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      1  1.16       rin /*	$NetBSD: thread.c,v 1.16 2023/08/23 03:49:00 rin Exp $	*/
      2   1.1  christos 
      3   1.1  christos /*-
      4   1.1  christos  * Copyright (c) 2006 The NetBSD Foundation, Inc.
      5   1.1  christos  * All rights reserved.
      6   1.1  christos  *
      7   1.1  christos  * This code is derived from software contributed to The NetBSD Foundation
      8   1.1  christos  * by Anon Ymous.
      9   1.1  christos  *
     10   1.1  christos  * Redistribution and use in source and binary forms, with or without
     11   1.1  christos  * modification, are permitted provided that the following conditions
     12   1.1  christos  * are met:
     13   1.1  christos  * 1. Redistributions of source code must retain the above copyright
     14   1.1  christos  *    notice, this list of conditions and the following disclaimer.
     15   1.1  christos  * 2. Redistributions in binary form must reproduce the above copyright
     16   1.1  christos  *    notice, this list of conditions and the following disclaimer in the
     17   1.1  christos  *    documentation and/or other materials provided with the distribution.
     18   1.1  christos  *
     19   1.1  christos  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
     20   1.1  christos  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
     21   1.1  christos  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
     22   1.1  christos  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
     23   1.1  christos  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
     24   1.1  christos  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
     25   1.1  christos  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
     26   1.1  christos  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
     27   1.1  christos  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
     28   1.1  christos  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
     29   1.1  christos  * POSSIBILITY OF SUCH DAMAGE.
     30   1.1  christos  */
     31   1.1  christos 
     32   1.1  christos /*
     33   1.1  christos  * This module contains the threading and sorting routines.
     34   1.1  christos  */
     35   1.1  christos 
     36   1.1  christos #ifdef THREAD_SUPPORT
     37   1.1  christos 
     38   1.1  christos #include <sys/cdefs.h>
     39   1.1  christos #ifndef __lint__
     40  1.16       rin __RCSID("$NetBSD: thread.c,v 1.16 2023/08/23 03:49:00 rin Exp $");
     41   1.1  christos #endif /* not __lint__ */
     42   1.1  christos 
     43   1.1  christos #include <assert.h>
     44   1.1  christos #include <ctype.h>
     45   1.1  christos #include <stdio.h>
     46   1.1  christos #include <stdlib.h>
     47   1.1  christos #include <util.h>
     48   1.1  christos 
     49   1.1  christos #include "def.h"
     50   1.1  christos #include "glob.h"
     51   1.1  christos #include "extern.h"
     52   1.1  christos #include "format.h"
     53   1.1  christos #include "thread.h"
     54   1.1  christos 
     55   1.1  christos 
     56   1.1  christos struct thread_s {
     57   1.1  christos 	struct message *t_head;		/* head of the thread */
     58   1.1  christos 	struct message **t_msgtbl;	/* message array indexed by msgnum */
     59   1.1  christos 	int t_msgCount;			/* count of messages in thread */
     60   1.1  christos };
     61   1.1  christos #define THREAD_INIT	{NULL, NULL, 0}
     62   1.1  christos 
     63   1.1  christos typedef int state_t;
     64   1.1  christos #define S_STATE_INIT	0
     65   1.1  christos #define S_EXPOSE	1	/* flag to expose the thread */
     66   1.1  christos #define S_RESTRICT	2	/* flag to restrict to tagged messages */
     67   1.4  christos #define S_IS_EXPOSE(a)		((a) & S_EXPOSE)
     68   1.4  christos #define S_IS_RESTRICT(a)	((a) & S_RESTRICT)
     69   1.1  christos 
     70   1.1  christos /* XXX - this isn't really a thread */
     71   1.1  christos static struct thread_s message_array  = THREAD_INIT;	/* the basic message array */
     72   1.1  christos static struct thread_s current_thread = THREAD_INIT;	/* the current thread */
     73   1.1  christos 
     74   1.1  christos static state_t state = S_STATE_INIT;	/* the current state */
     75   1.1  christos 
     76   1.1  christos /*
     77   1.1  christos  * A state hook used by the format module.
     78   1.1  christos  */
     79   1.1  christos PUBLIC int
     80   1.1  christos thread_hidden(void)
     81   1.1  christos {
     82   1.1  christos 	return !S_IS_EXPOSE(state);
     83   1.1  christos }
     84   1.1  christos 
     85   1.1  christos /************************************************************************
     86   1.1  christos  * Debugging stuff that should evaporate eventually.
     87   1.1  christos  */
     88   1.1  christos #ifdef THREAD_DEBUG
     89   1.1  christos static void
     90   1.1  christos show_msg(struct message *mp)
     91   1.1  christos {
     92   1.1  christos 	if (mp == NULL)
     93   1.1  christos 		return;
     94   1.1  christos 	/*
     95   1.1  christos 	 * Arg!  '%p' doesn't like the '0' modifier.
     96   1.1  christos 	 */
     97   1.2  christos 	(void)printf("%3d (%p):"
     98   1.2  christos 	    " flink=%p blink=%p clink=%p plink=%p"
     99   1.1  christos 	    " depth=%d flags=0x%03x\n",
    100   1.2  christos 	    mp->m_index, mp,
    101   1.2  christos 	    mp->m_flink, mp->m_blink, mp->m_clink, mp->m_plink,
    102   1.2  christos 	    mp->m_depth, mp->m_flag);
    103   1.1  christos }
    104   1.1  christos 
    105   1.1  christos #ifndef __lint__
    106   1.1  christos __unused
    107   1.1  christos static void
    108   1.1  christos show_thread(struct message *mp)
    109   1.1  christos {
    110   1.1  christos 	(void)printf("current_thread.t_head=%p\n", current_thread.t_head);
    111   1.1  christos 	for (/*EMPTY*/; mp; mp = next_message(mp))
    112   1.1  christos 		show_msg(mp);
    113   1.1  christos }
    114   1.1  christos #endif
    115   1.1  christos 
    116   1.1  christos PUBLIC int
    117   1.1  christos thread_showcmd(void *v)
    118   1.1  christos {
    119   1.1  christos 	int *ip;
    120   1.1  christos 
    121   1.1  christos 	(void)printf("current_thread.t_head=%p\n", current_thread.t_head);
    122   1.1  christos 	for (ip = v; *ip; ip++)
    123   1.1  christos 		show_msg(get_message(*ip));
    124   1.1  christos 
    125   1.1  christos 	return 0;
    126   1.1  christos }
    127   1.1  christos #endif /* THREAD_DEBUG */
    128   1.1  christos 
    129   1.1  christos /*************************************************************************
    130   1.1  christos  * tag/restrict routines
    131   1.1  christos  */
    132   1.1  christos 
    133   1.1  christos /*
    134   1.1  christos  * Return TRUE iff all messages forward or below this one are tagged.
    135   1.1  christos  */
    136   1.1  christos static int
    137   1.1  christos is_tagged_core(struct message *mp)
    138   1.1  christos {
    139   1.5  christos 	if (S_IS_EXPOSE(state))
    140   1.5  christos 		return 1;
    141   1.5  christos 
    142   1.1  christos 	for (/*EMPTY*/; mp; mp = mp->m_flink)
    143   1.1  christos 		if ((mp->m_flag & MTAGGED) == 0 ||
    144   1.1  christos 		    is_tagged_core(mp->m_clink) == 0)
    145   1.1  christos 			return 0;
    146   1.1  christos 	return 1;
    147   1.1  christos }
    148   1.1  christos 
    149   1.1  christos static int
    150   1.1  christos is_tagged(struct message *mp)
    151   1.1  christos {
    152   1.5  christos 	return mp->m_flag & MTAGGED && is_tagged_core(mp->m_clink);
    153   1.1  christos }
    154   1.1  christos 
    155   1.1  christos /************************************************************************
    156   1.1  christos  * These are the core routines to access messages via the links used
    157   1.1  christos  * everywhere outside this module and fio.c.
    158   1.1  christos  */
    159   1.1  christos 
    160   1.1  christos static int
    161   1.1  christos has_parent(struct message *mp)
    162   1.1  christos {
    163   1.1  christos 	return mp->m_plink != NULL &&
    164   1.1  christos 	    mp->m_plink->m_clink != current_thread.t_head;
    165   1.1  christos }
    166   1.1  christos 
    167   1.1  christos static struct message *
    168   1.1  christos next_message1(struct message *mp)
    169   1.1  christos {
    170   1.1  christos 	if (mp == NULL)
    171   1.1  christos 		return NULL;
    172   1.1  christos 
    173   1.1  christos 	if (S_IS_EXPOSE(state) == 0)
    174   1.1  christos 		return mp->m_flink;
    175   1.4  christos 
    176   1.1  christos 	if (mp->m_clink)
    177   1.1  christos 		return mp->m_clink;
    178   1.1  christos 
    179   1.1  christos 	while (mp->m_flink == NULL && has_parent(mp))
    180   1.1  christos 		mp = mp->m_plink;
    181   1.1  christos 
    182   1.1  christos 	return mp->m_flink;
    183   1.1  christos }
    184   1.1  christos 
    185   1.1  christos static struct message *
    186   1.1  christos prev_message1(struct message *mp)
    187   1.1  christos {
    188   1.1  christos 	if (mp == NULL)
    189   1.1  christos 		return NULL;
    190   1.1  christos 
    191   1.1  christos 	if (S_IS_EXPOSE(state) && mp->m_blink == NULL && has_parent(mp))
    192   1.1  christos 		return mp->m_plink;
    193   1.4  christos 
    194   1.1  christos 	return mp->m_blink;
    195   1.1  christos }
    196   1.1  christos 
    197   1.1  christos PUBLIC struct message *
    198   1.1  christos next_message(struct message *mp)
    199   1.1  christos {
    200   1.1  christos 	if (S_IS_RESTRICT(state) == 0)
    201   1.1  christos 		return next_message1(mp);
    202   1.1  christos 
    203   1.1  christos 	while ((mp = next_message1(mp)) != NULL && is_tagged(mp))
    204   1.1  christos 		continue;
    205   1.1  christos 
    206   1.1  christos 	return mp;
    207   1.1  christos }
    208   1.1  christos 
    209   1.1  christos PUBLIC struct message *
    210   1.1  christos prev_message(struct message *mp)
    211   1.1  christos {
    212   1.1  christos 	if (S_IS_RESTRICT(state) == 0)
    213   1.1  christos 		return prev_message1(mp);
    214   1.1  christos 
    215   1.1  christos 	while ((mp = prev_message1(mp)) != NULL && is_tagged(mp))
    216   1.1  christos 		continue;
    217   1.1  christos 
    218   1.1  christos 	return mp;
    219   1.1  christos }
    220   1.1  christos 
    221   1.1  christos static struct message *
    222   1.1  christos first_message(struct message *mp)
    223   1.1  christos {
    224   1.1  christos 	if (S_IS_RESTRICT(state) && is_tagged(mp))
    225   1.1  christos 		mp = next_message(mp);
    226   1.1  christos 	return mp;
    227   1.1  christos }
    228   1.1  christos 
    229   1.1  christos PUBLIC struct message *
    230   1.1  christos get_message(int msgnum)
    231   1.1  christos {
    232   1.1  christos 	struct message *mp;
    233   1.1  christos 
    234   1.1  christos 	if (msgnum < 1 || msgnum > current_thread.t_msgCount)
    235   1.1  christos 		return NULL;
    236   1.1  christos 	mp = current_thread.t_msgtbl[msgnum - 1];
    237   1.1  christos 	assert(mp->m_index == msgnum);
    238   1.1  christos 	return mp;
    239   1.1  christos }
    240   1.1  christos 
    241   1.1  christos PUBLIC int
    242   1.1  christos get_msgnum(struct message *mp)
    243   1.1  christos {
    244   1.1  christos 	return mp ? mp->m_index : 0;
    245   1.1  christos }
    246   1.1  christos 
    247   1.1  christos PUBLIC int
    248   1.1  christos get_msgCount(void)
    249   1.1  christos {
    250   1.1  christos 	return current_thread.t_msgCount;
    251   1.1  christos }
    252   1.1  christos 
    253   1.1  christos PUBLIC int
    254   1.1  christos get_abs_msgCount(void)
    255   1.1  christos {
    256   1.1  christos 	return message_array.t_msgCount;
    257   1.1  christos }
    258   1.1  christos 
    259   1.1  christos PUBLIC struct message *
    260   1.1  christos get_abs_message(int msgnum)
    261   1.1  christos {
    262   1.1  christos 	if (msgnum < 1 || msgnum > message_array.t_msgCount)
    263   1.1  christos 		return NULL;
    264   1.1  christos 
    265   1.1  christos 	return &message_array.t_head[msgnum - 1];
    266   1.1  christos }
    267   1.1  christos 
    268   1.1  christos PUBLIC struct message *
    269   1.1  christos next_abs_message(struct message *mp)
    270   1.1  christos {
    271   1.1  christos 	int i;
    272   1.1  christos 
    273   1.5  christos 	i = (int)(mp - message_array.t_head);
    274   1.4  christos 
    275   1.1  christos 	if (i < 0 || i + 1 >= message_array.t_msgCount)
    276   1.1  christos 		return NULL;
    277   1.1  christos 
    278   1.1  christos 	return &message_array.t_head[i + 1];
    279   1.1  christos }
    280   1.1  christos 
    281   1.1  christos /************************************************************************/
    282   1.1  christos /*
    283   1.1  christos  * routines to handle the recursion of commands.
