tail)) == size && !memcmp (SDATA (SYMBOL_NAME (tail)), ptr, size_byte)) return tail; else if (XSYMBOL (tail)->next == 0) break; } XSETINT (tem, hash); return tem; } void map_obarray (Lisp_Object obarray, void (*fn) (Lisp_Object, Lisp_Object), Lisp_Object arg) { ptrdiff_t i; register Lisp_Object tail; CHECK_VECTOR (obarray); for (i = ASIZE (obarray) - 1; i >= 0; i--) { tail = AREF (obarray, i); if (SYMBOLP (tail)) while (1) { (*fn) (tail, arg); if (XSYMBOL (tail)->next == 0) break; XSETSYMBOL (tail, XSYMBOL (tail)->next); } } } static void mapatoms_1 (Lisp_Object sym, Lisp_Object function) { call1 (function, sym); } DEFUN ("mapatoms", Fmapatoms, Smapatoms, 1, 2, 0, doc: /* Call FUNCTION on every symbol in OBARRAY. OBARRAY defaults to the value of `obarray'. */) (Lisp_Object function, Lisp_Object obarray) { if (NILP (obarray)) obarray = Vobarray; obarray = check_obarray (obarray); map_obarray (obarray, mapatoms_1, function); return Qnil; } #define OBARRAY_SIZE 1511 void init_obarray (void) { Lisp_Object oblength; ptrdiff_t size = 100 + MAX_MULTIBYTE_LENGTH; XSETFASTINT (oblength, OBARRAY_SIZE); Vobarray = Fmake_vector (oblength, make_number (0)); initial_obarray = Vobarray; staticpro (&initial_obarray); Qunbound = Fmake_symbol (build_pure_c_string ("unbound")); /* Set temporary dummy values to Qnil and Vpurify_flag to satisfy the NILP (Vpurify_flag) check in intern_c_string. */ Qnil = make_number (-1); Vpurify_flag = make_number (1); Qnil = intern_c_string ("nil"); /* Fmake_symbol inits fields of new symbols with Qunbound and Qnil, so those two need to be fixed manually. */ SET_SYMBOL_VAL (XSYMBOL (Qunbound), Qunbound); set_symbol_function (Qunbound, Qunbound); set_symbol_plist (Qunbound, Qnil); SET_SYMBOL_VAL (XSYMBOL (Qnil), Qnil); XSYMBOL (Qnil)->constant = 1; XSYMBOL (Qnil)->declared_special = 1; set_symbol_plist (Qnil, Qnil); Qt = intern_c_string ("t"); SET_SYMBOL_VAL (XSYMBOL (Qt), Qt); XSYMBOL (Qnil)->declared_special = 1; XSYMBOL (Qt)->constant = 1; /* Qt is correct even if CANNOT_DUMP. loadup.el will set to nil at end. */ Vpurify_flag = Qt; DEFSYM (Qvariable_documentation, "variable-documentation"); read_buffer = xmalloc (size); read_buffer_size = size; } void defsubr (struct Lisp_Subr *sname) { Lisp_Object sym, tem; sym = intern_c_string (sname->symbol_name); XSETTYPED_PVECTYPE (sname, size, PVEC_SUBR); XSETSUBR (tem, sname); set_symbol_function (sym, tem); } #ifdef NOTDEF /* Use fset in subr.el now! */ void defalias (struct Lisp_Subr *sname, char *string) { Lisp_Object sym; sym = intern (string); XSETSUBR (XSYMBOL (sym)->function, sname); } #endif /* NOTDEF */ /* Define an "integer variable"; a symbol whose value is forwarded to a C variable of type EMACS_INT. Sample call (with "xx" to fool make-docfile): DEFxxVAR_INT ("emacs-priority", &emacs_priority, "Documentation"); */ void defvar_int (struct Lisp_Intfwd *i_fwd, const char *namestring, EMACS_INT *address) { Lisp_Object sym; sym = intern_c_string (namestring); i_fwd->type = Lisp_Fwd_Int; i_fwd->intvar = address; XSYMBOL (sym)->declared_special = 1; XSYMBOL (sym)->redirect = SYMBOL_FORWARDED; SET_SYMBOL_FWD (XSYMBOL (sym), (union Lisp_Fwd *)i_fwd); } /* Similar but define a variable whose value is t if address contains 1, nil if address contains 0. */ void defvar_bool (struct Lisp_Boolfwd *b_fwd, const char *namestring, bool *address) { Lisp_Object sym; sym = intern_c_string (namestring); b_fwd->type = Lisp_Fwd_Bool; b_fwd->boolvar = address; XSYMBOL (sym)->declared_special = 1; XSYMBOL (sym)->redirect = SYMBOL_FORWARDED; SET_SYMBOL_FWD (XSYMBOL (sym), (union Lisp_Fwd *)b_fwd); Vbyte_boolean_vars = Fcons (sym, Vbyte_boolean_vars); } /* Similar