sbin/rcorder/rcorder.c

1.5      mrg /*	$NetBSD: rcorder.c,v 1.5 2000/07/17 14:16:22 mrg Exp $	*/
1.1      mrg
1.1      mrg /*
1.1      mrg  * Copyright (c) 1998, 1999 Matthew R. Green
1.1      mrg  * All rights reserved.
1.1      mrg  * Copyright (c) 1998
1.1      mrg  * 	Perry E. Metzger.  All rights reserved.
1.1      mrg  *
1.1      mrg  * Redistribution and use in source and binary forms, with or without
1.1      mrg  * modification, are permitted provided that the following conditions
1.1      mrg  * are met:
1.1      mrg  * 1. Redistributions of source code must retain the above copyright
1.1      mrg  *    notice, this list of conditions and the following disclaimer.
1.1      mrg  * 2. Redistributions in binary form must reproduce the above copyright
1.1      mrg  *    notice, this list of conditions and the following disclaimer in the
1.1      mrg  *    documentation and/or other materials provided with the distribution.
1.1      mrg  * 3. All advertising materials mentioning features or use of this software
1.1      mrg  *    must display the following acknowledgement:
1.1      mrg  *	This product includes software developed for the NetBSD Project
1.1      mrg  *	by Perry E. Metzger.
1.1      mrg  * 4. The name of the author may not be used to endorse or promote products
1.1      mrg  *    derived from this software without specific prior written permission.
1.1      mrg  *
1.1      mrg  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1      mrg  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1      mrg  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1      mrg  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1      mrg  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1      mrg  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1      mrg  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1      mrg  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1      mrg  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1      mrg  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1      mrg  */
1.1      mrg
1.1      mrg #include <sys/types.h>
1.3    enami #include <sys/stat.h>
1.1      mrg
1.1      mrg #include <err.h>
1.1      mrg #include <stdio.h>
1.1      mrg #include <stdlib.h>
1.1      mrg #include <string.h>
1.1      mrg #include <unistd.h>
1.1      mrg #include <util.h>
1.1      mrg
1.1      mrg #include "ealloc.h"
1.1      mrg #include "sprite.h"
1.1      mrg #include "hash.h"
1.1      mrg
1.1      mrg #ifdef DEBUG
1.1      mrg int debug = 0;
1.1      mrg # define	DPRINTF(args) if (debug) { fflush(stdout); fprintf args; }
1.1      mrg #else
1.1      mrg # define	DPRINTF(args)
1.1      mrg #endif
1.1      mrg
1.1      mrg #define REQUIRE_STR	"# REQUIRE:"
1.1      mrg #define REQUIRE_LEN	(sizeof(REQUIRE_STR) - 1)
1.1      mrg #define REQUIRES_STR	"# REQUIRES:"
1.1      mrg #define REQUIRES_LEN	(sizeof(REQUIRES_STR) - 1)
1.1      mrg #define PROVIDE_STR	"# PROVIDE:"
1.1      mrg #define PROVIDE_LEN	(sizeof(PROVIDE_STR) - 1)
1.1      mrg #define PROVIDES_STR	"# PROVIDES:"
1.1      mrg #define PROVIDES_LEN	(sizeof(PROVIDES_STR) - 1)
1.1      mrg #define BEFORE_STR	"# BEFORE:"
1.1      mrg #define BEFORE_LEN	(sizeof(BEFORE_STR) - 1)
1.5      mrg #define KEYWORD_STR	"# KEYWORD:"
1.5      mrg #define KEYWORD_LEN	(sizeof(KEYWORD_STR) - 1)
1.5      mrg #define KEYWORDS_STR	"# KEYWORDS:"
1.5      mrg #define KEYWORDS_LEN	(sizeof(KEYWORDS_STR) - 1)
1.1      mrg
1.1      mrg int exit_code;
1.1      mrg int file_count;
1.1      mrg char **file_list;
1.1      mrg
1.1      mrg typedef int bool;
1.1      mrg #define TRUE 1
1.1      mrg #define FALSE 0
1.1      mrg typedef bool flag;
1.1      mrg #define SET TRUE
1.1      mrg #define RESET FALSE
1.1      mrg
1.1      mrg Hash_Table provide_hash_s, *provide_hash;