    284   1.1  christos  */
    285   1.1  christos PUBLIC int
    286   1.1  christos do_recursion(void)
    287   1.1  christos {
    288   1.1  christos 	return S_IS_EXPOSE(state) == 0 && value(ENAME_RECURSIVE_CMDS) != NULL;
    289   1.1  christos }
    290   1.1  christos 
    291   1.1  christos static int
    292   1.1  christos thread_recursion_flist(struct message *mp, int (*fn)(struct message *, void *), void *args)
    293   1.1  christos {
    294   1.1  christos 	int retval;
    295   1.1  christos 	for (/*EMPTY*/; mp; mp = mp->m_flink) {
    296   1.1  christos 		if (S_IS_RESTRICT(state) && is_tagged(mp))
    297   1.1  christos 			continue;
    298   1.1  christos 		if ((retval = fn(mp, args)) != 0 ||
    299   1.1  christos 		    (retval = thread_recursion_flist(mp->m_clink, fn, args)) != 0)
    300   1.1  christos 			return retval;
    301   1.1  christos 	}
    302   1.1  christos 
    303   1.1  christos 	return 0;
    304   1.1  christos }
    305   1.1  christos 
    306   1.1  christos PUBLIC int
    307   1.1  christos thread_recursion(struct message *mp, int (*fn)(struct message *, void *), void *args)
    308   1.1  christos {
    309   1.1  christos 	int retval;
    310   1.1  christos 
    311   1.1  christos 	assert(mp != NULL);
    312   1.1  christos 
    313   1.1  christos 	if ((retval = fn(mp, args)) != 0)
    314   1.1  christos 		return retval;
    315   1.1  christos 
    316   1.1  christos 	if (do_recursion() &&
    317   1.1  christos 	    (retval = thread_recursion_flist(mp->m_clink, fn, args)) != 0)
    318   1.1  christos 		return retval;
    319   1.1  christos 
    320   1.1  christos 	return 0;
    321   1.1  christos }
    322   1.1  christos 
    323   1.1  christos /************************************************************************
    324   1.1  christos  * A hook for sfmtfield() in format.c.  It is the only place outside
    325   1.1  christos  * this module that the m_depth is known.
    326   1.1  christos  */
    327   1.1  christos PUBLIC int
    328   1.1  christos thread_depth(void)
    329   1.1  christos {
    330   1.1  christos 	return current_thread.t_head ? current_thread.t_head->m_depth : 0;
    331   1.1  christos }
    332   1.1  christos 
    333   1.1  christos /************************************************************************/
    334   1.1  christos 
    335   1.1  christos static int
    336   1.1  christos reindex_core(struct message *mp)
    337   1.1  christos {
    338   1.1  christos 	int i;
    339   1.1  christos 	assert(mp->m_blink == NULL);
    340   1.1  christos 
    341   1.1  christos 	i = 0;
    342   1.3  christos 	for (mp = first_message(mp); mp; mp = mp->m_flink) {
    343   1.1  christos 		assert(mp->m_flink == NULL || mp == mp->m_flink->m_blink);
    344   1.1  christos 		assert(mp->m_blink == NULL || mp == mp->m_blink->m_flink);
    345   1.1  christos 
    346   1.3  christos 		assert(mp->m_size != 0);
    347   1.3  christos 
    348   1.1  christos 		if (S_IS_RESTRICT(state) == 0 || !is_tagged(mp))
    349   1.1  christos 			mp->m_index = ++i;
    350   1.1  christos 
    351   1.1  christos 		if (mp->m_clink)
    352   1.1  christos 			(void)reindex_core(mp->m_clink);
    353   1.1  christos 	}
    354   1.1  christos 	return i;
    355   1.1  christos }
    356   1.1  christos 
    357   1.1  christos 
    358   1.1  christos static void
    359   1.1  christos reindex(struct thread_s *tp)
    360   1.1  christos {
    361   1.1  christos 	struct message *mp;
    362   1.1  christos 	int i;
    363   1.1  christos 
    364   1.3  christos 	assert(tp != NULL);
    365   1.3  christos 
    366   1.3  christos 	if ((mp = tp->t_head) == NULL || mp->m_size == 0)
    367   1.3  christos 		return;
    368   1.3  christos 
    369   1.3  christos 	assert(mp->m_blink == NULL);
    370   1.1  christos 
    371   1.1  christos 	if (S_IS_EXPOSE(state) == 0) {
    372   1.1  christos 		/*
    373   1.1  christos 		 * We special case this so that all the hidden
    374   1.1  christos 		 * sub-threads get indexed, not just the current one.
    375   1.1  christos 		 */
    376   1.1  christos 		i = reindex_core(tp->t_head);
    377   1.1  christos 	}
    378   1.1  christos 	else {
    379   1.4  christos 		i = 0;
    380   1.1  christos 		for (mp = first_message(tp->t_head); mp; mp = next_message(mp))
    381   1.1  christos 			mp->m_index = ++i;
    382   1.1  christos 	}
    383   1.1  christos 
    384   1.1  christos 	assert(i <= message_array.t_msgCount);
    385   1.1  christos 
    386   1.1  christos 	tp->t_msgCount = i;
    387   1.1  christos 	i = 0;
    388   1.1  christos 	for (mp = first_message(tp->t_head); mp; mp = next_message(mp))
    389   1.1  christos 		tp->t_msgtbl[i++] = mp;
    390   1.1  christos }
    391   1.1  christos 
    392   1.1  christos static void
    393   1.1  christos redepth_core(struct message *mp, int depth, struct message *parent)
    394   1.1  christos {
    395   1.1  christos 	assert(mp->m_blink == NULL);
    396   1.1  christos 	assert((parent == NULL && depth == 0) ||
    397   1.1  christos 	       (parent != NULL && depth != 0 && depth == parent->m_depth + 1));
    398   1.1  christos 
    399   1.1  christos 	for (/*EMPTY*/; mp; mp = mp->m_flink) {
    400   1.1  christos 		assert(mp->m_plink == parent);
    401   1.1  christos 		assert(mp->m_flink == NULL || mp == mp->m_flink->m_blink);
    402   1.1  christos 		assert(mp->m_blink == NULL || mp == mp->m_blink->m_flink);
    403   1.3  christos 		assert(mp->m_size != 0);
    404   1.1  christos 
    405   1.1  christos 		mp->m_depth = depth;
    406   1.1  christos 		if (mp->m_clink)
    407   1.1  christos 			redepth_core(mp->m_clink, depth + 1, mp);
    408   1.1  christos 	}
    409   1.1  christos }
    410   1.1  christos 
    411   1.1  christos static void
    412   1.1  christos redepth(struct thread_s *thread)
    413   1.1  christos {
    414   1.1  christos 	int depth;
    415   1.1  christos 	struct message *mp;
    416   1.1  christos 
    417   1.1  christos 	assert(thread != NULL);
    418   1.1  christos 
    419   1.3  christos 	if ((mp = thread->t_head) == NULL || mp->m_size == 0)
    420   1.1  christos 		return;
    421   1.1  christos 
    422   1.1  christos 	depth = mp->m_plink ? mp->m_plink->m_depth + 1 : 0;
    423   1.1  christos 
    424   1.1  christos #ifndef NDEBUG	/* a sanity check if asserts are active */
    425   1.1  christos 	{
    426   1.1  christos 		struct message *tp;
    427   1.1  christos 		int i;
    428   1.1  christos 		i = 0;
    429   1.1  christos 		for (tp = mp->m_plink; tp; tp = tp->m_plink)
    430   1.1  christos 			i++;
    431   1.1  christos 		assert(i == depth);
    432   1.1  christos 	}
    433   1.1  christos #endif
    434   1.1  christos 
    435   1.1  christos 	redepth_core(mp, depth, mp->m_plink);
    436   1.1  christos }
    437   1.1  christos 
    438   1.1  christos /************************************************************************
    439   1.1  christos  * To be called after reallocating the main message list.  It is here
    440   1.1  christos  * as it needs access to current_thread.t_head.
