/* vi:set ts=8 sts=4 sw=4: * * VIM - Vi IMproved by Bram Moolenaar * * Do ":help uganda" in Vim to read copying and usage conditions. * Do ":help credits" in Vim to see a list of people who contributed. * See README.txt for an overview of the Vim source code. */ /* * undo.c: multi level undo facility * * The saved lines are stored in a list of lists (one for each buffer): * * b_u_oldhead------------------------------------------------+ * | * V * +--------------+ +--------------+ +--------------+ * b_u_newhead--->| u_header | | u_header | | u_header | * | uh_next------>| uh_next------>| uh_next---->NULL * NULL<--------uh_prev |<---------uh_prev |<---------uh_prev | * | uh_entry | | uh_entry | | uh_entry | * +--------|-----+ +--------|-----+ +--------|-----+ * | | | * V V V * +--------------+ +--------------+ +--------------+ * | u_entry | | u_entry | | u_entry | * | ue_next | | ue_next | | ue_next | * +--------|-----+ +--------|-----+ +--------|-----+ * | | | * V V V * +--------------+ NULL NULL * | u_entry | * | ue_next | * +--------|-----+ * | * V * etc. * * Each u_entry list contains the information for one undo or redo. * curbuf->b_u_curhead points to the header of the last undo (the next redo), * or is NULL if nothing has been undone (end of the branch). * * For keeping alternate undo/redo branches the uh_alt field is used. Thus at * each point in the list a branch may appear for an alternate to redo. The * uh_seq field is numbered sequentially to be able to find a newer or older * branch. * * +---------------+ +---------------+ * b_u_oldhead --->| u_header | | u_header | * | uh_alt_next ---->| uh_alt_next ----> NULL * NULL <----- uh_alt_prev |<------ uh_alt_prev | * | uh_prev | | uh_prev | * +-----|---------+ +-----|---------+ * | | * V V * +---------------+ +---------------+ * | u_header | | u_header | * | uh_alt_next | | uh_alt_next | * b_u_newhead --->| uh_alt_prev | | uh_alt_prev | * | uh_prev | | uh_prev | * +-----|---------+ +-----|---------+ * | | * V V * NULL +---------------+ +---------------+ * | u_header | | u_header | * | uh_alt_next ---->| uh_alt_next | * | uh_alt_prev |<------ uh_alt_prev | * | uh_prev | | uh_prev | * +-----|---------+ +-----|---------+ * | | * etc. etc. * * * All data is allocated and will all be freed when the buffer is unloaded. */ /* Uncomment the next line for including the u_check() function. This warns * for errors in the debug information. */ /* #define U_DEBUG 1 */ #define UH_MAGIC 0x18dade /* value for uh_magic when in use */ #define UE_MAGIC 0xabc123 /* value for ue_magic when in use */ /* Size of buffer used for encryption. */ #define CRYPT_BUF_SIZE 8192 #include "vim.h" /* Structure passed around between functions. * Avoids passing cryptstate_T when encryption not available. */ typedef struct { buf_T *bi_buf; FILE *bi_fp; #ifdef FEAT_CRYPT cryptstate_T *bi_state; char_u *bi_buffer; /* CRYPT_BUF_SIZE, NULL when not buffering */ size_t bi_used; /* bytes written to/read from bi_buffer */ size_t bi_avail; /* bytes available in bi_buffer */ #endif } bufinfo_T; static long get_undolevel __ARGS((void)); static void u_unch_branch __ARGS((u_header_T *uhp)); static u_entry_T *u_get_headentry __ARGS((void)); static void u_getbot __ARGS((void)); static void u_doit __ARGS((int count)); static void u_undoredo __ARGS((int undo)); static void u_undo_end __ARGS((int did_undo, int absolute)); static void u_add_time __ARGS((char_u *buf, size_t buflen, time_t tt)); static void u_freeheader __ARGS((buf_T *buf, u_header_T *uhp, u_header_T **uhpp)); static void u_freebranch __ARGS((buf_T *buf, u_header_T *uhp, u_header_T **uhpp)); static void u_freeentries __ARGS((buf_T *buf, u_header_T *uhp, u_header_T **uhpp)); static void u_freeentry __ARGS((u_entry_T *, long)); #ifdef FEAT_PERSISTENT_UNDO static void corruption_error __ARGS((char *mesg, char_u *file_name)); static void u_free_uhp __ARGS((u_header_T *uhp)); static int undo_write __ARGS((bufinfo_T *bi, char_u *ptr, size_t len)); static int undo_flush __ARGS((bufinfo_T *bi)); static int fwrite_crypt __ARGS((bufinfo_T *bi, char_u *ptr, size_t len)); static int undo_write_bytes __ARGS((bufinfo_T *bi, long_u nr, int len)); static void put_header_ptr __ARGS((bufinfo_T *bi, u_header_T *uhp)); static int undo_read_4c __ARGS((bufinfo_T *bi)); static int undo_read_2c __ARGS((bufinfo_T *bi)); static int undo_read_byte __ARGS((bufinfo_T *bi)); static time_t undo_read_time __ARGS((bufinfo_T *bi)); static int undo_read __ARGS((bufinfo_T *bi, char_u *buffer, size_t size)); static char_u *read_string_decrypt __ARGS((bufinfo_T *bi, int len)); static int serialize_header __ARGS((bufinfo_T *bi, char_u *hash)); static int serialize_uhp __ARGS((bufinfo_T *bi, u_header_T *uhp)); static u_header_T *unserialize_uhp __ARGS((bufinfo_T *bi, char_u *file_name)); static int serialize_uep __ARGS((bufinfo_T *bi, u_entry_T *uep)); static u_entry_T *unserialize_uep __ARGS((bufinfo_T *bi, int *error, char_u *file_name)); static void serialize_pos __ARGS((bufinfo_T *bi, pos_T pos)); static void unserialize_pos __ARGS((bufinfo_T *bi, pos_T *pos)); static void serialize_visualinfo __ARGS((bufinfo_T *bi, visualinfo_T *info)); static void unserialize_visualinfo __ARGS((bufinfo_T *bi, visualinfo_T *info)); #endif #define U_ALLOC_LINE(size) lalloc((long_u)(size), FALSE) static char_u *u_save_line __ARGS((linenr_T)); /* used in undo_end() to report number of added and deleted lines */ static long u_newcount, u_oldcount; /* * When 'u' flag included in 'cpoptions', we behave like vi. Need to remember * the action that "u" should do. */ static int undo_undoes = FALSE; static int lastmark = 0; #if defined(U_DEBUG) || defined(PROTO) /* * Check the undo structures for being valid. Print a warning when something * looks wrong. */ static int seen_b_u_curhead; static int seen_b_u_newhead; static int header_count; static void u_check_tree(u_header_T *uhp, u_header_T *exp_uh_next, u_header_T *exp_uh_alt_prev) { u_entry_T *uep; if (uhp == NULL) return; ++header_count; if (uhp == curbuf->b_u_curhead && ++seen_b_u_curhead > 1) { EMSG("b_u_curhead found twice (looping?)"); return; } if (uhp == curbuf->b_u_newhead && ++seen_b_u_newhead > 1) { EMSG("b_u_newhead found twice (looping?)"); return; } if (uhp->uh_magic != UH_MAGIC) EMSG("uh_magic wrong (may be using freed memory)"); else { /* Check pointers back are correct. */ if (uhp->uh_next.ptr != exp_uh_next) { EMSG("uh_next wrong"); smsg((char_u *)"expected: 0x%x, actual: 0x%x", exp_uh_next, uhp->uh_next.ptr); } if (uhp->uh_alt_prev.ptr != exp_uh_alt_prev) { EMSG("uh_alt_prev wrong"); smsg((char_u *)"expected: 0x%x, actual: 0x%x", exp_uh_alt_prev, uhp->uh_alt_prev.ptr); } /* Check the undo tree at this header. */ for (uep = uhp->uh_entry; uep != NULL; uep = uep->ue_next) { if (uep->ue_magic != UE_MAGIC) { EMSG("ue_magic wrong (may be using freed memory)"); break; } } /* Check the next alt tree. */ u_check_tree(uhp->uh_alt_next.ptr, uhp->uh_next.ptr, uhp); /* Check the next header in this branch. */ u_check_tree(uhp->uh_prev.ptr, uhp, NULL); } } static void u_check(int newhead_may_be_NULL) { seen_b_u_newhead = 0; seen_b_u_curhead = 0; header_count = 0; u_check_tree(curbuf->b_u_oldhead, NULL, NULL); if (seen_b_u_newhead == 0 && curbuf->b_u_oldhead != NULL && !(newhead_may_be_NULL && curbuf->b_u_newhead == NULL)) EMSGN("b_u_newhead invalid: 0x%x", curbuf->b_u_newhead); if (curbuf->b_u_curhead != NULL && seen_b_u_curhead == 0) EMSGN("b_u_curhead invalid: 0x%x", curbuf->b_u_curhead); if (header_count != curbuf->b_u_numhead) { EMSG("b_u_numhead invalid"); smsg((char_u *)"expected: %ld, actual: %ld", (long)header_count, (long)curbuf->b_u_numhead); } } #endif /* * Save the current line for both the "u" and "U" command. * Careful: may trigger autocommands that reload the buffer. * Returns OK or FAIL. */ int u_save_cursor() { return (u_save((linenr_T)(curwin->w_cursor.lnum - 1), (linenr_T)(curwin->w_cursor.lnum + 1))); } /* * Save the lines between "top" and "bot" for both the "u" and "U" command. * "top" may be 0 and bot may be curbuf->b_ml.ml_line_count + 1. * Careful: may trigger autocommands that reload the buffer. * Returns FAIL when lines could not be saved, OK otherwise. */ int u_save(top, bot) linenr_T top, bot; { if (undo_off) return OK; if (top > curbuf->b_ml.ml_line_count || top >= bot || bot > curbuf->b_ml.ml_line_count + 1) return FALSE; /* rely on caller to do error messages */ if (top + 2 == bot) u_saveline((linenr_T)(top + 1)); return (u_savecommon(top, bot, (linenr_T)0, FALSE)); } /* * Save the line "lnum" (used by ":s" and "~" command). * The line is replaced, so the new bottom line is lnum + 1. * Careful: may trigger autocommands that reload the buffer. * Returns FAIL when lines could not be saved, OK otherwise. */ int u_savesub(lnum) linenr_T lnum; { if (undo_off) return OK; return (u_savecommon(lnum - 1, lnum + 1, lnum + 1, FALSE)); } /* * A new line is inserted before line "lnum" (used by :s command). * The line is inserted, so the new bottom line is lnum + 1. * Careful: may trigger autocommands that reload the buffer. * Returns FAIL when lines could not be saved, OK otherwise. */ int u_inssub(lnum) linenr_T lnum; { if (undo_off) return OK; return (u_savecommon(lnum - 1, lnum, lnum + 1, FALSE)); } /* * Save the lines "lnum" - "lnum" + nlines (used by delete command). * The lines are deleted, so the new bottom line is lnum, unless the buffer * becomes empty. * Careful: may trigger autocommands that reload the buffer. * Returns FAIL when lines could not be saved, OK otherwise. */ int u_savedel(lnum, nlines) linenr_T lnum; long nlines; { if (undo_off) return OK; return (u_savecommon(lnum - 1, lnum + nlines, nlines == curbuf->b_ml.ml_line_count ? 