but define a variable whose value is the Lisp Object stored at address. Two versions: with and without gc-marking of the C variable. The nopro version is used when that variable will be gc-marked for some other reason, since marking the same slot twice can cause trouble with strings. */ void defvar_lisp_nopro (struct Lisp_Objfwd *o_fwd, const char *namestring, Lisp_Object *address) { Lisp_Object sym; sym = intern_c_string (namestring); o_fwd->type = Lisp_Fwd_Obj; o_fwd->objvar = address; XSYMBOL (sym)->declared_special = 1; XSYMBOL (sym)->redirect = SYMBOL_FORWARDED; SET_SYMBOL_FWD (XSYMBOL (sym), (union Lisp_Fwd *)o_fwd); } void defvar_lisp (struct Lisp_Objfwd *o_fwd, const char *namestring, Lisp_Object *address) { defvar_lisp_nopro (o_fwd, namestring, address); staticpro (address); } /* Similar but define a variable whose value is the Lisp Object stored at a particular offset in the current kboard object. */ void defvar_kboard (struct Lisp_Kboard_Objfwd *ko_fwd, const char *namestring, int offset) { Lisp_Object sym; sym = intern_c_string (namestring); ko_fwd->type = Lisp_Fwd_Kboard_Obj; ko_fwd->offset = offset; XSYMBOL (sym)->declared_special = 1; XSYMBOL (sym)->redirect = SYMBOL_FORWARDED; SET_SYMBOL_FWD (XSYMBOL (sym), (union Lisp_Fwd *)ko_fwd); } /* Check that the elements of Vload_path exist. */ static void load_path_check (void) { Lisp_Object path_tail; /* The only elements that might not exist are those from PATH_LOADSEARCH, EMACSLOADPATH. Anything else is only added if it exists. */ for (path_tail = Vload_path; !NILP (path_tail); path_tail = XCDR (path_tail)) { Lisp_Object dirfile; dirfile = Fcar (path_tail); if (STRINGP (dirfile)) { dirfile = Fdirectory_file_name (dirfile); if (access (SSDATA (dirfile), 0) < 0) dir_warning ("Warning: Lisp directory `%s' does not exist.\n", XCAR (path_tail)); } } } /* Record the value of load-path used at the start of dumping so we can see if the site changed it later during dumping. */ static Lisp_Object dump_path; /* Compute the default Vload_path, with the following logic: If CANNOT_DUMP: use EMACSLOADPATH env-var if set; otherwise use PATH_LOADSEARCH, prepending PATH_SITELOADSEARCH unless --no-site-lisp. The remainder is what happens when dumping works: If purify-flag (ie dumping) just use PATH_DUMPLOADSEARCH. Otherwise use EMACSLOADPATH if set, else PATH_LOADSEARCH. If !initialized, then just set both Vload_path and dump_path. If initialized, then if Vload_path != dump_path, do nothing. (Presumably the load-path has already been changed by something. This can only be from a site-load file during dumping, or because EMACSLOADPATH is set.) If Vinstallation_directory is not nil (ie, running uninstalled): If installation-dir/lisp exists and not already a member, we must be running uninstalled. Reset the load-path to just installation-dir/lisp. (The default PATH_LOADSEARCH refers to the eventual installation directories. Since we are not yet installed, we should not use them, even if they exist.) If installation-dir/lisp does not exist, just add dump_path at the end instead. Add installation-dir/leim (if exists and not already a member) at the front. Add installation-dir/site-lisp (if !no_site_lisp, and exists and not already a member) at the front. If installation-dir != source-dir (ie running an uninstalled, out-of-tree build) AND install-dir/src/Makefile exists BUT install-dir/src/Makefile.in does NOT exist (this is a sanity check), then repeat the above steps for source-dir/lisp, leim and site-lisp. Finally, add the site-lisp directories at the front (if !no_site_lisp). */ void init_lread (void) { const char *normal; #ifdef CANNOT_DUMP #ifdef HAVE_NS