    441   1.1  christos  */
    442   1.1  christos PUBLIC void
    443  1.15       mrg thread_fix_old_links(struct message *nmessage, ptrdiff_t off, int omsgCount)
    444   1.1  christos {
    445   1.1  christos 	int i;
    446   1.1  christos 
    447   1.1  christos #ifndef NDEBUG
    448   1.1  christos 	message_array.t_head = nmessage; /* for assert check in thread_fix_new_links */
    449   1.1  christos #endif
    450   1.1  christos 
    451   1.9  christos # define FIX_LINK(p)	do {\
    452  1.15       mrg 	p = nmessage + off;\
    453  1.11    rillig   } while (0)
    454   1.9  christos 
    455   1.1  christos 	FIX_LINK(current_thread.t_head);
    456   1.1  christos 	for (i = 0; i < omsgCount; i++) {
    457   1.1  christos 		FIX_LINK(nmessage[i].m_blink);
    458   1.1  christos 		FIX_LINK(nmessage[i].m_flink);
    459   1.1  christos 		FIX_LINK(nmessage[i].m_clink);
    460   1.1  christos 		FIX_LINK(nmessage[i].m_plink);
    461   1.1  christos 	}
    462   1.9  christos 	for (i = 0; i < current_thread.t_msgCount; i++)
    463   1.1  christos 		FIX_LINK(current_thread.t_msgtbl[i]);
    464   1.1  christos 
    465   1.1  christos # undef FIX_LINK
    466   1.1  christos }
    467   1.1  christos 
    468   1.1  christos static void
    469   1.1  christos thread_init(struct thread_s *tp, struct message *mp, int msgCount)
    470   1.1  christos {
    471   1.1  christos 	int i;
    472   1.1  christos 
    473   1.1  christos 	if (tp->t_msgtbl == NULL || msgCount > tp->t_msgCount) {
    474   1.1  christos 		if (tp->t_msgtbl)
    475   1.1  christos 			free(tp->t_msgtbl);
    476   1.1  christos 		tp->t_msgtbl = ecalloc((size_t)msgCount, sizeof(tp->t_msgtbl[0]));
    477   1.1  christos 	}
    478   1.1  christos 	tp->t_head = mp;
    479   1.1  christos 	tp->t_msgCount = msgCount;
    480   1.1  christos 	for (i = 0; i < msgCount; i++)
    481   1.1  christos 		tp->t_msgtbl[i] = &mp[i];
    482   1.1  christos }
    483   1.1  christos 
    484   1.1  christos /*
    485   1.1  christos  * To be called after reading in the new message structures.
    486   1.1  christos  * It is here as it needs access to current_thread.t_head.
    487   1.1  christos  */
    488   1.1  christos PUBLIC void
    489   1.1  christos thread_fix_new_links(struct message *message, int omsgCount, int msgCount)
    490   1.1  christos {
    491   1.1  christos 	int i;
    492   1.1  christos 	struct message *lastmp;
    493   1.1  christos 
    494   1.1  christos 	/* This should only be called at the top level if omsgCount != 0! */
    495   1.1  christos 	assert(omsgCount == 0 || message->m_plink == NULL);
    496   1.1  christos 	assert(omsgCount == 0 || message_array.t_msgCount == omsgCount);
    497   1.1  christos 	assert(message_array.t_head == message);
    498   1.1  christos 
    499   1.1  christos 	message_array.t_head = message;
    500   1.1  christos 	message_array.t_msgCount = msgCount;
    501   1.1  christos 	assert(message_array.t_msgtbl == NULL);	/* never used */
    502   1.1  christos 
    503   1.1  christos 	lastmp = NULL;
    504   1.1  christos 	if (omsgCount) {
    505   1.1  christos 		/*
    506   1.1  christos 		 * Find the end of the toplevel thread.
    507   1.1  christos 		 */
    508   1.1  christos 		for (i = 0; i < omsgCount; i++) {
    509   1.1  christos 			if (message_array.t_head[i].m_depth == 0 &&
    510   1.1  christos 			    message_array.t_head[i].m_flink == NULL) {
    511   1.1  christos 				lastmp = &message_array.t_head[i];
    512   1.1  christos 				break;
    513   1.1  christos 			}
    514   1.1  christos 		}
    515   1.1  christos #ifndef NDEBUG
    516   1.1  christos 		/*
    517   1.1  christos 		 * lastmp better be unique!!!
    518   1.1  christos 		 */
    519   1.1  christos 		for (i++; i < omsgCount; i++)
    520   1.1  christos 			assert(message_array.t_head[i].m_depth != 0 ||
    521   1.1  christos 			    message_array.t_head[i].m_flink != NULL);
    522   1.1  christos 		assert(lastmp != NULL);
    523   1.1  christos #endif /* NDEBUG */
    524   1.1  christos 	}
    525   1.1  christos 	/*
    526   1.1  christos 	 * Link and index the new messages linearly at depth 0.
    527   1.1  christos 	 */
    528   1.1  christos 	for (i = omsgCount; i < msgCount; i++) {
    529   1.1  christos 		message[i].m_index = i + 1;
    530   1.1  christos 		message[i].m_depth = 0;
    531   1.1  christos 		message[i].m_blink = lastmp;
    532   1.1  christos 		message[i].m_flink = NULL;
    533   1.1  christos 		message[i].m_clink = NULL;
    534   1.1  christos 		message[i].m_plink = NULL;
    535   1.1  christos 		if (lastmp)
    536   1.1  christos 			lastmp->m_flink = &message[i];
    537   1.1  christos 		lastmp = &message[i];
    538   1.1  christos 	}
    539   1.1  christos 
    540   1.1  christos 	/*
    541   1.1  christos 	 * Make sure the current thread is setup correctly.
    542   1.1  christos 	 */
    543   1.1  christos 	if (omsgCount == 0) {
    544   1.1  christos 		thread_init(&current_thread, message, msgCount);
    545   1.1  christos 	}
    546   1.1  christos 	else {
    547   1.1  christos 		/*
    548   1.1  christos 		 * Make sure current_thread.t_msgtbl is always large
    549   1.1  christos 		 * enough.
    550   1.1  christos 		 */
    551   1.1  christos 		current_thread.t_msgtbl =
    552   1.1  christos 		    erealloc(current_thread.t_msgtbl,
    553   1.1  christos 			msgCount * sizeof(*current_thread.t_msgtbl));
    554   1.1  christos 
    555   1.1  christos 		assert(current_thread.t_head != NULL);
    556   1.1  christos 		if (current_thread.t_head->m_depth == 0)
    557   1.1  christos 			reindex(&current_thread);
    558   1.1  christos 	}
    559   1.1  christos }
    560   1.1  christos 
    561   1.1  christos /************************************************************************/
    562   1.1  christos /*
    563   1.1  christos  * All state changes should go through here!!!
    564   1.1  christos  */
    565   1.5  christos 
    566   1.5  christos /*
    567   1.5  christos  * NOTE: It is the caller's responsibility to ensure that the "dot"
    568   1.5  christos  * will be valid after a state change.  For example, when changing
    569   1.5  christos  * from exposed to hidden threads, it is necessary to move the dot to
    570   1.5  christos  * the head of the thread or it will not be seen.  Use thread_top()
    571   1.5  christos  * for this.  Likewise, use first_visible_message() to locate the
    572   1.5  christos  * first visible message after a state change.
    573   1.5  christos  */
    574   1.5  christos 
    575   1.1  christos static state_t
    576   1.1  christos set_state(int and_bits, int xor_bits)
    577   1.1  christos {
    578   1.1  christos 	state_t old_state;
    579   1.1  christos 	old_state = state;
    580   1.1  christos 	state &= and_bits;
    581   1.1  christos 	state ^= xor_bits;
    582   1.1  christos 	reindex(&current_thread);
    583   1.1  christos 	redepth(&current_thread);
    584   1.1  christos 	return old_state;
    585   1.1  christos }
    586   1.1  christos 
    587   1.5  christos static struct message *
    588   1.5  christos first_visible_message(struct message *mp)
    589   1.5  christos {
    590   1.5  christos 	struct message *oldmp;
    591   1.5  christos 
    592   1.5  christos 	if (mp == NULL)
    593   1.5  christos 		mp = current_thread.t_head;
    594   1.5  christos 
    595  1.12  christos 	if (mp == NULL)
    596  1.12  christos 		return NULL;
    597  1.12  christos 
    598   1.5  christos 	oldmp = mp;
    599   1.5  christos 	if ((S_IS_RESTRICT(state) && is_tagged(mp)) || mp->m_flag & MDELETED)
    600   1.5  christos 		mp = next_message(mp);
    601   1.5  christos 
    602   1.5  christos 	if (mp == NULL) {
    603   1.5  christos 		mp = oldmp;
    604   1.5  christos 		if ((S_IS_RESTRICT(state) && is_tagged(mp)) || mp->m_flag & MDELETED)
    605   1.5  christos 			mp = prev_message(mp);
    606   1.5  christos 	}
    607   1.5  christos 	if (mp == NULL)
    608   1.5  christos 		mp = current_thread.t_head;
    609   1.5  christos 
    610   1.5  christos 	return mp;
    611   1.5  christos }
    612   1.5  christos 
    613   1.1  christos static void
    614   1.1  christos restore_state(state_t new_state)
    615   1.1  christos {
    616   1.1  christos 	state = new_state;
    617   1.1  christos 	reindex(&current_thread);
    618   1.1  christos 	redepth(&current_thread);
    619   1.5  christos 	dot = first_visible_message(dot);
    620   1.5  christos }
    621   1.5  christos 
    622   1.5  christos static struct message *
    623   1.5  christos thread_top(struct message *mp)
    624   1.5  christos {
    625   1.5  christos 	while (mp && mp->m_plink) {
    626   1.5  christos 		if (mp->m_plink->m_clink == current_thread.t_head)
    627   1.5  christos 			break;
    628   1.5  christos 		mp = mp->m_plink;
    629   1.5  christos 	}
    630   1.5  christos 	return mp;
    631   1.1  christos }
    632   1.1  christos 
    633   1.1  christos /************************************************************************/
    634   1.1  christos /*
    635   1.1  christos  * Possibly show the message list.
    636   1.1  christos  */
    637   1.1  christos static void
    638   1.1  christos thread_announce(void *v)
    639   1.1  christos {
    640   1.1  christos 	int vec[2];
    641   1.1  christos 
    642   1.1  christos 	if (v == NULL)	/* check this here to avoid it before each call */
    643   1.1  christos 	    return;
    644   1.1  christos 
    645   1.1  christos 	if (dot == NULL) {
    646   1.1  christos 		(void)printf("No applicable messages\n");
    647   1.1  christos 		return;
    648   1.1  christos 	}
    649   1.1  christos 	vec[0] = get_msgnum(dot);
    650   1.1  christos 	vec[1] = 0;
    651   1.1  christos 	if (get_msgCount() > 0 && value(ENAME_NOHEADER) == NULL)
    652   1.1  christos 		(void)headers(vec);
    653   1.1  christos 	sawcom = 0;	/* so next will print the first message */
    654   1.1  christos }
    655   1.1  christos 
    656   1.1  christos /************************************************************************/
    657   1.1  christos 
    658   1.1  christos /*
    659   1.1  christos  * Flatten out the portion of the thread starting with the given
    660   1.1  christos  * message.