1.1      mrg
1.1      mrg typedef struct provnode provnode;
1.1      mrg typedef struct filenode filenode;
1.1      mrg typedef struct f_provnode f_provnode;
1.1      mrg typedef struct f_reqnode f_reqnode;
1.5      mrg typedef struct strnodelist strnodelist;
1.1      mrg
1.1      mrg struct provnode {
1.1      mrg 	flag		head;
1.1      mrg 	flag		in_progress;
1.1      mrg 	filenode	*fnode;
1.1      mrg 	provnode	*next, *last;
1.1      mrg };
1.1      mrg
1.1      mrg struct f_provnode {
1.1      mrg 	provnode	*pnode;
1.1      mrg 	f_provnode	*next;
1.1      mrg };
1.1      mrg
1.1      mrg struct f_reqnode {
1.1      mrg 	Hash_Entry	*entry;
1.1      mrg 	f_reqnode	*next;
1.1      mrg };
1.1      mrg
1.5      mrg struct strnodelist {
1.5      mrg 	filenode	*node;
1.5      mrg 	char		*s;
1.5      mrg 	strnodelist	*next;
1.5      mrg };
1.5      mrg
1.1      mrg struct filenode {
1.1      mrg 	char		*filename;
1.1      mrg 	flag		in_progress;
1.1      mrg 	filenode	*next, *last;
1.1      mrg 	f_reqnode	*req_list;
1.1      mrg 	f_provnode	*prov_list;
1.5      mrg 	strnodelist	*keyword_list;
1.1      mrg };
1.1      mrg
1.5      mrg filenode fn_head_s, *fn_head;
1.1      mrg
1.5      mrg strnodelist *bl_list;
1.5      mrg strnodelist *keep_list;
1.5      mrg strnodelist *skip_list;
1.1      mrg
1.1      mrg void do_file __P((filenode *fnode));
1.5      mrg void strnode_add __P((strnodelist **, char *, filenode *));
1.5      mrg int skip_ok __P((filenode *fnode));
1.5      mrg int keep_ok __P((filenode *fnode));
1.1      mrg void satisfy_req __P((f_reqnode *rnode, char *filename));
1.1      mrg void crunch_file __P((char *));
1.1      mrg void parse_require __P((filenode *, char *));
1.1      mrg void parse_provide __P((filenode *, char *));
1.1      mrg void parse_before __P((filenode *, char *));
1.5      mrg void parse_keywords __P((filenode *, char *));
1.1      mrg filenode *filenode_new __P((char *));
1.1      mrg void add_require __P((filenode *, char *));
1.1      mrg void add_provide __P((filenode *, char *));
1.1      mrg void add_before __P((filenode *, char *));
1.5      mrg void add_keyword __P((filenode *, char *));
1.1      mrg void insert_before __P((void));
1.1      mrg Hash_Entry *make_fake_provision __P((filenode *));
1.1      mrg void crunch_all_files __P((void));
1.1      mrg void initialize __P((void));
1.1      mrg void generate_ordering __P((void));
1.1      mrg int main __P((int, char *[]));
1.1      mrg
1.1      mrg int
1.1      mrg main(argc, argv)
1.1      mrg 	int argc;
1.1      mrg 	char *argv[];
1.1      mrg {
1.1      mrg 	int ch;
1.1      mrg
1.5      mrg 	while ((ch = getopt(argc, argv, "dk:s:")) != -1)
1.1      mrg 		switch (ch) {
1.1      mrg 		case 'd':
1.1      mrg #ifdef DEBUG
1.1      mrg 			debug = 1;
1.1      mrg #else
1.1      mrg 			warnx("debugging not compiled in, -d ignored");
1.1      mrg #endif
1.1      mrg 			break;
1.5      mrg 		case 'k':
1.5      mrg 			strnode_add(&keep_list, optarg, 0);
1.5      mrg 			break;
1.5      mrg 		case 's':
1.5      mrg 			strnode_add(&skip_list, optarg, 0);
1.5      mrg 			break;
1.1      mrg 		default:
1.1      mrg 			/* XXX should crunch it? */
1.1      mrg 			break;
1.1      mrg 		}
1.1      mrg 	argc -= optind;
1.1      mrg 	argv += optind;
1.1      mrg
1.1      mrg 	file_count = argc;
1.1      mrg 	file_list = argv;
1.1      mrg
1.1      mrg 	DPRINTF((stderr, "parse_args\n"));
1.1      mrg 	initialize();
1.1      mrg 	DPRINTF((stderr, "initialize\n"));
1.1      mrg 	crunch_all_files();
1.1      mrg 	DPRINTF((stderr, "crunch_all_files\n"));
1.1      mrg 	generate_ordering();
1.1      mrg 	DPRINTF((stderr, "generate_ordering\n"));
1.1      mrg
1.1      mrg 	exit(exit_code);
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * initialise various variables.