2 : lnum, FALSE)); } /* * Return TRUE when undo is allowed. Otherwise give an error message and * return FALSE. */ int undo_allowed() { /* Don't allow changes when 'modifiable' is off. */ if (!curbuf->b_p_ma) { EMSG(_(e_modifiable)); return FALSE; } #ifdef HAVE_SANDBOX /* In the sandbox it's not allowed to change the text. */ if (sandbox != 0) { EMSG(_(e_sandbox)); return FALSE; } #endif /* Don't allow changes in the buffer while editing the cmdline. The * caller of getcmdline() may get confused. */ if (textlock != 0) { EMSG(_(e_secure)); return FALSE; } return TRUE; } /* * Get the undolevle value for the current buffer. */ static long get_undolevel() { if (curbuf->b_p_ul == NO_LOCAL_UNDOLEVEL) return p_ul; return curbuf->b_p_ul; } /* * Common code for various ways to save text before a change. * "top" is the line above the first changed line. * "bot" is the line below the last changed line. * "newbot" is the new bottom line. Use zero when not known. * "reload" is TRUE when saving for a buffer reload. * Careful: may trigger autocommands that reload the buffer. * Returns FAIL when lines could not be saved, OK otherwise. */ int u_savecommon(top, bot, newbot, reload) linenr_T top, bot; linenr_T newbot; int reload; { linenr_T lnum; long i; u_header_T *uhp; u_header_T *old_curhead; u_entry_T *uep; u_entry_T *prev_uep; long size; if (!reload) { /* When making changes is not allowed return FAIL. It's a crude way * to make all change commands fail. */ if (!undo_allowed()) return FAIL; #ifdef FEAT_NETBEANS_INTG /* * Netbeans defines areas that cannot be modified. Bail out here when * trying to change text in a guarded area. */ if (netbeans_active()) { if (netbeans_is_guarded(top, bot)) { EMSG(_(e_guarded)); return FAIL; } if (curbuf->b_p_ro) { EMSG(_(e_nbreadonly)); return FAIL; } } #endif #ifdef FEAT_AUTOCMD /* * Saving text for undo means we are going to make a change. Give a * warning for a read-only file before making the change, so that the * FileChangedRO event can replace the buffer with a read-write version * (e.g., obtained from a source control system). */ change_warning(0); if (bot > curbuf->b_ml.ml_line_count + 1) { /* This happens when the FileChangedRO autocommand changes the * file in a way it becomes shorter. */ EMSG(_("E881: Line count changed unexpectedly")); return FAIL; } #endif } #ifdef U_DEBUG u_check(FALSE); #endif size = bot - top - 1; /* * If curbuf->b_u_synced == TRUE make a new header. */ if (curbuf->b_u_synced) { #ifdef FEAT_JUMPLIST /* Need to create new entry in b_changelist. */ curbuf->b_new_change = TRUE; #endif if (get_undolevel() >= 0) { /* * Make a new header entry. Do this first so that we don't mess * up the undo info when out of memory. */ uhp = (u_header_T *)U_ALLOC_LINE(sizeof(u_header_T)); if (uhp == NULL) goto nomem; #ifdef U_DEBUG uhp->uh_magic = UH_MAGIC; #endif } else uhp = NULL; /* * If we undid more than we redid, move the entry lists before and * including curbuf->b_u_curhead to an alternate branch. */ old_curhead = curbuf->b_u_curhead; if (old_curhead != NULL) { curbuf->b_u_newhead = old_curhead->uh_next.ptr; curbuf->b_u_curhead = NULL; } /* * free headers to keep the size right */ while (curbuf->b_u_numhead > get_undolevel() && curbuf->b_u_oldhead != NULL) { u_header_T *uhfree = curbuf->b_u_oldhead; if (uhfree == old_curhead) /* Can't reconnect the branch, delete all of it. */ u_freebranch(curbuf, uhfree, &old_curhead); else if (uhfree->uh_alt_next.ptr == NULL) /* There is no branch, only free one header. */ u_freeheader(curbuf, uhfree, &old_curhead); else { /* Free the oldest alternate branch as a whole. */ while (uhfree->uh_alt_next.ptr != NULL) uhfree = uhfree->uh_alt_next.ptr; u_freebranch(curbuf, uhfree, &old_curhead); } #ifdef U_DEBUG u_check(TRUE); #endif } if (uhp == NULL) /* no undo at all */ { if (old_curhead != NULL) u_freebranch(curbuf, old_curhead, NULL); curbuf->b_u_synced = FALSE; return OK; } uhp->uh_prev.ptr = NULL; uhp->uh_next.ptr = curbuf->b_u_newhead; uhp->uh_alt_next.ptr = old_curhead; if (old_curhead != NULL) { uhp->uh_alt_prev.ptr = old_curhead->uh_alt_prev.ptr; if (uhp->uh_alt_prev.ptr != NULL) uhp->uh_alt_prev.ptr->uh_alt_next.ptr = uhp; old_curhead->uh_alt_prev.ptr = uhp; if (curbuf->b_u_oldhead == old_curhead) curbuf->b_u_oldhead = uhp; } else uhp->uh_alt_prev.ptr = NULL; if (curbuf->b_u_newhead != NULL) curbuf->b_u_newhead->uh_prev.ptr = uhp; uhp->uh_seq = ++curbuf->b_u_seq_last; curbuf->b_u_seq_cur = uhp->uh_seq; uhp->uh_time = time(NULL); uhp->uh_save_nr = 0; curbuf->b_u_time_cur = uhp->uh_time + 1; uhp->uh_walk = 0; uhp->uh_entry = NULL; uhp->uh_getbot_entry = NULL; uhp->uh_cursor = curwin->w_cursor; /* save cursor pos. for undo */ #ifdef FEAT_VIRTUALEDIT if (virtual_active() && curwin->w_cursor.coladd > 0) uhp->uh_cursor_vcol = getviscol(); else uhp->uh_cursor_vcol = -1; #endif /* save changed and buffer empty flag for undo */ uhp->uh_flags = (curbuf->b_changed ? UH_CHANGED : 0) + ((curbuf->b_ml.ml_flags & ML_EMPTY) ? UH_EMPTYBUF : 0); /* save named marks and Visual marks for undo */ mch_memmove(uhp->uh_namedm, curbuf->b_namedm, sizeof(pos_T) * NMARKS); uhp->uh_visual = curbuf->b_visual; curbuf->b_u_newhead = uhp; if (curbuf->b_u_oldhead == NULL) curbuf->b_u_oldhead = uhp; ++curbuf->b_u_numhead; } else { if (get_undolevel() < 0) /* no undo at all */ return OK; /* * When saving a single line, and it has been saved just before, it * doesn't make sense saving it again. Saves a lot of memory when * making lots of changes inside the same line. * This is only possible if the previous change didn't increase or * decrease the number of lines. * Check the ten last changes. More doesn't make sense and takes too * long. */ if (size == 1) { uep = u_get_headentry(); prev_uep = NULL; for (i = 0; i < 10; ++i) { if (uep == NULL) break; /* If lines have been inserted/deleted we give up. * Also when the line was included in a multi-line save. */ if ((curbuf->b_u_newhead->uh_getbot_entry != uep ? (uep->ue_top + uep->ue_size + 1 != (uep->ue_bot == 0 ? curbuf->b_ml.ml_line_count + 1 : uep->ue_bot)) : uep->ue_lcount != curbuf->b_ml.ml_line_count) || (uep->ue_size > 1 && top >= uep->ue_top && top + 2 <= uep->ue_top + uep->ue_size + 1)) break; /* If it's the same line we can skip saving it again. */ if (uep->ue_size == 1 && uep->ue_top == top) { if (i > 0) { /* It's not the last entry: get ue_bot for the last * entry now. Following deleted/inserted lines go to * the re-used entry. */ u_getbot(); curbuf->b_u_synced = FALSE; /* Move the found entry to become the last entry. The * order of undo/redo doesn't matter for the entries * we move it over, since they don't change the line * count and don't include this line. It does matter * for the found entry if the line count is changed by * the executed command. */ prev_uep->ue_next = uep->ue_next; uep->ue_next = curbuf->b_u_newhead->uh_entry; curbuf->b_u_newhead->uh_entry = uep; } /* The executed command may change the line count. */ if (newbot != 0) uep->ue_bot = newbot; else if (bot > curbuf->b_ml.ml_line_count) uep->ue_bot = 0; else { uep->ue_lcount = curbuf->b_ml.ml_line_count; curbuf->b_u_newhead->uh_getbot_entry = uep; } return OK; } prev_uep = uep; uep = uep->ue_next; } } /* find line number for ue_bot for previous u_save() */ u_getbot(); } #if !defined(UNIX) && !defined(DJGPP) && !defined(WIN32) && !defined(__EMX__) /* * With Amiga and MSDOS 16 bit we can't handle big undo's, because * then u_alloc_line would have to allocate a block larger than 32K */ if (size >= 8000) goto nomem; #endif /* * add lines in front of entry list */ uep = (u_entry_T *)U_ALLOC_LINE(sizeof(u_entry_T)); if (uep == NULL) goto nomem; vim_memset(uep, 0, sizeof(u_entry_T)); #ifdef U_DEBUG uep->ue_magic = UE_MAGIC; #endif uep->ue_size = size; uep->ue_top = top; if (newbot != 0) uep->ue_bot = newbot; /* * Use 0 for ue_bot if bot is below last line. * Otherwise we have to compute ue_bot later. */ else if (bot > curbuf->b_ml.ml_line_count) uep->ue_bot = 0; else { uep->ue_lcount = curbuf->b_ml.ml_line_count; curbuf->b_u_newhead->uh_getbot_entry = uep; } if (size > 0) { if ((uep->ue_array = (char_u **)U_ALLOC_LINE( sizeof(char_u *) * size)) == NULL) { u_freeentry(uep, 0L); goto nomem; } for (i = 0, lnum = top + 1; i < size; ++i) { fast_breakcheck(); if (got_int) { u_freeentry(uep, i); return FAIL; } if ((uep->ue_array[i] = u_save_line(lnum++)) == NULL) { u_freeentry(uep, i); goto nomem; } } } else uep->ue_array = NULL; uep->ue_next = curbuf->b_u_newhead->uh_entry; curbuf->b_u_newhead->uh_entry = uep; curbuf->b_u_synced = FALSE; undo_undoes = FALSE; #ifdef U_DEBUG u_check(FALSE); #endif return OK; nomem: msg_silent = 0; /* must display the prompt */ if (ask_yesno((char_u *)_("No undo possible; continue anyway"), TRUE) == 'y') { undo_off = TRUE; /* will be reset when character typed */ return OK; } do_outofmem_msg((long_u)0); return FAIL; } #if defined(FEAT_PERSISTENT_UNDO) || defined(PROTO) # define UF_START_MAGIC "Vim\237UnDo\345" /* magic at start of undofile */ # define UF_START_MAGIC_LEN 9 # define UF_HEADER_MAGIC 0x5fd0 /* magic at start of header */ # define UF_HEADER_END_MAGIC 0xe7aa /* magic after last header */ # define UF_ENTRY_MAGIC 0xf518 /* magic at start of entry */ # define UF_ENTRY_END_MAGIC 0x3581 /* magic after last entry */ # define UF_VERSION 2 /* 2-byte undofile version number */ # define UF_VERSION_CRYPT 0x8002 /* idem, encrypted */ /* extra fields for header */ # define UF_LAST_SAVE_NR 1 /* extra fields for uhp */ # define UHP_SAVE_NR 1 static char_u e_not_open[] = N_("E828: Cannot open undo file for writing: %s"); /* * Compute the hash for the current buffer text into hash[UNDO_HASH_SIZE]. */ void u_compute_hash(hash) char_u *hash; { context_sha256_T ctx; linenr_T lnum; char_u *p; sha256_start(&ctx); for (lnum = 1; lnum <= curbuf->b_ml.ml_line_count; ++lnum) { p = ml_get(lnum); sha256_update(&ctx, p, (UINT32_T)(STRLEN(p) + 1)); } sha256_finish(&ctx, hash); } /* * Return an allocated string of the full path of the target undofile. * When "reading" is TRUE find the file to read, go over all directories in * 'undodir'. * When "reading" is FALSE use the first name where the directory exists. * Returns NULL when there is no place to write or no file to read. */ char_u * u_get_undo_file_name(buf_ffname, reading) char_u *buf_ffname; int reading; { char_u *dirp; char_u dir_name[IOSIZE + 1]; char_u *munged_name = NULL; char_u *undo_file_name = NULL; int dir_len; char_u *p; struct stat st; char_u *ffname = buf_ffname; #ifdef HAVE_READLINK char_u fname_buf[MAXPATHL]; #endif if (ffname == NULL) return NULL; #ifdef HAVE_READLINK /* Expand symlink in the file name, so that