    661   1.1  christos  */
    662   1.1  christos static void
    663   1.1  christos flattencmd_core(struct message *mp)
    664   1.1  christos {
    665   1.1  christos 	struct message **marray;
    666   1.1  christos 	size_t mcount;
    667   1.1  christos 	struct message *tp;
    668   1.1  christos 	struct message *nextmp;
    669   1.7     lukem 	size_t i;
    670   1.1  christos 
    671   1.1  christos 	if (mp == NULL)
    672   1.1  christos 		return;
    673   1.1  christos 
    674   1.1  christos 	mcount = 1;
    675   1.1  christos 	for (tp = next_message(mp); tp && tp->m_depth > mp->m_depth; tp = next_message(tp))
    676   1.1  christos 		mcount++;
    677   1.1  christos 
    678   1.1  christos 	if (tp && tp->m_depth < mp->m_depth)
    679   1.1  christos 		nextmp = NULL;
    680   1.1  christos 	else
    681   1.1  christos 		nextmp = tp;
    682   1.1  christos 
    683   1.1  christos 	if (mcount == 1)
    684   1.1  christos 		return;
    685   1.1  christos 
    686   1.1  christos 	marray = csalloc(mcount, sizeof(*marray));
    687   1.1  christos 	tp = mp;
    688   1.1  christos 	for (i = 0; i < mcount; i++) {
    689   1.1  christos 		marray[i] = tp;
    690   1.1  christos 		tp = next_message(tp);
    691   1.1  christos 	}
    692   1.1  christos 	mp->m_clink = NULL;
    693   1.1  christos 	for (i = 1; i < mcount; i++) {
    694   1.1  christos 		marray[i]->m_depth = mp->m_depth;
    695   1.1  christos 		marray[i]->m_plink = mp->m_plink;
    696   1.1  christos 		marray[i]->m_clink = NULL;
    697   1.1  christos 		marray[i]->m_blink = marray[i - 1];
    698   1.1  christos 		marray[i - 1]->m_flink = marray[i];
    699   1.1  christos 	}
    700   1.1  christos 	marray[i - 1]->m_flink = nextmp;
    701   1.1  christos 	if (nextmp)
    702   1.1  christos 		nextmp->m_blink = marray[i - 1];
    703   1.1  christos }
    704   1.1  christos 
    705   1.1  christos /*
    706   1.1  christos  * Flatten out all thread parts given in the message list, or the
    707   1.1  christos  * current thread, if none given.
    708   1.1  christos  */
    709   1.1  christos PUBLIC int
    710   1.1  christos flattencmd(void *v)
    711   1.1  christos {
    712   1.1  christos 	int *msgvec;
    713   1.1  christos 	int *ip;
    714   1.1  christos 
    715   1.1  christos 	msgvec = v;
    716   1.1  christos 
    717   1.1  christos 	if (*msgvec) { /* a message was supplied */
    718   1.1  christos 		for (ip = msgvec; *ip; ip++) {
    719   1.1  christos 			struct message *mp;
    720   1.1  christos 			mp = get_message(*ip);
    721   1.1  christos 			if (mp != NULL)
    722   1.1  christos 				flattencmd_core(mp);
    723   1.1  christos 		}
    724   1.1  christos 	}
    725   1.1  christos 	else { /* no message given - flatten current thread */
    726   1.1  christos 		struct message *mp;
    727   1.1  christos 		for (mp = first_message(current_thread.t_head);
    728   1.1  christos 		     mp; mp = next_message(mp))
    729   1.1  christos 			flattencmd_core(mp);
    730   1.1  christos 	}
    731   1.1  christos 	redepth(&current_thread);
    732   1.1  christos 	thread_announce(v);
    733   1.1  christos 	return 0;
    734   1.1  christos }
    735   1.1  christos 
    736   1.1  christos 
    737   1.1  christos /************************************************************************/
    738   1.1  christos /*
    739   1.1  christos  * The basic sort structure.  For each message the index and key
    740   1.1  christos  * fields are set.  The key field is used for the basic sort and the
    741   1.1  christos  * index is used to ensure that the order from the current thread is
    742   1.1  christos  * maintained when the key compare is equal.
    743   1.1  christos  */
    744   1.1  christos struct key_sort_s {
    745   1.1  christos 	struct message *mp; /* the message the following refer to */
    746   1.1  christos 	union {
    747   1.1  christos 		char   *str;	/* string sort key (typically a field or address) */
    748   1.1  christos 		long   lines;	/* a long sort key (typically a message line count) */
    749   1.1  christos 		off_t  size;	/* a size sort key (typically the message size) */
    750   1.1  christos 		time_t time;	/* a time sort key (typically from date or headline) */
    751   1.1  christos 	} key;
    752   1.1  christos 	int    index;	/* index from of the current thread before sorting */
    753   1.1  christos 	/* XXX - do we really want index?  It is always set to mp->m_index */
    754   1.1  christos };
    755   1.1  christos 
    756   1.1  christos /*
    757   1.1  christos  * This is the compare function obtained from the key_tbl[].  It is
    758   1.1  christos  * used by thread_array() to identify the end of the thread and by
    759   1.1  christos  * qsort_cmpfn() to do the basic sort.
    760   1.1  christos  */
    761   1.1  christos static struct {
    762   1.1  christos 	int inv;
    763   1.1  christos 	int (*fn)(const void *, const void *);
    764   1.1  christos } cmp;
    765   1.1  christos 
    766   1.1  christos /*
    767   1.1  christos  * The routine passed to qsort.  Note that cmpfn must be set first!
    768   1.1  christos  */
    769   1.1  christos static int
    770   1.1  christos qsort_cmpfn(const void *left, const void *right)
    771   1.1  christos {
    772   1.1  christos 	int delta;
    773   1.1  christos 	const struct key_sort_s *lp = left;
    774   1.1  christos 	const struct key_sort_s *rp = right;
    775   1.1  christos 
    776   1.1  christos 	delta = cmp.fn(left, right);
    777   1.1  christos 	return delta ? cmp.inv ? - delta : delta : lp->index - rp->index;
    778   1.1  christos }
    779   1.1  christos 
    780   1.1  christos static void
    781   1.1  christos link_array(struct key_sort_s *marray, size_t mcount)
    782   1.1  christos {
    783   1.7     lukem 	size_t i;
    784   1.1  christos 	struct message *lastmp;
    785   1.1  christos 	lastmp = NULL;
    786   1.1  christos 	for (i = 0; i < mcount; i++) {
    787   1.8  christos 		marray[i].mp->m_index = (int)i + 1;
    788   1.1  christos 		marray[i].mp->m_blink = lastmp;
    789   1.1  christos 		marray[i].mp->m_flink = NULL;
    790   1.1  christos 		if (lastmp)
    791   1.1  christos 			lastmp->m_flink = marray[i].mp;
    792   1.1  christos 		lastmp = marray[i].mp;
    793   1.1  christos 	}
    794   1.1  christos 	if (current_thread.t_head->m_plink)
    795   1.1  christos 		current_thread.t_head->m_plink->m_clink = marray[0].mp;
    796   1.1  christos 
    797   1.1  christos 	current_thread.t_head = marray[0].mp;
    798   1.1  christos }
    799   1.1  christos 
    800   1.1  christos static void
    801   1.7     lukem cut_array(struct key_sort_s *marray, size_t beg, size_t end)
    802   1.1  christos {
    803   1.7     lukem 	size_t i;
    804   1.1  christos 
    805   1.1  christos 	if (beg + 1 < end) {
    806   1.1  christos 		assert(marray[beg].mp->m_clink == NULL);
    807   1.1  christos 
    808   1.1  christos 		marray[beg].mp->m_clink = marray[beg + 1].mp;
    809   1.1  christos 		marray[beg + 1].mp->m_blink = NULL;
    810   1.1  christos 
    811   1.1  christos 		marray[beg].mp->m_flink = marray[end].mp;
    812   1.1  christos 		if (marray[end].mp)
    813   1.1  christos 			marray[end].mp->m_blink = marray[beg].mp;
    814   1.1  christos 
    815   1.1  christos 		marray[end - 1].mp->m_flink = NULL;
    816   1.1  christos 
    817   1.1  christos 		for (i = beg + 1; i < end; i++)
    818   1.1  christos 			marray[i].mp->m_plink = marray[beg].mp;
    819   1.1  christos 	}
    820   1.1  christos }
    821   1.1  christos 
    822   1.1  christos static void
    823   1.1  christos thread_array(struct key_sort_s *marray, size_t mcount, int cutit)
    824   1.1  christos {
    825   1.1  christos 	struct message *parent;
    826   1.1  christos 
    827  1.13  christos 	if (mcount == 0)
    828  1.13  christos 		return;
    829  1.13  christos 
    830   1.1  christos 	parent = marray[0].mp->m_plink;
    831   1.1  christos 	qsort(marray, mcount, sizeof(*marray), qsort_cmpfn);
    832   1.1  christos 	link_array(marray, mcount);
    833   1.1  christos 
    834   1.1  christos 	if (cutit) {
    835   1.7     lukem 		size_t i, j;
    836   1.1  christos 		/*
    837   1.1  christos 		 * Flatten out the array.
    838   1.1  christos 		 */
    839   1.1  christos 		for (i = 0; i < mcount; i++) {
    840   1.1  christos 			marray[i].mp->m_plink = parent;
    841   1.1  christos 			marray[i].mp->m_clink = NULL;
    842   1.1  christos 		}
    843   1.1  christos 
    844   1.1  christos 		/*
    845   1.1  christos 		 * Now chop it up.  There is really only one level here.
    846   1.1  christos 		 */
    847   1.1  christos 		i = 0;
    848   1.1  christos 		for (j = 1; j < mcount; j++) {
    849   1.1  christos 			if (cmp.fn(&marray[i], &marray[j]) != 0) {
    850   1.1  christos 				cut_array(marray, i, j);
    851   1.1  christos 				i = j;
    852   1.1  christos 			}
    853   1.1  christos 		}
    854   1.1  christos 		cut_array(marray, i, j);
    855   1.1  christos 	}
    856   1.1  christos }
    857   1.1  christos 
    858   1.1  christos /************************************************************************/
    859   1.1  christos /*
    860   1.1  christos  * thread_on_reference() is the core reference threading routine.  It
    861   1.1  christos  * is not a command itself by called by threadcmd().
    862   1.1  christos  */
    863   1.1  christos 
    864   1.1  christos static void
    865   1.1  christos adopt_child(struct message *parent, struct message *child)
    866   1.1  christos {
    867   1.1  christos 	/*
    868   1.1  christos 	 * Unhook the child from its current location.
    869   1.1  christos 	 */
    870   1.1  christos 	if (child->m_blink != NULL) {
    871   1.1  christos 		child->m_blink->m_flink = child->m_flink;
    872   1.1  christos 	}
    873   1.1  christos 	if (child->m_flink != NULL) {
    874   1.1  christos 		child->m_flink->m_blink = child->m_blink;
    875   1.1  christos 	}
    876   1.4  christos 
    877   1.1  christos 	/*
    878   1.1  christos 	 * Link the child to the parent.