1.1      mrg  */
1.1      mrg void
1.1      mrg initialize()
1.1      mrg {
1.1      mrg
1.1      mrg 	fn_head = &fn_head_s;
1.1      mrg
1.1      mrg 	provide_hash = &provide_hash_s;
1.1      mrg 	Hash_InitTable(provide_hash, file_count);
1.1      mrg }
1.1      mrg
1.5      mrg /* generic function to insert a new strnodelist element */
1.5      mrg void
1.5      mrg strnode_add(listp, s, fnode)
1.5      mrg 	strnodelist **listp;
1.5      mrg 	char *s;
1.5      mrg 	filenode *fnode;
1.5      mrg {
1.5      mrg 	strnodelist *ent;
1.5      mrg
1.5      mrg 	ent = emalloc(sizeof *ent);
1.5      mrg 	ent->node = fnode;
1.5      mrg 	ent->s = s;
1.5      mrg 	ent->next = *listp;
1.5      mrg 	*listp = ent;
1.5      mrg }
1.5      mrg
1.1      mrg /*
1.1      mrg  * below are the functions that deal with creating the lists
1.1      mrg  * from the filename's given and the dependancies and provisions
1.1      mrg  * in each of these files.  no ordering or checking is done here.
1.1      mrg  */
1.1      mrg
1.1      mrg /*
1.1      mrg  * we have a new filename, create a new filenode structure.
1.1      mrg  * fill in the bits, and put it in the filenode linked list
1.1      mrg  */
1.1      mrg filenode *
1.1      mrg filenode_new(filename)
1.1      mrg 	char *filename;
1.1      mrg {
1.1      mrg 	filenode *temp;
1.1      mrg
1.1      mrg 	temp = emalloc(sizeof(*temp));
1.1      mrg 	memset(temp, 0, sizeof(*temp));
1.1      mrg 	temp->filename = estrdup(filename);
1.1      mrg 	temp->req_list = NULL;
1.1      mrg 	temp->prov_list = NULL;
1.5      mrg 	temp->keyword_list = NULL;
1.1      mrg 	temp->in_progress = RESET;
1.1      mrg 	/*
1.1      mrg 	 * link the filenode into the list of filenodes.
1.1      mrg 	 * note that the double linking means we can delete a
1.1      mrg 	 * filenode without searching for where it belongs.
1.1      mrg 	 */
1.1      mrg 	temp->next = fn_head->next;
1.1      mrg 	if (temp->next != NULL)
1.1      mrg 		temp->next->last = temp;
1.1      mrg 	temp->last = fn_head;
1.1      mrg 	fn_head->next = temp;
1.1      mrg 	return (temp);
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.5      mrg  * add a requirement to a filenode.
1.1      mrg  */
1.1      mrg void
1.1      mrg add_require(fnode, s)
1.1      mrg 	filenode *fnode;
1.1      mrg 	char *s;
1.1      mrg {
1.1      mrg 	Hash_Entry *entry;
1.1      mrg 	f_reqnode *rnode;
1.1      mrg 	int new;
1.1      mrg
1.1      mrg 	entry = Hash_CreateEntry(provide_hash, s, &new);
1.1      mrg 	if (new)
1.1      mrg 		Hash_SetValue(entry, NULL);
1.1      mrg 	rnode = emalloc(sizeof(*rnode));
1.1      mrg 	rnode->entry = entry;
1.1      mrg 	rnode->next = fnode->req_list;
1.1      mrg 	fnode->req_list = rnode;
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * add a provision to a filenode.  if this provision doesn't
1.1      mrg  * have a head node, create one here.