we put the undo file with the * actual file instead of with the symlink. */ if (resolve_symlink(ffname, fname_buf) == OK) ffname = fname_buf; #endif /* Loop over 'undodir'. When reading find the first file that exists. * When not reading use the first directory that exists or ".". */ dirp = p_udir; while (*dirp != NUL) { dir_len = copy_option_part(&dirp, dir_name, IOSIZE, ","); if (dir_len == 1 && dir_name[0] == '.') { /* Use same directory as the ffname, * "dir/name" -> "dir/.name.un~" */ undo_file_name = vim_strnsave(ffname, (int)(STRLEN(ffname) + 5)); if (undo_file_name == NULL) break; p = gettail(undo_file_name); #ifdef VMS /* VMS can not handle more than one dot in the filenames * use "dir/name" -> "dir/_un_name" - add _un_ * at the beginning to keep the extension */ mch_memmove(p + 4, p, STRLEN(p) + 1); mch_memmove(p, "_un_", 4); #else /* Use same directory as the ffname, * "dir/name" -> "dir/.name.un~" */ mch_memmove(p + 1, p, STRLEN(p) + 1); *p = '.'; STRCAT(p, ".un~"); #endif } else { dir_name[dir_len] = NUL; if (mch_isdir(dir_name)) { if (munged_name == NULL) { munged_name = vim_strsave(ffname); if (munged_name == NULL) return NULL; for (p = munged_name; *p != NUL; mb_ptr_adv(p)) if (vim_ispathsep(*p)) *p = '%'; } undo_file_name = concat_fnames(dir_name, munged_name, TRUE); } } /* When reading check if the file exists. */ if (undo_file_name != NULL && (!reading || mch_stat((char *)undo_file_name, &st) >= 0)) break; vim_free(undo_file_name); undo_file_name = NULL; } vim_free(munged_name); return undo_file_name; } static void corruption_error(mesg, file_name) char *mesg; char_u *file_name; { EMSG3(_("E825: Corrupted undo file (%s): %s"), mesg, file_name); } static void u_free_uhp(uhp) u_header_T *uhp; { u_entry_T *nuep; u_entry_T *uep; uep = uhp->uh_entry; while (uep != NULL) { nuep = uep->ue_next; u_freeentry(uep, uep->ue_size); uep = nuep; } vim_free(uhp); } /* * Write a sequence of bytes to the undo file. * Buffers and encrypts as needed. * Returns OK or FAIL. */ static int undo_write(bi, ptr, len) bufinfo_T *bi; char_u *ptr; size_t len; { #ifdef FEAT_CRYPT if (bi->bi_buffer != NULL) { size_t len_todo = len; char_u *p = ptr; while (bi->bi_used + len_todo >= CRYPT_BUF_SIZE) { size_t n = CRYPT_BUF_SIZE - bi->bi_used; mch_memmove(bi->bi_buffer + bi->bi_used, p, n); len_todo -= n; p += n; bi->bi_used = CRYPT_BUF_SIZE; if (undo_flush(bi) == FAIL) return FAIL; } if (len_todo > 0) { mch_memmove(bi->bi_buffer + bi->bi_used, p, len_todo); bi->bi_used += len_todo; } return OK; } #endif if (fwrite(ptr, len, (size_t)1, bi->bi_fp) != 1) return FAIL; return OK; } #ifdef FEAT_CRYPT static int undo_flush(bi) bufinfo_T *bi; { if (bi->bi_used > 0) { crypt_encode_inplace(bi->bi_state, bi->bi_buffer, bi->bi_used); if (fwrite(bi->bi_buffer, bi->bi_used, (size_t)1, bi->bi_fp) != 1) return FAIL; bi->bi_used = 0; } return OK; } #endif /* * Write "ptr[len]" and crypt the bytes when needed. * Returns OK or FAIL. */ static int fwrite_crypt(bi, ptr, len) bufinfo_T *bi; char_u *ptr; size_t len; { #ifdef FEAT_CRYPT char_u *copy; char_u small_buf[100]; size_t i; if (bi->bi_state != NULL && bi->bi_buffer == NULL) { /* crypting every piece of text separately */ if (len < 100) copy = small_buf; /* no malloc()/free() for short strings */ else { copy = lalloc(len, FALSE); if (copy == NULL) return 0; } crypt_encode(bi->bi_state, ptr, len, copy); i = fwrite(copy, len, (size_t)1, bi->bi_fp); if (copy != small_buf) vim_free(copy); return i == 1 ? OK : FAIL; } #endif return undo_write(bi, ptr, len); } /* * Write a number, MSB first, in "len" bytes. * Must match with undo_read_?c() functions. * Returns OK or FAIL. */ static int undo_write_bytes(bi, nr, len) bufinfo_T *bi; long_u nr; int len; { char_u buf[8]; int i; int bufi = 0; for (i = len - 1; i >= 0; --i) buf[bufi++] = nr >> (i * 8); return undo_write(bi, buf, (size_t)len); } /* * Write the pointer to an undo header. Instead of writing the pointer itself * we use the sequence number of the header. This is converted back to * pointers when reading. */ static void put_header_ptr(bi, uhp) bufinfo_T *bi; u_header_T *uhp; { undo_write_bytes(bi, (long_u)(uhp != NULL ? uhp->uh_seq : 0), 4); } static int undo_read_4c(bi) bufinfo_T *bi; { #ifdef FEAT_CRYPT if (bi->bi_buffer != NULL) { char_u buf[4]; int n; undo_read(bi, buf, (size_t)4); n = (buf[0] << 24) + (buf[1] << 16) + (buf[2] << 8) + buf[3]; return n; } #endif return get4c(bi->bi_fp); } static int undo_read_2c(bi) bufinfo_T *bi; { #ifdef FEAT_CRYPT if (bi->bi_buffer != NULL) { char_u buf[2]; int n; undo_read(bi, buf, (size_t)2); n = (buf[0] << 8) + buf[1]; return n; } #endif return get2c(bi->bi_fp); } static int undo_read_byte(bi) bufinfo_T *bi; { #ifdef FEAT_CRYPT if (bi->bi_buffer != NULL) { char_u buf[1]; undo_read(bi, buf, (size_t)1); return buf[0]; } #endif return getc(bi->bi_fp); } static time_t undo_read_time(bi) bufinfo_T *bi; { #ifdef FEAT_CRYPT if (bi->bi_buffer != NULL) { char_u buf[8]; time_t n = 0; int i; undo_read(bi, buf, (size_t)8); for (i = 0; i < 8; ++i) n = (n << 8) + buf[i]; return n; } #endif return get8ctime(bi->bi_fp); } /* * Read "buffer[size]" from the undo file. * Return OK or FAIL. */ static int undo_read(bi, buffer, size) bufinfo_T *bi; char_u *buffer; size_t size; { #ifdef FEAT_CRYPT if (bi->bi_buffer != NULL) { int size_todo = size; char_u *p = buffer; while (size_todo > 0) { size_t n; if (bi->bi_used >= bi->bi_avail) { n = fread(bi->bi_buffer, 1, (size_t)CRYPT_BUF_SIZE, bi->bi_fp); if (n <= 0) { /* Error may be checked for only later. Fill with zeros, * so that the reader won't use garbage. */ vim_memset(p, 0, size_todo); return FAIL; } bi->bi_avail = n; bi->bi_used = 0; crypt_decode_inplace(bi->bi_state, bi->bi_buffer, bi->bi_avail); } n = size_todo; if (n > bi->bi_avail - bi->bi_used) n = bi->bi_avail - bi->bi_used; mch_memmove(p, bi->bi_buffer + bi->bi_used, n); bi->bi_used += n; size_todo -= n; p += n; } return OK; } #endif if (fread(buffer, (size_t)size, 1, bi->bi_fp) != 1) return FAIL; return OK; } /* * Read a string of length "len" from "bi->bi_fd". * "len" can be zero to allocate an empty line. * Decrypt the bytes if needed. * Append a NUL. * Returns a pointer to allocated memory or NULL for failure. */ static char_u * read_string_decrypt(bi, len) bufinfo_T *bi; int len; { char_u *ptr = alloc((unsigned)len + 1); if (ptr != NULL) { if (len > 0 && undo_read(bi, ptr, len) == FAIL) { vim_free(ptr); return NULL; } ptr[len] = NUL; #ifdef FEAT_CRYPT if (bi->bi_state != NULL && bi->bi_buffer == NULL) crypt_decode_inplace(bi->bi_state, ptr, len); #endif } return ptr; } /* * Writes the (not encrypted) header and initializes encryption if needed. */ static int serialize_header(bi, hash) bufinfo_T *bi; char_u *hash; { int len; buf_T *buf = bi->bi_buf; FILE *fp = bi->bi_fp; char_u time_buf[8]; /* Start writing, first the magic marker and undo info version. */ if (fwrite(UF_START_MAGIC, (size_t)UF_START_MAGIC_LEN, (size_t)1, fp) != 1) return FAIL; /* If the buffer is encrypted then all text bytes following will be * encrypted. Numbers and other info is not crypted. */ #ifdef FEAT_CRYPT if (*buf->b_p_key != NUL) { char_u *header; int header_len; undo_write_bytes(bi, (long_u)UF_VERSION_CRYPT, 2); bi->bi_state = crypt_create_for_writing(crypt_get_method_nr(buf), buf->b_p_key, &header, &header_len); if (bi->bi_state == NULL) return FAIL; len = (int)fwrite(header, (size_t)header_len, (size_t)1, fp); vim_free(header); if (len != 1) { crypt_free_state(bi->bi_state); bi->bi_state = NULL; return FAIL; } if (crypt_whole_undofile(crypt_get_method_nr(buf))) { bi->bi_buffer = alloc(CRYPT_BUF_SIZE); if (bi->bi_buffer == NULL) { crypt_free_state(bi->bi_state); bi->bi_state = NULL; return FAIL; } bi->bi_used = 0; } } else #endif undo_write_bytes(bi, (long_u)UF_VERSION, 2); /* Write a hash of the buffer text, so that we can verify it is still the * same when reading the buffer text. */ if (undo_write(bi, hash, (size_t)UNDO_HASH_SIZE) == FAIL) return FAIL; /* buffer-specific data */ undo_write_bytes(bi, (long_u)buf->b_ml.ml_line_count, 4); len = buf->b_u_line_ptr != NULL ? (int)STRLEN(buf->b_u_line_ptr) : 0; undo_write_bytes(bi, (long_u)len, 4); if (len > 0 && fwrite_crypt(bi, buf->b_u_line_ptr, (size_t)len) == FAIL) return FAIL; undo_write_bytes(bi, (long_u)buf->b_u_line_lnum, 4); undo_write_bytes(bi, (long_u)buf->b_u_line_colnr, 4); /* Undo structures header data */ put_header_ptr(bi, buf->b_u_oldhead); put_header_ptr(bi, buf->b_u_newhead); put_header_ptr(bi, buf->b_u_curhead); undo_write_bytes(bi, (long_u)buf->b_u_numhead, 4); undo_write_bytes(bi, (long_u)buf->b_u_seq_last, 4); undo_write_bytes(bi, (long_u)buf->b_u_seq_cur, 4); time_to_bytes(buf->b_u_time_cur, time_buf); undo_write(bi, time_buf, 8); /* Optional fields. */ undo_write_bytes(bi, 4, 1); undo_write_bytes(bi, UF_LAST_SAVE_NR, 1); undo_write_bytes(bi, (long_u)buf->b_u_save_nr_last, 4); undo_write_bytes(bi, 0, 1); /* end marker */ return OK; } static int serialize_uhp(bi, uhp) bufinfo_T *bi; u_header_T *uhp; { int i; u_entry_T *uep; char_u time_buf[8]; if (undo_write_bytes(bi, (long_u)UF_HEADER_MAGIC, 2) == FAIL) return FAIL; put_header_ptr(bi, uhp->uh_next.ptr); put_header_ptr(bi, uhp->uh_prev.ptr); put_header_ptr(bi, uhp->uh_alt_next.ptr); put_header_ptr(bi, uhp->uh_alt_prev.ptr); undo_write_bytes(bi, uhp->uh_seq, 4); serialize_pos(bi, uhp->uh_cursor); #ifdef FEAT_VIRTUALEDIT undo_write_bytes(bi, (long_u)uhp->uh_cursor_vcol, 4); #else undo_write_bytes(bi, (long_u)0, 4); #endif undo_write_bytes(bi, (long_u)uhp->uh_flags, 2); /* Assume NMARKS will stay the same. */ for (i = 0; i < NMARKS; ++i) serialize_pos(bi, uhp->uh_namedm[i]); serialize_visualinfo(bi, &uhp->uh_visual); time_to_bytes(uhp->uh_time, time_buf); undo_write(bi, time_buf, 8); /* Optional fields. */ undo_write_bytes(bi, 4, 1); undo_write_bytes(bi, UHP_SAVE_NR, 1); undo_write_bytes(bi, (long_u)uhp->uh_save_nr, 4); undo_write_bytes(bi, 0, 1); /* end marker */ /* Write all the entries. */ for (uep = uhp->uh_entry; uep != NULL; uep = uep->ue_next) { undo_write_bytes(bi, (long_u)UF_ENTRY_MAGIC, 2); if (serialize_uep(bi, uep) == FAIL) return FAIL; } undo_write_bytes(bi, (long_u)UF_ENTRY_END_MAGIC, 