const char *loadpath = ns_load_path (); #endif normal = PATH_LOADSEARCH; #ifdef HAVE_NS Vload_path = decode_env_path ("EMACSLOADPATH", loadpath ? loadpath : normal); #else Vload_path = decode_env_path ("EMACSLOADPATH", normal); #endif load_path_check (); /* FIXME CANNOT_DUMP platforms should get source-dir/lisp etc added to their load-path too, AFAICS. I don't think we can tell the difference between initialized and !initialized in this case, so we'll have to do it unconditionally when Vinstallation_directory is non-nil. */ if (!no_site_lisp && !egetenv ("EMACSLOADPATH")) { Lisp_Object sitelisp; sitelisp = decode_env_path (0, PATH_SITELOADSEARCH); if (! NILP (sitelisp)) Vload_path = nconc2 (sitelisp, Vload_path); } #else /* !CANNOT_DUMP */ if (NILP (Vpurify_flag)) { normal = PATH_LOADSEARCH; /* If the EMACSLOADPATH environment variable is set, use its value. This doesn't apply if we're dumping. */ if (egetenv ("EMACSLOADPATH")) Vload_path = decode_env_path ("EMACSLOADPATH", normal); } else normal = PATH_DUMPLOADSEARCH; /* In a dumped Emacs, we normally reset the value of Vload_path using PATH_LOADSEARCH, since the value that was dumped uses lisp/ in the source directory, instead of the path of the installed elisp libraries. However, if it appears that Vload_path has already been changed from the default that was saved before dumping, don't change it further. Changes can only be due to EMACSLOADPATH, or site-lisp files that were processed during dumping. */ if (initialized) { if (NILP (Fequal (dump_path, Vload_path))) { /* Do not make any changes, just check the elements exist. */ /* Note: --no-site-lisp is ignored. I don't know what to do about this. */ load_path_check (); } else { #ifdef HAVE_NS const char *loadpath = ns_load_path (); Vload_path = decode_env_path (0, loadpath ? loadpath : normal); #else Vload_path = decode_env_path (0, normal); #endif if (!NILP (Vinstallation_directory)) { Lisp_Object tem, tem1; /* Add to the path the lisp subdir of the installation dir, if it exists. Note: in out-of-tree builds, this directory is empty save for Makefile. */ tem = Fexpand_file_name (build_string ("lisp"), Vinstallation_directory); tem1 = Ffile_exists_p (tem); if (!NILP (tem1)) { if (NILP (Fmember (tem, Vload_path))) { /* We are running uninstalled. The default load-path points to the eventual installed lisp, leim directories. We should not use those now, even if they exist, so start over from a clean slate. */ Vload_path = Fcons (tem, Qnil); } } else /* That dir doesn't exist, so add the build-time Lisp dirs instead. */ Vload_path = nconc2 (Vload_path, dump_path); /* Add leim under the installation dir, if it exists. */ tem = Fexpand_file_name (build_string ("leim"), Vinstallation_directory); tem1 = Ffile_exists_p (tem); if (!NILP (tem1)) { if (NILP (Fmember (tem, Vload_path))) Vload_path = Fcons (tem, Vload_path); } /* Add site-lisp under the installation dir, if it exists. */ if (!no_site_lisp) { tem = Fexpand_file_name (build_string ("site-lisp"), Vinstallation_directory); tem1 = Ffile_exists_p (tem); if (!NILP (tem1)) { if (NILP (Fmember (tem, Vload_path))) Vload_path = Fcons (tem, Vload_path); } } /* If Emacs was not built in the source directory, and it is run from where it was built, add to load-path the lisp, leim and site-lisp dirs under that directory. */ if (NILP (Fequal (Vinstallation_directory, Vsource_directory))) { Lisp_Object tem2; tem = Fexpand_file_name (build_string ("src/Makefile"), Vinstallation_directory); tem1 = Ffile_exists_p (tem); /* Don't be fooled if they moved the entire source tree AFTER dumping Emacs. If the build directory is indeed different from the source dir, src/Makefile.in