1.1      mrg  */
1.1      mrg void
1.1      mrg add_provide(fnode, s)
1.1      mrg 	filenode *fnode;
1.1      mrg 	char *s;
1.1      mrg {
1.1      mrg 	Hash_Entry *entry;
1.1      mrg 	f_provnode *f_pnode;
1.1      mrg 	provnode *pnode, *head;
1.1      mrg 	int new;
1.1      mrg
1.1      mrg 	entry = Hash_CreateEntry(provide_hash, s, &new);
1.1      mrg 	head = Hash_GetValue(entry);
1.1      mrg
1.1      mrg 	/* create a head node if necessary. */
1.1      mrg 	if (head == NULL) {
1.1      mrg 		head = emalloc(sizeof(*head));
1.1      mrg 		head->head = SET;
1.1      mrg 		head->in_progress = RESET;
1.1      mrg 		head->fnode = NULL;
1.1      mrg 		head->last = head->next = NULL;
1.1      mrg 		Hash_SetValue(entry, head);
1.2  thorpej 	}
1.2  thorpej #if 0
1.2  thorpej 	/*
1.2  thorpej 	 * Don't warn about this.  We want to be able to support
1.2  thorpej 	 * scripts that do two complex things:
1.2  thorpej 	 *
1.2  thorpej 	 *	- Two independent scripts which both provide the
1.2  thorpej 	 *	  same thing.  Both scripts must be executed in
1.2  thorpej 	 *	  any order to meet the barrier.  An example:
1.2  thorpej 	 *
1.2  thorpej 	 *		Script 1:
1.2  thorpej 	 *
1.2  thorpej 	 *			PROVIDE: mail
1.2  thorpej 	 *			REQUIRE: LOGIN
1.2  thorpej 	 *
1.2  thorpej 	 *		Script 2:
1.2  thorpej 	 *
1.2  thorpej 	 *			PROVIDE: mail
1.2  thorpej 	 *			REQUIRE: LOGIN
1.2  thorpej 	 *
1.2  thorpej 	 * 	- Two interdependent scripts which both provide the
1.2  thorpej 	 *	  same thing.  Both scripts must be executed in
1.2  thorpej 	 *	  graph order to meet the barrier.  An example:
1.2  thorpej 	 *
1.2  thorpej 	 *		Script 1:
1.2  thorpej 	 *
1.2  thorpej 	 *			PROVIDE: nameservice dnscache
1.2  thorpej 	 *			REQUIRE: SERVERS
1.2  thorpej 	 *
1.2  thorpej 	 *		Script 2:
1.2  thorpej 	 *
1.2  thorpej 	 *			PROVIDE: nameservice nscd
1.2  thorpej 	 *			REQUIRE: dnscache
1.2  thorpej 	 */
1.2  thorpej 	else if (new == 0) {
1.1      mrg 		warnx("file `%s' provides `%s'.", fnode->filename, s);
1.2  thorpej 		warnx("\tpreviously seen in `%s'.",
1.2  thorpej 		    head->next->fnode->filename);
1.1      mrg 	}
1.2  thorpej #endif
1.1      mrg
1.1      mrg 	pnode = emalloc(sizeof(*pnode));
1.1      mrg 	pnode->head = RESET;
1.1      mrg 	pnode->in_progress = RESET;
1.1      mrg 	pnode->fnode = fnode;
1.1      mrg 	pnode->next = head->next;
1.1      mrg 	pnode->last = head;
1.1      mrg 	head->next = pnode;
1.1      mrg 	if (pnode->next != NULL)
1.1      mrg 		pnode->next->last = pnode;
1.1      mrg
1.1      mrg 	f_pnode = emalloc(sizeof(*f_pnode));
1.1      mrg 	f_pnode->pnode = pnode;
1.1      mrg 	f_pnode->next = fnode->prov_list;
1.1      mrg 	fnode->prov_list = f_pnode;
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * put the BEFORE: lines to a list and handle them later.
1.1      mrg  */
1.1      mrg void
1.1      mrg add_before(fnode, s)
1.1      mrg 	filenode *fnode;
1.1      mrg 	char *s;
1.1      mrg {
1.5      mrg 	strnodelist *bf_ent;
1.1      mrg
1.1      mrg 	bf_ent = emalloc(sizeof *bf_ent);
1.1      mrg 	bf_ent->node = fnode;
1.1      mrg 	bf_ent->s = s;
1.1      mrg 	bf_ent->next = bl_list;
1.1      mrg 	bl_list = bf_ent;
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.5      mrg  * add a key to a filenode.
1.5      mrg  */
1.5      mrg void
1.5      mrg add_keyword(fnode, s)
1.5      mrg 	filenode *fnode;
1.5      mrg 	char *s;
1.5      mrg {
1.5      mrg
1.5      mrg 	strnode_add(&fnode->keyword_list, s, fnode);
1.5      mrg }
1.5      mrg
1.5      mrg /*
1.1      mrg  * loop over the rest of a REQUIRE line, giving each word to
1.1      mrg  * add_require() to do the real work.
1.1      mrg  */
1.1      mrg void
1.1      mrg parse_require(node, buffer)
1.1      mrg 	filenode *node;
1.1      mrg 	char *buffer;
1.1      mrg {
1.1      mrg 	char *s;
1.1      mrg
1.1      mrg 	while ((s = strsep(&buffer, " \t\n")) != NULL)
1.1      mrg 		if (*s != '\0')
1.1      mrg 			add_require(node, s);
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * loop over the rest of a PROVIDE line, giving each word to
1.1      mrg  * add_provide() to do the real work.