2); return OK; } static u_header_T * unserialize_uhp(bi, file_name) bufinfo_T *bi; char_u *file_name; { u_header_T *uhp; int i; u_entry_T *uep, *last_uep; int c; int error; uhp = (u_header_T *)U_ALLOC_LINE(sizeof(u_header_T)); if (uhp == NULL) return NULL; vim_memset(uhp, 0, sizeof(u_header_T)); #ifdef U_DEBUG uhp->uh_magic = UH_MAGIC; #endif uhp->uh_next.seq = undo_read_4c(bi); uhp->uh_prev.seq = undo_read_4c(bi); uhp->uh_alt_next.seq = undo_read_4c(bi); uhp->uh_alt_prev.seq = undo_read_4c(bi); uhp->uh_seq = undo_read_4c(bi); if (uhp->uh_seq <= 0) { corruption_error("uh_seq", file_name); vim_free(uhp); return NULL; } unserialize_pos(bi, &uhp->uh_cursor); #ifdef FEAT_VIRTUALEDIT uhp->uh_cursor_vcol = undo_read_4c(bi); #else (void)undo_read_4c(bi); #endif uhp->uh_flags = undo_read_2c(bi); for (i = 0; i < NMARKS; ++i) unserialize_pos(bi, &uhp->uh_namedm[i]); unserialize_visualinfo(bi, &uhp->uh_visual); uhp->uh_time = undo_read_time(bi); /* Optional fields. */ for (;;) { int len = undo_read_byte(bi); int what; if (len == 0) break; what = undo_read_byte(bi); switch (what) { case UHP_SAVE_NR: uhp->uh_save_nr = undo_read_4c(bi); break; default: /* field not supported, skip */ while (--len >= 0) (void)undo_read_byte(bi); } } /* Unserialize the uep list. */ last_uep = NULL; while ((c = undo_read_2c(bi)) == UF_ENTRY_MAGIC) { error = FALSE; uep = unserialize_uep(bi, &error, file_name); if (last_uep == NULL) uhp->uh_entry = uep; else last_uep->ue_next = uep; last_uep = uep; if (uep == NULL || error) { u_free_uhp(uhp); return NULL; } } if (c != UF_ENTRY_END_MAGIC) { corruption_error("entry end", file_name); u_free_uhp(uhp); return NULL; } return uhp; } /* * Serialize "uep". */ static int serialize_uep(bi, uep) bufinfo_T *bi; u_entry_T *uep; { int i; size_t len; undo_write_bytes(bi, (long_u)uep->ue_top, 4); undo_write_bytes(bi, (long_u)uep->ue_bot, 4); undo_write_bytes(bi, (long_u)uep->ue_lcount, 4); undo_write_bytes(bi, (long_u)uep->ue_size, 4); for (i = 0; i < uep->ue_size; ++i) { len = STRLEN(uep->ue_array[i]); if (undo_write_bytes(bi, (long_u)len, 4) == FAIL) return FAIL; if (len > 0 && fwrite_crypt(bi, uep->ue_array[i], len) == FAIL) return FAIL; } return OK; } static u_entry_T * unserialize_uep(bi, error, file_name) bufinfo_T *bi; int *error; char_u *file_name; { int i; u_entry_T *uep; char_u **array; char_u *line; int line_len; uep = (u_entry_T *)U_ALLOC_LINE(sizeof(u_entry_T)); if (uep == NULL) return NULL; vim_memset(uep, 0, sizeof(u_entry_T)); #ifdef U_DEBUG uep->ue_magic = UE_MAGIC; #endif uep->ue_top = undo_read_4c(bi); uep->ue_bot = undo_read_4c(bi); uep->ue_lcount = undo_read_4c(bi); uep->ue_size = undo_read_4c(bi); if (uep->ue_size > 0) { array = (char_u **)U_ALLOC_LINE(sizeof(char_u *) * uep->ue_size); if (array == NULL) { *error = TRUE; return uep; } vim_memset(array, 0, sizeof(char_u *) * uep->ue_size); } else array = NULL; uep->ue_array = array; for (i = 0; i < uep->ue_size; ++i) { line_len = undo_read_4c(bi); if (line_len >= 0) line = read_string_decrypt(bi, line_len); else { line = NULL; corruption_error("line length", file_name); } if (line == NULL) { *error = TRUE; return uep; } array[i] = line; } return uep; } /* * Serialize "pos". */ static void serialize_pos(bi, pos) bufinfo_T *bi; pos_T pos; { undo_write_bytes(bi, (long_u)pos.lnum, 4); undo_write_bytes(bi, (long_u)pos.col, 4); #ifdef FEAT_VIRTUALEDIT undo_write_bytes(bi, (long_u)pos.coladd, 4); #else undo_write_bytes(bi, (long_u)0, 4); #endif } /* * Unserialize the pos_T at the current position. */ static void unserialize_pos(bi, pos) bufinfo_T *bi; pos_T *pos; { pos->lnum = undo_read_4c(bi); if (pos->lnum < 0) pos->lnum = 0; pos->col = undo_read_4c(bi); if (pos->col < 0) pos->col = 0; #ifdef FEAT_VIRTUALEDIT pos->coladd = undo_read_4c(bi); if (pos->coladd < 0) pos->coladd = 0; #else (void)undo_read_4c(bi); #endif } /* * Serialize "info". */ static void serialize_visualinfo(bi, info) bufinfo_T *bi; visualinfo_T *info; { serialize_pos(bi, info->vi_start); serialize_pos(bi, info->vi_end); undo_write_bytes(bi, (long_u)info->vi_mode, 4); undo_write_bytes(bi, (long_u)info->vi_curswant, 4); } /* * Unserialize the visualinfo_T at the current position. */ static void unserialize_visualinfo(bi, info) bufinfo_T *bi; visualinfo_T *info; { unserialize_pos(bi, &info->vi_start); unserialize_pos(bi, &info->vi_end); info->vi_mode = undo_read_4c(bi); info->vi_curswant = undo_read_4c(bi); } /* * Write the undo tree in an undo file. * When "name" is not NULL, use it as the name of the undo file. * Otherwise use buf->b_ffname to generate the undo file name. * "buf" must never be null, buf->b_ffname is used to obtain the original file * permissions. * "forceit" is TRUE for ":wundo!", FALSE otherwise. * "hash[UNDO_HASH_SIZE]" must be the hash value of the buffer text. */ void u_write_undo(name, forceit, buf, hash) char_u *name; int forceit; buf_T *buf; char_u *hash; { u_header_T *uhp; char_u *file_name; int mark; #ifdef U_DEBUG int headers_written = 0; #endif int fd; FILE *fp = NULL; int perm; int write_ok = FALSE; #ifdef UNIX int st_old_valid = FALSE; struct stat st_old; struct stat st_new; #endif bufinfo_T bi; #ifdef FEAT_CRYPT bi.bi_state = NULL; bi.bi_buffer = NULL; #endif if (name == NULL) { file_name = u_get_undo_file_name(buf->b_ffname, FALSE); if (file_name == NULL) { if (p_verbose > 0) { verbose_enter(); smsg((char_u *) _("Cannot write undo file in any directory in 'undodir'")); verbose_leave(); } return; } } else file_name = name; /* * Decide about the permission to use for the undo file. If the buffer * has a name use the permission of the original file. Otherwise only * allow the user to access the undo file. */ perm = 0600; if (buf->b_ffname != NULL) { #ifdef UNIX if (mch_stat((char *)buf->b_ffname, &st_old) >= 0) { perm = st_old.st_mode; st_old_valid = TRUE; } #else perm = mch_getperm(buf->b_ffname); if (perm < 0) perm = 0600; #endif } /* strip any s-bit */ perm = perm & 0777; /* If the undo file already exists, verify that it actually is an undo * file, and delete it. */ if (mch_getperm(file_name) >= 0) { if (name == NULL || !forceit) { /* Check we can read it and it's an undo file. */ fd = mch_open((char *)file_name, O_RDONLY|O_EXTRA, 0); if (fd < 0) { if (name != NULL || p_verbose > 0) { if (name == NULL) verbose_enter(); smsg((char_u *) _("Will not overwrite with undo file, cannot read: %s"), file_name); if (name == NULL) verbose_leave(); } goto theend; } else { char_u mbuf[UF_START_MAGIC_LEN]; int len; len = read_eintr(fd, mbuf, UF_START_MAGIC_LEN); close(fd); if (len < UF_START_MAGIC_LEN || memcmp(mbuf, UF_START_MAGIC, UF_START_MAGIC_LEN) != 0) { if (name != NULL || p_verbose > 0) { if (name == NULL) verbose_enter(); smsg((char_u *) _("Will not overwrite, this is not an undo file: %s"), file_name); if (name == NULL) verbose_leave(); } goto theend; } } } mch_remove(file_name); } /* If there is no undo information at all, quit here after deleting any * existing undo file. */ if (buf->b_u_numhead == 0 && buf->b_u_line_ptr == NULL) { if (p_verbose > 0) verb_msg((char_u *)_("Skipping undo file write, nothing to undo")); goto theend; } fd = mch_open((char *)file_name, O_CREAT|O_EXTRA|O_WRONLY|O_EXCL|O_NOFOLLOW, perm); if (fd < 0) { EMSG2(_(e_not_open), file_name); goto theend; } (void)mch_setperm(file_name, perm); if (p_verbose > 0) { verbose_enter(); smsg((char_u *)_("Writing undo file: %s"), file_name); verbose_leave(); } #ifdef U_DEBUG /* Check there is no problem in undo info before writing. */ u_check(FALSE); #endif #ifdef UNIX /* * Try to set the group of the undo file same as the original file. If * this fails, set the protection bits for the group same as the * protection bits for others. */ if (st_old_valid && mch_stat((char *)file_name, &st_new) >= 0 && st_new.st_gid != st_old.st_gid # ifdef HAVE_FCHOWN /* sequent-ptx lacks fchown() */ && fchown(fd, (uid_t)-1, st_old.st_gid) != 0 # endif ) mch_setperm(file_name, (perm & 0707) | ((perm & 07) << 3)); # if defined(HAVE_SELINUX) || defined(HAVE_SMACK) if (buf->b_ffname != NULL) mch_copy_sec(buf->b_ffname, file_name); # endif #endif fp = fdopen(fd, "w"); if (fp == NULL) { EMSG2(_(e_not_open), file_name); close(fd); mch_remove(file_name); goto theend; } /* Undo must be synced. */ u_sync(TRUE); /* * Write the header. Initializes encryption, if enabled. */ bi.bi_buf = buf; bi.bi_fp = fp; if (serialize_header(&bi, hash) == FAIL) goto write_error; /* * Iteratively serialize UHPs and their UEPs from the top down. */ mark = ++lastmark; uhp = buf->b_u_oldhead; while (uhp != NULL) { /* Serialize current UHP if we haven't seen it */ if (uhp->uh_walk != mark) { uhp->uh_walk = mark; #ifdef U_DEBUG ++headers_written; #endif if (serialize_uhp(&bi, uhp) == FAIL) goto write_error; } /* Now walk through the tree - algorithm from undo_time(). */ if (uhp->uh_prev.ptr != NULL && uhp->uh_prev.ptr->uh_walk != mark) uhp = uhp->uh_prev.ptr; else if (uhp->uh_alt_next.ptr != NULL && uhp->uh_alt_next.ptr->uh_walk != mark) uhp = uhp->uh_alt_next.ptr; else if (uhp->uh_next.ptr != NULL && uhp->uh_alt_prev.ptr == NULL && uhp->uh_next.ptr->uh_walk != mark) uhp = uhp->uh_next.ptr; else if (uhp->uh_alt_prev.ptr != NULL) uhp = uhp->uh_alt_prev.ptr; else uhp = uhp->uh_next.ptr; } if (undo_write_bytes(&bi, (long_u)UF_HEADER_END_MAGIC, 2) == OK) write_ok = TRUE; #ifdef U_DEBUG if (headers_written != buf->b_u_numhead) { EMSGN("Written %ld headers, ...", headers_written); EMSGN("... but numhead is %ld", buf->b_u_numhead); } #endif #ifdef FEAT_CRYPT if (bi.bi_state != NULL && undo_flush(&bi) == FAIL) write_ok = FALSE; #endif write_error: fclose(fp); if (!write_ok) EMSG2(_("E829: write error in undo file: %s"), file_name); #if defined(MACOS_CLASSIC) || defined(WIN3264) /* Copy file attributes; for systems where this can only be done after * closing the file. */ if (buf->b_ffname != NULL) (void)mch_copy_file_attribute(buf->b_ffname, file_name); #endif #ifdef HAVE_ACL if (buf->b_ffname != NULL) { vim_acl_T acl; /* For systems that support ACL: get the ACL from the original file. */ acl = mch_get_acl(buf->b_ffname); mch_set_acl(file_name, acl); mch_free_acl(acl); } #endif theend: #ifdef FEAT_CRYPT if (bi.bi_state != NULL) crypt_free_state(bi.bi_state); vim_free(bi.bi_buffer); #endif if (file_name != name) vim_free(file_name); } /* * Load the undo tree from an undo file. * If "name" is not NULL use it as the undo file name. This also means being * a bit more verbose. * Otherwise use curbuf->b_ffname to generate the undo file name. * "hash[UNDO_HASH_SIZE]" must be the hash value of the buffer text. */ void u_read_undo(name, hash, orig_name) char_u *name; char_u *hash; char_u *orig_name; { char_u *file_name; FILE *fp; long version, str_len; char_u *line_ptr = NULL; linenr_T line_lnum; colnr_T line_colnr; linenr_T line_count; int num_head = 0; long old_header_seq, new_header_seq, cur_header_seq; long seq_last, seq_cur; long last_save_nr = 0; short old_idx = -1, new_idx = -1, cur_idx = -1; long num_read_uhps = 0; time_t seq_time; int i, j; int c; u_header_T *uhp; u_header_T **uhp_table = NULL; char_u read_hash[UNDO_HASH_SIZE]; char_u magic_buf[UF_START_MAGIC_LEN]; #ifdef U_DEBUG int *uhp_table_used; #endif #ifdef UNIX struct stat st_orig; struct stat st_undo; #endif bufinfo_T bi; if (name == NULL) { file_name = u_get_undo_file_name(curbuf->b_ffname, TRUE); if (file_name == NULL) return; #ifdef UNIX /* For safety we only read an undo file if the owner is equal to the * owner of the text file or equal to the current user. */ if (mch_stat((char *)orig_name, &st_orig) >= 0 && mch_stat((char *)file_name, &st_undo) >= 0 && st_orig.st_uid != st_undo.st_uid && st_undo.st_uid != getuid()) { if (p_verbose > 0) { verbose_enter(); smsg((char_u *)_("Not reading undo file, owner differs: %s"), file_name); verbose_leave(); } return; } #endif } else file_name = name; if (p_verbose > 0) { verbose_enter(); smsg((char_u *)_("Reading undo file: %s"), file_name); verbose_leave(); } fp = mch_fopen((char *)file_name, "r"); if (fp == NULL) { if (name != NULL || p_verbose > 0) EMSG2(_("E822: Cannot open undo file for reading: %s"), file_name); goto error; } bi.bi_buf = curbuf; bi.bi_fp = fp; #ifdef FEAT_CRYPT bi.bi_state = NULL; bi.bi_buffer = NULL; #endif /* * Read the undo file header. */ if (fread(magic_buf, UF_START_MAGIC_LEN, 1, fp) != 1 || memcmp(magic_buf, UF_START_MAGIC, UF_START_MAGIC_LEN) != 0) { EMSG2(_("E823: Not an undo file: %s"), file_name); goto error; } version = get2c(fp); if (version == UF_VERSION_CRYPT) { #ifdef FEAT_CRYPT if (*curbuf->b_p_key == NUL) { EMSG2(_("E832: Non-encrypted file has encrypted undo file: %s"), file_name); goto error; } bi.bi_state = crypt_create_from_file(fp, curbuf->b_p_key); if (bi.bi_state == NULL) { EMSG2(_("E826: Undo file decryption failed: %s"), file_name); goto error; } if (crypt_whole_undofile(bi.bi_state->method_nr)) { bi.bi_buffer = alloc(CRYPT_BUF_SIZE); if (bi.bi_buffer == NULL) { crypt_free_state(bi.bi_state); bi.bi_state = NULL; goto error; } bi.bi_avail = 0; bi.bi_used = 0; } #else EMSG2(_("E827: Undo file is encrypted: %s"), file_name); goto error; #endif } else if (version != UF_VERSION) { EMSG2(_("E824: Incompatible undo file: %s"), file_name); goto error; } if (undo_read(&bi, read_hash, (size_t)UNDO_HASH_SIZE) == FAIL) { corruption_error("hash", file_name); goto error; } line_count = (linenr_T)undo_read_4c(&bi); if (memcmp(hash, read_hash, UNDO_HASH_SIZE) != 0 || line_count != curbuf->b_ml.ml_line_count) { if (p_verbose > 0 || name != NULL) { if (name == NULL) verbose_enter(); give_warning((char_u *) _("File contents changed, cannot use undo info"), TRUE); if (name == NULL) verbose_leave(); } goto error; } /* Read undo data for "U" command. */ str_len = undo_read_4c(&bi); if (str_len < 0) goto error; if (str_len > 0) line_ptr = read_string_decrypt(&bi, str_len); line_lnum = (linenr_T)undo_read_4c(&bi); line_colnr = (colnr_T)undo_read_4c(&bi); if (line_lnum < 0 || line_colnr < 0) { corruption_error("line lnum/col", file_name); goto error; } /* Begin general undo data */ old_header_seq = undo_read_4c(&bi); new_header_seq = undo_read_4c(&bi); cur_header_seq = undo_read_4c(&bi); num_head = undo_read_4c(&bi); seq_last = undo_read_4c(&bi); seq_cur = undo_read_4c(&bi); seq_time = undo_read_time(&bi); /* Optional header fields. */ for (;;) { int len = undo_read_byte(&bi); int what; if (len == 0 || len == EOF) break; what = undo_read_byte(&bi); switch (what) { case UF_LAST_SAVE_NR: last_save_nr = undo_read_4c(&bi); break; default: /* field not supported, skip */ while (--len >= 0) (void)undo_read_byte(&bi); } } /* uhp_table will store the freshly created undo headers we allocate * until we insert them into curbuf. The table remains sorted by the * sequence numbers of the headers. * When there are no headers uhp_table is NULL. */ if (num_head > 0) { uhp_table = (u_header_T **)U_ALLOC_LINE( num_head * sizeof(u_header_T *)); if (uhp_table == NULL) goto error; } while ((c = undo_read_2c(&bi)) == UF_HEADER_MAGIC) { if (num_read_uhps >= num_head) { corruption_error("num_head too small", file_name); goto error; } uhp = unserialize_uhp(&bi, file_name); if (uhp == NULL) goto error; uhp_table[num_read_uhps++] = uhp; } if (num_read_uhps != num_head) { corruption_error("num_head", file_name); goto error; } if (c != UF_HEADER_END_MAGIC) { corruption_error("end marker", file_name); goto error; } #ifdef U_DEBUG uhp_table_used = (int *)alloc_clear( (unsigned)(sizeof(int) * num_head + 1)); # define SET_FLAG(j) ++uhp_table_used[j] #else # define SET_FLAG(j) #endif /* We have put all of the headers into a table. Now we iterate through the * table and swizzle each sequence number we have stored in uh_*_seq into * a pointer corresponding to the header with that sequence number. */ for (i = 0; i < num_head; i++) { uhp = uhp_table[i]; if (uhp == NULL) continue; for (j = 0; j < num_head; j++) if (uhp_table[j] != NULL && i != j && uhp_table[i]->uh_seq == uhp_table[j]->uh_seq) { corruption_error("duplicate uh_seq", file_name); goto error; } for (j = 0; j < num_head; j++) if (uhp_table[j] != NULL && uhp_table[j]->uh_seq == uhp->uh_next.seq) { uhp->uh_next.ptr = uhp_table[j]; SET_FLAG(j); break; } for (j = 0; j < num_head; j++) if (uhp_table[j] != NULL && uhp_table[j]->uh_seq == uhp->uh_prev.seq) { uhp->uh_prev.ptr = uhp_table[j]; SET_FLAG(j); break; } for (j = 0; j < num_head; j++) if (uhp_table[j] != NULL && uhp_table[j]->uh_seq == uhp->uh_alt_next.seq) { uhp->uh_alt_next.ptr = uhp_table[j]; SET_FLAG(j); break; } for (j = 0; j < num_head; j++) if (uhp_table[j] != NULL && uhp_table[j]->uh_seq == uhp->uh_alt_prev.seq) { uhp->uh_alt_prev.ptr = uhp_table[j]; SET_FLAG(j); break; } if (old_header_seq > 0 && old_idx < 0 && uhp->uh_seq == old_header_seq) { old_idx = i; SET_FLAG(i); } if (new_header_seq > 0 && new_idx < 0 && uhp->uh_seq == new_header_seq) { new_idx = i; SET_FLAG(i); } if (cur_header_seq > 0 && cur_idx < 0 && uhp->uh_seq == cur_header_seq) { cur_idx = i; SET_FLAG(i); } } /* Now that we have read the undo info successfully, free the current undo * info and use the info from the file. */ u_blockfree(curbuf); curbuf->b_u_oldhead = old_idx < 0 ? NULL : uhp_table[old_idx]; curbuf->b_u_newhead = new_idx < 0 ? NULL : uhp_table[new_idx]; curbuf->b_u_curhead = cur_idx < 0 ? NULL : uhp_table[cur_idx]; curbuf->b_u_line_ptr = line_ptr; curbuf->b_u_line_lnum = line_lnum; curbuf->b_u_line_colnr = line_colnr; curbuf->b_u_numhead = num_head; curbuf->b_u_seq_last = seq_last; curbuf->b_u_seq_cur = seq_cur; curbuf->b_u_time_cur = seq_time; curbuf->b_u_save_nr_last = last_save_nr; curbuf->b_u_save_nr_cur = last_save_nr; curbuf->b_u_synced = TRUE; vim_free(uhp_table); #ifdef U_DEBUG for (i = 0; i < num_head; ++i) if (uhp_table_used[i] == 0) EMSGN("uhp_table entry %ld not used, leaking memory", i); vim_free(uhp_table_used); u_check(TRUE); #endif if (name != NULL) smsg((char_u *)_("Finished reading undo file %s"), file_name); goto theend; error: vim_free(line_ptr); if (uhp_table != NULL) { for (i = 0; i < num_read_uhps; i++) if (uhp_table[i] != NULL) u_free_uhp(uhp_table[i]); vim_free(uhp_table); } theend: #ifdef FEAT_CRYPT if (bi.bi_state != NULL) crypt_free_state(bi.bi_state); vim_free(bi.bi_buffer); #endif if (fp != NULL) fclose(fp); if (file_name != name) vim_free(file_name); return; } #endif /* FEAT_PERSISTENT_UNDO */ /* * If 'cpoptions' contains 'u': Undo the previous undo or redo (vi compatible). * If 'cpoptions' does not contain 'u': Always undo. */ void u_undo(count) int count; { /* * If we get an undo command while executing a macro, we behave like the * original vi. If this happens twice in one macro the result will not * be compatible. */ if (curbuf->b_u_synced == FALSE) { u_sync(TRUE); count = 1; } if (vim_strchr(p_cpo, CPO_UNDO) == NULL) undo_undoes = TRUE; else undo_undoes = !undo_undoes; u_doit(count); } /* * If 'cpoptions' contains 'u': Repeat the previous undo or redo. * If 'cpoptions' does not contain 'u': Always redo. */ void u_redo(count) int count; { if (vim_strchr(p_cpo, CPO_UNDO) == NULL) undo_undoes = FALSE; u_doit(count); } /* * Undo or redo, depending on 'undo_undoes', 'count' times. */ static void u_doit(startcount) int startcount; { int count = startcount; if (!undo_allowed()) return; u_newcount = 0; u_oldcount = 0; if (curbuf->b_ml.ml_flags & ML_EMPTY) u_oldcount = -1; while (count--) { /* Do the change warning now, so that it triggers FileChangedRO when * needed. This may cause the file to be reloaded, that must happen * before we do anything, because it may change curbuf->b_u_curhead * and more. */ change_warning(0); if (undo_undoes) { if (curbuf->b_u_curhead == NULL) /* first undo */ curbuf->b_u_curhead = curbuf->b_u_newhead; else if (get_undolevel() > 0) /* multi level undo */ /* get next undo */ curbuf->b_u_curhead = curbuf->b_u_curhead->uh_next.ptr; /* nothing to undo */ if (curbuf->b_u_numhead == 0 || curbuf->b_u_curhead == NULL) { /* stick curbuf->b_u_curhead at end */ curbuf->b_u_curhead = curbuf->b_u_oldhead; beep_flush(); if (count == startcount - 1) { MSG(_("Already at oldest change")); return; } break; } u_undoredo(TRUE); } else { if (curbuf->b_u_curhead == NULL || get_undolevel() <= 0) { beep_flush(); /* nothing to redo */ if (count == startcount - 1) { MSG(_("Already at newest change")); return; } break; } u_undoredo(FALSE); /* Advance for next redo. Set "newhead" when at