OpenSolaris_b135/cmd/bart/create.c
/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License (the "License").
* You may not use this file except in compliance with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2009 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#include <signal.h>
#include <unistd.h>
#include <sys/acl.h>
#include <sys/statvfs.h>
#include <sys/wait.h>
#include "bart.h"
#include <aclutils.h>
static int sanitize_reloc_root(char *root, size_t bufsize);
static int create_manifest_filelist(char **argv, char *reloc_root);
static int create_manifest_rule(char *reloc_root, FILE *rule_fp);
static void output_manifest(void);
static int eval_file(const char *fname, const struct stat64 *statb);
static char *sanitized_fname(const char *, boolean_t);
static char *get_acl_string(const char *fname, const struct stat64 *statb,
int *err_code);
static int generate_hash(int fdin, char *hash_str);
static int read_filelist(char *reloc_root, char **argv, char *buf,
size_t bufsize);
static int walker(const char *name, const struct stat64 *sp,
int type, struct FTW *ftwx);
/*
* The following globals are necessary due to the "walker" function
* provided by nftw(). Since there is no way to pass them through to the
* walker function, they must be global.
*/
static int compute_chksum = 1, eval_err = 0;
static struct rule *subtree_root;
static char reloc_root[PATH_MAX];
static struct statvfs64 parent_vfs;
int
bart_create(int argc, char **argv)
{
boolean_t filelist_input;
int ret, c, output_pipe[2];
FILE *rules_fd = NULL;
pid_t pid;
filelist_input = B_FALSE;
reloc_root[0] = '\0';
while ((c = getopt(argc, argv, "Inr:R:")) != EOF) {
switch (c) {
case 'I':
if (rules_fd != NULL) {
(void) fprintf(stderr, "%s", INPUT_ERR);
usage();
}
filelist_input = B_TRUE;
break;
case 'n':
compute_chksum = 0;
break;
case 'r':
if (strcmp(optarg, "-") == 0)
rules_fd = stdin;
else
rules_fd = fopen(optarg, "r");
if (rules_fd == NULL) {
perror(optarg);
usage();
}
break;
case 'R':
(void) strlcpy(reloc_root, optarg, sizeof (reloc_root));
ret = sanitize_reloc_root(reloc_root,
sizeof (reloc_root));
if (ret == 0)
usage();
break;
case '?':
default :
usage();
}
}
argv += optind;
if (pipe(output_pipe) < 0) {
perror("");
exit(FATAL_EXIT);
}
pid = fork();
if (pid < 0) {
perror(NULL);
exit(FATAL_EXIT);
}
/*
* Break the creation of a manifest into two parts: the parent process
* generated the data whereas the child process sorts the data.
*
* The processes communicate through the pipe.
*/
if (pid > 0) {
/*
* Redirect the stdout of this process so it goes into
* output_pipe[0]. The output of this process will be read
* by the child, which will sort the output.
*/
if (dup2(output_pipe[0], STDOUT_FILENO) != STDOUT_FILENO) {
perror(NULL);
exit(FATAL_EXIT);
}
(void) close(output_pipe[0]);
(void) close(output_pipe[1]);
if (filelist_input == B_TRUE) {
ret = create_manifest_filelist(argv, reloc_root);
} else {
ret = create_manifest_rule(reloc_root, rules_fd);
}
/* Close stdout so the sort in the child proc will complete */
(void) fclose(stdout);
} else {
/*
* Redirect the stdin of this process so its read in from
* the pipe, which is the parent process in this case.
*/
if (dup2(output_pipe[1], STDIN_FILENO) != STDIN_FILENO) {
perror(NULL);
exit(FATAL_EXIT);
}
(void) close(output_pipe[0]);
output_manifest();
}
/* Wait for the child proc (the sort) to complete */
(void) wait(0);
return (ret);
}
/*
* Handle the -R option and sets 'root' to be the absolute path of the
* relocatable root. This is useful when the user specifies '-R ../../foo'.
*
* Return code is whether or not the location spec'd by the -R flag is a
* directory or not.
*/
static int
sanitize_reloc_root(char *root, size_t bufsize)
{
char pwd[PATH_MAX];
/*
* First, save the current directory and go to the location
* specified with the -R option.
*/
(void) getcwd(pwd, sizeof (pwd));
if (chdir(root) < 0) {
/* Failed to change directory, something is wrong.... */
perror(root);
return (0);
}
/*
* Save the absolute path of the relocatable root directory.
*/
(void) getcwd(root, bufsize);
/*
* Now, go back to where we started, necessary for picking up a rules
* file.