1.1      mrg  */
1.1      mrg void
1.1      mrg parse_provide(node, buffer)
1.1      mrg 	filenode *node;
1.1      mrg 	char *buffer;
1.1      mrg {
1.1      mrg 	char *s;
1.1      mrg
1.1      mrg 	while ((s = strsep(&buffer, " \t\n")) != NULL)
1.1      mrg 		if (*s != '\0')
1.1      mrg 			add_provide(node, s);
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * loop over the rest of a BEFORE line, giving each word to
1.1      mrg  * add_before() to do the real work.
1.1      mrg  */
1.1      mrg void
1.1      mrg parse_before(node, buffer)
1.1      mrg 	filenode *node;
1.1      mrg 	char *buffer;
1.1      mrg {
1.1      mrg 	char *s;
1.1      mrg
1.1      mrg 	while ((s = strsep(&buffer, " \t\n")) != NULL)
1.1      mrg 		if (*s != '\0')
1.1      mrg 			add_before(node, s);
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.5      mrg  * loop over the rest of a KEYWORD line, giving each word to
1.5      mrg  * add_keyword() to do the real work.
1.5      mrg  */
1.5      mrg void
1.5      mrg parse_keywords(node, buffer)
1.5      mrg 	filenode *node;
1.5      mrg 	char *buffer;
1.5      mrg {
1.5      mrg 	char *s;
1.5      mrg
1.5      mrg 	while ((s = strsep(&buffer, " \t\n")) != NULL)
1.5      mrg 		if (*s != '\0')
1.5      mrg 			add_keyword(node, s);
1.5      mrg }
1.5      mrg
1.5      mrg /*
1.1      mrg  * given a file name, create a filenode for it, read in lines looking
1.1      mrg  * for provision and requirement lines, building the graphs as needed.
1.1      mrg  */
1.1      mrg void
1.1      mrg crunch_file(filename)
1.1      mrg 	char *filename;
1.1      mrg {
1.1      mrg 	FILE *fp;
1.1      mrg 	char *buf;
1.5      mrg 	int require_flag, provide_flag, before_flag, keywords_flag,
1.5      mrg 	    directive_flag;
1.1      mrg 	filenode *node;
1.1      mrg 	char delims[3] = { '\\', '\\', '\0' };
1.3    enami 	struct stat st;
1.1      mrg
1.1      mrg 	directive_flag = 0;
1.1      mrg
1.1      mrg 	if ((fp = fopen(filename, "r")) == NULL) {
1.1      mrg 		warn("could not open %s", filename);
1.3    enami 		return;
1.3    enami 	}
1.3    enami
1.3    enami 	if (fstat(fileno(fp), &st) == -1) {
1.3    enami 		warn("could not stat %s", filename);
1.4    enami 		fclose(fp);
1.3    enami 		return;
1.3    enami 	}
1.3    enami
1.3    enami 	if (!S_ISREG(st.st_mode)) {
1.3    enami 		warnx("%s is not a file", filename);
1.4    enami 		fclose(fp);
1.1      mrg 		return;
1.1      mrg 	}
1.1      mrg
1.1      mrg 	node = filenode_new(filename);
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * we don't care about length, line number, don't want # for comments,
1.1      mrg 	 * and have no flags.