the end of the * redoable changes. */ if (curbuf->b_u_curhead->uh_prev.ptr == NULL) curbuf->b_u_newhead = curbuf->b_u_curhead; curbuf->b_u_curhead = curbuf->b_u_curhead->uh_prev.ptr; } } u_undo_end(undo_undoes, FALSE); } /* * Undo or redo over the timeline. * When "step" is negative go back in time, otherwise goes forward in time. * When "sec" is FALSE make "step" steps, when "sec" is TRUE use "step" as * seconds. * When "file" is TRUE use "step" as a number of file writes. * When "absolute" is TRUE use "step" as the sequence number to jump to. * "sec" must be FALSE then. */ void undo_time(step, sec, file, absolute) long step; int sec; int file; int absolute; { long target; long closest; long closest_start; long closest_seq = 0; long val; u_header_T *uhp; u_header_T *last; int mark; int nomark; int round; int dosec = sec; int dofile = file; int above = FALSE; int did_undo = TRUE; /* First make sure the current undoable change is synced. */ if (curbuf->b_u_synced == FALSE) u_sync(TRUE); u_newcount = 0; u_oldcount = 0; if (curbuf->b_ml.ml_flags & ML_EMPTY) u_oldcount = -1; /* "target" is the node below which we want to be. * Init "closest" to a value we can't reach. */ if (absolute) { target = step; closest = -1; } else { /* When doing computations with time_t subtract starttime, because * time_t converted to a long may result in a wrong number. */ if (dosec) target = (long)(curbuf->b_u_time_cur - starttime) + step; else if (dofile) { if (step < 0) { /* Going back to a previous write. If there were changes after * the last write, count that as moving one file-write, so * that ":earlier 1f" undoes all changes since the last save. */ uhp = curbuf->b_u_curhead; if (uhp != NULL) uhp = uhp->uh_next.ptr; else uhp = curbuf->b_u_newhead; if (uhp != NULL && uhp->uh_save_nr != 0) /* "uh_save_nr" was set in the last block, that means * there were no changes since the last write */ target = curbuf->b_u_save_nr_cur + step; else /* count the changes since the last write as one step */ target = curbuf->b_u_save_nr_cur + step + 1; if (target <= 0) /* Go to before first write: before the oldest change. Use * the sequence number for that. */ dofile = FALSE; } else { /* Moving forward to a newer write. */ target = curbuf->b_u_save_nr_cur + step; if (target > curbuf->b_u_save_nr_last) { /* Go to after last write: after the latest change. Use * the sequence number for that. */ target = curbuf->b_u_seq_last + 1; dofile = FALSE; } } } else target = curbuf->b_u_seq_cur + step; if (step < 0) { if (target < 0) target = 0; closest = -1; } else { if (dosec) closest = (long)(time(NULL) - starttime + 1); else if (dofile) closest = curbuf->b_u_save_nr_last + 2; else closest = curbuf->b_u_seq_last + 2; if (target >= closest) target = closest - 1; } } closest_start = closest; closest_seq = curbuf->b_u_seq_cur; /* * May do this twice: * 1. Search for "target", update "closest" to the best match found. * 2. If "target" not found search for "closest". * * When using the closest time we use the sequence number in the second * round, because there may be several entries with the same time. */ for (round = 1; round <= 2; ++round) { /* Find the path from the current state to where we want to go. The * desired state can be anywhere in the undo tree, need to go all over * it. We put "nomark" in uh_walk where we have been without success, * "mark" where it could possibly be. */ mark = ++lastmark; nomark = ++lastmark; if (curbuf->b_u_curhead == NULL) /* at leaf of the tree */ uhp = curbuf->b_u_newhead; else uhp = curbuf->b_u_curhead; while (uhp != NULL) { uhp->uh_walk = mark; if (dosec) val = (long)(uhp->uh_time - starttime); else if (dofile) val = uhp->uh_save_nr; else val = uhp->uh_seq; if (round == 1 && !(dofile && val == 0)) { /* Remember the header that is closest to the target. * It must be at least in the right direction (checked with * "b_u_seq_cur"). When the timestamp is equal find the * highest/lowest sequence number. */ if ((step < 0 ? uhp->uh_seq <= curbuf->b_u_seq_cur : uhp->uh_seq > curbuf->b_u_seq_cur) && ((dosec && val == closest) ? (step < 0 ? uhp->uh_seq < closest_seq : uhp->uh_seq > closest_seq) : closest == closest_start || (val > target ? (closest > target ? val - target <= closest - target : val - target <= target - closest) : (closest > target ? target - val <= closest - target : target - val <= target - closest)))) { closest = val; closest_seq = uhp->uh_seq; } } /* Quit searching when we found a match. But when searching for a * time we need to continue looking for the best uh_seq. */ if (target == val && !dosec) { target = uhp->uh_seq; break; } /* go down in the tree if we haven't been there */ if (uhp->uh_prev.ptr != NULL && uhp->uh_prev.ptr->uh_walk != nomark && uhp->uh_prev.ptr->uh_walk != mark) uhp = uhp->uh_prev.ptr; /* go to alternate branch if we haven't been there */ else if (uhp->uh_alt_next.ptr != NULL && uhp->uh_alt_next.ptr->uh_walk != nomark && uhp->uh_alt_next.ptr->uh_walk != mark) uhp = uhp->uh_alt_next.ptr; /* go up in the tree if we haven't been there and we are at the * start of alternate branches */ else if (uhp->uh_next.ptr != NULL && uhp->uh_alt_prev.ptr == NULL && uhp->uh_next.ptr->uh_walk != nomark && uhp->uh_next.ptr->uh_walk != mark) { /* If still at the start we don't go through this change. */ if (uhp == curbuf->b_u_curhead) uhp->uh_walk = nomark; uhp = uhp->uh_next.ptr; } else { /* need to backtrack; mark this node as useless */ uhp->uh_walk = nomark; if (uhp->uh_alt_prev.ptr != NULL) uhp = uhp->uh_alt_prev.ptr; else uhp = uhp->uh_next.ptr; } } if (uhp != NULL) /* found it */ break; if (absolute) { EMSGN(_("E830: Undo number %ld not found"), step); return; } if (closest == closest_start) { if (step < 0) MSG(_("Already at oldest change")); else MSG(_("Already at newest change")); return; } target = closest_seq; dosec = FALSE; dofile = FALSE; if (step < 0) above = TRUE; /* stop above the header */ } /* If we found it: Follow the path to go to where we want to be. */ if (uhp != NULL) { /* * First go up the tree as much as needed. */ while (!got_int) { /* Do the change warning now, for the same reason as above. */ change_warning(0); uhp = curbuf->b_u_curhead; if (uhp == NULL) uhp = curbuf->b_u_newhead; else uhp = uhp->uh_next.ptr; if (uhp == NULL || uhp->uh_walk != mark || (uhp->uh_seq == target && !above)) break; curbuf->b_u_curhead = uhp; u_undoredo(TRUE); uhp->uh_walk = nomark; /* don't go back down here */ } /* * And now go down the tree (redo), branching off where needed. */ while (!got_int) { /* Do the change warning now, for the same reason as above. */ change_warning(0); uhp = curbuf->b_u_curhead; if (uhp == NULL) break; /* Go back to the first branch with a mark. */ while (uhp->uh_alt_prev.ptr != NULL && uhp->uh_alt_prev.ptr->uh_walk == mark) uhp = uhp->uh_alt_prev.ptr; /* Find the last branch with a mark, that's the one. */ last = uhp; while (last->uh_alt_next.ptr != NULL && last->uh_alt_next.ptr->uh_walk == mark) last = last->uh_alt_next.ptr; if (last != uhp) { /* Make the used branch the first entry in the list of * alternatives to make "u" and CTRL-R take this branch. */ while (uhp->uh_alt_prev.ptr != NULL) uhp = uhp->uh_alt_prev.ptr; if (last->uh_alt_next.ptr != NULL) last->uh_alt_next.ptr->uh_alt_prev.ptr = last->uh_alt_prev.ptr; last->uh_alt_prev.ptr->uh_alt_next.ptr = last->uh_alt_next.ptr; last->uh_alt_prev.ptr = NULL; last->uh_alt_next.ptr = uhp; uhp->uh_alt_prev.ptr = last; if (curbuf->b_u_oldhead == uhp) curbuf->b_u_oldhead = last; uhp = last; if (uhp->uh_next.ptr != NULL) uhp->uh_next.ptr->uh_prev.ptr = uhp; } curbuf->b_u_curhead = uhp; if (uhp->uh_walk != mark) break; /* must have reached the target */ /* Stop when going backwards in time and didn't find the exact * header we were looking for. */ if (uhp->uh_seq == target && above) { curbuf->b_u_seq_cur = target - 1; break; } u_undoredo(FALSE); /* Advance "curhead" to below the header we last used. If it * becomes NULL then we need to set "newhead" to this leaf. */ if (uhp->uh_prev.ptr == NULL) curbuf->b_u_newhead = uhp; curbuf->b_u_curhead = uhp->uh_prev.ptr; did_undo = FALSE; if (uhp->uh_seq == target) /* found it! */ break; uhp = uhp->uh_prev.ptr; if (uhp == NULL || uhp->uh_walk != mark) { /* Need to redo more but can't find it... */ EMSG2(_(e_intern2), "undo_time()"); break; } } } u_undo_end(did_undo, absolute); } /* * u_undoredo: common code for undo and redo * * The lines in the file are replaced by the lines in the entry list at * curbuf->b_u_curhead. The replaced lines in the file are saved in the entry * list for the next undo/redo. * * When "undo" is TRUE we go up in the tree, when FALSE we go down. */ static void u_undoredo(undo) int undo; { char_u **newarray = NULL; linenr_T oldsize; linenr_T newsize; linenr_T top, bot; linenr_T lnum; linenr_T newlnum = MAXLNUM; long i; u_entry_T *uep, *nuep; u_entry_T *newlist = NULL; int old_flags; int new_flags; pos_T namedm[NMARKS]; visualinfo_T visualinfo; int empty_buffer; /* buffer became empty */ u_header_T *curhead = curbuf->b_u_curhead; #ifdef FEAT_AUTOCMD /* Don't want autocommands using the undo structures here, they are * invalid till the end. */ block_autocmds(); #endif #ifdef U_DEBUG u_check(FALSE); #endif old_flags = curhead->uh_flags; new_flags = (curbuf->b_changed ? UH_CHANGED : 0) + ((curbuf->b_ml.ml_flags & ML_EMPTY) ? UH_EMPTYBUF : 0); setpcmark(); /* * save marks before undo/redo */ mch_memmove(namedm, curbuf->b_namedm, sizeof(pos_T) * NMARKS); visualinfo = curbuf->b_visual; curbuf->b_op_start.lnum = curbuf->b_ml.ml_line_count; curbuf->b_op_start.col = 0; curbuf->b_op_end.lnum = 0; curbuf->b_op_end.col = 0; for (uep = curhead->uh_entry; uep != NULL; uep = nuep) { top = uep->ue_top; bot = uep->ue_bot; if (bot == 0) bot = curbuf->b_ml.ml_line_count + 1; if (top > curbuf->b_ml.ml_line_count || top >= bot || bot > curbuf->b_ml.ml_line_count + 1) { #ifdef FEAT_AUTOCMD unblock_autocmds(); #endif EMSG(_("E438: u_undo: line numbers wrong")); changed(); /* don't want UNCHANGED now */ return; } oldsize = bot - top - 1; /* number of lines before undo */ newsize = uep->ue_size; /* number of lines after undo */ if (top < newlnum) { /* If the saved cursor is