    879   1.1  christos 	 */
    880   1.1  christos 	if (parent->m_clink == NULL) { /* parent has no child */
    881   1.1  christos 		parent->m_clink = child;
    882   1.1  christos 		child->m_blink = NULL;
    883   1.1  christos 	}
    884   1.1  christos 	else { /* add message to end of parent's child's flist */
    885   1.1  christos 		struct message *t;
    886   1.1  christos 		for (t = parent->m_clink; t && t->m_flink; t = t->m_flink)
    887   1.1  christos 			continue;
    888   1.1  christos 		t->m_flink = child;
    889   1.1  christos 		child->m_blink = t;
    890   1.1  christos 	}
    891   1.1  christos 	child->m_flink = NULL;
    892   1.1  christos 	child->m_plink = parent;
    893   1.1  christos }
    894   1.1  christos 
    895   1.1  christos /*
    896   1.1  christos  * Get the parent ID for a message (if there is one).
    897   1.1  christos  *
    898   1.1  christos  * See RFC 2822, sec 3.6.4.
    899   1.1  christos  *
    900   1.1  christos  * Many mailers seem to screw up the In-Reply-To: and/or
    901   1.1  christos  * References: fields, generally by omitting one or both.
    902   1.1  christos  *
    903   1.1  christos  * We give preference to the "References" field.  If it does
    904   1.1  christos  * not exist, try the "In-Reply-To" field.  If neither exist,
    905   1.1  christos  * then the message is either not a reply or someone isn't
    906   1.1  christos  * adding the necessary fields, so skip it.
    907   1.1  christos  */
    908   1.1  christos static char *
    909   1.1  christos get_parent_id(struct message *mp)
    910   1.1  christos {
    911   1.1  christos 	struct name *refs;
    912   1.1  christos 
    913   1.1  christos 	if ((refs = extract(hfield("references", mp), 0)) != NULL) {
    914   1.1  christos 		char *id;
    915   1.1  christos 		while (refs->n_flink)
    916   1.1  christos 			refs = refs->n_flink;
    917   1.1  christos 
    918   1.1  christos 		id = skin(refs->n_name);
    919   1.1  christos 		if (*id != '\0')
    920   1.1  christos 			return id;
    921   1.1  christos 	}
    922   1.1  christos 
    923   1.1  christos 	return skin(hfield("in-reply-to", mp));
    924   1.1  christos }
    925   1.1  christos 
    926   1.1  christos /*
    927   1.1  christos  * Thread on the "In-Reply-To" and "Reference" fields.  This is the
    928   1.1  christos  * normal way to thread.
    929   1.1  christos  */
    930   1.1  christos static void
    931   1.1  christos thread_on_reference(struct message *mp)
    932   1.1  christos {
    933   1.5  christos 	struct {
    934   1.5  christos 		struct message *mp;
    935   1.5  christos 		char *message_id;
    936   1.5  christos 		char *parent_id;
    937   1.5  christos 	} *marray;
    938   1.1  christos 	struct message *parent;
    939   1.1  christos 	state_t oldstate;
    940   1.7     lukem 	size_t mcount, i;
    941   1.1  christos 
    942   1.1  christos 	assert(mp == current_thread.t_head);
    943   1.1  christos 
    944   1.5  christos 	oldstate = set_state(~(S_RESTRICT | S_EXPOSE), S_EXPOSE); /* restrict off, expose on */
    945   1.1  christos 
    946   1.1  christos 	mcount = get_msgCount();
    947   1.1  christos 
    948   1.1  christos 	if (mcount < 2)	/* it's hard to thread so few messages! */
    949   1.1  christos 		goto done;
    950   1.1  christos 
    951   1.1  christos 	marray = csalloc(mcount + 1, sizeof(*marray));
    952   1.1  christos 
    953   1.1  christos 	/*
    954   1.1  christos 	 * Load up the array (skin where necessary).
    955   1.1  christos 	 *
    956   1.1  christos 	 * With a 40K message file, most of the time is spent here,
    957   1.1  christos 	 * not in the search loop below.
    958   1.1  christos 	 */
    959   1.1  christos 	for (i = 0; i < mcount; i++) {
    960   1.1  christos 		marray[i].mp = mp;
    961   1.1  christos 		marray[i].message_id = skin(hfield("message-id", mp));
    962   1.1  christos 		marray[i].parent_id = get_parent_id(mp);
    963   1.1  christos 		mp = next_message(mp);
    964   1.1  christos 	}
    965   1.1  christos 
    966   1.1  christos 	/*
    967   1.1  christos 	 * Save the old parent.
    968   1.1  christos 	 */
    969   1.1  christos 	parent = marray[0].mp->m_plink;
    970   1.1  christos 
    971   1.1  christos 	/*
    972   1.1  christos 	 * flatten the array.
    973   1.1  christos 	 */
    974   1.1  christos 	marray[0].mp->m_clink = NULL;
    975   1.1  christos 	for (i = 1; i < mcount; i++) {
    976   1.1  christos 		marray[i].mp->m_depth = marray[0].mp->m_depth;
    977   1.1  christos 		marray[i].mp->m_plink = marray[0].mp->m_plink;
    978   1.1  christos 		marray[i].mp->m_clink = NULL;
    979   1.1  christos 		marray[i].mp->m_blink = marray[i - 1].mp;
    980   1.1  christos 		marray[i - 1].mp->m_flink = marray[i].mp;
    981   1.1  christos 	}
    982   1.1  christos 	marray[i - 1].mp->m_flink = NULL;
    983   1.1  christos 
    984   1.1  christos 	/*
    985   1.1  christos 	 * Walk the array hooking up the replies with their parents.
    986   1.1  christos 	 */
    987   1.1  christos 	for (i = 0; i < mcount; i++) {
    988   1.1  christos 		struct message *child;
    989   1.1  christos 		char *parent_id;
    990   1.7     lukem 		size_t j;
    991   1.1  christos 
    992   1.1  christos 		if ((parent_id = marray[i].parent_id) == NULL)
    993   1.1  christos 			continue;
    994   1.1  christos 
    995   1.1  christos 		child = marray[i].mp;
    996   1.1  christos 
    997   1.1  christos 		/*
    998   1.1  christos 		 * Look for the parent message and link this one in
    999   1.1  christos 		 * appropriately.
   1000   1.1  christos 		 *
   1001   1.1  christos 		 * XXX - This will not scale nicely, though it does
   1002   1.1  christos 		 * not appear to be the dominant loop even with 40K
   1003   1.1  christos 		 * messages.  If this becomes a problem, implement a
   1004   1.1  christos 		 * binary search.
   1005   1.1  christos 		 */
   1006   1.1  christos 		for (j = 0; j < mcount; j++) {
   1007   1.1  christos 			/* message_id will be NULL on mbox files */
   1008  1.10  christos 			if (marray[j].message_id == NULL)
   1009   1.1  christos 				continue;
   1010   1.1  christos 
   1011   1.1  christos 			if (equal(marray[j].message_id, parent_id)) {
   1012   1.1  christos 				/*
   1013   1.1  christos 				 * The child is at the top level.  If
   1014   1.1  christos 				 * it is being adopted and it was top
   1015   1.1  christos 				 * left (current_thread.t_head), then
   1016   1.1  christos 				 * its right sibling is the new top
   1017   1.1  christos 				 * left (current_thread.t_head).
   1018   1.1  christos 				 */
   1019   1.1  christos 				if (current_thread.t_head == child) {
   1020   1.1  christos 					current_thread.t_head = child->m_flink;
   1021   1.1  christos 					assert(current_thread.t_head != NULL);
   1022   1.1  christos 				}
   1023   1.1  christos 				adopt_child(marray[j].mp, child);
   1024   1.1  christos 				break;
   1025   1.1  christos 			}
   1026   1.1  christos 		}
   1027   1.1  christos 	}
   1028   1.1  christos 
   1029   1.1  christos 	if (parent)
   1030   1.1  christos 		parent->m_clink = current_thread.t_head;
   1031   1.1  christos 	/*
   1032   1.1  christos 	 * If the old state is not exposed, reset the dot to the head
   1033   1.1  christos 	 * of the thread it lived in, so it will be in a valid spot
   1034   1.1  christos 	 * when things are re-hidden.
   1035   1.1  christos 	 */
   1036   1.1  christos 	if (!S_IS_EXPOSE(oldstate))
   1037   1.1  christos 		dot = thread_top(dot);
   1038   1.1  christos  done:
   1039   1.1  christos 	restore_state(oldstate);
   1040   1.1  christos }
   1041   1.1  christos 
   1042   1.1  christos /************************************************************************/
   1043   1.1  christos /*
   1044   1.1  christos  * Tagging commands.
   1045   1.1  christos  */
   1046   1.1  christos static int
   1047   1.1  christos tag1(int *msgvec, int and_bits, int xor_bits)
   1048   1.1  christos {
   1049   1.1  christos 	int *ip;
   1050   1.1  christos 
   1051   1.1  christos 	for (ip = msgvec; *ip != 0; ip++)
   1052   1.1  christos 		(void)set_m_flag(*ip, and_bits, xor_bits);
   1053   1.1  christos 
   1054   1.1  christos 	reindex(&current_thread);
   1055   1.1  christos /*	thread_announce(v); */
   1056   1.1  christos 	return 0;
   1057   1.1  christos }
   1058   1.1  christos 
   1059   1.1  christos /*
   1060   1.1  christos  * Tag the current message dot or a message list.
   1061   1.1  christos  */
   1062   1.1  christos PUBLIC int
   1063   1.1  christos tagcmd(void *v)
   1064   1.1  christos {
   1065   1.1  christos 	return tag1(v, ~MTAGGED, MTAGGED);
   1066   1.1  christos }
   1067   1.1  christos 
   1068   1.1  christos /*
   1069   1.1  christos  * Untag the current message dot or a message list.
   1070   1.1  christos  */
   1071   1.1  christos PUBLIC int
   1072   1.1  christos untagcmd(void *v)
   1073   1.1  christos {
   1074   1.1  christos 	return tag1(v, ~MTAGGED, 0);
   1075   1.1  christos }
   1076   1.1  christos 
   1077   1.1  christos /*
   1078   1.1  christos  * Invert all tags in the message list.
   1079   1.1  christos  */
   1080   1.1  christos PUBLIC int
   1081   1.1  christos invtagscmd(void *v)
   1082   1.1  christos {
   1083   1.1  christos 	return tag1(v, ~0, MTAGGED);
   1084   1.1  christos }
   1085   1.1  christos 
   1086   1.1  christos /*
   1087   1.1  christos  * Tag all messages below the current dot or below a specified
   1088   1.1  christos  * message.