1.1      mrg 	 */
1.1      mrg 	while ((buf = fparseln(fp, NULL, NULL, delims, 0))) {
1.5      mrg 		require_flag = provide_flag = before_flag = keywords_flag = 0;
1.1      mrg 		if (strncmp(REQUIRE_STR, buf, REQUIRE_LEN) == 0)
1.1      mrg 			require_flag = REQUIRE_LEN;
1.1      mrg 		else if (strncmp(REQUIRES_STR, buf, REQUIRES_LEN) == 0)
1.1      mrg 			require_flag = REQUIRES_LEN;
1.1      mrg 		else if (strncmp(PROVIDE_STR, buf, PROVIDE_LEN) == 0)
1.1      mrg 			provide_flag = PROVIDE_LEN;
1.1      mrg 		else if (strncmp(PROVIDES_STR, buf, PROVIDES_LEN) == 0)
1.1      mrg 			provide_flag = PROVIDES_LEN;
1.1      mrg 		else if (strncmp(BEFORE_STR, buf, BEFORE_LEN) == 0)
1.1      mrg 			before_flag = BEFORE_LEN;
1.5      mrg 		else if (strncmp(KEYWORD_STR, buf, KEYWORD_LEN) == 0)
1.5      mrg 			keywords_flag = KEYWORD_LEN;
1.5      mrg 		else if (strncmp(KEYWORDS_STR, buf, KEYWORDS_LEN) == 0)
1.5      mrg 			keywords_flag = KEYWORDS_LEN;
1.1      mrg
1.1      mrg 		if (require_flag)
1.1      mrg 			parse_require(node, buf + require_flag);
1.1      mrg
1.1      mrg 		if (provide_flag)
1.1      mrg 			parse_provide(node, buf + provide_flag);
1.1      mrg
1.1      mrg 		if (before_flag)
1.1      mrg 			parse_before(node, buf + before_flag);
1.5      mrg
1.5      mrg 		if (keywords_flag)
1.5      mrg 			parse_keywords(node, buf + keywords_flag);
1.1      mrg 	}
1.1      mrg 	fclose(fp);
1.1      mrg }
1.1      mrg
1.1      mrg Hash_Entry *
1.1      mrg make_fake_provision(node)
1.1      mrg 	filenode *node;
1.1      mrg {
1.1      mrg 	Hash_Entry *entry;
1.1      mrg 	f_provnode *f_pnode;
1.1      mrg 	provnode *head, *pnode;
1.1      mrg 	static	int i = 0;
1.1      mrg 	int	new;
1.1      mrg 	char buffer[30];
1.1      mrg
1.1      mrg 	do {
1.1      mrg 		snprintf(buffer, sizeof buffer, "fake_prov_%08d", i++);
1.1      mrg 		entry = Hash_CreateEntry(provide_hash, buffer, &new);
1.1      mrg 	} while (new == 0);
1.1      mrg 	head = emalloc(sizeof(*head));
1.1      mrg 	head->head = SET;
1.1      mrg 	head->in_progress = RESET;
1.1      mrg 	head->fnode = NULL;
1.1      mrg 	head->last = head->next = NULL;
1.1      mrg 	Hash_SetValue(entry, head);
1.1      mrg
1.1      mrg 	pnode = emalloc(sizeof(*pnode));
1.1      mrg 	pnode->head = RESET;
1.1      mrg 	pnode->in_progress = RESET;
1.1      mrg 	pnode->fnode = node;
1.1      mrg 	pnode->next = head->next;
1.1      mrg 	pnode->last = head;
1.1      mrg 	head->next = pnode;
1.1      mrg 	if (pnode->next != NULL)
1.1      mrg 		pnode->next->last = pnode;
1.1      mrg
1.1      mrg 	f_pnode = emalloc(sizeof(*f_pnode));
1.1      mrg 	f_pnode->pnode = pnode;
1.1      mrg 	f_pnode->next = node->prov_list;
1.1      mrg 	node->prov_list = f_pnode;
1.1      mrg
1.1      mrg 	return (entry);
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * go through the BEFORE list, inserting requirements into the graph(s)
1.1      mrg  * as required.  in the before list, for each entry B, we have a file F
1.1      mrg  * and a string S.  we create a "fake" provision (P) that F provides.
1.1      mrg  * for each entry in the provision list for S, add a requirement to
1.1      mrg  * that provisions filenode for P.
1.1      mrg  */
1.1      mrg void
1.1      mrg insert_before()
1.1      mrg {
1.1      mrg 	Hash_Entry *entry, *fake_prov_entry;
1.1      mrg 	provnode *pnode;
1.1      mrg 	f_reqnode *rnode;
1.5      mrg 	strnodelist *bl;
1.1      mrg 	int new;
1.1      mrg
1.1      mrg 	while (bl_list != NULL) {
1.1      mrg 		bl = bl_list->next;
1.1      mrg
1.1      mrg 		fake_prov_entry = make_fake_provision(bl_list->node);
1.1      mrg
1.1      mrg 		entry = Hash_CreateEntry(provide_hash, bl_list->s, &new);
1.1      mrg 		if (new == 1)
1.1      mrg 			warnx("file `%s' is before unknown provision `%s'", bl_list->node->filename, bl_list->s);
1.1      mrg
1.1      mrg 		for (pnode = Hash_GetValue(entry); pnode; pnode = pnode->next) {
1.1      mrg 			if (pnode->head)
1.1      mrg 				continue;
1.1      mrg
1.1      mrg 			rnode = emalloc(sizeof(*rnode));
1.1      mrg 			rnode->entry = fake_prov_entry;
1.1      mrg 			rnode->next = pnode->fnode->req_list;
1.1      mrg 			pnode->fnode->req_list = rnode;
1.1      mrg 		}
1.1      mrg
1.1      mrg 		free(bl_list);
1.1      mrg 		bl_list = bl;
1.1      mrg 	}
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * loop over all the files calling crunch_file() on them to do the
1.1      mrg  * real work.  after we have built all the nodes, insert the BEFORE:
1.1      mrg  * lines into graph(s).