*/
if (chdir(pwd) < 0) {
/* Failed to change directory, something is wrong.... */
perror(root);
return (0);
}
/*
* Make sure the path returned does not have a trailing /. This
* can only happen when the entire pathname is "/".
*/
if (strcmp(root, "/") == 0)
root[0] = '\0';
/*
* Since the earlier chdir() succeeded, return success.
*/
return (1);
}
/*
* This is the worker bee which creates the manifest based upon the command
* line options supplied by the user.
*
* NOTE: create_manifest() eventually outputs data to a pipe, which is read in
* by the child process. The child process is running output_manifest(), which
* is responsible for generating sorted output.
*/
static int
create_manifest_rule(char *reloc_root, FILE *rule_fp)
{
struct rule *root;
int ret_status = EXIT;
uint_t flags;
if (compute_chksum)
flags = ATTR_CONTENTS;
else
flags = 0;
ret_status = read_rules(rule_fp, reloc_root, flags, 1);
/* Loop through every single subtree */
for (root = get_first_subtree(); root != NULL;
root = get_next_subtree(root)) {
/*
* Check to see if this subtree should have contents
* checking turned on or off.
*
* NOTE: The 'compute_chksum' and 'parent_vfs'
* are a necessary hack: the variables are used in
* walker(), both directly and indirectly. Since
* the parameters to walker() are defined by nftw(),
* the globals are really a backdoor mechanism.
*/
ret_status = statvfs64(root->subtree, &parent_vfs);
if (ret_status < 0) {
perror(root->subtree);
continue;
}
/*
* Walk the subtree and invoke the callback function
* walker()
*/
subtree_root = root;
(void) nftw64(root->subtree, &walker, 20, FTW_PHYS);
/*
* Ugly but necessary:
*
* walker() must return 0, or the tree walk will stop,
* so warning flags must be set through a global.
*/
if (eval_err == WARNING_EXIT)
ret_status = WARNING_EXIT;
}
return (ret_status);
}
static int
create_manifest_filelist(char **argv, char *reloc_root)
{
int ret_status = EXIT;
char input_fname[PATH_MAX];
while (read_filelist(reloc_root, argv,
input_fname, sizeof (input_fname)) != -1) {
struct stat64 stat_buf;
int ret;
ret = lstat64(input_fname, &stat_buf);
if (ret < 0) {
ret_status = WARNING_EXIT;
perror(input_fname);
} else {
ret = eval_file(input_fname, &stat_buf);
if (ret == WARNING_EXIT)
ret_status = WARNING_EXIT;
}
}
return (ret_status);
}
/*
* output_manifest() the child process. It reads in the output from
* create_manifest() and sorts it.
*/
static void
output_manifest(void)
{
char *env[] = {"LC_CTYPE=C", "LC_COLLATE=C", "LC_NUMERIC=C", NULL};
time_t time_val;
struct tm *tm;
char time_buf[1024];
(void) printf("%s", MANIFEST_VER);
time_val = time((time_t)0);
tm = localtime(&time_val);
(void) strftime(time_buf, sizeof (time_buf), "%A, %B %d, %Y (%T)", tm);
(void) printf("! %s\n", time_buf);
(void) printf("%s", FORMAT_STR);
(void) fflush(stdout);
/*
* Simply run sort and read from the the current stdin, which is really
* the output of create_manifest().
* Also, make sure the output is unique, since a given file may be
* included by several stanzas.
*/
if (execle("/usr/bin/sort", "sort", "-u", NULL, env) < 0) {
perror("");
exit(FATAL_EXIT);
}
/*NOTREACHED*/
}
/*
* Callback function for nftw()
*/
static int
walker(const char *name, const struct stat64 *sp, int type, struct FTW *ftwx)
{
int ret;
struct statvfs64 path_vfs;
boolean_t dir_flag = B_FALSE;
struct rule *rule;
switch (type) {
case FTW_F: /* file */
rule = check_rules(name, 'F');
if (rule != NULL) {
if (rule->attr_list & ATTR_CONTENTS)
compute_chksum = 1;
else
compute_chksum = 0;
}
break;
case FTW_SL: /* symbolic link */
case FTW_DP: /* end of directory */
case FTW_DNR: /* unreadable directory */
case FTW_NS: /* unstatable file */
break;
case FTW_D: /* enter directory */
dir_flag = B_TRUE;
ret = statvfs64(name, &path_vfs);
if (ret < 0)
eval_err = WARNING_EXIT;
break;
default:
(void) fprintf(stderr, INVALID_FILE, name);
eval_err = WARNING_EXIT;
break;
}
/* This is the function which really processes the file */
ret = eval_file(name, sp);
/*
* Since the parameters to walker() are constrained by nftw(),
* need to use a global to reflect a WARNING. Sigh.