   1089   1.1  christos  */
   1090   1.1  christos PUBLIC int
   1091   1.1  christos tagbelowcmd(void *v)
   1092   1.1  christos {
   1093   1.1  christos 	int *msgvec;
   1094   1.1  christos 	struct message *mp;
   1095   1.1  christos 	state_t oldstate;
   1096   1.1  christos 	int depth;
   1097   1.1  christos 
   1098   1.1  christos 	msgvec = v;
   1099   1.1  christos 
   1100   1.5  christos 	oldstate = set_state(~(S_RESTRICT | S_EXPOSE), S_EXPOSE); /* restrict off, expose on */
   1101   1.1  christos 	mp = get_message(*msgvec);
   1102   1.1  christos 	if (mp) {
   1103   1.1  christos 		depth = mp->m_depth;
   1104   1.1  christos 		for (mp = first_message(current_thread.t_head); mp; mp = next_message(mp))
   1105   1.9  christos 			if (mp->m_depth > depth) {
   1106   1.1  christos 				mp->m_flag |= MTAGGED;
   1107   1.1  christos 				touch(mp);
   1108   1.1  christos 			}
   1109   1.1  christos 	}
   1110   1.5  christos 	/* dot is OK */
   1111   1.1  christos 	restore_state(oldstate);
   1112   1.1  christos /*	thread_announce(v); */
   1113   1.1  christos 	return 0;
   1114   1.1  christos }
   1115   1.1  christos 
   1116   1.1  christos /*
   1117   1.1  christos  * Do not display the tagged messages.
   1118   1.1  christos  */
   1119   1.1  christos PUBLIC int
   1120   1.1  christos hidetagscmd(void *v)
   1121   1.1  christos {
   1122   1.5  christos 	(void)set_state(~S_RESTRICT, S_RESTRICT);	/* restrict on */
   1123   1.5  christos 	dot = first_visible_message(dot);
   1124   1.1  christos 	thread_announce(v);
   1125   1.1  christos 	return 0;
   1126   1.1  christos }
   1127   1.1  christos 
   1128   1.1  christos /*
   1129   1.1  christos  * Display the tagged messages.
   1130   1.1  christos  */
   1131   1.1  christos PUBLIC int
   1132   1.1  christos showtagscmd(void *v)
   1133   1.1  christos {
   1134   1.5  christos 	(void)set_state(~S_RESTRICT, 0);		/* restrict off */
   1135   1.5  christos 	dot = first_visible_message(dot);
   1136   1.1  christos 	thread_announce(v);
   1137   1.1  christos 	return 0;
   1138   1.1  christos }
   1139   1.1  christos 
   1140   1.1  christos /************************************************************************/
   1141   1.1  christos /*
   1142   1.1  christos  * Basic threading commands.
   1143   1.1  christos  */
   1144   1.1  christos /*
   1145   1.1  christos  * Show the threads.
   1146   1.1  christos  */
   1147   1.1  christos PUBLIC int
   1148   1.1  christos exposecmd(void *v)
   1149   1.1  christos {
   1150   1.1  christos 	(void)set_state(~S_EXPOSE, S_EXPOSE);	/* expose on */
   1151   1.5  christos 	dot = first_visible_message(dot);
   1152   1.1  christos 	thread_announce(v);
   1153   1.1  christos 	return 0;
   1154   1.1  christos }
   1155   1.1  christos 
   1156   1.1  christos /*
   1157   1.1  christos  * Hide the threads.
   1158   1.1  christos  */
   1159   1.1  christos PUBLIC int
   1160   1.1  christos hidecmd(void *v)
   1161   1.1  christos {
   1162   1.1  christos 	dot = thread_top(dot);
   1163   1.5  christos 	(void)set_state(~S_EXPOSE, 0);		/* expose off */
   1164   1.5  christos 	dot = first_visible_message(dot);
   1165   1.1  christos 	thread_announce(v);
   1166   1.1  christos 	return 0;
   1167   1.1  christos }
   1168   1.1  christos 
   1169   1.1  christos /*
   1170   1.1  christos  * Up one level in the thread tree.  Go up multiple levels if given an
   1171   1.1  christos  * argument.
   1172   1.1  christos  */
   1173   1.1  christos PUBLIC int
   1174   1.1  christos upcmd(void *v)
   1175   1.1  christos {
   1176   1.1  christos 	char *str;
   1177   1.1  christos 	int upcnt;
   1178   1.1  christos 	int upone;
   1179   1.1  christos 
   1180   1.1  christos 	str = v;
   1181   1.4  christos 	str = skip_WSP(str);
   1182   1.1  christos 	if (*str == '\0')
   1183   1.1  christos 		upcnt = 1;
   1184   1.1  christos 	else
   1185   1.1  christos 		upcnt = atoi(str);
   1186   1.1  christos 
   1187   1.1  christos 	if (upcnt < 1) {
   1188   1.1  christos 		(void)printf("Sorry, argument must be > 0.\n");
   1189   1.1  christos 		return 0;
   1190   1.1  christos 	}
   1191   1.1  christos 	if (dot == NULL) {
   1192   1.1  christos 		(void)printf("No applicable messages\n");
   1193   1.1  christos 		return 0;
   1194   1.1  christos 	}
   1195   1.1  christos 	if (dot->m_plink == NULL) {
   1196   1.1  christos 		(void)printf("top thread\n");
   1197   1.1  christos 		return 0;
   1198   1.1  christos 	}
   1199   1.1  christos 	upone = 0;
   1200   1.1  christos 	while (upcnt-- > 0) {
   1201   1.1  christos 		struct message *parent;
   1202   1.1  christos 		parent = current_thread.t_head->m_plink;
   1203   1.1  christos 		if (parent == NULL) {
   1204   1.1  christos 			(void)printf("top thread\n");
   1205   1.1  christos 			break;
   1206   1.1  christos 		}
   1207   1.1  christos 		else {
   1208   1.1  christos 			struct message *mp;
   1209   1.1  christos 			assert(current_thread.t_head->m_depth > 0);
   1210   1.1  christos 			for (mp = parent; mp && mp->m_blink; mp = mp->m_blink)
   1211   1.1  christos 				continue;
   1212   1.1  christos 			current_thread.t_head = mp;
   1213   1.1  christos 			dot = parent;
   1214   1.1  christos 			upone = 1;
   1215   1.1  christos 		}
   1216   1.1  christos 	}
   1217   1.1  christos 	if (upone) {
   1218   1.1  christos 		reindex(&current_thread);
   1219   1.1  christos 		thread_announce(v);
   1220   1.1  christos 	}
   1221   1.1  christos 	return 0;
   1222   1.1  christos }
   1223   1.1  christos 
   1224   1.1  christos /*
   1225   1.1  christos  * Go down one level in the thread tree from the current dot or a
   1226   1.1  christos  * given message number if given.
   1227   1.1  christos  */
   1228   1.1  christos PUBLIC int
   1229   1.1  christos downcmd(void *v)
   1230   1.1  christos {
   1231   1.1  christos 	struct message *child;
   1232   1.1  christos 	struct message *mp;
   1233   1.1  christos 	int *msgvec = v;
   1234   1.1  christos 
   1235   1.1  christos 	if ((mp = get_message(*msgvec)) == NULL ||
   1236   1.1  christos 	    (child = mp->m_clink) == NULL)
   1237   1.1  christos 		(void)printf("no sub-thread\n");
   1238   1.1  christos 	else {
   1239   1.1  christos 		current_thread.t_head = child;
   1240   1.1  christos 		dot = child;
   1241   1.1  christos 		reindex(&current_thread);
   1242   1.1  christos 		thread_announce(v);
   1243   1.1  christos 	}
   1244   1.1  christos 	return 0;
   1245   1.1  christos }
   1246   1.1  christos 
   1247   1.1  christos /*
   1248   1.1  christos  * Set the current thread level to the current dot or to the message
   1249   1.1  christos  * if given.
   1250   1.1  christos  */
   1251   1.1  christos PUBLIC int
   1252   1.1  christos tsetcmd(void *v)
   1253   1.1  christos {
   1254   1.1  christos 	struct message *mp;
   1255   1.1  christos 	int *msgvec = v;
   1256   1.1  christos 
   1257   1.1  christos 	if ((mp = get_message(*msgvec)) == NULL)
   1258   1.1  christos 		(void)printf("invalid message\n");
   1259   1.1  christos 	else {
   1260   1.1  christos 		for (/*EMPTY*/; mp->m_blink; mp = mp->m_blink)
   1261   1.1  christos 			continue;
   1262   1.1  christos 		current_thread.t_head = mp;
   1263   1.1  christos 		reindex(&current_thread);
   1264   1.1  christos 		thread_announce(v);
   1265   1.1  christos 	}
   1266   1.1  christos 	return 0;
   1267   1.1  christos }
   1268   1.1  christos 
   1269   1.1  christos /*
   1270   1.1  christos  * Reverse the current thread order.  If threaded, it only operates on
   1271   1.1  christos  * the heads.
   1272   1.1  christos  */
   1273   1.1  christos static void
   1274   1.1  christos reversecmd_core(struct thread_s *tp)
   1275   1.1  christos {
   1276   1.1  christos 	struct message *thread_start;
   1277   1.1  christos 	struct message *mp;
   1278   1.1  christos 	struct message *lastmp;
   1279   1.1  christos 	struct message *old_flink;
   1280   1.1  christos 
   1281   1.1  christos 	thread_start = tp->t_head;
   1282   1.1  christos 
   1283   1.1  christos 	assert(thread_start->m_blink == NULL);
   1284   1.1  christos 
   1285   1.1  christos 	lastmp = NULL;
   1286   1.1  christos 	for (mp = thread_start; mp; mp = old_flink) {
   1287   1.1  christos 		old_flink = mp->m_flink;
   1288   1.1  christos 		mp->m_flink = mp->m_blink;
   1289   1.1  christos 		mp->m_blink = old_flink;
   1290   1.1  christos 		lastmp = mp;
   1291   1.1  christos 	}
   1292   1.1  christos 	if (thread_start->m_plink)
   1293   1.1  christos 		thread_start->m_plink->m_clink = lastmp;
   1294   1.1  christos 
   1295   1.1  christos 	current_thread.t_head = lastmp;
   1296   1.1  christos 	reindex(tp);
   1297   1.1  christos }
   1298   1.1  christos 
   1299   1.1  christos PUBLIC int
   1300   1.1  christos reversecmd(void *v)
   1301   1.1  christos {
   1302   1.1  christos 	reversecmd_core(&current_thread);
   1303   1.1  christos 	thread_announce(v);
   1304   1.1  christos 	return 0;
   1305   1.1  christos }
   1306   1.1  christos 
   1307   1.1  christos 
   1308   1.1  christos /*
   1309   1.1  christos  * Get threading and sorting modifiers.