somewhere in this undo block, move it to * the remembered position. Makes "gwap" put the cursor back * where it was. */ lnum = curhead->uh_cursor.lnum; if (lnum >= top && lnum <= top + newsize + 1) { curwin->w_cursor = curhead->uh_cursor; newlnum = curwin->w_cursor.lnum - 1; } else { /* Use the first line that actually changed. Avoids that * undoing auto-formatting puts the cursor in the previous * line. */ for (i = 0; i < newsize && i < oldsize; ++i) if (STRCMP(uep->ue_array[i], ml_get(top + 1 + i)) != 0) break; if (i == newsize && newlnum == MAXLNUM && uep->ue_next == NULL) { newlnum = top; curwin->w_cursor.lnum = newlnum + 1; } else if (i < newsize) { newlnum = top + i; curwin->w_cursor.lnum = newlnum + 1; } } } empty_buffer = FALSE; /* delete the lines between top and bot and save them in newarray */ if (oldsize > 0) { if ((newarray = (char_u **)U_ALLOC_LINE( sizeof(char_u *) * oldsize)) == NULL) { do_outofmem_msg((long_u)(sizeof(char_u *) * oldsize)); /* * We have messed up the entry list, repair is impossible. * we have to free the rest of the list. */ while (uep != NULL) { nuep = uep->ue_next; u_freeentry(uep, uep->ue_size); uep = nuep; } break; } /* delete backwards, it goes faster in most cases */ for (lnum = bot - 1, i = oldsize; --i >= 0; --lnum) { /* what can we do when we run out of memory? */ if ((newarray[i] = u_save_line(lnum)) == NULL) do_outofmem_msg((long_u)0); /* remember we deleted the last line in the buffer, and a * dummy empty line will be inserted */ if (curbuf->b_ml.ml_line_count == 1) empty_buffer = TRUE; ml_delete(lnum, FALSE); } } else newarray = NULL; /* insert the lines in u_array between top and bot */ if (newsize) { for (lnum = top, i = 0; i < newsize; ++i, ++lnum) { /* * If the file is empty, there is an empty line 1 that we * should get rid of, by replacing it with the new line */ if (empty_buffer && lnum == 0) ml_replace((linenr_T)1, uep->ue_array[i], TRUE); else ml_append(lnum, uep->ue_array[i], (colnr_T)0, FALSE); vim_free(uep->ue_array[i]); } vim_free((char_u *)uep->ue_array); } /* adjust marks */ if (oldsize != newsize) { mark_adjust(top + 1, top + oldsize, (long)MAXLNUM, (long)newsize - (long)oldsize); if (curbuf->b_op_start.lnum > top + oldsize) curbuf->b_op_start.lnum += newsize - oldsize; if (curbuf->b_op_end.lnum > top + oldsize) curbuf->b_op_end.lnum += newsize - oldsize; } changed_lines(top + 1, 0, bot, newsize - oldsize); /* set '[ and '] mark */ if (top + 1 < curbuf->b_op_start.lnum) curbuf->b_op_start.lnum = top + 1; if (newsize == 0 && top + 1 > curbuf->b_op_end.lnum) curbuf->b_op_end.lnum = top + 1; else if (top + newsize > curbuf->b_op_end.lnum) curbuf->b_op_end.lnum = top + newsize; u_newcount += newsize; u_oldcount += oldsize; uep->ue_size = oldsize; uep->ue_array = newarray; uep->ue_bot = top + newsize + 1; /* * insert this entry in front of the new entry list */ nuep = uep->ue_next; uep->ue_next = newlist; newlist = uep; } curhead->uh_entry = newlist; curhead->uh_flags = new_flags; if ((old_flags & UH_EMPTYBUF) && bufempty()) curbuf->b_ml.ml_flags |= ML_EMPTY; if (old_flags & UH_CHANGED) changed(); else #ifdef FEAT_NETBEANS_INTG /* per netbeans undo rules, keep it as modified */ if (!isNetbeansModified(curbuf)) #endif unchanged(curbuf, FALSE); /* * restore marks from before undo/redo */ for (i = 0; i < NMARKS; ++i) if (curhead->uh_namedm[i].lnum != 0) { curbuf->b_namedm[i] = curhead->uh_namedm[i]; curhead->uh_namedm[i] = namedm[i]; } if (curhead->uh_visual.vi_start.lnum != 0) { curbuf->b_visual = curhead->uh_visual; curhead->uh_visual = visualinfo; } /* * If the cursor is only off by one line, put it at the same position as * before starting the change (for the "o" command). * Otherwise the cursor should go to the first undone line. */ if (curhead->uh_cursor.lnum + 1 == curwin->w_cursor.lnum && curwin->w_cursor.lnum > 1) --curwin->w_cursor.lnum; if (curwin->w_cursor.lnum <= curbuf->b_ml.ml_line_count) { if (curhead->uh_cursor.lnum == curwin->w_cursor.lnum) { curwin->w_cursor.col = curhead->uh_cursor.col; #ifdef FEAT_VIRTUALEDIT if (virtual_active() && curhead->uh_cursor_vcol >= 0) coladvance((colnr_T)curhead->uh_cursor_vcol); else curwin->w_cursor.coladd = 0; #endif } else beginline(BL_SOL | BL_FIX); } else { /* We get here with the current cursor line being past the end (eg * after adding lines at the end of the file, and then undoing it). * check_cursor() will move the cursor to the last line. Move it to * the first column here. */ curwin->w_cursor.col = 0; #ifdef FEAT_VIRTUALEDIT curwin->w_cursor.coladd = 0; #endif } /* Make sure the cursor is on an existing line and column. */ check_cursor(); /* Remember where we are for "g-" and ":earlier 10s". */ curbuf->b_u_seq_cur = curhead->uh_seq; if (undo) /* We are below the previous undo. However, to make ":earlier 1s" * work we compute this as being just above the just undone change. */ --curbuf->b_u_seq_cur; /* Remember where we are for ":earlier 1f" and ":later 1f". */ if (curhead->uh_save_nr != 0) { if (undo) curbuf->b_u_save_nr_cur = curhead->uh_save_nr - 1; else curbuf->b_u_save_nr_cur = curhead->uh_save_nr; } /* The timestamp can be the same for multiple changes, just use the one of * the undone/redone change. */ curbuf->b_u_time_cur = curhead->uh_time; #ifdef FEAT_AUTOCMD unblock_autocmds(); #endif #ifdef U_DEBUG u_check(FALSE); #endif } /* * If we deleted or added lines, report the number of less/more lines. * Otherwise, report the number of changes (this may be incorrect * in some cases, but it's better than nothing). */ static void u_undo_end(did_undo, absolute) int did_undo; /* just did an undo */ int absolute; /* used ":undo N" */ { char *msgstr; u_header_T *uhp; char_u msgbuf[80]; #ifdef FEAT_FOLDING if ((fdo_flags & FDO_UNDO) && KeyTyped) foldOpenCursor(); #endif if (global_busy /* no messages now, wait until global is finished */ || !messaging()) /* 'lazyredraw' set, don't do messages now */ return; if (curbuf->b_ml.ml_flags & ML_EMPTY) --u_newcount; u_oldcount -= u_newcount; if (u_oldcount == -1) msgstr = N_("more line"); else if (u_oldcount < 0) msgstr = N_("more lines"); else if (u_oldcount == 1) msgstr = N_("line less"); else if (u_oldcount > 1) msgstr = N_("fewer lines"); else { u_oldcount = u_newcount; if (u_newcount == 1) msgstr = N_("change"); else msgstr = N_("changes"); } if (curbuf->b_u_curhead != NULL) { /* For ":undo N" we prefer a "after #N" message. */ if (absolute && curbuf->b_u_curhead->uh_next.ptr != NULL) { uhp = curbuf->b_u_curhead->uh_next.ptr; did_undo = FALSE; } else if (did_undo) uhp = curbuf->b_u_curhead; else uhp = curbuf->b_u_curhead->uh_next.ptr; } else uhp = curbuf->b_u_newhead; if (uhp == NULL) *msgbuf = NUL; else u_add_time(msgbuf, sizeof(msgbuf), uhp->uh_time); #ifdef FEAT_CONCEAL { win_T *wp; FOR_ALL_WINDOWS(wp) { if (wp->w_buffer == curbuf && wp->w_p_cole > 0) redraw_win_later(wp, NOT_VALID); } } #endif smsg((char_u *)_("%ld %s; %s #%ld %s"), u_oldcount < 0 ? -u_oldcount : u_oldcount, _(msgstr), did_undo ? _("before") : _("after"), uhp == NULL ? 0L : uhp->uh_seq, msgbuf); } /* * u_sync: stop adding to the current entry list */ void u_sync(force) int force; /* Also sync when no_u_sync is set. */ { /* Skip it when already synced or syncing is disabled. */ if (curbuf->b_u_synced || (!force && no_u_sync > 0)) return; #if defined(FEAT_XIM) && defined(FEAT_GUI_GTK) if (im_is_preediting()) return; /* XIM is busy, don't break an undo sequence */ #endif if (get_undolevel() < 0) curbuf->b_u_synced = TRUE; /* no entries, nothing to do */ else { u_getbot(); /* compute ue_bot of previous u_save */ curbuf->b_u_curhead = NULL; } } /* * ":undolist": List the leafs of the undo tree */ void ex_undolist(eap) exarg_T *eap UNUSED; { garray_T ga; u_header_T *uhp; int mark; int nomark; int changes = 1; int i; /* * 1: walk the tree to find all leafs, put the info in "ga". * 2: sort the lines * 3: display the list */ mark = ++lastmark; nomark = ++lastmark; ga_init2(&ga, (int)sizeof(char *), 20); uhp = curbuf->b_u_oldhead; while (uhp != NULL) { if (uhp->uh_prev.ptr == NULL && uhp->uh_walk != nomark && uhp->uh_walk != mark) { if (ga_grow(&ga, 1) == FAIL) break; vim_snprintf((char *)IObuff, IOSIZE, "%6ld %7ld ", uhp->uh_seq, changes); u_add_time(IObuff + STRLEN(IObuff), IOSIZE - STRLEN(IObuff), uhp->uh_time); if (uhp->uh_save_nr > 0) { while (STRLEN(IObuff) < 33) STRCAT(IObuff, " "); vim_snprintf_add((char *)IObuff, IOSIZE, " %3ld", uhp->uh_save_nr); } ((char_u **)(ga.ga_data))[ga.ga_len++] = vim_strsave(IObuff); } uhp->uh_walk = mark; /* go down in the tree if we haven't been there */ if (uhp->uh_prev.ptr != NULL && uhp->uh_prev.ptr->uh_walk != nomark && uhp->uh_prev.ptr->uh_walk != mark) { uhp = uhp->uh_prev.ptr; ++changes; } /* go to alternate branch if we haven't been there */ else if (uhp->uh_alt_next.ptr != NULL && uhp->uh_alt_next.ptr->uh_walk != nomark && uhp->uh_alt_next.ptr->uh_walk != mark) uhp = uhp->uh_alt_next.ptr; /* go up in the tree if we haven't been there and we are at the * start of alternate branches */ else if (uhp->uh_next.ptr != NULL && uhp->uh_alt_prev.ptr == NULL && uhp->uh_next.ptr->uh_walk != nomark && uhp->uh_next.ptr->uh_walk != mark) { uhp = uhp->uh_next.ptr; --changes; } else { /* need to backtrack; mark this node as done */ uhp->uh_walk = nomark; if (uhp->uh_alt_prev.ptr != NULL) uhp = uhp->uh_alt_prev.ptr; else { uhp = uhp->uh_next.ptr; --changes; } } } if (ga.ga_len == 0) MSG(_("Nothing to undo")); else { sort_strings((char_u **)ga.ga_data, ga.ga_len); msg_start(); msg_puts_attr((char_u *)_("number changes when saved"), hl_attr(HLF_T)); for (i = 0; i < ga.ga_len && !got_int; ++i) { msg_putchar('\n'); if (got_int) break; msg_puts(((char_u **)ga.ga_data)[i]); } msg_end(); ga_clear_strings(&ga); } } /* * Put the timestamp of an undo header in "buf[buflen]" in a nice format. */ static void u_add_time(buf, buflen, tt) char_u *buf; size_t buflen; time_t tt; { #ifdef HAVE_STRFTIME struct tm *curtime; if (time(NULL) - tt >= 100) { curtime = localtime(&tt); if (time(NULL) - tt < (60L * 60L * 12L)) /* within 12 hours */ (void)strftime((char *)buf, buflen, "%H:%M:%S", curtime); else /* longer ago */ (void)strftime((char *)buf, buflen, "%Y/%m/%d %H:%M:%S", curtime); } else #endif vim_snprintf((char *)buf, buflen, _("%ld seconds ago"), (long)(time(NULL) - tt)); } /* * ":undojoin": continue adding to the last entry list */ void ex_undojoin(eap) exarg_T *eap UNUSED; { if (curbuf->b_u_newhead == NULL) return; /* nothing changed before */ if (curbuf->b_u_curhead != NULL) { EMSG(_("E790: undojoin is not allowed after undo")); return; } if (!curbuf->b_u_synced) return; /* already unsynced */ if (get_undolevel() < 0) return; /* no entries, nothing to do */ else { /* Go back to the last entry */ curbuf->b_u_curhead = curbuf->b_u_newhead; curbuf->b_u_synced = FALSE; /* no entries, nothing to do */ } } /* * Called after writing or reloading the file and setting b_changed to FALSE. * Now an undo means that the buffer is modified. */ void u_unchanged(buf) buf_T *buf; { u_unch_branch(buf->b_u_oldhead); buf->b_did_warn = FALSE; } /* * After reloading a buffer which was saved for 'undoreload': Find the first * line that was changed and set the cursor there. */ void u_find_first_changed() { u_header_T *uhp = curbuf->b_u_newhead; u_entry_T *uep; linenr_T lnum; if (curbuf->b_u_curhead != NULL || uhp == NULL) return; /* undid something in an autocmd? */ /* Check that the last undo block was for the whole file. */ uep = uhp->uh_entry; if (uep->ue_top != 0 || uep->ue_bot != 0) return; for (lnum = 1; lnum < curbuf->b_ml.ml_line_count && lnum <= uep->ue_size; ++lnum) if (STRCMP(ml_get_buf(curbuf, lnum, FALSE), uep->ue_array[lnum - 1]) != 0) { clearpos(&(uhp->uh_cursor)); uhp->uh_cursor.lnum = lnum; return; } if (curbuf->b_ml.ml_line_count != uep->ue_size) { /* lines added or deleted at the end, put the cursor there */ clearpos(&(uhp->uh_cursor)); uhp->uh_cursor.lnum = lnum; } } /* * Increase the write count, store it in the last undo header, what would be * used for "u". */ void u_update_save_nr(buf) buf_T *buf; { u_header_T *uhp; ++buf->b_u_save_nr_last; buf->b_u_save_nr_cur = buf->b_u_save_nr_last; uhp = buf->b_u_curhead; if (uhp != NULL) uhp = uhp->uh_next.ptr; else uhp = buf->b_u_newhead; if (uhp != NULL) uhp->uh_save_nr = buf->b_u_save_nr_last; } static void u_unch_branch(uhp) u_header_T *uhp; { u_header_T *uh; for (uh = uhp; uh != NULL; uh = uh->uh_prev.ptr) { uh->uh_flags |= UH_CHANGED; if (uh->uh_alt_next.ptr != NULL) u_unch_branch(uh->uh_alt_next.ptr); /* recursive */ } } /* * Get pointer to last added entry. * If it's not valid, give an error message and return NULL. */ static u_entry_T * u_get_headentry() { if (curbuf->b_u_newhead == NULL || curbuf->b_u_newhead->uh_entry == NULL) { EMSG(_("E439: undo list corrupt")); return NULL; } return curbuf->b_u_newhead->uh_entry; } /* * u_getbot(): compute the line number of the previous u_save * It is called only when b_u_synced is FALSE. */ static void u_getbot() { u_entry_T *uep; linenr_T extra; uep = u_get_headentry(); /* check for corrupt undo list */ if (uep == NULL) return; uep = curbuf->b_u_newhead->uh_getbot_entry; if (uep != NULL) { /* * the new ue_bot is computed from the number of lines that has been * inserted (0 - deleted) since calling u_save. This is equal to the * old line count subtracted from the current line count. */ extra = curbuf->b_ml.ml_line_count - uep->ue_lcount; uep->ue_bot = uep->ue_top + uep->ue_size + 1 + extra; if (uep->ue_bot < 1 || uep->ue_bot > curbuf->b_ml.ml_line_count) { EMSG(_("E440: undo line missing")); uep->ue_bot = uep->ue_top + 1; /* assume all lines deleted, will * get all the old lines back * without deleting the current * ones */ } curbuf->b_u_newhead->uh_getbot_entry = NULL; } curbuf->b_u_synced = TRUE; } /* * Free one header "uhp" and its entry list and adjust the pointers. */ static void u_freeheader(buf, uhp, uhpp) buf_T *buf; u_header_T *uhp; u_header_T **uhpp; /* if not NULL reset when freeing this header */ { u_header_T *uhap; /* When there is an alternate redo list free that branch completely, * because we can never go there. */ if (uhp->uh_alt_next.ptr != NULL) u_freebranch(buf, uhp->uh_alt_next.ptr, uhpp); if (uhp->uh_alt_prev.ptr != NULL) uhp->uh_alt_prev.ptr->uh_alt_next.ptr = NULL; /* Update the links in the list to remove the header. */ if (uhp->uh_next.ptr == NULL) buf->b_u_oldhead = uhp->uh_prev.ptr; else uhp->uh_next.ptr->uh_prev.ptr = uhp->uh_prev.ptr; if (uhp->uh_prev.ptr == NULL) buf->b_u_newhead = uhp->uh_next.ptr; else for (uhap = uhp->uh_prev.ptr; uhap != NULL; uhap = uhap->uh_alt_next.ptr) uhap->uh_next.ptr = uhp->uh_next.ptr; u_freeentries(buf, uhp, uhpp); } /* * Free an alternate branch and any following alternate branches. */ static void u_freebranch(buf, uhp, uhpp) buf_T *buf; u_header_T *uhp; u_header_T **uhpp; /* if not NULL reset when freeing this header */ { u_header_T *tofree, *next; /* If this is the top branch we may need to use u_freeheader() to update * all the pointers. */ if (uhp == buf->b_u_oldhead) { while (buf->b_u_oldhead != NULL) u_freeheader(buf, buf->b_u_oldhead, uhpp); return; } if (uhp->uh_alt_prev.ptr != NULL) uhp->uh_alt_prev.ptr->uh_alt_next.ptr = NULL; next = uhp; while (next != NULL) { tofree = next; if (tofree->uh_alt_next.ptr != NULL) u_freebranch(buf, tofree->uh_alt_next.ptr, uhpp); /* recursive */ next = tofree->uh_prev.ptr; u_freeentries(buf, tofree, uhpp); } } /* * Free all the undo entries for one header and the header itself. * This means that "uhp" is invalid when returning. */ static void u_freeentries(buf, uhp, uhpp) buf_T *buf; u_header_T *uhp; u_header_T **uhpp; /* if not NULL reset when freeing this header */ { u_entry_T *uep, *nuep; /* Check for pointers to the header that become invalid now. */ if (buf->b_u_curhead == uhp) buf->b_u_curhead = NULL; if (buf->b_u_newhead == uhp) buf->b_u_newhead = NULL; /* freeing the newest entry */ if (uhpp != NULL && uhp == *uhpp) *uhpp = NULL; for (uep = uhp->uh_entry; uep != NULL; uep = nuep) { nuep = uep->ue_next; u_freeentry(uep, uep->ue_size); } #ifdef U_DEBUG uhp->uh_magic = 0; #endif vim_free((char_u *)uhp); --buf->b_u_numhead; } /* * free entry 'uep' and 'n' lines in uep->ue_array[] */ static void u_freeentry(uep, n) u_entry_T *uep; long n; { while (n > 0) vim_free(uep->ue_array[--n]); vim_free((char_u *)uep->ue_array); #ifdef U_DEBUG uep->ue_magic = 0; #endif vim_free((char_u *)uep); } /* * invalidate the undo buffer; called when storage has already been released */ void u_clearall(buf) buf_T *buf; { buf->b_u_newhead = buf->b_u_oldhead = buf->b_u_curhead = NULL; buf->b_u_synced = TRUE; buf->b_u_numhead = 0; buf->b_u_line_ptr = NULL; buf->b_u_line_lnum = 0; } /* * save the line "lnum" for the "U" command */ void u_saveline(lnum) linenr_T lnum; { if (lnum == curbuf->b_u_line_lnum) /* line is already saved */ return; if (lnum < 1 || lnum > curbuf->b_ml.ml_line_count) /* should never happen */ return; u_clearline(); curbuf->b_u_line_lnum = lnum; if (curwin->w_cursor.lnum == lnum) curbuf->b_u_line_colnr = curwin->w_cursor.col; else curbuf->b_u_line_colnr = 0; if ((curbuf->b_u_line_ptr = u_save_line(lnum)) == NULL) do_outofmem_msg((long_u)0); } /* * clear the line saved for the "U" command * (this is used externally for crossing a line while in insert mode) */ void u_clearline() { if (curbuf->b_u_line_ptr != NULL) { vim_free(curbuf->b_u_line_ptr); curbuf->b_u_line_ptr = NULL; curbuf->b_u_line_lnum = 0; } } /* * Implementation of the "U" command. * Differentiation from vi: "U" can be undone with the next "U". * We also allow the cursor to be in another line. * Careful: may trigger autocommands that reload the buffer. */ void u_undoline() { colnr_T t; char_u *oldp; if (undo_off) return; if (curbuf->b_u_line_ptr == NULL || curbuf->b_u_line_lnum > curbuf->b_ml.ml_line_count) { beep_flush(); return; } /* first save the line for the 'u' command */ if (u_savecommon(curbuf->b_u_line_lnum - 1, curbuf->b_u_line_lnum + 1, (linenr_T)0, FALSE) == FAIL) return; oldp = u_save_line(curbuf->b_u_line_lnum); if (oldp == NULL) { do_outofmem_msg((long_u)0); return; } ml_replace(curbuf->b_u_line_lnum, curbuf->b_u_line_ptr, TRUE); changed_bytes(curbuf->b_u_line_lnum, 0); vim_free(curbuf->b_u_line_ptr); curbuf->b_u_line_ptr = oldp; t = curbuf->b_u_line_colnr; if (curwin->w_cursor.lnum == curbuf->b_u_line_lnum) curbuf->b_u_line_colnr = curwin->w_cursor.col; curwin->w_cursor.col = t; curwin->w_cursor.lnum = curbuf->b_u_line_lnum; check_cursor_col(); } /* * Free all allocated memory blocks for the buffer 'buf'. */ void u_blockfree(buf) buf_T *buf; { while (buf->b_u_oldhead != NULL) u_freeheader(buf, buf->b_u_oldhead, NULL); vim_free(buf->b_u_line_ptr); } /* * u_save_line(): allocate memory and copy line 'lnum' into it. * Returns NULL when out of memory. */ static char_u * u_save_line(lnum) linenr_T lnum; { return vim_strsave(ml_get(lnum)); } /* * Check if the 'modified' flag is set, or 'ff' has changed (only need to * check the first character, because it can only be "dos", "unix" or "mac"). * "nofile" and "scratch" type buffers are considered to always be unchanged. */ int bufIsChanged(buf) buf_T *buf; { return #ifdef FEAT_QUICKFIX !bt_dontwrite(buf) && #endif (buf->b_changed || file_ff_differs(buf, TRUE)); } int curbufIsChanged() { return #ifdef FEAT_QUICKFIX !bt_dontwrite(curbuf) && #endif (curbuf->b_changed || file_ff_differs(curbuf, TRUE)); } #if defined(FEAT_EVAL) || defined(PROTO) /* * For undotree(): Append the list of undo blocks at "first_uhp" to "list". * Recursive. */ void u_eval_tree(first_uhp, list) u_header_T *first_uhp; list_T *list; { u_header_T *uhp = first_uhp; dict_T *dict; while (uhp != NULL) { dict = dict_alloc(); if (dict == NULL) return; dict_add_nr_str(dict, "seq", uhp->uh_seq, NULL); dict_add_nr_str(dict, "time", (long)uhp->uh_time, NULL); if (uhp == curbuf->b_u_newhead) dict_add_nr_str(dict, "newhead", 1, NULL); if (uhp == curbuf->b_u_curhead) dict_add_nr_str(dict, "curhead", 1, NULL); if (uhp->uh_save_nr > 0) dict_add_nr_str(dict, "save", uhp->uh_save_nr, NULL); if (uhp->uh_alt_next.ptr != NULL) { list_T *alt_list = list_alloc(); if (alt_list != NULL) { /* Recursive call to add alternate undo tree. */ u_eval_tree(uhp->uh_alt_next.ptr, alt_list); dict_add_list(dict, "alt", alt_list); } } list_append_dict(list, dict); uhp = uhp->uh_prev.ptr; } } #endif