1.1      mrg  */
1.1      mrg void
1.1      mrg crunch_all_files()
1.1      mrg {
1.1      mrg 	int i;
1.1      mrg
1.1      mrg 	for (i = 0; i < file_count; i++)
1.1      mrg 		crunch_file(file_list[i]);
1.1      mrg 	insert_before();
1.1      mrg }
1.1      mrg
1.1      mrg /*
1.1      mrg  * below are the functions that traverse the graphs we have built
1.1      mrg  * finding out the desired ordering, printing each file in turn.
1.1      mrg  * if missing requirements, or cyclic graphs are detected, a
1.1      mrg  * warning will be issued, and we will continue on..
1.1      mrg  */
1.1      mrg
1.1      mrg /*
1.1      mrg  * given a requirement node (in a filename) we attempt to satisfy it.
1.1      mrg  * we do some sanity checking first, to ensure that we have providers,
1.1      mrg  * aren't already satisfied and aren't already being satisfied (ie,
1.1      mrg  * cyclic).  if we pass all this, we loop over the provision list
1.1      mrg  * calling do_file() (enter recursion) for each filenode in this
1.1      mrg  * provision.
1.1      mrg  */
1.1      mrg void
1.1      mrg satisfy_req(rnode, filename)
1.1      mrg 	f_reqnode *rnode;
1.1      mrg 	char *filename;
1.1      mrg {
1.1      mrg 	Hash_Entry *entry;
1.1      mrg 	provnode *head;
1.1      mrg
1.1      mrg 	entry = rnode->entry;
1.1      mrg 	head = Hash_GetValue(entry);
1.1      mrg
1.1      mrg 	if (head == NULL) {
1.1      mrg 		warnx("requirement `%s' in file `%s' has no providers.",
1.1      mrg 		    Hash_GetKey(entry), filename);
1.1      mrg 		exit_code = 1;
1.1      mrg 		return;
1.1      mrg 	}
1.1      mrg
1.1      mrg 	/* return if the requirement is already satisfied. */
1.1      mrg 	if (head->next == NULL)
1.1      mrg 		return;
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * if list is marked as in progress,
1.1      mrg 	 *	print that there is a circular dependency on it and abort
1.1      mrg 	 */
1.1      mrg 	if (head->in_progress == SET) {
1.1      mrg 		warnx("Circular dependency on provision `%s' in file `%s'.",
1.1      mrg 		    Hash_GetKey(entry), filename);
1.1      mrg 		exit_code = 1;
1.1      mrg 		return;
1.1      mrg 	}
1.1      mrg
1.1      mrg 	head->in_progress = SET;
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * while provision_list is not empty
1.1      mrg 	 *	do_file(first_member_of(provision_list));
1.1      mrg 	 */
1.1      mrg 	while (head->next != NULL)
1.1      mrg 		do_file(head->next->fnode);
1.1      mrg }
1.1      mrg
1.5      mrg int
1.5      mrg skip_ok(fnode)
1.5      mrg 	filenode *fnode;
1.5      mrg {
1.5      mrg 	strnodelist *s;
1.5      mrg 	strnodelist *k;
1.5      mrg
1.5      mrg 	for (s = skip_list; s; s = s->next)
1.5      mrg 		for (k = fnode->keyword_list; k; k = k->next)
1.5      mrg 			if (strcmp(k->s, s->s) == 0)
1.5      mrg 				return (0);
1.5      mrg
1.5      mrg 	return (1);
1.5      mrg }
1.5      mrg
1.5      mrg int
1.5      mrg keep_ok(fnode)
1.5      mrg 	filenode *fnode;
1.5      mrg {
1.5      mrg 	strnodelist *s;
1.5      mrg 	strnodelist *k;
1.5      mrg
1.5      mrg 	for (s = keep_list; s; s = s->next)
1.5      mrg 		for (k = fnode->keyword_list; k; k = k->next)
1.5      mrg 			if (strcmp(k->s, s->s) == 0)
1.5      mrg 				return (1);
1.5      mrg
1.5      mrg 	/* an empty keep_list means every one */
1.5      mrg 	return (!keep_list);
1.5      mrg }
1.5      mrg
1.1      mrg /*
1.1      mrg  * given a filenode, we ensure we are not a cyclic graph.  if this
1.1      mrg  * is ok, we loop over the filenodes requirements, calling satisfy_req()
1.1      mrg  * for each of them.. once we have done this, remove this filenode
1.1      mrg  * from each provision table, as we are now done.