*/
if (ret == WARNING_EXIT)
eval_err = WARNING_EXIT;
/*
* This is a case of a directory which crosses into a mounted
* filesystem of a different type, e.g., UFS -> NFS.
* BART should not walk the new filesystem (by specification), so
* set this consolidation-private flag so the rest of the subtree
* under this directory is not waled.
*/
if (dir_flag &&
(strcmp(parent_vfs.f_basetype, path_vfs.f_basetype) != 0))
ftwx->quit = FTW_PRUNE;
return (0);
}
/*
* This file does the per-file evaluation and is run to generate every entry
* in the manifest.
*
* All output is written to a pipe which is read by the child process,
* which is running output_manifest().
*/
static int
eval_file(const char *fname, const struct stat64 *statb)
{
int fd, ret, err_code, i;
char last_field[PATH_MAX], ftype, *acl_str;
char *quoted_name;
err_code = EXIT;
switch (statb->st_mode & S_IFMT) {
/* Regular file */
case S_IFREG: ftype = 'F'; break;
/* Directory */
case S_IFDIR: ftype = 'D'; break;
/* Block Device */
case S_IFBLK: ftype = 'B'; break;
/* Character Device */
case S_IFCHR: ftype = 'C'; break;
/* Named Pipe */
case S_IFIFO: ftype = 'P'; break;
/* Socket */
case S_IFSOCK: ftype = 'S'; break;
/* Door */
case S_IFDOOR: ftype = 'O'; break;
/* Symbolic link */
case S_IFLNK: ftype = 'L'; break;
default: ftype = '-'; break;
}
/* First, make sure this file should be cataloged */
if ((subtree_root != NULL) &&
(exclude_fname(fname, ftype, subtree_root)))
return (err_code);
for (i = 0; i < PATH_MAX; i++)
last_field[i] = '\0';
/*
* Regular files, compute the MD5 checksum and put it into 'last_field'
* UNLESS instructed to ignore the checksums.
*/
if (ftype == 'F') {
if (compute_chksum) {
fd = open(fname, O_RDONLY|O_LARGEFILE);
if (fd < 0) {
err_code = WARNING_EXIT;
perror(fname);
/* default value since the computution failed */
(void) strcpy(last_field, "-");
} else {
if (generate_hash(fd, last_field) != 0) {
err_code = WARNING_EXIT;
(void) fprintf(stderr, CONTENTS_WARN,
fname);
(void) strcpy(last_field, "-");
}
}
(void) close(fd);
}
/* Instructed to ignore checksums, just put in a '-' */
else
(void) strcpy(last_field, "-");
}
/*
* For symbolic links, put the destination of the symbolic link into
* 'last_field'
*/
if (ftype == 'L') {
ret = readlink(fname, last_field, sizeof (last_field));
if (ret < 0) {
err_code = WARNING_EXIT;
perror(fname);
/* default value since the computation failed */
(void) strcpy(last_field, "-");
}
else
(void) strlcpy(last_field,
sanitized_fname(last_field, B_FALSE),
sizeof (last_field));
/*
* Boundary condition: possible for a symlink to point to
* nothing [ ln -s '' link_name ]. For this case, set the
* destination to "\000".
*/
if (strlen(last_field) == 0)
(void) strcpy(last_field, "\\000");
}
acl_str = get_acl_string(fname, statb, &err_code);
/* Sanitize 'fname', so its in the proper format for the manifest */
quoted_name = sanitized_fname(fname, B_TRUE);
/* Start to build the entry.... */
(void) printf("%s %c %d %o %s %x %d %d", quoted_name, ftype,
(int)statb->st_size, (int)statb->st_mode, acl_str,
(int)statb->st_mtime, (int)statb->st_uid, (int)statb->st_gid);
/* Finish it off based upon whether or not it's a device node */
if ((ftype == 'B') || (ftype == 'C'))
(void) printf(" %x\n", (int)statb->st_rdev);
else if (strlen(last_field) > 0)
(void) printf(" %s\n", last_field);
else
(void) printf("\n");
/* free the memory consumed */
free(acl_str);
free(quoted_name);
return (err_code);
}
/*
* When creating a manifest, make sure all '?', tabs, space, newline, '/'
* and '[' are all properly quoted. Convert them to a "\ooo" where the 'ooo'
* represents their octal value. For filesystem objects, as opposed to symlink
* targets, also canonicalize the pathname.