and src/Makefile will not be found together. */ tem = Fexpand_file_name (build_string ("src/Makefile.in"), Vinstallation_directory); tem2 = Ffile_exists_p (tem); if (!NILP (tem1) && NILP (tem2)) { tem = Fexpand_file_name (build_string ("lisp"), Vsource_directory); if (NILP (Fmember (tem, Vload_path))) Vload_path = Fcons (tem, Vload_path); tem = Fexpand_file_name (build_string ("leim"), Vsource_directory); if (NILP (Fmember (tem, Vload_path))) Vload_path = Fcons (tem, Vload_path); if (!no_site_lisp) { tem = Fexpand_file_name (build_string ("site-lisp"), Vsource_directory); tem1 = Ffile_exists_p (tem); if (!NILP (tem1)) { if (NILP (Fmember (tem, Vload_path))) Vload_path = Fcons (tem, Vload_path); } } } } /* Vinstallation_directory != Vsource_directory */ } /* if Vinstallation_directory */ /* Check before adding the site-lisp directories. The install should have created them, but they are not required, so no need to warn if they are absent. Or we might be running before installation. */ load_path_check (); /* Add the site-lisp directories at the front. */ if (!no_site_lisp) { Lisp_Object sitelisp; sitelisp = decode_env_path (0, PATH_SITELOADSEARCH); if (! NILP (sitelisp)) Vload_path = nconc2 (sitelisp, Vload_path); } } /* if dump_path == Vload_path */ } else /* !initialized */ { /* NORMAL refers to PATH_DUMPLOADSEARCH, ie the lisp dir in the source directory. We used to add ../lisp (ie the lisp dir in the build directory) at the front here, but that caused trouble because it was copied from dump_path into Vload_path, above, when Vinstallation_directory was non-nil. It should not be necessary, since in out of tree builds lisp/ is empty, save for Makefile. */ Vload_path = decode_env_path (0, normal); dump_path = Vload_path; /* No point calling load_path_check; load-path only contains essential elements from the source directory at this point. They cannot be missing unless something went extremely (and improbably) wrong, in which case the build will fail in obvious ways. */ } #endif /* !CANNOT_DUMP */ Vvalues = Qnil; load_in_progress = 0; Vload_file_name = Qnil; load_descriptor_list = Qnil; Vstandard_input = Qt; Vloads_in_progress = Qnil; } /* Print a warning, using format string FORMAT, that directory DIRNAME does not exist. Print it on stderr and put it in *Messages*. */ void dir_warning (const char *format, Lisp_Object dirname) { fprintf (stderr, format, SDATA (dirname)); /* Don't log the warning before we've initialized!! */ if (initialized) { USE_SAFE_ALLOCA; char *buffer = SAFE_ALLOCA (SBYTES (dirname) + strlen (format) - (sizeof "%s" - 1) + 1); ptrdiff_t message_len = esprintf (buffer, format, SDATA (dirname)); message_dolog (buffer, message_len, 0, STRING_MULTIBYTE (dirname)); SAFE_FREE (); } } void syms_of_lread (void) { defsubr (&Sread); defsubr (&Sread_from_string); defsubr (&Sintern); defsubr (&Sintern_soft); defsubr (&Sunintern); defsubr (&Sget_load_suffixes); defsubr (&Sload); defsubr (&Seval_buffer); defsubr (&Seval_region); defsubr (&Sread_char); defsubr (&Sread_char_exclusive); defsubr (&Sread_event); defsubr (&Sget_file_char); defsubr (&Smapatoms); defsubr (&Slocate_file_internal); DEFVAR_LISP ("obarray", Vobarray, doc: /* Symbol table for use by `intern' and `read'. It is a vector whose length ought to be prime for best results. The vector's contents don't make sense if examined from Lisp programs; to find all the symbols in an obarray, use `mapatoms'. */); DEFVAR_LISP ("values", Vvalues, doc: /* List of values of all expressions which were read, evaluated and printed. Order is reverse chronological. */); XSYMBOL (intern ("values"))->declared_special = 0; DEFVAR_LISP ("standard-input", Vstandard_input, doc: /* Stream for read to get input from. See documentation of `read' for possible values. */); Vstandard_input = Qt; DEFVAR_LISP ("read-with-symbol-positions", Vread_with_symbol_positions, doc: /* If non-nil, add position of read symbols to `read-symbol-positions-list'. If this variable is a buffer, then only forms read from that buffer will be added to `read-symbol-positions-list'. If this variable is t, then all read forms will be added. The effect of all other values other than nil are not currently defined, although they may be in the future. The positions are relative to the last call to `read' or `read-from-string'. It is probably a bad idea to set this variable at the toplevel; bind it instead. */); Vread_with_symbol_positions = Qnil; DEFVAR_LISP ("read-symbol-positions-list", Vread_symbol_positions_list, doc: /* A list mapping read symbols to their positions. This variable is modified during calls to `read' or `read-from-string', but only when `read-with-symbol-positions' is non-nil. Each element of the list looks like (SYMBOL . CHAR-POSITION), where CHAR-POSITION is an integer giving the offset of that occurrence of the symbol from the position where `read' or `read-from-string' started. Note that a symbol will appear multiple times in this list, if it was read multiple times. The list is in the same order as the symbols were read in. */); Vread_symbol_positions_list = Qnil; DEFVAR_LISP ("read-circle", Vread_circle, doc: /* Non-nil means read recursive structures using #N= and #N# syntax. */); Vread_circle = Qt; DEFVAR_LISP ("load-path", Vload_path, doc: /* List of directories to search for files to load. Each element is a string (directory name) or nil (try default directory). Initialized based on EMACSLOADPATH environment variable, if any, otherwise to default specified by file `epaths.h' when Emacs was built. */); DEFVAR_LISP ("load-suffixes", Vload_suffixes, doc: /* List of suffixes for (compiled or source) Emacs Lisp files. This list should not include the empty string. `load' and related functions try to append these suffixes, in order, to the specified file name if a Lisp suffix is allowed or required. */); Vload_suffixes = Fcons (build_pure_c_string (".elc"), Fcons (build_pure_c_string (".el"), Qnil)); DEFVAR_LISP ("load-file-rep-suffixes", Vload_file_rep_suffixes, doc: /* List of suffixes that indicate representations of \ the same file. This list should normally start with the empty string. Enabling Auto Compression mode appends the suffixes in `jka-compr-load-suffixes' to this list and disabling Auto Compression mode removes them again. `load' and related functions use this list to determine whether they should look for compressed versions of a file and, if so, which suffixes they should try to append to the file name in order to do so. However, if you want to customize which suffixes the loading functions recognize as compression suffixes, you should customize `jka-compr-load-suffixes' rather than the present variable. */); Vload_file_rep_suffixes = Fcons (empty_unibyte_string, Qnil); DEFVAR_BOOL ("load-in-progress", load_in_progress, doc: /* Non-nil if inside of `load'. */); DEFSYM (Qload_in_progress, "load-in-progress"); DEFVAR_LISP ("after-load-alist", Vafter_load_alist, doc: /* An alist of expressions to be evalled when particular files are loaded. Each element looks like (REGEXP-OR-FEATURE FORMS...). REGEXP-OR-FEATURE is either a regular expression to match file names, or a symbol \(a feature name). When `load' is run and the file-name argument matches an element's REGEXP-OR-FEATURE, or when `provide' is run and provides the symbol REGEXP-OR-FEATURE, the