1.1      mrg  */
1.1      mrg void
1.1      mrg do_file(fnode)
1.1      mrg 	filenode *fnode;
1.1      mrg {
1.1      mrg 	f_reqnode *r, *r_tmp;
1.1      mrg 	f_provnode *p, *p_tmp;
1.1      mrg 	provnode *pnode;
1.1      mrg 	int was_set;
1.1      mrg
1.1      mrg 	DPRINTF((stderr, "do_file on %s.\n", fnode->filename));
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * if fnode is marked as in progress,
1.1      mrg 	 *	 print that fnode; is circularly depended upon and abort.
1.1      mrg 	 */
1.1      mrg 	if (fnode->in_progress == SET) {
1.1      mrg 		warnx("Circular dependency on file `%s'.",
1.1      mrg 			fnode->filename);
1.1      mrg 		was_set = exit_code = 1;
1.1      mrg 	} else
1.1      mrg 		was_set = 0;
1.1      mrg
1.1      mrg 	/* mark fnode */
1.1      mrg 	fnode->in_progress = SET;
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * for each requirement of fnode -> r
1.1      mrg 	 *	satisfy_req(r, filename)
1.1      mrg 	 */
1.1      mrg 	r = fnode->req_list;
1.1      mrg 	while (r != NULL) {
1.1      mrg 		r_tmp = r;
1.1      mrg 		satisfy_req(r, fnode->filename);
1.1      mrg 		r = r->next;
1.1      mrg 		free(r_tmp);
1.1      mrg 	}
1.1      mrg 	fnode->req_list = NULL;
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * for each provision of fnode -> p
1.1      mrg 	 *	remove fnode from provision list for p in hash table
1.1      mrg 	 */
1.1      mrg 	p = fnode->prov_list;
1.1      mrg 	while (p != NULL) {
1.1      mrg 		p_tmp = p;
1.1      mrg 		pnode = p->pnode;
1.1      mrg 		if (pnode->next != NULL) {
1.1      mrg 			pnode->next->last = pnode->last;
1.1      mrg 		}
1.1      mrg 		if (pnode->last != NULL) {
1.1      mrg 			pnode->last->next = pnode->next;
1.1      mrg 		}
1.1      mrg 		free(pnode);
1.1      mrg 		p = p->next;
1.1      mrg 		free(p_tmp);
1.1      mrg 	}
1.1      mrg 	fnode->prov_list = NULL;
1.1      mrg
1.1      mrg 	/* do_it(fnode) */
1.1      mrg 	DPRINTF((stderr, "next do: "));
1.1      mrg
1.1      mrg 	/* if we were already in progress, don't print again */
1.5      mrg 	if (was_set == 0 && skip_ok(fnode) && keep_ok(fnode))
1.1      mrg 		printf("%s\n", fnode->filename);
1.1      mrg
1.1      mrg 	if (fnode->next != NULL) {
1.1      mrg 		fnode->next->last = fnode->last;
1.1      mrg 	}
1.1      mrg 	if (fnode->last != NULL) {
1.1      mrg 		fnode->last->next = fnode->next;
1.1      mrg 	}
1.1      mrg
1.1      mrg 	DPRINTF((stderr, "nuking %s\n", fnode->filename));
1.1      mrg 	free(fnode->filename);
1.1      mrg 	free(fnode);
1.1      mrg }
1.1      mrg
1.1      mrg void
1.1      mrg generate_ordering()
1.1      mrg {
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * while there remain undone files{f},
1.1      mrg 	 *	pick an arbitrary f, and do_file(f)
1.1      mrg 	 * Note that the first file in the file list is perfectly
1.1      mrg 	 * arbitrary, and easy to find, so we use that.
1.1      mrg 	 */
1.1      mrg
1.1      mrg 	/*
1.1      mrg 	 * N.B.: the file nodes "self delete" after they execute, so
1.1      mrg 	 * after each iteration of the loop, the head will be pointing
1.1      mrg 	 * to something totally different. The loop ends up being
1.1      mrg 	 * executed only once for every strongly connected set of
1.1      mrg 	 * nodes.
1.1      mrg 	 */
1.1      mrg 	while (fn_head->next != NULL) {
1.1      mrg 		DPRINTF((stderr, "generate on %s\n", fn_head->next->filename));
1.1      mrg 		do_file(fn_head->next);
1.1      mrg 	}
1.1      mrg }