   1310   1.1  christos  */
   1311   1.1  christos #define MF_IGNCASE	1	/* ignore case when sorting */
   1312   1.1  christos #define MF_REVERSE	2	/* reverse sort direction */
   1313   1.1  christos #define MF_SKIN		4	/* "skin" the field to remove comments */
   1314   1.1  christos static int
   1315   1.1  christos get_modifiers(char **str)
   1316   1.1  christos {
   1317   1.1  christos 	int modflags;
   1318   1.1  christos 	char *p;
   1319   1.1  christos 
   1320   1.1  christos 	modflags = 0;
   1321   1.1  christos 	for (p = *str; p && *p; p++) {
   1322   1.1  christos 		switch (*p) {
   1323   1.1  christos 		case '!':
   1324   1.1  christos 			modflags |= MF_REVERSE;
   1325   1.1  christos 			break;
   1326   1.1  christos 		case '^':
   1327   1.1  christos 			modflags |= MF_IGNCASE;
   1328   1.1  christos 			break;
   1329   1.1  christos 		case '-':
   1330   1.1  christos 			modflags |= MF_SKIN;
   1331   1.1  christos 			break;
   1332   1.1  christos 		case ' ':
   1333   1.1  christos 		case '\t':
   1334   1.1  christos 			break;
   1335   1.1  christos 		default:
   1336   1.1  christos 			goto done;
   1337   1.1  christos 		}
   1338   1.1  christos 	}
   1339   1.1  christos  done:
   1340   1.1  christos 	*str = p;
   1341   1.1  christos 	return modflags;
   1342   1.1  christos }
   1343   1.1  christos 
   1344   1.1  christos /************************************************************************/
   1345   1.1  christos /*
   1346   1.1  christos  * The key_sort_s compare routines.
   1347   1.1  christos  */
   1348   1.1  christos 
   1349   1.1  christos static int
   1350   1.1  christos keystrcmp(const void *left, const void *right)
   1351   1.1  christos {
   1352   1.1  christos 	const struct key_sort_s *lp = left;
   1353   1.1  christos 	const struct key_sort_s *rp = right;
   1354   1.1  christos 
   1355   1.1  christos 	lp = left;
   1356   1.1  christos 	rp = right;
   1357   1.1  christos 
   1358   1.1  christos 	if (rp->key.str == NULL && lp->key.str == NULL)
   1359   1.1  christos 		return 0;
   1360   1.1  christos 	else if (rp->key.str == NULL)
   1361   1.1  christos 		return -1;
   1362   1.1  christos 	else if (lp->key.str == NULL)
   1363   1.1  christos 		return 1;
   1364   1.1  christos 	else
   1365   1.1  christos 		return strcmp(lp->key.str, rp->key.str);
   1366   1.1  christos }
   1367   1.1  christos 
   1368   1.1  christos static int
   1369   1.1  christos keystrcasecmp(const void *left, const void *right)
   1370   1.1  christos {
   1371   1.1  christos 	const struct key_sort_s *lp = left;
   1372   1.1  christos 	const struct key_sort_s *rp = right;
   1373   1.1  christos 
   1374   1.1  christos 	if (rp->key.str == NULL && lp->key.str == NULL)
   1375   1.1  christos 		return 0;
   1376   1.1  christos 	else if (rp->key.str == NULL)
   1377   1.1  christos 		return -1;
   1378   1.1  christos 	else if (lp->key.str == NULL)
   1379   1.1  christos 		return 1;
   1380   1.1  christos 	else
   1381   1.1  christos 		return strcasecmp(lp->key.str, rp->key.str);
   1382   1.1  christos }
   1383   1.1  christos 
   1384   1.1  christos static int
   1385   1.1  christos keylongcmp(const void *left, const void *right)
   1386   1.1  christos {
   1387   1.1  christos 	const struct key_sort_s *lp = left;
   1388   1.1  christos 	const struct key_sort_s *rp = right;
   1389   1.1  christos 
   1390   1.1  christos 	if (lp->key.lines > rp->key.lines)
   1391   1.1  christos 		return 1;
   1392   1.1  christos 
   1393   1.1  christos 	if (lp->key.lines < rp->key.lines)
   1394   1.1  christos 		return -1;
   1395   1.1  christos 
   1396   1.1  christos 	return 0;
   1397   1.1  christos }
   1398   1.1  christos 
   1399   1.1  christos static int
   1400   1.1  christos keyoffcmp(const void *left, const void *right)
   1401   1.1  christos {
   1402   1.1  christos 	const struct key_sort_s *lp = left;
   1403   1.1  christos 	const struct key_sort_s *rp = right;
   1404   1.1  christos 
   1405   1.1  christos 	if (lp->key.size > rp->key.size)
   1406   1.1  christos 		return 1;
   1407   1.1  christos 
   1408   1.1  christos 	if (lp->key.size < rp->key.size)
   1409   1.1  christos 		return -1;
   1410   1.1  christos 
   1411   1.1  christos 	return 0;
   1412   1.1  christos }
   1413   1.1  christos 
   1414   1.1  christos static int
   1415   1.1  christos keytimecmp(const void *left, const void *right)
   1416   1.1  christos {
   1417   1.1  christos 	double delta;
   1418   1.1  christos 	const struct key_sort_s *lp = left;
   1419   1.1  christos 	const struct key_sort_s *rp = right;
   1420   1.1  christos 
   1421   1.1  christos 	delta = difftime(lp->key.time, rp->key.time);
   1422   1.1  christos 	if (delta > 0)
   1423   1.1  christos 		return 1;
   1424   1.1  christos 
   1425   1.1  christos 	if (delta < 0)
   1426   1.1  christos 		return -1;
   1427   1.1  christos 
   1428   1.1  christos 	return 0;
   1429   1.1  christos }
   1430   1.1  christos 
   1431   1.1  christos /************************************************************************
   1432   1.1  christos  * key_sort_s loading routines.
   1433   1.1  christos  */
   1434   1.1  christos static void
   1435   1.1  christos field_load(struct key_sort_s *marray, size_t mcount, struct message *mp,
   1436   1.1  christos     const char *key, int skin_it)
   1437   1.1  christos {
   1438   1.7     lukem 	size_t i;
   1439   1.1  christos 	for (i = 0; i < mcount; i++) {
   1440   1.1  christos 		marray[i].mp = mp;
   1441   1.1  christos 		marray[i].key.str =
   1442   1.1  christos 		    skin_it ? skin(hfield(key, mp)) : hfield(key, mp);
   1443   1.1  christos 		marray[i].index = mp->m_index;
   1444   1.1  christos 		mp = next_message(mp);
   1445   1.1  christos 	}
   1446   1.1  christos }
   1447   1.1  christos 
   1448   1.1  christos static void
   1449   1.1  christos subj_load(struct key_sort_s *marray, size_t mcount, struct message *mp,
   1450   1.1  christos     const char *key __unused, int flags __unused)
   1451   1.1  christos {
   1452   1.7     lukem 	size_t i;
   1453   1.1  christos #ifdef __lint__
   1454   1.1  christos 	flags = flags;
   1455   1.1  christos 	key = key;
   1456   1.1  christos #endif
   1457   1.1  christos 	for (i = 0; i < mcount; i++) {
   1458   1.1  christos 		char *subj = hfield(key, mp);
   1459   1.9  christos 		while (strncasecmp(subj, "Re:", 3) == 0)
   1460   1.4  christos 			subj = skip_WSP(subj + 3);
   1461   1.1  christos 		marray[i].mp = mp;
   1462   1.1  christos 		marray[i].key.str = subj;
   1463   1.1  christos 		marray[i].index = mp->m_index;
   1464   1.1  christos 		mp = next_message(mp);
   1465   1.1  christos 	}
   1466   1.1  christos }
   1467   1.1  christos 
   1468   1.1  christos 
   1469   1.1  christos static void
   1470   1.1  christos lines_load(struct key_sort_s *marray, size_t mcount, struct message *mp,
   1471   1.1  christos     const char *key __unused, int flags)
   1472   1.1  christos {
   1473   1.7     lukem 	size_t i;
   1474   1.1  christos 	int use_blines;
   1475   1.1  christos 	int use_hlines;
   1476   1.1  christos #ifdef __lint__
   1477   1.1  christos 	key = key;
   1478   1.1  christos #endif
   1479   1.1  christos #define HLINES	1
   1480   1.1  christos #define BLINES	2
   1481   1.1  christos #define TLINES	3
   1482   1.1  christos 	use_hlines = flags == HLINES;
   1483   1.1  christos 	use_blines = flags == BLINES;
   1484   1.1  christos 
   1485   1.1  christos 	for (i = 0; i < mcount; i++) {
   1486   1.1  christos 		marray[i].mp = mp;
   1487   1.1  christos 		marray[i].key.lines = use_hlines ? mp->m_lines - mp->m_blines :
   1488   1.1  christos 		    use_blines ? mp->m_blines : mp->m_lines;
   1489   1.1  christos 		marray[i].index = mp->m_index;
   1490   1.1  christos 		mp = next_message(mp);
   1491   1.1  christos 	}
   1492   1.1  christos }
   1493   1.1  christos 
   1494   1.1  christos static void
   1495   1.1  christos size_load(struct key_sort_s *marray, size_t mcount, struct message *mp,
   1496   1.1  christos     const char *key __unused, int flags __unused)
   1497   1.1  christos {
   1498   1.7     lukem 	size_t i;
   1499   1.1  christos #ifdef __lint__
   1500   1.1  christos 	flags = flags;
   1501   1.1  christos 	key = key;
   1502   1.1  christos #endif
   1503   1.1  christos 	for (i = 0; i < mcount; i++) {
   1504   1.1  christos 		marray[i].mp = mp;
   1505   1.1  christos 		marray[i].key.size = mp->m_size;
   1506   1.1  christos 		marray[i].index = mp->m_index;
   1507   1.1  christos 		mp = next_message(mp);
   1508   1.1  christos 	}
   1509   1.1  christos }
   1510   1.1  christos 
   1511   1.1  christos static void __unused
   1512   1.1  christos date_load(struct key_sort_s *marray, size_t mcount, struct message *mp,
   1513   1.1  christos     const char *key __unused, int flags)
   1514   1.1  christos {
   1515   1.7     lukem 	size_t i;
   1516   1.1  christos 	int use_hl_date;
   1517   1.1  christos 	int zero_hour_min_sec;
   1518   1.1  christos #ifdef __lint__
   1519   1.1  christos 	key = key;
   1520   1.1  christos #endif
   1521   1.1  christos #define RDAY 1
   1522   1.1  christos #define SDAY 2
   1523   1.1  christos #define RDATE 3
   1524   1.1  christos #define SDATE 4
   1525   1.1  christos 	use_hl_date       = (flags == RDAY || flags == RDATE);
   1526   1.1  christos 	zero_hour_min_sec = (flags == RDAY || flags == SDAY);
   1527   1.1  christos 
   1528   1.1  christos 	for (i = 0; i < mcount; i++) {
   1529   1.1  christos 		struct tm tm;
   1530   1.1  christos 		(void)dateof(&tm, mp, use_hl_date);
   1531   1.1  christos 		if (zero_hour_min_sec) {
   1532   1.1  christos 			tm.tm_sec = 0;
   1533   1.1  christos 			tm.tm_min = 0;
   1534   1.1  christos 			tm.tm_hour = 0;
   1535   1.1  christos 		}
   1536   1.1  christos 		marray[i].mp = mp;
   1537   1.1  christos 		marray[i].key.time = mktime(&tm);
   1538   1.1  christos 		marray[i].index = mp->m_index;
   1539   1.1  christos 		mp = next_message(mp);
   1540   1.1  christos 	}
   1541   1.1  christos }
   1542   1.1  christos 
   1543   1.1  christos static void
   1544   1.1  christos from_load(struct key_sort_s *marray, size_t mcount, struct message *mp,
   1545   1.1  christos     const char *key __unused, int flags __unused)
   1546   1.1  christos {
   1547   1.7     lukem 	size_t i;
   1548   1.1  christos #ifdef __lint__
   1549   1.1  christos 	flags = flags;
   1550   1.1  christos 	key = key;
   1551   1.1  christos #endif
   1552   1.1  christos 	for (i = 0; i < mcount; i++) {
   1553   1.1  christos 		marray[i].mp = mp;
   1554   1.1  christos 		marray[i].key.str = nameof(mp, 0);
   1555   1.1  christos 		marray[i].index = mp->m_index;
   1556   1.1  christos 		mp = next_message(mp);
   1557   1.1  christos 	}
   1558   1.1  christos }
   1559   1.1  christos 
   1560   1.1  christos /************************************************************************
   1561   1.1  christos  * The master table that controls all sorting and threading.