*/
static char *
sanitized_fname(const char *fname, boolean_t canon_path)
{
const char *ip;
unsigned char ch;
char *op, *quoted_name;
/* Initialize everything */
quoted_name = safe_calloc((4 * PATH_MAX) + 1);
ip = fname;
op = quoted_name;
if (canon_path) {
/*
* In the case when a relocatable root was used, the relocatable
* root should *not* be part of the manifest.
*/
ip += strlen(reloc_root);
/*
* In the case when the '-I' option was used, make sure
* the quoted_name starts with a '/'.
*/
if (*ip != '/')
*op++ = '/';
}
/* Now walk through 'fname' and build the quoted string */
while ((ch = *ip++) != 0) {
switch (ch) {
/* Quote the following characters */
case ' ':
case '*':
case '\n':
case '?':
case '[':
case '\\':
case '\t':
op += sprintf(op, "\\%.3o", (unsigned char)ch);
break;
/* Otherwise, simply append them */
default:
*op++ = ch;
break;
}
}
*op = 0;
return (quoted_name);
}
/*
* Function responsible for generating the ACL information for a given
* file. Note, the string is put into buffer malloc'd by this function.
* It's the responsibility of the caller to free the buffer. This function
* should never return a NULL pointer.
*/
static char *
get_acl_string(const char *fname, const struct stat64 *statb, int *err_code)
{
acl_t *aclp;
char *acltext;
int error;
if (S_ISLNK(statb->st_mode)) {
return (safe_strdup("-"));
}
/*
* Include trivial acl's
*/
error = acl_get(fname, 0, &aclp);
if (error != 0) {
*err_code = WARNING_EXIT;
(void) fprintf(stderr, "%s: %s\n", fname, acl_strerror(error));
return (safe_strdup("-"));
} else {
acltext = acl_totext(aclp, 0);
acl_free(aclp);
if (acltext == NULL)
return (safe_strdup("-"));
else
return (acltext);
}
}
/*
*
* description: This routine reads stdin in BUF_SIZE chunks, uses the bits
* to update the md5 hash buffer, and outputs the chunks
* to stdout. When stdin is exhausted, the hash is computed,
* converted to a hexadecimal string, and returned.
*
* returns: The md5 hash of stdin, or NULL if unsuccessful for any reason.
*/
static int
generate_hash(int fdin, char *hash_str)
{
unsigned char buf[BUF_SIZE];
unsigned char hash[MD5_DIGEST_LENGTH];
int i, amtread;
MD5_CTX ctx;
MD5Init(&ctx);
for (;;) {
amtread = read(fdin, buf, sizeof (buf));
if (amtread == 0)
break;
if (amtread < 0)
return (1);
/* got some data. Now update hash */
MD5Update(&ctx, buf, amtread);
}
/* done passing through data, calculate hash */
MD5Final(hash, &ctx);
for (i = 0; i < MD5_DIGEST_LENGTH; i++)
(void) sprintf(hash_str + (i*2), "%2.2x", hash[i]);
return (0);
}
/*
* Used by 'bart create' with the '-I' option. Return each entry into a 'buf'
* with the appropriate exit code: '0' for success and '-1' for failure.
*/
static int
read_filelist(char *reloc_root, char **argv, char *buf, size_t bufsize)
{
static int argv_index = -1;
static boolean_t read_stdinput = B_FALSE;
char temp_buf[PATH_MAX];
char *cp;
/*
* INITIALIZATION:
* Setup this code so it knows whether or not to read sdtin.
* Also, if reading from argv, setup the index, "argv_index"
*/
if (argv_index == -1) {
argv_index = 0;
/* In this case, no args after '-I', so read stdin */
if (argv[0] == NULL)
read_stdinput = B_TRUE;
}
buf[0] = '\0';
if (read_stdinput) {
if (fgets(temp_buf, PATH_MAX, stdin) == NULL)
return (-1);
cp = strtok(temp_buf, "\n");
} else {
cp = argv[argv_index++];
}
if (cp == NULL)
return (-1);
/*
* Unlike similar code elsewhere, avoid adding a leading
* slash for relative pathnames.
*/
(void) snprintf(buf, bufsize,
(reloc_root[0] == '\0' || cp[0] == '/') ? "%s%s" : "%s/%s",
reloc_root, cp);
return (0);
}