FORMS in the element are executed. An error in FORMS does not undo the load, but does prevent execution of the rest of the FORMS. */); Vafter_load_alist = Qnil; DEFVAR_LISP ("load-history", Vload_history, doc: /* Alist mapping loaded file names to symbols and features. Each alist element should be a list (FILE-NAME ENTRIES...), where FILE-NAME is the name of a file that has been loaded into Emacs. The file name is absolute and true (i.e. it doesn't contain symlinks). As an exception, one of the alist elements may have FILE-NAME nil, for symbols and features not associated with any file. The remaining ENTRIES in the alist element describe the functions and variables defined in that file, the features provided, and the features required. Each entry has the form `(provide . FEATURE)', `(require . FEATURE)', `(defun . FUNCTION)', `(autoload . SYMBOL)', `(defface . SYMBOL)', or `(t . SYMBOL)'. Entries like `(t . SYMBOL)' may precede a `(defun . FUNCTION)' entry, and means that SYMBOL was an autoload before this file redefined it as a function. In addition, entries may also be single symbols, which means that SYMBOL was defined by `defvar' or `defconst'. During preloading, the file name recorded is relative to the main Lisp directory. These file names are converted to absolute at startup. */); Vload_history = Qnil; DEFVAR_LISP ("load-file-name", Vload_file_name, doc: /* Full name of file being loaded by `load'. */); Vload_file_name = Qnil; DEFVAR_LISP ("user-init-file", Vuser_init_file, doc: /* File name, including directory, of user's initialization file. If the file loaded had extension `.elc', and the corresponding source file exists, this variable contains the name of source file, suitable for use by functions like `custom-save-all' which edit the init file. While Emacs loads and evaluates the init file, value is the real name of the file, regardless of whether or not it has the `.elc' extension. */); Vuser_init_file = Qnil; DEFVAR_LISP ("current-load-list", Vcurrent_load_list, doc: /* Used for internal purposes by `load'. */); Vcurrent_load_list = Qnil; DEFVAR_LISP ("load-read-function", Vload_read_function, doc: /* Function used by `load' and `eval-region' for reading expressions. The default is nil, which means use the function `read'. */); Vload_read_function = Qnil; DEFVAR_LISP ("load-source-file-function", Vload_source_file_function, doc: /* Function called in `load' to load an Emacs Lisp source file. The value should be a function for doing code conversion before reading a source file. It can also be nil, in which case loading is done without any code conversion. If the value is a function, it is called with four arguments, FULLNAME, FILE, NOERROR, NOMESSAGE. FULLNAME is the absolute name of the file to load, FILE is the non-absolute name (for messages etc.), and NOERROR and NOMESSAGE are the corresponding arguments passed to `load'. The function should return t if the file was loaded. */); Vload_source_file_function = Qnil; DEFVAR_BOOL ("load-force-doc-strings", load_force_doc_strings, doc: /* Non-nil means `load' should force-load all dynamic doc strings. This is useful when the file being loaded is a temporary copy. */); load_force_doc_strings = 0; DEFVAR_BOOL ("load-convert-to-unibyte", load_convert_to_unibyte, doc: /* Non-nil means `read' converts strings to unibyte whenever possible. This is normally bound by `load' and `eval-buffer' to control `read', and is not meant for users to change. */); load_convert_to_unibyte = 0; DEFVAR_LISP ("source-directory", Vsource_directory, doc: /* Directory in which Emacs sources were found when Emacs was built. You cannot count on them to still be