   1562   1.1  christos  */
   1563   1.1  christos static const struct key_tbl_s {
   1564   1.1  christos 	const char *key;
   1565   1.1  christos 	void (*loadfn)(struct key_sort_s *, size_t, struct message *, const char *, int);
   1566   1.1  christos 	int flags;
   1567   1.1  christos 	int (*cmpfn)(const void*, const void*);
   1568   1.1  christos 	int (*casecmpfn)(const void*, const void*);
   1569   1.1  christos } key_tbl[] = {
   1570   1.1  christos 	{"blines",	lines_load,	BLINES,	keylongcmp,	keylongcmp},
   1571   1.1  christos 	{"hlines",	lines_load,	HLINES,	keylongcmp,	keylongcmp},
   1572   1.1  christos 	{"tlines",	lines_load,	TLINES,	keylongcmp,	keylongcmp},
   1573   1.1  christos 	{"size",	size_load,	0,	keyoffcmp,	keyoffcmp},
   1574   1.1  christos 	{"sday",	date_load,	SDAY,	keytimecmp,	keytimecmp},
   1575   1.1  christos 	{"rday",	date_load,	RDAY,	keytimecmp,	keytimecmp},
   1576   1.1  christos 	{"sdate",	date_load,	SDATE,	keytimecmp,	keytimecmp},
   1577   1.1  christos 	{"rdate",	date_load,	RDATE,	keytimecmp,	keytimecmp},
   1578   1.1  christos 	{"from",	from_load,	0,	keystrcasecmp,	keystrcasecmp},
   1579   1.1  christos 	{"subject",	subj_load,	0,	keystrcmp,	keystrcasecmp},
   1580   1.1  christos 	{NULL,		field_load,	0,	keystrcmp,	keystrcasecmp},
   1581   1.1  christos };
   1582   1.1  christos 
   1583   1.1  christos #ifdef USE_EDITLINE
   1584   1.1  christos /*
   1585   1.1  christos  * This is for use in complete.c to get the list of threading key
   1586   1.1  christos  * names without exposing the key_tbl[].  The first name is returned
   1587   1.1  christos  * if called with a pointer to a NULL pointer.  Subsequent calls with
   1588   1.1  christos  * the same cookie give successive names.  A NULL return indicates the
   1589   1.1  christos  * end of the list.
   1590   1.1  christos  */
   1591   1.1  christos PUBLIC const char *
   1592   1.1  christos thread_next_key_name(const void **cookie)
   1593   1.1  christos {
   1594   1.1  christos 	const struct key_tbl_s *kp;
   1595   1.1  christos 
   1596   1.1  christos 	kp = *cookie;
   1597   1.1  christos 	if (kp == NULL)
   1598   1.1  christos 		kp = key_tbl;
   1599   1.1  christos 
   1600   1.1  christos 	*cookie = kp->key ? &kp[1] : NULL;
   1601   1.1  christos 
   1602   1.1  christos 	return kp->key;
   1603   1.1  christos }
   1604   1.1  christos #endif /* USE_EDITLINE */
   1605   1.1  christos 
   1606   1.1  christos static const struct key_tbl_s *
   1607   1.1  christos get_key(const char *key)
   1608   1.1  christos {
   1609   1.1  christos 	const struct key_tbl_s *kp;
   1610   1.1  christos 	for (kp = key_tbl; kp->key != NULL; kp++)
   1611   1.1  christos 		if (strcmp(kp->key, key) == 0)
   1612   1.1  christos 			return kp;
   1613   1.1  christos 	return kp;
   1614   1.1  christos }
   1615   1.1  christos 
   1616   1.1  christos static int (*
   1617   1.1  christos get_cmpfn(const struct key_tbl_s *kp, int ignorecase)
   1618   1.1  christos )(const void*, const void*)
   1619   1.1  christos {
   1620   1.1  christos 	if (ignorecase)
   1621   1.1  christos 		return kp->casecmpfn;
   1622   1.1  christos 	else
   1623   1.1  christos 		return kp->cmpfn;
   1624   1.1  christos }
   1625   1.1  christos 
   1626   1.1  christos static void
   1627   1.1  christos thread_current_on(char *str, int modflags, int cutit)
   1628   1.1  christos {
   1629   1.1  christos 	const struct key_tbl_s *kp;
   1630   1.1  christos 	struct key_sort_s *marray;
   1631   1.1  christos 	size_t mcount;
   1632   1.1  christos 	state_t oldstate;
   1633   1.1  christos 
   1634   1.5  christos 	oldstate = set_state(~(S_RESTRICT | S_EXPOSE), cutit ? S_EXPOSE : 0);
   1635   1.1  christos 
   1636   1.1  christos 	kp = get_key(str);
   1637   1.1  christos 	mcount = get_msgCount();
   1638   1.1  christos 	marray = csalloc(mcount + 1, sizeof(*marray));
   1639   1.1  christos 	kp->loadfn(marray, mcount, current_thread.t_head, str,
   1640   1.1  christos 	    kp->flags ? kp->flags : modflags & MF_SKIN);
   1641   1.1  christos 	cmp.fn = get_cmpfn(kp, modflags & MF_IGNCASE);
   1642   1.1  christos 	cmp.inv = modflags & MF_REVERSE;
   1643   1.1  christos 	thread_array(marray, mcount, cutit);
   1644   1.4  christos 
   1645   1.1  christos 	if (!S_IS_EXPOSE(oldstate))
   1646   1.1  christos 		dot = thread_top(dot);
   1647   1.1  christos 	restore_state(oldstate);
   1648   1.1  christos }
   1649   1.1  christos 
   1650   1.1  christos /*
   1651   1.1  christos  * The thread command.  Thread the current thread on its references or
   1652   1.1  christos  * on a specified field.
   1653   1.1  christos  */
   1654   1.1  christos PUBLIC int
   1655   1.1  christos threadcmd(void *v)
   1656   1.1  christos {
   1657   1.1  christos 	char *str;
   1658   1.1  christos 
   1659   1.4  christos 	str = v;
   1660   1.1  christos 	if (*str == '\0')
   1661   1.1  christos 		thread_on_reference(current_thread.t_head);
   1662   1.1  christos 	else {
   1663   1.1  christos 		int modflags;
   1664   1.1  christos 		modflags = get_modifiers(&str);
   1665   1.1  christos 		thread_current_on(str, modflags, 1);
   1666   1.1  christos 	}
   1667   1.1  christos 	thread_announce(v);
   1668   1.1  christos 	return 0;
   1669   1.1  christos }
   1670   1.1  christos 
   1671   1.1  christos /*
   1672   1.1  christos  * Remove all threading information, reverting to the startup state.
   1673   1.1  christos  */
   1674   1.1  christos PUBLIC int
   1675   1.1  christos unthreadcmd(void *v)
   1676   1.1  christos {
   1677   1.1  christos 	thread_fix_new_links(message_array.t_head, 0, message_array.t_msgCount);
   1678   1.1  christos 	thread_announce(v);
   1679   1.1  christos 	return 0;
   1680   1.1  christos }
   1681   1.1  christos 
   1682   1.1  christos /*
   1683   1.1  christos  * The sort command.
   1684   1.1  christos  */
   1685   1.1  christos PUBLIC int
   1686   1.1  christos sortcmd(void *v)
   1687   1.1  christos {
   1688   1.1  christos 	int modflags;
   1689   1.1  christos 	char *str;
   1690   1.1  christos 
   1691   1.1  christos 	str = v;
   1692   1.1  christos 	modflags = get_modifiers(&str);
   1693   1.1  christos 	if (*str != '\0')
   1694   1.1  christos 		thread_current_on(str, modflags, 0);
   1695   1.1  christos 	else {
   1696   1.1  christos 		if (modflags & MF_REVERSE)
   1697   1.1  christos 			reversecmd_core(&current_thread);
   1698   1.1  christos 		else {
   1699   1.1  christos 			(void)printf("sort on what?\n");
   1700   1.1  christos 			return 0;
   1701   1.1  christos 		}
   1702   1.1  christos 	}
   1703   1.1  christos 	thread_announce(v);
   1704   1.1  christos 	return 0;
   1705   1.1  christos }
   1706   1.1  christos 
   1707   1.1  christos 
   1708   1.1  christos /*
   1709   1.1  christos  * Delete duplicate messages (based on their "Message-Id" field).
   1710   1.1  christos  */
   1711   1.1  christos /*ARGSUSED*/
   1712   1.1  christos PUBLIC int
   1713   1.1  christos deldupscmd(void *v __unused)
   1714   1.1  christos {
   1715   1.1  christos 	struct message *mp;
   1716   1.1  christos 	int depth;
   1717   1.1  christos 	state_t oldstate;
   1718   1.1  christos 
   1719   1.5  christos 	oldstate = set_state(~(S_RESTRICT | S_EXPOSE), S_EXPOSE); /* restrict off, expose on */
   1720   1.1  christos 
   1721   1.1  christos 	thread_current_on(__UNCONST("Message-Id"), 0, 1);
   1722   1.1  christos 	reindex(&current_thread);
   1723   1.1  christos 	redepth(&current_thread);
   1724   1.1  christos 	depth = current_thread.t_head->m_depth;
   1725   1.5  christos 	for (mp = first_message(current_thread.t_head); mp; mp = next_message(mp)) {
   1726   1.9  christos 		if (mp->m_depth > depth) {
   1727   1.5  christos 			mp->m_flag &= ~(MPRESERVE | MSAVED | MBOX);
   1728   1.5  christos 			mp->m_flag |= MDELETED | MTOUCH;
   1729   1.1  christos 			touch(mp);
   1730   1.1  christos 		}
   1731   1.5  christos 	}
   1732   1.5  christos 	dot = thread_top(dot);	/* do this irrespective of the oldstate */
   1733   1.1  christos 	restore_state(oldstate);
   1734   1.5  christos /*	thread_announce(v); */
   1735   1.1  christos 	return 0;
   1736   1.1  christos }
   1737   1.1  christos 
   1738   1.1  christos #endif /* THREAD_SUPPORT */
   1739