there! */); Vsource_directory = Fexpand_file_name (build_string ("../"), Fcar (decode_env_path (0, PATH_DUMPLOADSEARCH))); DEFVAR_LISP ("preloaded-file-list", Vpreloaded_file_list, doc: /* List of files that were preloaded (when dumping Emacs). */); Vpreloaded_file_list = Qnil; DEFVAR_LISP ("byte-boolean-vars", Vbyte_boolean_vars, doc: /* List of all DEFVAR_BOOL variables, used by the byte code optimizer. */); Vbyte_boolean_vars = Qnil; DEFVAR_BOOL ("load-dangerous-libraries", load_dangerous_libraries, doc: /* Non-nil means load dangerous compiled Lisp files. Some versions of XEmacs use different byte codes than Emacs. These incompatible byte codes can make Emacs crash when it tries to execute them. */); load_dangerous_libraries = 0; DEFVAR_BOOL ("force-load-messages", force_load_messages, doc: /* Non-nil means force printing messages when loading Lisp files. This overrides the value of the NOMESSAGE argument to `load'. */); force_load_messages = 0; DEFVAR_LISP ("bytecomp-version-regexp", Vbytecomp_version_regexp, doc: /* Regular expression matching safe to load compiled Lisp files. When Emacs loads a compiled Lisp file, it reads the first 512 bytes from the file, and matches them against this regular expression. When the regular expression matches, the file is considered to be safe to load. See also `load-dangerous-libraries'. */); Vbytecomp_version_regexp = build_pure_c_string ("^;;;.\\(in Emacs version\\|bytecomp version FSF\\)"); DEFSYM (Qlexical_binding, "lexical-binding"); DEFVAR_LISP ("lexical-binding", Vlexical_binding, doc: /* Whether to use lexical binding when evaluating code. Non-nil means that the code in the current buffer should be evaluated with lexical binding. This variable is automatically set from the file variables of an interpreted Lisp file read using `load'. Unlike other file local variables, this must be set in the first line of a file. */); Vlexical_binding = Qnil; Fmake_variable_buffer_local (Qlexical_binding); DEFVAR_LISP ("eval-buffer-list", Veval_buffer_list, doc: /* List of buffers being read from by calls to `eval-buffer' and `eval-region'. */); Veval_buffer_list = Qnil; DEFVAR_LISP ("old-style-backquotes", Vold_style_backquotes, doc: /* Set to non-nil when `read' encounters an old-style backquote. */); Vold_style_backquotes = Qnil; DEFSYM (Qold_style_backquotes, "old-style-backquotes"); /* Vsource_directory was initialized in init_lread. */ load_descriptor_list = Qnil; staticpro (&load_descriptor_list); DEFSYM (Qcurrent_load_list, "current-load-list"); DEFSYM (Qstandard_input, "standard-input"); DEFSYM (Qread_char, "read-char"); DEFSYM (Qget_file_char, "get-file-char"); DEFSYM (Qget_emacs_mule_file_char, "get-emacs-mule-file-char"); DEFSYM (Qload_force_doc_strings, "load-force-doc-strings"); DEFSYM (Qbackquote, "`"); DEFSYM (Qcomma, ","); DEFSYM (Qcomma_at, ",@"); DEFSYM (Qcomma_dot, ",."); DEFSYM (Qinhibit_file_name_operation, "inhibit-file-name-operation"); DEFSYM (Qascii_character, "ascii-character"); DEFSYM (Qfunction, "function"); DEFSYM (Qload, "load"); DEFSYM (Qload_file_name, "load-file-name"); DEFSYM (Qeval_buffer_list, "eval-buffer-list"); DEFSYM (Qfile_truename, "file-truename"); DEFSYM (Qdir_ok, "dir-ok"); DEFSYM (Qdo_after_load_evaluation, "do-after-load-evaluation"); staticpro (&dump_path); staticpro (&read_objects); read_objects = Qnil; staticpro (&seen_list); seen_list = Qnil; Vloads_in_progress = Qnil; staticpro (&Vloads_in_progress); DEFSYM (Qhash_table, "hash-table"); DEFSYM (Qdata, "data"); DEFSYM (Qtest, "test"); DEFSYM (Qsize, "size"); DEFSYM (Qweakness, "weakness"); DEFSYM (Qrehash_size, "rehash-size"); DEFSYM (Qrehash_threshold, "rehash-threshold"); }